ISOLATED POLYNUCLEOTIDES, POLYPEPTIDES AND METHODS OF USING SAME FOR INCREASING ABIOTIC STRESS TOLERANCE, BIOMASS AND YIELD OF PLANTS

Abstract

Provided are isolated polypeptides which are at least 80% homologous to SEQ ID NOs: 552-897 and 6029-10629, isolated polynucleotides which are at least 80% identical to SEQ ID NOs: 1-551 and 898-6028, nucleic acid constructs comprising same, transgenic cells expressing same, transgenic plants expressing same and method of using same for increasing yield, abiotic stress tolerance, growth rate, biomass, vigor, oil content, photosynthetic capacity, seed yield, fiber yield, fiber quality, fiber length, and/or nitrogen use efficiency of a plant.

Description

FIELD AND BACKGROUND OF THE INVENTION

The present invention, in some embodiments thereof, relates to isolated polypeptides and polynucleotides, nucleic acid constructs comprising same, transgenic cells comprising same, transgenic plants exogenously expressing same and more particularly, but not exclusively, to methods of using same for increasing yield (e.g., seed yield, oil yield), biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, fiber length, photosynthetic capacity, fertilizer use efficiency (e.g., nitrogen use efficiency) and/or abiotic stress tolerance of a plant.

Yield is affected by various factors, such as, the number and size of the plant organs, plant architecture (for example, the number of branches), grains set length, number of filled grains, vigor (e.g. seedling), growth rate, root development, utilization of water, nutrients (e.g., nitrogen) and fertilizers, and stress tolerance.

Crops such as, corn, rice, wheat, canola and soybean account for over half of total human caloric intake, whether through direct consumption of the seeds themselves or through consumption of meat products raised on processed seeds or forage. Seeds are also a source of sugars, proteins and oils and metabolites used in industrial processes. The ability to increase plant yield, whether through increase dry matter accumulation rate, modifying cellulose or lignin composition, increase stalk strength, enlarge meristem size, change of plant branching pattern, erectness of leaves, increase in fertilization efficiency, enhanced seed dry matter accumulation rate, modification of seed development, enhanced seed filling or by increasing the content of oil, starch or protein in the seeds would have many applications in agricultural and non-agricultural uses such as in the biotechnological production of pharmaceuticals, antibodies or vaccines.

Vegetable or seed oils are the major source of energy and nutrition in human and animal diet. They are also used for the production of industrial products, such as paints, inks and lubricants. In addition, plant oils represent renewable sources of long-chain hydrocarbons which can be used as fuel. Since the currently used fossil fuels are finite resources and are gradually being depleted, fast growing biomass crops may be used as alternative fuels or for energy feedstocks and may reduce the dependence on fossil energy supplies. However, the major bottleneck for increasing consumption of plant oils as bio-fuel is the oil price, which is still higher than fossil fuel. In addition, the production rate of plant oil is limited by the availability of agricultural land and water. Thus, increasing plant oil yields from the same growing area can effectively overcome the shortage in production space and can decrease vegetable oil prices at the same time.

Studies aiming at increasing plant oil yields focus on the identification of genes involved in oil metabolism as well as in genes capable of increasing plant and seed yields in transgenic plants. Genes known to be involved in increasing plant oil yields include those participating in fatty acid synthesis or sequestering such as desaturase [e.g., DELTA6, DELTA12 or acyl-ACP (Ssi2; Arabidopsis Information Resource (TAIR; arabidopsis (dot) org/). TAIR No. AT2G43710)], OleosinA (TAIR No. AT3G01570) or FAD3 (TAIR No. AT2G29980), and various transcription factors and activators such as Lecd [TAIR No. AT1G21970, Lotan et al. 1998. Cell. 26; 93(7):1195-205]. Lec2 [TAIR No. AT1G28300. Santos Mendoza et al. 2005, FEBS Lett. 579(21):4666-70]. Fus3 (TAIR No. AT3G26790), ABI3 [TAIR No. AT3G24650, Lara et al. 2003. J Biol Chem. 278(23): 21003-11] and Wril [TAIR No. AT3G54320, Cernac and Benning, 2004. Plant J. 40(4): 575-85].

Genetic engineering efforts aiming at increasing oil content in plants (e.g., in seeds) include upregulating endoplasmic reticulum (FAD3) and plastidal (FAD7) fatty acid desaturases in potato (Zabrouskov V., et al., 2002; Physiol Plant. 116:172-185); over-expressing the GmDof4 and GmDof11 transcription factors (Wang H W et al., 2007; Plant J. 52:716-29); over-expressing a yeast glycerol-3-phosphate dehydrogenase under the control of a seed-specific promoter (Vigeolas H, et al. 2007, Plant Biotechnol J. 5:431-41; U.S. Pat. Appl. No. 20060168684); using Arabidopsis FAE1 and yeast SLC1-1 genes for improvements in erucic acid and oil content in rapeseed (Katavic V. et al., 2000, Biochem Soc Trans. 28:935-7).

Various patent applications disclose genes and proteins which can increase oil content in plants. These include for example, U.S. Pat. Appl. No. 20080076179 (lipid metabolism protein); U.S. Pat. Appl. No. 20060206961 (the Ypr140w polypeptide); U.S. Pat. Appl. No. 20060174373 [triacylglycerols synthesis enhancing protein (TEP)]; U.S. Pat. Appl. Nos. 20070169219, 20070006345, 20070006346 and 20060195943 (disclose transgenic plants with improved nitrogen use efficiency which can be used for the conversion into fuel or chemical feedstocks); WO2008/122980 (polynucleotides for increasing oil content, growth rate, biomass, yield and/or vigor of a plant).

A common approach to promote plant growth has been, and continues to be, the use of natural as well as synthetic nutrients (fertilizers). Thus, fertilizers are the fuel behind the “green revolution”, directly responsible for the exceptional increase in crop yields during the last 40 years, and are considered the number one overhead expense in agriculture. For example, inorganic nitrogenous fertilizers such as ammonium nitrate, potassium nitrate, or urea, typically accounts for 40% of the costs associated with crops such as corn and wheat. Of the three macronutrients provided as main fertilizers [Nitrogen (N). Phosphate (P) and Potassium (K)], nitrogen is often the rate-limiting element in plant growth and all field crops have a fundamental dependence on inorganic nitrogenous fertilizer. Nitrogen is responsible for biosynthesis of amino and nucleic acids, prosthetic groups, plant hormones, plant chemical defenses, etc. and usually needs to be replenished every year, particularly for cereals, which comprise more than half of the cultivated areas worldwide. Thus, nitrogen is translocated to the shoot, where it is stored in the leaves and stalk during the rapid step of plant development and up until flowering. In corn for example, plants accumulate the bulk of their organic nitrogen during the period of grain germination, and until flowering. Once fertilization of the plant has occurred, grains begin to form and become the main sink of plant nitrogen. The stored nitrogen can be then redistributed from the leaves and stalk that served as storage compartments until grain formation.

Since fertilizer is rapidly depleted from most soil types, it must be supplied to growing crops two or three times during the growing season. In addition, the low nitrogen use efficiency (NUE) of the main crops (e.g., in the range of only 30-70%) negatively affects the input expenses for the farmer, due to the excess fertilizer applied. Moreover, the over and inefficient use of fertilizers are major factors responsible for environmental problems such as eutrophication of groundwater, lakes, rivers and seas, nitrate pollution in drinking water which can cause methemoglobinemia, phosphate pollution, atmospheric pollution and the like. However, in spite of the negative impact of fertilizers on the environment, and the limits on fertilizer use, which have been legislated in several countries, the use of fertilizers is expected to increase in order to support food and fiber production for rapid population growth on limited land resources. For example, it has been estimated that by 2050, more than 150 million tons of nitrogenous fertilizer will be used worldwide annually.

Increased use efficiency of nitrogen by plants should enable crops to be cultivated with lower fertilizer input, or alternatively to be cultivated on soils of poorer quality and would therefore have significant economic impact in both developed and developing agricultural systems.

Genetic improvement of fertilizer use efficiency (FUE) in plants can be generated either via traditional breeding or via genetic engineering.

Attempts to generate plants with increased FUE have been described in U.S. Pat. Appl. Publication No. 20020046419 (U.S. Pat. No. 7,262,055 to Choo. et al.); U.S. Pat. Appl. No. 20050108791 to Edgerton et al.; U.S. Pat. Appl. No. 20060179511 to Chomet et al.; Good, A. et al. 2007 (Engineering nitrogen use efficiency with alanine aminotransferase. Canadian Journal of Botany 85: 252-262); and Good A G et al. 2004 (Trends Plant Sci. 9:597-605).

Yanagisawa et al. (Proc. Natl. Acad. Sci. U.S.A. 2004 101:7833-8) describe Dof1 transgenic plants which exhibit improved growth under low-nitrogen conditions.

U.S. Pat. No. 6,084,153 to Good et al. discloses the use of a stress responsive promoter to control the expression of Alanine Amine Transferase (AlaAT) and transgenic canola plants with improved drought and nitrogen deficiency tolerance when compared to control plants.

Abiotic stress (ABS; also referred to as “environmental stress”) conditions such as salinity, drought, flood, suboptimal temperature and toxic chemical pollution, cause substantial damage to agricultural plants. Most plants have evolved strategies to protect themselves against these conditions. However, if the severity and duration of the stress conditions are too great, the effects on plant development, growth and yield of most crop plants are profound. Furthermore, most of the crop plants are highly susceptible to abiotic stress and thus necessitate optimal growth conditions for commercial crop yields. Continuous exposure to stress causes major alterations in the plant metabolism which ultimately leads to cell death and consequently yield losses.

Drought is a gradual phenomenon, which involves periods of abnormally dry weather that persists long enough to produce serious hydrologic imbalances such as crop damage, water supply shortage and increased susceptibility to various diseases. In severe cases, drought can last many years and results in devastating effects on agriculture and water supplies. Furthermore, drought is associated with increase susceptibility to various diseases.

For most crop plants, the land regions of the world are too arid. In addition, overuse of available water results in increased loss of agriculturally-usable land (desertification), and increase of salt accumulation in soils adds to the loss of available water in soils.

Salinity, high salt levels, affects one in five hectares of irrigated land. None of the top five food crops, i.e., wheat, corn, rice, potatoes, and soybean, can tolerate excessive salt. Detrimental effects of salt on plants result from both water deficit, which leads to osmotic stress (similar to drought stress), and the effect of excess sodium ions on critical biochemical processes. As with freezing and drought, high salt causes water deficit; and the presence of high salt makes it difficult for plant roots to extract water from their environment. Soil salinity is thus one of the more important variables that determine whether a plant may thrive. In many parts of the world, sizable land areas are uncultivable due to naturally high soil salinity. Thus, salination of soils that are used for agricultural production is a significant and increasing problem in regions that rely heavily on agriculture, and is worsen by over-utilization, over-fertilization and water shortage, typically caused by climatic change and the demands of increasing population. Salt tolerance is of particular importance early in a plant's lifecycle, since evaporation from the soil surface causes upward water movement, and salt accumulates in the upper soil layer where the seeds are placed. On the other hand, germination normally takes place at a salt concentration which is higher than the mean salt level in the whole soil profile.

Salt and drought stress signal transduction consist of ionic and osmotic homeostasis signaling pathways. The ionic aspect of salt stress is signaled via the SOS pathway where a calcium-responsive SOS3-SOS2 protein kinase complex controls the expression and activity of ion transporters such as SOS1. The osmotic component of salt stress involves complex plant reactions that overlap with drought and/or cold stress responses.

Suboptimal temperatures affect plant growth and development through the whole plant life cycle. Thus, low temperatures reduce germination rate and high temperatures result in leaf necrosis. In addition, mature plants that are exposed to excess of heat may experience heat shock, which may arise in various organs, including leaves and particularly fruit, when transpiration is insufficient to overcome heat stress. Heat also damages cellular structures, including organelles and cytoskeleton, and impairs membrane function. Heat shock may produce a decrease in overall protein synthesis, accompanied by expression of heat shock proteins, e.g., chaperones, which are involved in refolding proteins denatured by heat. High-temperature damage to pollen almost always occurs in conjunction with drought stress, and rarely occurs under well-watered conditions. Combined stress can alter plant metabolism in novel ways. Excessive chilling conditions, e.g., low, but above freezing, temperatures affect crops of tropical origins, such as soybean, rice, maize, and cotton. Typical chilling damage includes wilting, necrosis, chlorosis or leakage of ions from cell membranes. The underlying mechanisms of chilling sensitivity are not completely understood yet, but probably involve the level of membrane saturation and other physiological deficiencies.

Excessive light conditions, which occur under clear atmospheric conditions subsequent to cold late summer/autumn nights, can lead to photoinhibition of photosynthesis (disruption of photosynthesis). In addition, chilling may lead to yield losses and lower product quality through the delayed ripening of maize.

Common aspects of drought, cold and salt stress response [Reviewed in Xiong and Zhu (2002) Plant Cell Environ. 25: 131-139] include: (a) transient changes in the cytoplasmic calcium levels early in the signaling event; (b) signal transduction via mitogen-activated and/or calcium dependent protein kinases (CDPKs) and protein phosphatases; (c) increases in abscisic acid levels in response to stress triggering a subset of responses; (d) inositol phosphates as signal molecules (at least for a subset of the stress responsive transcriptional changes; (e) activation of phospholipases which in turn generates a diverse array of second messenger molecules, some of which might regulate the activity of stress responsive kinases; (f) induction of late embryogenesis abundant (LEA) type genes including the CRT/DRE responsive COR/RD genes; (g) increased levels of antioxidants and compatible osmolytes such as proline and soluble sugars; and (h) accumulation of reactive oxygen species such as superoxide, hydrogen peroxide, and hydroxyl radicals. Abscisic acid biosynthesis is regulated by osmotic stress at multiple steps. Both ABA-dependent and -independent osmotic stress signaling first modify constitutively expressed transcription factors, leading to the expression of early response transcriptional activators, which then activate downstream stress tolerance effector genes.

Several genes which increase tolerance to cold or salt stress can also improve drought stress protection, these include for example, the transcription factor AtCBF/DREB1, OsCDPK7 (Saijo et al. 2000, Plant J. 23: 319-327) or AVPI (a vacuolar pyrophosphatase-proton pump, Gaxiola et al. 2001. Proc. Natl. Acad. Sci. USA 98: 11444-11449).

Studies have shown that plant adaptations to adverse environmental conditions are complex genetic traits with polygenic nature. Conventional means for crop and horticultural improvements utilize selective breeding techniques to identify plants having desirable characteristics. However, selective breeding is tedious, time consuming and has an unpredictable outcome. Furthermore, limited germplasm resources for yield improvement and incompatibility in crosses between distantly related plant species represent significant problems encountered in conventional breeding. Advances in genetic engineering have allowed mankind to modify the germplasm of plants by expression of genes-of-interest in plants. Such a technology has the capacity to generate crops or plants with improved economic, agronomic or horticultural traits.

Genetic engineering efforts, aimed at conferring abiotic stress tolerance to transgenic crops, have been described in various publications [Apse and Blumwald (Curr Opin Biotechnol. 13:146-150, 2002). Quesada et al. (Plant Physiol. 130:951-963, 2002), Holmström et al. (Nature 379: 683-684, 1996). Xu et al. (Plant Physiol 110: 249-257, 1996), Pilon-Smits and Ebskamp (Plant Physiol 107: 125-130, 1995) and Tarczynski et al. (Science 259: 508-510, 1993)].

Various patents and patent applications disclose genes and proteins which can be used for increasing tolerance of plants to abiotic stresses. These include for example, U.S. Pat. Nos. 5,296,462 and 5,356,816 (for increasing tolerance to cold stress); U.S. Pat. No. 6,670,528 (for increasing ABST); U.S. Pat. No. 6,720,477 (for increasing ABST): U.S. application Ser. Nos. 09/938,842 and 10/342,224 (for increasing ABST); U.S. application Ser. No. 10/231,035 (for increasing ABST); WO2004/104162 (for increasing ABST and biomass); WO2007/020638 (for increasing ABST, biomass, vigor and/or yield); WO2007/049275 (for increasing ABST, biomass, vigor and/or yield); WO2010/076756 (for increasing ABST, biomass and/or yield);. WO2009/083958 (for increasing water use efficiency, fertilizer use efficiency, biotic/abiotic stress tolerance, yield and/or biomass); WO2010/020941 (for increasing nitrogen use efficiency, abiotic stress tolerance, yield and/or biomass); WO2009/141824 (for increasing plant utility); WO2010/049897 (for increasing plant yield).

Nutrient deficiencies cause adaptations of the root architecture, particularly notably for example is the root proliferation within nutrient rich patches to increase nutrient uptake. Nutrient deficiencies cause also the activation of plant metabolic pathways which maximize the absorption, assimilation and distribution processes such as by activating architectural changes. Engineering the expression of the triggered genes may cause the plant to exhibit the architectural changes and enhanced metabolism also under other conditions.

In addition, it is widely known that the plants usually respond to water deficiency by creating a deeper root system that allows access to moisture located in deeper soil layers. Triggering this effect will allow the plants to access nutrients and water located in deeper soil horizons particularly those readily dissolved in water like nitrates.

Cotton and cotton by-products provide raw materials that are used to produce a wealth of consumer-based products in addition to textiles including cotton foodstuffs, livestock feed, fertilizer and paper. The production, marketing, consumption and trade of cotton-based products generate an excess of $100 billion annually in the U.S. alone, making cotton the number one value-added crop.

Even though 90% of cotton's value as a crop resides in the fiber (lint), yield and fiber quality has declined due to general erosion in genetic diversity of cotton varieties, and an increased vulnerability of the crop to environmental conditions.

There are many varieties of cotton plant, from which cotton fibers with a range of characteristics can be obtained and used for various applications. Cotton fibers may be characterized according to a variety of properties, some of which are considered highly desirable within the textile industry for the production of increasingly high quality products and optimal exploitation of modem spinning technologies. Commercially desirable properties include length, length uniformity, fineness, maturity ratio, decreased fuzz fiber production, micronaire, bundle strength, and single fiber strength. Much effort has been put into the improvement of the characteristics of cotton fibers mainly focusing on fiber length and fiber fineness. In particular, there is a great demand for cotton fibers of specific lengths.

A cotton fiber is composed of a single cell that has differentiated from an epidermal cell of the seed coat, developing through four stages, i.e., initiation, elongation, secondary cell wall thickening and maturation stages. More specifically, the elongation of a cotton fiber commences in the epidermal cell of the ovule immediately following flowering, after which the cotton fiber rapidly elongates for approximately 21 days. Fiber elongation is then terminated, and a secondary cell wall is formed and grown through maturation to become a mature cotton fiber.

Several candidate genes which are associated with the elongation, formation, quality and yield of cotton fibers were disclosed in various patent applications such as U.S. Pat. No. 5,880,100 and U.S. patent application Ser. Nos. 08/580,545, 08/867,484 and 09/262,653 (describing genes involved in cotton fiber elongation stage); WO0245485 (improving fiber quality by modulating sucrose synthase); U.S. Pat. No. 6,472,588 and WO0117333 (increasing fiber quality by transformation with a DNA encoding sucrose phosphate synthase); WO9508914 (using a fiber-specific promoter and a coding sequence encoding cotton peroxidase); WO9626639 (using an ovary specific promoter sequence to express plant growth modifying hormones in cotton ovule tissue, for altering fiber quality characteristics such as fiber dimension and strength); U.S. Pat. No. 5,981,834, U.S. Pat. No. 5,597,718, U.S. Pat. No. 5,620,882, U.S. Pat. No. 5,521,708 and U.S. Pat. No. 5,495,070 (coding sequences to alter the fiber characteristics of transgenic fiber producing plants); U.S. patent applications U.S. 2002049999 and U.S. 2003074697 (expressing a gene coding for endoxyloglucan transferase, catalase or peroxidase for improving cotton fiber characteristics); WO 01/40250 (improving cotton fiber quality by modulating transcription factor gene expression); WO 96/40924 (a cotton fiber transcriptional initiation regulatory region associated which is expressed in cotton fiber); EP0834566 (a gene which controls the fiber formation mechanism in cotton plant); WO2005/121364 (improving cotton fiber quality by modulating gene expression); WO2008/075364 (improving fiber quality, yield/biomass/vigor and/or abiotic stress tolerance of plants).

WO publication No. 2004/104162 discloses methods of increasing abiotic stress tolerance and/or biomass in plants and plants generated thereby.

WO publication No. 2004/111183 discloses nucleotide sequences for regulating gene expression in plant trichomes and constructs and methods utilizing same.

WO publication No. 2004/081173 discloses novel plant derived regulatory sequences and constructs and methods of using such sequences for directing expression of exogenous polynucleotide sequences in plants.

WO publication No. 2005/121364 discloses polynucleotides and polypeptides involved in plant fiber development and methods of using same for improving fiber quality, yield and/or biomass of a fiber producing plant.

WO publication No. 2007/049275 discloses isolated polypeptides, polynucleotides encoding same, transgenic plants expressing same and methods of using same for increasing fertilizer use efficiency, plant abiotic stress tolerance and biomass.

WO publication No. 2007/020638 discloses methods of increasing abiotic stress tolerance and/or biomass in plants and plants generated thereby.

WO publication No. 2008/122980 discloses genes constructs and methods for increasing oil content, growth rate and biomass of plants.

WO publication No. 2008/075364 discloses polynucleotides involved in plant fiber development and methods of using same.

WO publication No. 2009/083958 discloses methods of increasing water use efficiency, fertilizer use efficiency, biotic/abiotic stress tolerance, yield and biomass in plant and plants generated thereby.

WO publication No. 2009/141824 discloses isolated polynucleotides and methods using same for increasing plant utility.

WO publication No. 2009/013750 discloses genes, constructs and methods of increasing abiotic stress tolerance, biomass and/or yield in plants generated thereby.

WO publication No. 2010/020941 discloses methods of increasing nitrogen use efficiency, abiotic stress tolerance, yield and biomass in plants and plants generated thereby.

WO publication No. 2010/076756 discloses isolated polynucleotides for increasing abiotic stress tolerance, yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, and/or nitrogen use efficiency of a plant.

WO2010/100595 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing plant yield and/or agricultural characteristics.

WO publication No. 2010/049897 discloses isolated polynucleotides and polypeptides and methods of using same for increasing plant yield, biomass, growth rate, vigor, oil content, abiotic stress tolerance of plants and nitrogen use efficiency.

WO2010/143138 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing nitrogen use efficiency, fertilizer use efficiency, yield, growth rate, vigor, biomass, oil content, abiotic stress tolerance and/or water use efficiency

WO publication No. 2011/080674 discloses isolated polynucleotides and polypeptides and methods of using same for increasing plant yield, biomass, growth rate, vigor, oil content, abiotic stress tolerance of plants and nitrogen use efficiency.

WO2011/015985 publication discloses polynucleotides and polypeptides for increasing desirable plant qualities.

WO2011/135527 publication discloses isolated polynucleotides and polypeptides for increasing plant yield and/or agricultural characteristics.

WO2012/028993 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing nitrogen use efficiency, yield, growth rate, vigor, biomass, oil content, and/or abiotic stress tolerance.

WO2012/085862 publication discloses isolated polynucleotides and polypeptides, and methods of using same for improving plant properties.

WO2012/150598 publication discloses isolated polynucleotides and polypeptides and methods of using same for increasing plant yield, biomass, growth rate, vigor, oil content, abiotic stress tolerance of plants and nitrogen use efficiency.

WO2013/027223 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing plant yield and/or agricultural characteristics.

WO2013/080203 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing nitrogen use efficiency, yield, growth rate, vigor, biomass, oil content, and/or abiotic stress tolerance.

WO2013/098819 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing yield of plants.

WO2013/128448 publication discloses isolated polynucleotides and polypeptides and methods of using same for increasing plant yield, biomass, growth rate, vigor, oil content, abiotic stress tolerance of plants and nitrogen use efficiency.

WO 2013/179211 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing plant yield and/or agricultural characteristics.

WO2014/033714 publication discloses isolated polynucleotides, polypeptides and methods of using same for increasing abiotic stress tolerance, biomass and yield of plants.

WO2014/102773 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing nitrogen use efficiency of plants.

WO2014/102774 publication discloses isolated polynucleotides and polypeptides, construct and plants comprising same and methods of using same for increasing nitrogen use efficiency of plants.

WO2014/188428 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing plant yield and/or agricultural characteristics.

WO2015/029031 publication discloses isolated polynucleotides and polypeptides, and methods of using same for increasing plant yield and/or agricultural characteristics.

SUMMARY OF THE INVENTION

According to an aspect of some embodiments of the present invention there is provided a method of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least 80% identical to SEQ ID NO: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629, thereby increasing the yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a method of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629, thereby increasing the yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a method of producing a crop comprising growing a crop plant transformed with an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least 80% homologous to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629, wherein the crop plant is derived from plants which have been transformed with the exogenous polynucleotide and which have been selected for increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and/or increased abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions, and the crop plant having the increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and/or increased abiotic stress tolerance, thereby producing the crop.

According to an aspect of some embodiments of the present invention there is provided a method of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence at least 80% identical to SEQ ID NO: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028, thereby increasing the yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a method of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028, thereby increasing the yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a method of producing a crop comprising growing a crop plant transformed with an exogenous polynucleotide which comprises a nucleic acid sequence which is at least 80% identical to the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028, wherein the crop plant is derived from plants which have been transformed with the exogenous polynucleotide and which have been selected for increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and/or increased abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions, and the crop plant having the increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and/or increased abiotic stress tolerance, thereby producing the crop.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises an amino acid sequence at least 80% homologous to the amino acid sequence set forth in SEQ ID NO: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629, wherein the amino acid sequence is capable of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide comprising a nucleic acid sequence at least 80% identical to SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 or 6028, wherein the nucleic acid sequence is capable of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide comprising the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

According to an aspect of some embodiments of the present invention there is provided a nucleic acid construct comprising the isolated polynucleotide of some embodiments of the invention, and a promoter for directing transcription of the nucleic acid sequence in a host cell.

According to an aspect of some embodiments of the present invention there is provided an isolated polypeptide comprising an amino acid sequence at least 80% homologous to SEQ ID NO: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629, wherein the amino acid sequence is capable of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant.

According to an aspect of some embodiments of the present invention there is provided an isolated polypeptide comprising the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to an aspect of some embodiments of the present invention there is provided a plant cell exogenously expressing the polynucleotide of some embodiments of the invention, or the nucleic acid construct of some embodiments of the invention.

According to an aspect of some embodiments of the present invention there is provided a plant cell exogenously expressing the polypeptide of some embodiments of the invention.

According to an aspect of some embodiments of the present invention there is provided a transgenic plant comprising the nucleic acid construct of some embodiments of the invention, or the plant cell of some embodiments of the invention.

According to an aspect of some embodiments of the present invention there is provided a method of growing a crop, the method comprising seeding seeds and/or planting plantlets of a plant transformed with the isolated polynucleotide of some embodiments of the invention, or with the nucleic acid construct of some embodiments of the invention, wherein the plant is derived from plants which have been transformed with the exogenous polynucleotide and which have been selected for at least one trait selected from the group consisting of: increased nitrogen use efficiency, increased abiotic stress tolerance, increased biomass, increased growth rate, increased vigor, increased yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and increased oil content as compared to a non-transformed plant, thereby growing the crop.

According to an aspect of some embodiments of the present invention there is provided a method of selecting a transformed plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions, the method comprising:

(a) providing plants transformed with an exogenous polynucleotide encoding a polypeptide comprising an amino acid sequence at least 80% homologous to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629,

(b) selecting from the plants of step (a) a plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions,

thereby selecting the plant having the increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to the wild type plant of the same species which is grown under the same growth conditions.

According to an aspect of some embodiments of the present invention there is provided a method of selecting a transformed plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions, the method comprising:

(a) providing plants transformed with an exogenous polynucleotide at least 80% identical to the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028,

(b) selecting from the plants of step (a) a plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions,

thereby selecting the plant having the increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to the wild type plant of the same species which is grown under the same growth conditions.

According to some embodiments of the invention, the nucleic acid sequence encodes an amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to some embodiments of the invention, the nucleic acid sequence is selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

According to some embodiments of the invention, the polynucleotide consists of the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

According to some embodiments of the invention, the nucleic acid sequence encodes the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to some embodiments of the invention, the plant cell forms part of a plant.

According to some embodiments of the invention, the method further comprising growing the plant expressing the exogenous polynucleotide under the abiotic stress.

According to some embodiments of the invention, the abiotic stress is selected from the group consisting of salinity, drought, osmotic stress, water deprivation, flood, etiolation, low temperature, high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency, nitrogen deficiency, nutrient excess, atmospheric pollution and UV irradiation.

According to some embodiments of the invention, the yield comprises seed yield or oil yield.

According to some embodiments of the invention, the method further comprising growing the plant expressing the exogenous polynucleotide under nitrogen-limiting conditions.

According to some embodiments of the invention, the promoter is heterologous to the isolated polynucleotide and/or to the host cell.

According to some embodiments of the invention, the non-transformed plant is a wild type plant of identical genetic background.

According to some embodiments of the invention, the non-transformed plant is a wild type plant of the same species.

According to some embodiments of the invention, the non-transformed plant is grown under identical growth conditions.

According to some embodiments of the invention, the method further comprising selecting a plant having an increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to the wild type plant of the same species which is grown under the same growth conditions.

According to some embodiments of the invention, selecting is performed under non-stress conditions.

According to some embodiments of the invention, selecting is performed under abiotic stress conditions.

Unless otherwise defined, all technical and/or scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the invention pertains. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of embodiments of the invention, exemplary methods and/or materials are described below. In case of conflict, the patent specification, including definitions, will control. In addition, the materials, methods, and examples are illustrative only and are not intended to be necessarily limiting.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Some embodiments of the invention are herein described, by way of example only, with reference to the accompanying drawings. With specific reference now to the drawings in detail, it is stressed that the particulars shown are by way of example and for purposes of illustrative discussion of embodiments of the invention. In this regard, the description taken with the drawings makes apparent to those skilled in the art how embodiments of the invention may be practiced.

In the drawings:

FIG. 1 is a schematic illustration of the modified pGI binary plasmid containing the new At6669 promoter (SEQ ID NO: 10654) and the GUSintron (pQYN 6669) used for expressing the isolated polynucleotide sequences of the invention. RB—T-DNA right border; LB—T-DNA left border; MCS→Multiple cloning site; RE—any restriction enzyme; NOS pro=nopaline synthase promoter, NPT-II=neomycin phosphotransferase gene; NOS ter=nopaline synthase terminator; Poly-A signal (polyadenylation signal); GUSintron—the GUS reporter gene (coding sequence and intron). The isolated polynucleotide sequences of the invention were cloned into the vector while replacing the GUSintron reporter gene.

FIG. 2 is a schematic illustration of the modified pGI binary plasmid containing the new At6669 promoter (SEQ ID NO: 10654) (pQFN or pQFNc or pQsFN) used for expressing the isolated polynucleotide sequences of the invention. RB—T-DNA right border, LB—T-DNA left border; MCS—Multiple cloning site; RE—any restriction enzyme; NOS pro=nopaline synthase promoter; NPT-II=neomycin phosphotransferase gene; NOS ter=nopaline synthase terminator; Poly-A signal (polyadenylation signal); The isolated polynucleotide sequences of the invention were cloned into the MCS of the vector.

FIGS. 3A-F are images depicting visualization of root development of transgenic plants exogenously expressing the polynucleotide of some embodiments of the invention when grown in transparent agar plates under normal (FIGS. 3A-B), osmotic stress (15% PEG; FIGS. 3C-D) or nitrogen-limiting (FIGS. 3E-F) conditions. The different transgenes were grown in transparent agar plates for 17 days (7 days nursery and 10 days after transplanting). The plates were photographed every 3-4 days starting at day 1 after transplanting. FIG. 3A—An image of a photograph of plants taken following 10 after transplanting days on agar plates when grown under normal (standard) conditions. FIG. 3B—An image of root analysis of the plants shown in FIG. 3A in which the lengths of the roots measured are represented by arrows. FIG. 3C—An image of a photograph of plants taken following 10 days after transplanting on agar plates, grown under high osmotic (PEG 15%) conditions. FIG. 3D—An image of root analysis of the plants shown in FIG. 3C in which the lengths of the roots measured are represented by arrows. FIG. 3E—An image of a photograph of plants taken following 10 days after transplanting on agar plates, grown under low nitrogen conditions. FIG. 3F—An image of root analysis of the plants shown in FIG. 3E in which the lengths of the roots measured are represented by arrows.

FIG. 4 is a schematic illustration of the modified pGI binary plasmid containing the Root Promoter (pQNa RP) used for expressing the isolated polynucleotide sequences of the invention. RB—T-DNA right border; LB—T-DNA left border; NOS pro=nopaline synthase promoter; NPT-II=neomycin phosphotransferase gene; NOS ter=nopaline synthase terminator; Poly-A signal (polyadenylation signal); The isolated polynucleotide sequences according to some embodiments of the invention were cloned into the MCS (Multiple cloning site) of the vector.

FIG. 5 is a schematic illustration of the pQYN plasmid.

FIG. 6 is a schematic illustration of the pQFN plasmid.

FIG. 7 is a schematic illustration of the pQFYN plasmid.

FIG. 8 is a schematic illustration of the modified pGI binary plasmid (pQXNc) used for expressing the isolated polynucleotide sequences of some embodiments of the invention. RB—T-DNA right border; LB—T-DNA left border; NOS pro=nopaline synthase promoter; NPT-II=neomycin phosphotransferase gene; NOS ter=nopaline synthase terminator; RE=any restriction enzyme; Poly-A signal (polyadenylation signal); 35S—the 35S promoter (pQXNc); SEQ ID NO: 10650). The isolated polynucleotide sequences of some embodiments of the invention were cloned into the MCS (Multiple cloning site) of the vector.

FIGS. 9A-B are schematic illustrations of the pEBbVNi tDNA (FIG. 9A) and the pEBbNi tDNA (FIG. 9B) plasmids used in the Brachypodium experiments, pEBbVNi tDNA (FIG. 9A) was used for expression of the isolated polynucleotide sequences of some embodiments of the invention in Brachypodium. pEBbNi tDNA (FIG. 9B) was used for transformation into Brachypodium as a negative control. “RB”=right border; “2LBregion”=2 repeats of left border; “35S”=35S promoter (SEQ ID NO: 10666 in FIG. 9A); “Ubiquitin promoter (SEQ ID NO: 10640 in both of FIGS. 9A and 9B; “NOS ter”=nopaline synthase terminator, “Bar ORF”—BAR open reading frame (GenBank Accession No. JQ293091.1; SEQ ID NO: 10667); The isolated polynucleotide sequences of some embodiments of the invention were cloned into the Multiple cloning site of the vector using one or more of the indicated restriction enzyme sites.

FIG. 10 depicts seedling analysis of an Arabidopsis plant having shoots (upper part, marked “#1”) and roots (lower part, marked “#2”). Using an image analysis system the minimal convex area encompassed by the roots is determined. Such area corresponds to the root coverage of the plant.

FIG. 11 is a schematic illustration of the pQ6sVN plasmid. pQ6sVN was used for expression of the isolated polynucleotide sequences of some embodiments of the invention in Brachypodium. “35S(V)”=35S promoter (SEQ ID NO: 10666); “NOS ter”=nopaline synthase terminator, “Bar_GA”=BAR open reading frame optimized for expression in Brachypodium (SEQ ID NO: 11335); “Hygro”=Hygromycin resistance gene. “Ubi1 promoter”=10640; The isolated polynucleotide sequences of some embodiments of the invention were cloned into the Multiple cloning site of the vector (downstream of the “35S(V)” promoter) using one or more of the indicated restriction enzyme sites.

FIG. 12 is a schematic illustration of the pQsFN plasmid containing the new At6669 promoter (SEQ ID NO: 10654) used for expression the isolated polynucleotide sequences of the invention in Arabidopsis. RB—T-DNA right border, LB—T-DNA left border, MCS—Multiple cloning site; RE—any restriction enzyme; NOS pro=nopaline synthase promoter; NPT-II=neomycin phosphotransferase gene; NOS ter=nopaline synthase terminator; Poly-A signal (polyadenylation signal); The isolated polynucleotide sequences of the invention were cloned into the MCS of the vector.

FIG. 13 is schematic illustration pQ6sN plasmid, which is used as a negative control (“empty vector”) of the experiments performed when the plants were transformed with the pQ6sVN vector. “Ubi1” promoter (SEQ ID NO: 10640); NOS ter=nopaline synthase terminator, “Bar_GA”=BAR open reading frame optimized for expression in Brachypodium (SEQ ID NO: 11335).

DESCRIPTION OF SPECIFIC EMBODIMENTS OF THE INVENTION

The present invention, in some embodiments thereof, relates to isolated polynucleotides and polypeptides, nucleic acid constructs, transgenic cells and transgenic plants comprising same and methods of generating and using same, and, more particularly, but not exclusively, to methods of increasing yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality abiotic stress tolerance, and/or fertilizer use efficiency (e.g., nitrogen use efficiency) of a plant.

Before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not necessarily limited in its application to the details set forth in the following description or exemplified by the Examples. The invention is capable of other embodiments or of being practiced or carried out in various ways.

The present inventors have identified novel polypeptides and polynucleotides which can be used to generate nucleic acid constructs, transgenic plants and to increase nitrogen use efficiency, fertilizer use efficiency, yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance and/or water use efficiency of a plant, such as a wheat plant.

Thus, as shown in the Examples section which follows, the present inventors have utilized bioinformatics tools to identify polynucleotides which enhance/increase fertilizer use efficiency (e.g., nitrogen use efficiency), yield (e.g., seed yield, oil yield, oil content), growth rate, biomass, vigor, fiber yield, fiber quality, fiber length, photosynthetic capacity, and/or abiotic stress tolerance of a plant. Genes which affect the trait-of-interest were identified [SEQ ID NOs: 552-897 (for polypeptides); and SEQ ID NOs: 1-551 (for polynucleotides)] based on expression profiles of genes of several Arabidopsis, Barley, Sorghum, Maize, Brachypodium, soybean, cotton, Bean, wheat, tomato, and Foxtail millet ecotypes and accessions in various tissues and growth conditions, homology with genes known to affect the trait-of-interest and using digital expression profile in specific tissues and conditions (Tables 1-232, Examples 1, and 3-24 of the Examples section which follows). Homologous (e.g., orthologous) polypeptides and polynucleotides having the same function in increasing fertilizer use efficiency (e.g., nitrogen use efficiency), yield (e.g., seed yield, oil yield, oil content), growth rate, biomass, vigor, fiber yield, fiber quality, fiber length, photosynthetic capacity, and/or abiotic stress tolerance of a plant were also identified [SEQ ID NOs: 6029-10629 (for polypeptides), and SEQ ID NOs: 898-6028 (for polynucleotides); Table 2, Example 2 of the Examples section which follows]. The polynucleotides of some embodiments of the invention were cloned into binary vectors (Examples 25-26, Table 233), and were further transformed into Arabidopsis and Brachypodium plants (Examples 27-28). Transgenic plants over-expressing the identified polynucleotides were found to exhibit increased biomass, growth rate, vigor and yield under normal growth conditions, nitrogen limiting growth conditions or abiotic stress conditions (Tables 234-275; Examples 29-33) as compared to control plants grown under the same growth conditions. Altogether, these results suggest the use of the novel polynucleotides and polypeptides of the invention (e.g., SEQ ID NOs: 552-897 and 6029-10629; and SEQ ID NOs: 1-551 and 898-6028) for increasing nitrogen use efficiency, fertilizer use efficiency, yield (e.g., oil yield, seed yield and oil content), growth rate, biomass, vigor, fiber yield, fiber quality, fiber length, photosynthetic capacity, water use efficiency and/or abiotic stress tolerance of a plant.

Thus, according to an aspect of some embodiments of the invention, there is provided method of increasing oil content, yield, growth rate, biomass, vigor, fiber yield, fiber quality, fiber length, photosynthetic capacity, fertilizer use efficiency (e.g., nitrogen use efficiency) and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous (e.g., identical) to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-897 and 6029-10629, e.g., using an exogenous polynucleotide which is at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% identical to the polynucleotide selected from the group consisting of SEQ ID NOs: 1-551 and 898-6028, thereby increasing the oil content, yield, growth rate, biomass, vigor, fiber yield, fiber quality, fiber length, photosynthetic capacity, fertilizer use efficiency (e.g., nitrogen use efficiency) and/or abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the invention, there is provided method of increasing oil content, yield, growth rate, biomass, vigor, fiber yield, fiber quality, fiber length, photosynthetic capacity, fertilizer use efficiency (e.g., nitrogen use efficiency) and/or abiotic stress tolerance of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629, thereby increasing the oil content, yield, growth rate, biomass, vigor, fiber yield, fiber quality, fiber length, photosynthetic capacity, fertilizer use efficiency (e.g., nitrogen use efficiency) and/or abiotic stress tolerance of the plant.

As used herein the phrase “plant yield” refers to the amount (e.g., as determined by weight or size) or quantity (numbers) of tissues or organs produced per plant or per growing season. Hence increased yield could affect the economic benefit one can obtain from the plant in a certain growing area and/or growing time.

It should be noted that a plant yield can be affected by various parameters including, but not limited to, plant biomass; plant vigor; growth rate; seed yield; seed or grain quantity; seed or grain quality; oil yield; content of oil, starch and/or protein in harvested organs (e.g., seeds or vegetative parts of the plant); number of flowers (florets) per panicle (expressed as a ratio of number of filled seeds over number of primary panicles); harvest index; number of plants grown per area; number and size of harvested organs per plant and per area; number of plants per growing area (density); number of harvested organs in field; total leaf area; carbon assimilation and carbon partitioning (the distribution/allocation of carbon within the plant); resistance to shade; number of harvestable organs (e.g. seeds), seeds per pod, weight per seed; and modified architecture [such as increase stalk diameter, thickness or improvement of physical properties (e.g. elasticity)].

As used herein the phrase “seed yield” refers to the number or weight of the seeds per plant, seeds per pod, or per growing area or to the weight of a single seed, or to the oil extracted per seed. Hence seed yield can be affected by seed dimensions (e.g., length, width, perimeter, area and/or volume), number of (filled) seeds and seed filling rate and by seed oil content. Hence increase seed yield per plant could affect the economic benefit one can obtain from the plant in a certain growing area and/or growing time; and increase seed yield per growing area could be achieved by increasing seed yield per plant, and/or by increasing number of plants grown on the same given area.

The term “seed” (also referred to as “grain” or “kernel”) as used herein refers to a small embryonic plant enclosed in a covering called the seed coat (usually with some stored food), the product of the ripened ovule of gymnosperm and angiosperm plants which occurs after fertilization and some growth within the mother plant.

The phrase “oil content” as used herein refers to the amount of lipids in a given plant organ, either the seeds (seed oil content) or the vegetative portion of the plant (vegetative oil content) and is typically expressed as percentage of dry weight (10% humidity of seeds) or wet weight (for vegetative portion).

It should be noted that oil content is affected by intrinsic oil production of a tissue (e.g., seed, vegetative portion), as well as the mass or size of the oil-producing tissue per plant or per growth period.

In one embodiment, increase in oil content of the plant can be achieved by increasing the size/mass of a plant's tissue(s) which comprise oil per growth period. Thus, increased oil content of a plant can be achieved by increasing the yield, growth rate, biomass and vigor of the plant.

As used herein the phrase “plant biomass” refers to the amount (e.g., measured in grams of air-dry tissue) of a tissue produced from the plant in a growing season, which could also determine or affect the plant yield or the yield per growing area. An increase in plant biomass can be in the whole plant or in parts thereof such as aboveground (harvestable) parts, vegetative biomass, roots and seeds.

As used herein the term “root biomass” refers to the total weight of the plant's root(s). Root biomass can be determined directly by weighing the total root material (fresh and/or dry weight) of a plant.

Additional or alternatively, the root biomass can be indirectly determined by measuring root coverage, root density and/or root length of a plant.

It should be noted that plants having a larger root coverage exhibit higher fertilizer (e.g., nitrogen) use efficiency and/or higher water use efficiency as compared to plants with a smaller root coverage.

As used herein the phrase “root coverage” refers to the total area or volume of soil or of any plant-growing medium encompassed by the roots of a plant.

According to some embodiments of the invention, the root coverage is the minimal convex volume encompassed by the roots of the plant.

It should be noted that since each plant has a characteristic root system, e.g., some plants exhibit a shallow root system (e.g., only a few centimeters below ground level), while others have a deep in soil root system (e.g., a few tens of centimeters or a few meters deep in soil below ground level), measuring the root coverage of a plant can be performed in any depth of the soil or of the plant-growing medium, and comparison of root coverage between plants of the same species (e.g., a transgenic plant exogenously expressing the polynucleotide of some embodiments of the invention and a control plant) should be performed by measuring the root coverage in the same depth.

According to some embodiments of the invention, the root coverage is the minimal convex area encompassed by the roots of a plant in a specific depth.

A non-limiting example of measuring root coverage is shown in FIG. 10.

As used herein the term “root density” refers to the density of roots in a given area (e.g., area of soil or any plant growing medium). The root density can be determined by counting the root number per a predetermined area at a predetermined depth (in units of root number per area, e.g., mm², cm² or m²).

As used herein the phrase “root length” refers to the total length of the longest root of a single plant.

As used herein the phrase “root length growth rate” refers to the change in total root length per plant per time unit (e.g., per day).

As used herein the phrase “growth rate” refers to the increase in plant organ/tissue size per time (can be measured in cm² per day or cm/day).

As used herein the phrase “photosynthetic capacity” (also known as “A_max”) is a measure of the maximum rate at which leaves are able to fix carbon during photosynthesis. It is typically measured as the amount of carbon dioxide that is fixed per square meter per second, for example as μmol m⁻² sec⁻¹. Plants are able to increase their photosynthetic capacity by several modes of action, such as by increasing the total leaves area (e.g., by increase of leaves area, increase in the number of leaves, and increase in plant's vigor, e.g., the ability of the plant to grow new leaves along time course) as well as by increasing the ability of the plant to efficiently execute carbon fixation in the leaves. Hence, the increase in total leaves area can be used as a reliable measurement parameter for photosynthetic capacity increment.

As used herein the phrase “plant vigor” refers to the amount (measured by weight) of tissue produced by the plant in a given time. Hence increased vigor could determine or affect the plant yield or the yield per growing time or growing area. In addition, early vigor (seed and/or seedling) results in improved field stand.

Improving early vigor is an important objective of modern rice breeding programs in both temperate and tropical rice cultivars. Long roots are important for proper soil anchorage in water-seeded rice. Where rice is sown directly into flooded fields, and where plants must emerge rapidly through water, longer shoots are associated with vigour. Where drill-seeding is practiced, longer mesocotyls and coleoptiles are important for good seedling emergence. The ability to engineer early vigor into plants would be of great importance in agriculture. For example, poor early vigor has been a limitation to the introduction of maize (Zea mays L.) hybrids based on Corn Belt germplasm in the European Atlantic.

It should be noted that a plant trait such as yield, growth rate, biomass, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, fertilizer use efficiency (e.g., nitrogen use efficiency) can be determined under stress (e.g., abiotic stress, nitrogen-limiting conditions) and/or non-stress (normal) conditions.

As used herein, the phrase “non-stress conditions” refers to the growth conditions (e.g., water, temperature, light-dark cycles, humidity, salt concentration, fertilizer concentration in soil, nutrient supply such as nitrogen, phosphorous and/or potassium), that do not significantly go beyond the everyday climatic and other abiotic conditions that plants may encounter, and which allow optimal growth, metabolism, reproduction and/or viability of a plant at any stage in its life cycle (e.g., in a crop plant from seed to a mature plant and back to seed again). Persons skilled in the art are aware of normal soil conditions and climatic conditions for a given plant in a given geographic location. It should be noted that while the non-stress conditions may include some mild variations from the optimal conditions (which vary from one type/species of a plant to another), such variations do not cause the plant to cease growing without the capacity to resume growth.

Following is a non-limiting description of non-stress (normal) growth conditions which can be used for growing the transgenic plants expressing the polynucleotides or polypeptides of some embodiments of the invention.

For example, normal conditions for growing sorghum include irrigation with about 452,000 liter water per dunam (1000 square meters) and fertilization with about 14 units nitrogen per dunam per growing season.

Normal conditions for growing cotton include irrigation with about 580,000 liter water per dunam (1000 square meters) and fertilization with about 24 units nitrogen per dunam per growing season.

Normal conditions for growing bean include irrigation with about 524,000 liter water per dunam (1000 square meters) and fertilization with about 16 units nitrogen per dunam per growing season.

Normal conditions for growing B. Juncea include irrigation with about 861,000 liter water per dunam (1000 square meters) and fertilization with about 12 units nitrogen per dunam per growing season.

The phrase “abiotic stress” as used herein refers to any adverse effect on metabolism, growth, reproduction and/or viability of a plant. Accordingly, abiotic stress can be induced by suboptimal environmental growth conditions such as, for example, salinity, osmotic stress, water deprivation, drought, flooding, freezing, low or high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency (e.g., nitrogen deficiency or limited nitrogen), atmospheric pollution or UV irradiation. The implications of abiotic stress are discussed in the Background section.

The phrase “abiotic stress tolerance” as used herein refers to the ability of a plant to endure an abiotic stress without suffering a substantial alteration in metabolism, growth, productivity and/or viability.

Plants are subject to a range of environmental challenges. Several of these, including salt stress, general osmotic stress, drought stress and freezing stress, have the ability to impact whole plant and cellular water availability. Not surprisingly, then, plant responses to this collection of stresses are related. Zhu (2002) Ann. Rev. Plant Biol. 53: 247-273 et al. note that “most studies on water stress signaling have focused on salt stress primarily because plant responses to salt and drought are closely related and the mechanisms overlap”. Many examples of similar responses and pathways to this set of stresses have been documented. For example, the CBF transcription factors have been shown to condition resistance to salt, freezing and drought (Kasuga et al. (1999) Nature Biotech. 17: 287-291). The Arabidopsis rd29B gene is induced in response to both salt and dehydration stress, a process that is mediated largely through an ABA signal transduction process (Uno et al. (2000) Proc. Natl. Acad. Sci. USA 97: 11632-11637), resulting in altered activity of transcription factors that bind to an upstream element within the rd29B promoter. In Mesembryanthemum crystallinum (ice plant), Patharker and Cushman have shown that a calcium-dependent protein kinase (McCDPK1) is induced by exposure to both drought and salt stresses (Patharker and Cushman (2000) Plant J. 24: 679-691). The stress-induced kinase was also shown to phosphorylate a transcription factor, presumably altering its activity, although transcript levels of the target transcription factor are not altered in response to salt or drought stress. Similarly. Saijo et al. demonstrated that a rice salt/drought-induced calmodulin-dependent protein kinase (OsCDPK7) conferred increased salt and drought tolerance to rice when overexpressed (Saijo et al. (2000) Plant J. 23: 319-327).

Exposure to dehydration invokes similar survival strategies in plants as does freezing stress (see, for example, Yelenosky (1989) Plant Physiol 89: 444-451) and drought stress induces freezing tolerance (see, for example, Siminovitch et al. (1982) Plant Physiol 69: 250-255; and Guy et al. (1992) Planta 188: 265-270). In addition to the induction of cold-acclimation proteins, strategies that allow plants to survive in low water conditions may include, for example, reduced surface area, or surface oil or wax production. In another example increased solute content of the plant prevents evaporation and water loss due to heat, drought, salinity, osmoticum, and the like therefore providing a better plant tolerance to the above stresses.

It will be appreciated that some pathways involved in resistance to one stress (as described above), will also be involved in resistance to other stresses, regulated by the same or homologous genes. Of course, the overall resistance pathways are related, not identical, and therefore not all genes controlling resistance to one stress will control resistance to the other stresses. Nonetheless, if a gene conditions resistance to one of these stresses, it would be apparent to one skilled in the art to test for resistance to these related stresses. Methods of assessing stress resistance are further provided in the Examples section which follows.

As used herein the phrase “water use efficiency (WUE)” refers to the level of organic matter produced per unit of water consumed by the plant, i.e., the dry weight of a plant in relation to the plant's water use, e.g., the biomass produced per unit transpiration.

As used herein the phrase “fertilizer use efficiency” refers to the metabolic process(es) which lead to an increase in the plant's yield, biomass, vigor, and growth rate per fertilizer unit applied. The metabolic process can be the uptake, spread, absorbent, accumulation, relocation (within the plant) and use of one or more of the minerals and organic moieties absorbed by the plant, such as nitrogen, phosphates and/or potassium.

As used herein the phrase “fertilizer-limiting conditions” refers to growth conditions which include a level (e.g., concentration) of a fertilizer applied which is below the level needed for normal plant metabolism, growth, reproduction and/or viability.

As used herein the phrase “nitrogen use efficiency (NUE)” refers to the metabolic process(es) which lead to an increase in the plant's yield, biomass, vigor, and growth rate per nitrogen unit applied. The metabolic process can be the uptake, spread, absorbent, accumulation, relocation (within the plant) and use of nitrogen absorbed by the plant.

As used herein the phrase “nitrogen-limiting conditions” refers to growth conditions which include a level (e.g., concentration) of nitrogen (e.g., ammonium or nitrate) applied which is below the level needed for normal plant metabolism, growth, reproduction and/or viability.

Improved plant NUE and FUE is translated in the field into either harvesting similar quantities of yield, while implementing less fertilizers, or increased yields gained by implementing the same levels of fertilizers. Thus, improved NUE or FUE has a direct effect on plant yield in the field. Thus, the polynucleotides and polypeptides of some embodiments of the invention positively affect plant yield, seed yield, and plant biomass. In addition, the benefit of improved plant NUE will certainly improve crop quality and biochemical constituents of the seed such as protein yield and oil yield.

It should be noted that improved ABST will confer plants with improved vigor also under non-stress conditions, resulting in crops having improved biomass and/or yield e.g., elongated fibers for the cotton industry, higher oil content.

The term “fiber” is usually inclusive of thick-walled conducting cells such as vessels and tracheids and to fibrillar aggregates of many individual fiber cells. Hence, the term “fiber” refers to (a) thick-walled conducting and non-conducting cells of the xylem; (b) fibers of extraxylary origin, including those from phloem, bark, ground tissue, and epidermis; and (c) fibers from stems, leaves, roots, seeds, and flowers or inflorescences (such as those of Sorghum vulgare used in the manufacture of brushes and brooms).

Example of fiber producing plants, include, but are not limited to, agricultural crops such as cotton, silk cotton tree (Kapok. Ceiba pentandra), desert willow, creosote bush, winterfat, balsa, kenaf, roselle, jute, sisal abaca, flax, corn, sugar cane, hemp, ramie, kapok, coir, bamboo, spanish moss and Agave spp. (e.g. sisal).

As used herein the phrase “fiber quality” refers to at least one fiber parameter which is agriculturally desired, or required in the fiber industry (further described hereinbelow). Examples of such parameters, include but are not limited to, fiber length, fiber strength, fiber fitness, fiber weight per unit length, maturity ratio and uniformity (further described hereinbelow).

Cotton fiber (lint) quality is typically measured according to fiber length, strength and fineness. Accordingly, the lint quality is considered higher when the fiber is longer, stronger and finer.

As used herein the phrase “fiber yield” refers to the amount or quantity of fibers produced from the fiber producing plant.

As mentioned hereinabove, transgenic plants of the present invention can be used for improving myriad of commercially desired traits which are all interrelated as is discussed hereinbelow.

As used herein the term “trait” refers to a characteristic or quality of a plant which may overall (either directly or indirectly) improve the commercial value of the plant.

As used herein the term “increasing” refers to at least about 2%, at least about 3%, at least about 4%, at least about 5%, at least about 10%, at least about 15%, at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, increase in the trait [e.g., yield, seed yield, oil yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency)] of a plant as compared to a native plant or a wild type plant [i.e., a plant not modified with the biomolecules (polynucleotide or polypeptides) of the invention, e.g., a non-transformed plant of the same species which is grown under the same (e.g., identical) growth conditions].

The phrase “expressing within the plant an exogenous polynucleotide” as used herein refers to upregulating the expression level of an exogenous polynucleotide within the plant by introducing the exogenous polynucleotide into a plant cell or plant and expressing by recombinant means, as further described herein below.

As used herein “expressing” refers to expression at the mRNA and optionally polypeptide level.

As used herein, the phrase “exogenous polynucleotide” refers to a heterologous nucleic acid sequence which may not be naturally expressed within the plant (e.g., a nucleic acid sequence from a different species) or which overexpression in the plant is desired. The exogenous polynucleotide may be introduced into the plant in a stable or transient manner, so as to produce a ribonucleic acid (RNA) molecule and/or a polypeptide molecule. It should be noted that the exogenous polynucleotide may comprise a nucleic acid sequence which is identical or partially homologous to an endogenous nucleic acid sequence of the plant.

The term “endogenous” as used herein refers to any polynucleotide or polypeptide which is present and/or naturally expressed within a plant or a cell thereof.

According to some embodiments of the invention, the exogenous polynucleotide of the invention comprises a nucleic acid sequence encoding a polypeptide having an amino acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous (e.g., identical) to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629.

Homologous sequences include both orthologous and paralogous sequences. The term “paralogous” relates to gene-duplications within the genome of a species leading to paralogous genes. The term “orthologous” relates to homologous genes in different organisms due to ancestral relationship. Thus, orthologs are evolutionary counterparts derived from a single ancestral gene in the last common ancestor of given two species (Koonin E V and Galperin M Y (Sequence-Evolution-Function: Computational Approaches in Comparative Genomics. Boston: Kluwer Academic; 2003. Chapter 2. Evolutionary Concept in Genetics and Genomics. Available from: ncbi (dot) nlm (dot) nih (dot) gov/books/NBK20255) and therefore have great likelihood of having the same function.

One option to identify orthologues in monocot plant species is by performing a reciprocal blast search. This may be done by a first blast involving blasting the sequence-of-interest against any sequence database, such as the publicly available NCBI database which may be found at; ncbi (dot) nlm (dot) nih (dot) gov. If orthologues in rice were sought, the sequence-of-interest would be blasted against, for example, the 28,469 full-length cDNA clones from Oryza sativa Nipponbare available at NCBI. The blast results may be filtered. The full-length sequences of either the filtered results or the non-filtered results are then blasted back (second blast) against the sequences of the organism from which the sequence-of-interest is derived. The results of the first and second blasts are then compared. An orthologue is identified when the sequence resulting in the highest score (best hit) in the first blast identifies in the second blast the query sequence (the original sequence-of-interest) as the best hit. Using the same rational a paralogue (homolog to a gene in the same organism) is found. In case of large sequence families, the ClustalW program may be used [ebi (dot) ac (dot) uk/Tools/clustalw2/index (dot) html], followed by a neighbor-joining tree (wikipedia (dot) org/wiki/Neighbor-joining) which helps visualizing the clustering.

Homology (e.g., percent homology, sequence identity+sequence similarity) can be determined using any homology comparison software computing a pairwise sequence alignment.

As used herein. “sequence identity” or “identity” in the context of two nucleic acid or polypeptide sequences includes reference to the residues in the two sequences which are the same when aligned. When percentage of sequence identity is used in reference to proteins it is recognized that residue positions which are not identical often differ by conservative amino acid substitutions, where amino acid residues are substituted for other amino acid residues with similar chemical properties (e.g. charge or hydrophobicity) and therefore do not change the functional properties of the molecule. Where sequences differ in conservative substitutions, the percent sequence identity may be adjusted upwards to correct for the conservative nature of the substitution. Sequences which differ by such conservative substitutions are considered to have “sequence similarity” or “similarity”. Means for making this adjustment are well-known to those of skill in the art. Typically this involves scoring a conservative substitution as a partial rather than a full mismatch, thereby increasing the percentage sequence identity. Thus, for example, where an identical amino acid is given a score of 1 and a non-conservative substitution is given a score of zero, a conservative substitution is given a score between zero and 1. The scoring of conservative substitutions is calculated, e.g., according to the algorithm of Henikoff S and Henikoff J G. [Amino acid substitution matrices from protein blocks. Proc. Natl. Acad. Sci. U.S.A. 1992, 89(22): 10915-9].

Identity (e.g., percent homology) can be determined using any homology comparison software, including for example, the BlastN software of the National Center of Biotechnology Information (NCBI) such as by using default parameters.

According to some embodiments of the invention, the identity is a global identity, i.e., an identity over the entire amino acid or nucleic acid sequences of the invention and not over portions thereof.

According to some embodiments of the invention, the term “homology” or “homologous” refers to identity of two or more nucleic acid sequences; or identity of two or more amino acid sequences; or the identity of an amino acid sequence to one or more nucleic acid sequence.

According to some embodiments of the invention, the homology is a global homology, i.e., an homology over the entire amino acid or nucleic acid sequences of the invention and not over portions thereof.

The degree of homology or identity between two or more sequences can be determined using various known sequence comparison tools. Following is a non-limiting description of such tools which can be used along with some embodiments of the invention.

Pairwise global alignment was defined by S. B. Needleman and C. D. Wunsch, “A general method applicable to the search of similarities in the amino acid sequence of two proteins” Journal of Molecular Biology, 1970, pages 443-53, volume 48).

For example, when starting from a polypeptide sequence and comparing to other polypeptide sequences, the EMBOSS-6.0.1 Needleman-Wunsch algorithm (available from emboss(dot)sourceforge(dot)net/apps/cvs/emboss/apps/needle(dot)html) can be used to find the optimum alignment (including gaps) of two sequences along their entire length—a “Global alignment”. Default parameters for Needleman-Wunsch algorithm (EMBOSS-6.0.1) include: gapopen=10; gapextend=0.5; datafile=EBLOSUM62; brief=YES.

According to some embodiments of the invention, the parameters used with the EMBOSS-6.0.1 tool (for protein-protein comparison) include: gapopen=8; gapextend=2; datafile=EBLOSUM62; brief=YES.

According to some embodiments of the invention, the threshold used to determine homology using the EMBOSS-6.0.1 Needleman-Wunsch algorithm is 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or 100%.

When starting from a polypeptide sequence and comparing to polynucleotide sequences, the OneModel FramePlus algorithm [Halperin, E., Faigler, S. and Gill-More, R. (1999)—FramePlus: aligning DNA to protein sequences. Bioinformatics, 15, 867-873) (available from biocceleration(dot)com/Products(dot)html] can be used with following default parameters: model=frame+_p2n.model mode=local.

According to some embodiments of the invention, the parameters used with the OneModel FramePlus algorithm are model=frame+_p2n.model, mode=qglobal.

According to some embodiments of the invention, the threshold used to determine homology using the OneModel FramePlus algorithm is 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or 100%.

When starting with a polynucleotide sequence and comparing to other polynucleotide sequences the EMBOSS-6.0.1 Needleman-Wunsch algorithm (available from emboss(dot)sourceforge(dot)net/apps/cvs/emboss/apps/needle(dot)html) can be used with the following default parameters: (EMBOSS-6.0.1) gapopen=10; gapextend=0.5; datafile=EDNAFULL; brief=YES.

According to some embodiments of the invention, the parameters used with the EMBOSS-6.0.1 Needleman-Wunsch algorithm are gapopen=10; gapextend-0.2; datafile=EDNAFULL; brief=YES.

According to some embodiments of the invention, the threshold used to determine homology using the EMBOSS-6.0.1 Necdleman-Wunsch algorithm for comparison of polynucleotides with polynucleotides is 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or 100%.

According to some embodiment, determination of the degree of homology further requires employing the Smith-Waterman algorithm (for protein-protein comparison or nucleotide-nucleotide comparison).

Default parameters for GenCore 6.0 Smith-Waterman algorithm include: model=sw.model.

According to some embodiments of the invention, the threshold used to determine homology using the Smith-Waterman algorithm is 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or 100%.

According to some embodiments of the invention, the global homology is performed on sequences which are pre-selected by local homology to the polypeptide or polynucleotide of interest (e.g., 60% identity over 60% of the sequence length), prior to performing the global homology to the polypeptide or polynucleotide of interest (e.g., 80% global homology on the entire sequence). For example, homologous sequences are selected using the BLAST software with the Blastp and tBlastn algorithms as filters for the first stage, and the needle (EMBOSS package) or Frame+algorithm alignment for the second stage. Local identity (Blast alignments) is defined with a very permissive cutoff—60% Identity on a span of 60% of the sequences lengths because it is used only as a filter for the global alignment stage. In this specific embodiment (when the local identity is used), the default filtering of the Blast package is not utilized (by setting the parameter “-F F”).

In the second stage, homologs are defined based on a global identity of at least 80% to the core gene polypeptide sequence.

According to some embodiments of the invention, two distinct forms for finding the optimal global alignment for protein or nucleotide sequences are used:

1. Between Two Proteins (Following the Blastp Filter):

EMBOSS-6.0.1 Needleman-Wunsch algorithm with the following modified parameters: gapopen=8 gapextend=2. The rest of the parameters are unchanged from the default options listed here:

Standard (Mandatory) Qualifiers:

[-asequence] sequence Sequence filename and optional format, or reference (input USA)

[-bsequence] seqall Sequence(s) filename and optional format, or reference (input USA)

-gapopen float [10.0 for any sequence]. The gap open penalty is the score taken away when a gap is created. The best value depends on the choice of comparison matrix. The default value assumes you are using the EBLOSUM62 matrix for protein sequences, and the EDNAFULL matrix for nucleotide sequences. (Floating point number from 1.0 to 100.0)

-gapextend float [0.5 for any sequence]. The gap extension, penalty is added to the standard gap penalty for each base or residue in the gap. This is how long gaps are penalized. Usually you will expect a few long gaps rather than many short gaps, so the gap extension penalty should be lower than the gap penalty. An exception is where one or both sequences are single reads with possible sequencing errors in which case you would expect many single base gaps. You can get this result by setting the gap open penalty to zero (or very low) and using the gap extension penalty to control gap scoring. (Floating point number from 0.0 to 10.0)

[-outfile] align [*.needle] Output alignment file name

Additional (Optional) Qualifiers:

-datafile matrixf [EBLOSUM62 for protein, EDNAFULL for DNA]. This is the scoring matrix file used when comparing sequences. By default it is the file ‘EBLOSUM62’ (for proteins) or the file ‘EDNAFULL’ (for nucleic sequences). These files are found in the ‘data’ directory of the EMBOSS installation.

Advanced (Unprompted) Qualifiers:

-[no]brief boolean [Y] Brief identity and similarity

Associated Qualifiers:

“-asequence” associated qualifiers

-sbegin1 integer Start of the sequence to be used

-send1 integer End of the sequence to be used

-sreverse1 boolean Reverse (if DNA)

-sask1 boolcan Ask for begin/end/reverse

-snucleotide1 boolean Sequence is nucleotide

-sprotein1 boolean Sequence is protein

-slower1 boolean Make lower case

-supper1 boolean Make upper case

-sformat1 string Input sequence format

-sdbname1 string Database name

-sid1 string Entryname

-ufo1 string UFO features

-fformat1 string Features format

-fopenfile1 string Features file name

“-bsequence” associated qualifiers

-sbegin2 integer Start of each sequence to be used

-send2 integer End of each sequence to be used

-sreverse2 boolean Reverse (if DNA)

-sask2 boolean Ask for begin/end/reverse

-snucleotide2 boolean Sequence is nucleotide

-sprotein2 boolean Sequence is protein

-slower2 boolean Make lower case

-supper2 boolean Make upper case

-sformat2 string Input sequence format

-sdbname2 string Database name

-sid2 string Entryname

-ufo2 string UFO features

-fformat2 string Features format

-fopenfile2 string Features file name

“-outfile” associated qualifiers

-aformat3 string Alignment format

-aextension3 string File name extension

-adirectory3 string Output directory

-aname3 string Base file name

-awidth3 integer Alignment width

-aaccshow3 boolean Show accession number in the header

-adesshow3 boolean Show description in the header

-ausashow3 boolean Show the full USA in the alignment

-aglobal3 boolean Show the full sequence in alignment

General Qualifiers:

-auto boolean Turn off prompts

-stdout boolean Write first file to standard output

-filter boolean Read first file from standard input, write

• • first file to standard output

-options boolean Prompt for standard and additional values

-debug boolean Write debug output to program.dbg

-verbose boolean Report some/full command line options

-help boolean Report command line options. More information on associated and general qualifiers can be found with -help -verbose

-warning boolean Report warnings

-error boolean Report errors

-fatal boolean Report fatal errors

-die boolean Report dying program messages 2. Between a protein sequence and a nucleotide sequence (following the tblastn filter):

GenCore 6.0 OneModel application utilizing the Frame+algorithm with the following parameters: model=frame+_p2n.model mode=qglobal—q=protein.sequence -db=nucleotide.sequence. The rest of the parameters are unchanged from the default options:

Usage:

om -model=<model_fname>[-q=]query [-db=]database [options]
-model=<model_fname> Specifies the model that you want to run. All models supplied by Compugen are located in the directory $CGNROOT/models/.

Valid Command Line Parameters:

-dev=<dev_name> Selects the device to be used by the application.

• • Valid devices are:
    • bic—Bioccelerator (valid for SW. XSW. FRAME_N2P, and FRAME_P2N models).
    • xlg—BioX/G (valid for all models except XSW).
    • xlp—BioXI/P (valid for SW, FRAME+_N2P, and FRAME_P2N models).
    • xlh—BioXULH (valid for SW. FRAME+_N2P, and FRAME_P2N models).
    • soft—Software device (for all models).
      -q=<query> Defines the query set. The query can be a sequence file or a database reference. You can specify a query by its name or by accession number. The format is detected automatically. However, you may specify a format using the -qfmt parameter. If you do not specify a query, the program prompts for one. If the query set is a database reference, an output file is produced for each sequence in the query.
      -db=<database name> Chooses the database set. The database set can be a sequence file or a database reference. The database format is detected automatically. However, you may specify a format using -dfmt parameter.
      -qacc Add this parameter to the command line if you specify query using accession numbers.
      -dacc Add this parameter to the command line if you specify a database using accession numbers.
      -dfmt/-qfmt=<format_type> Chooses the database/query format type. Possible formats are:
  • fasta—fasta with seq type auto-detected.
  • fastap—fasta protein seq.
  • fastan—fasta nucleic seq.
  • gcg—gcg format, type is auto-detected.
  • gcg9seq—gcg9 format, type is auto-detected.
  • gcg9seqp—gcg9 format protein seq.
  • gcg9seqn—gcg9 format nucleic seq.
  • nbrf—nbrf seq, type is auto-detected.
  • nbrfp—nbrf protein seq.
  • nbrfn—nbrf nucleic seq.
  • embl—embl and swissprot format.
  • genbank—genbank format (nucleic).
  • blast—blast format.
  • nbrf_gcg—nbrf-gcg seq, type is auto-detected.
  • nbrf_gcgp—nbrf-gcg protein seq.
  • nbrf_gcgn—nbrf-gcg nucleic seq.
  • raw—raw ascii sequence, type is auto-detected.
  • rawp—raw ascii protein sequence.
  • rawn—raw ascii nucleic sequence.
  • pir—pir codata format, type is auto-detected.
  • profile—gcg profile (valid only for -qfmt
  • in SW. XSW. FRAME_P2N, and FRAME+_P2N).
    -out=<out_fname> The name of the output file.
    -suffix=<name> The output file name suffix.
    -gapop=<n> Gap open penalty. This parameter is not valid for FRAME+. For FrameSearch the default is 12.0. For other searches the default is 10.0.
    -gapext=<n> Gap extend penalty. This parameter is not valid for FRAME+. For FrameSearch the default is 4.0. For other models: the default for protein searches is 0.05, and the default for nucleic searches is 1.0.
    -qgapop=<n> The penalty for opening a gap in the query sequence. The default is 10.0. Valid for XSW.
    -qgapext=<n> The penalty for extending a gap in the query sequence. The default is 0.05. Valid for XSW.
    -start=<n> The position in the query sequence to begin the search.
    -end=<n> The position in the query sequence to stop the search.
    -qtrans Performs a translated search, relevant for a nucleic query against a protein database. The nucleic query is translated to six reading frames and a result is given for each frame.

Valid for SW and XSW.

-dtrans Performs a translated search, relevant for a protein query against a DNA database. Each database entry is translated to six reading frames and a result is given for each frame.

Valid for SW and XSW.

Note: “-qtrans” and “-dtrans” options are mutually exclusive.
-matrix=<matrix_file> Specifies the comparison matrix to be used in the search. The matrix must be in the BLAST format. If the matrix file is not located in $CGNROOT/tables/matrix, specify the full path as the value of the -matrix parameter.
-trans=<transtab_name> Translation table. The default location for the table is $CGNROOT/tables/trans.
-onestrand Restricts the search to just the top strand of the query/database nucleic sequence.
-list=<n> The maximum size of the output hit list. The default is 50.
-docalign=<n> The number of documentation lines preceding each alignment. The default is 10.
-thr_score=<score_name> The score that places limits on the display of results. Scores that are smaller than -thr_min value or larger than -thr_max value are not shown. Valid options are: quality.

• • zscore.
  • escore.
    -thr_max=<n> The score upper threshold. Results that are larger than -thr_max value are not shown.
    -thr_min=<n> The score lower threshold. Results that are lower than -thr_min value are not shown.
    -align=<n> The number of alignments reported in the output file.
    -noalign Do not display alignment.
    Note: “-align” and “-noalign” parameters are mutually exclusive.
    -outfmt=<format_name> Specifies the output format type. The default format is PFS.

Possible values are:

• • PFS—PFS text format
  • FASTA—FASTA text format
  • BLAST—BLAST text format
    -nonorm Do not perform score normalization.
    -norm=<norm_name> Specifies the normalization method. Valid options are:
  • log—logarithm normalization.
  • std—standard normalization.
  • stat—Pearson statistical method.
    Note: “-nonorm” and “-norm” parameters cannot be used together.
    Note: Parameters -xgapop. -xgapext, -fgapop, -fgapext. -ygapop, -ygapext, -delop, and -delext apply only to FRAME+.
    -xgapop=<n> The penalty for opening a gap when inserting a codon (triplet). The default is 12.0.
    -xgapext=<n> The penalty for extending a gap when inserting a codon (triplet). The default is 4.0.
    -ygapop=<n> The penalty for opening a gap when deleting an amino acid. The default is 12.0.
    -ygapext=<n> The penalty for extending a gap when deleting an amino acid. The default is 4.0.
    -fgapop=<n> The penalty for opening a gap when inserting a DNA base. The default is 6.0.
    -fgapext=<n> The penalty for extending a gap when inserting a DNA base. The default is 7.0.
    -delop=<n> The penalty for opening a gap when deleting a DNA base. The default is 6.0.
    -delext=<n> The penalty for extending a gap when deleting a DNA base. The default is 7.0.
    -silent No screen output is produced.
    -host=<host_name> The name of the host on which the server runs. By default, the application uses the host specified in the file $CGNROOT/cgnhosts.
    -wait Do not go to the background when the device is busy. This option is not relevant for the Parseq or Soft pseudo device.
    -batch Run the job in the background. When this option is specified, the file “$CGNROOT/defaults/batch.defaults” is used for choosing the batch command. If this file does not exist, the command “at now” is used to run the job.
    Note: “-batch” and “-wait” parameters are mutually exclusive.
    -version Prints the software version number.
    -help Displays this help message. To get more specific help type:
  • “om -model=<model_fname>-help”.

According to some embodiments the homology is a local homology or a local identity.

Local alignments tools include, but are not limited to the BlastP, BlastN, BlastX or TBLASTN software of the National Center of Biotechnology Information (NCBI), FASTA, and the Smith-Waterman algorithm.

A tblastn search allows the comparison between a protein sequence to the six-frame translations of a nucleotide database. It can be a very productive way of finding homologous protein coding regions in unannotated nucleotide sequences such as expressed sequence tags (ESTs) and draft genome records (HTG), located in the BLAST databases est and htgs, respectively.

Default parameters for blastp include: Max target sequences: 100; Expected threshold: e⁻⁵; Word size: 3; Max matches in a query range: 0; Scoring parameters: Matrix—BLOSUM62; filters and masking: Filter—low complexity regions.

Local alignments tools, which can be used include, but are not limited to, the tBLASTX algorithm, which compares the six-frame conceptual translation products of a nucleotide query sequence (both strands) against a protein sequence database. Default parameters include: Max target sequences: 100; Expected threshold: 10; Word size: 3; Max matches in a query range: 0; Scoring parameters: Matrix—BLOSUM62; filters and masking: Filter—low complexity regions.

According to some embodiments of the invention, the exogenous polynucleotide of the invention encodes a polypeptide having an amino acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% identical to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629.

According to some embodiments of the invention, the exogenous polynucleotide of the invention encodes a polypeptide having the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to some embodiments of the invention, the method of increasing yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency of a plant, is effected by expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% identical to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629, thereby increasing the yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency of the plant.

According to some embodiments of the invention, the exogenous polynucleotide encodes a polypeptide consisting of the amino acid sequence set forth by SEQ ID NO: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 or 10629.

According to an aspect of some embodiments of the invention, the method of increasing yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency of a plant, is effected by expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide comprising an amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629, thereby increasing the yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency of the plant.

According to an aspect of some embodiments of the invention, there is provided a method of increasing yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629, thereby increasing the yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency of the plant.

According to some embodiments of the invention, the exogenous polynucleotide encodes a polypeptide consisting of the amino acid sequence set forth by SEQ ID NO: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 or 10629.

According to some embodiments of the invention the exogenous polynucleotide comprises a nucleic acid sequence which is at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028.

According to an aspect of some embodiments of the invention, there is provided a method of increasing yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency of a plant, comprising expressing within the plant an exogenous polynucleotide comprising a nucleic acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028, thereby increasing the yield, biomass, growth rate, vigor, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance, and/or nitrogen use efficiency of the plant.

According to some embodiments of the invention the exogenous polynucleotide is at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the polynucleotide selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028.

According to some embodiments of the invention the exogenous polynucleotide is set forth by SEQ ID NO: 1-551, 898-6027 or 6028.

According to some embodiments of the invention the exogenous polynucleotide is set forth by the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

According to some embodiments of the invention the method of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant further comprising selecting a plant having an increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to the wild type plant of the same species which is grown under the same growth conditions.

It should be noted that selecting a transformed plant having an increased trait as compared to a native (or non-transformed) plant grown under the same growth conditions can be performed by selecting for the trait, e.g., validating the ability of the transformed plant to exhibit the increased trait using well known assays (e.g., seedling analyses, greenhouse assays, filed experiments) as is further described herein below.

According to some embodiments of the invention selecting is performed under non-stress conditions.

According to some embodiments of the invention selecting is performed under abiotic stress conditions.

According to some embodiments of the invention selecting is performed under nitrogen limiting (e.g., nitrogen deficient) conditions.

According to an aspect of some embodiments of the invention, there is provided a method of selecting a transformed plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions, the method comprising:

(a) providing plants transformed with an exogenous polynucleotide encoding a polypeptide comprising an amino acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% homologous (e.g., having sequence similarity or sequence identity) to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629,

(b) selecting from the plants of step (a) a plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance (e.g., by selecting the plants for the increased trait).

thereby selecting the plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to the wild type plant of the same species which is grown under the same growth conditions.

According to an aspect of some embodiments of the invention, there is provided a method of selecting a transformed plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions, the method comprising:

(a) providing plants transformed with an exogenous polynucleotide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028.

(b) selecting from the plants of step (a) a plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance, thereby selecting the plant having increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to the wild type plant of the same species which is grown under the same growth conditions.

As used herein the term “polynucleotide” refers to a single or double stranded nucleic acid sequence which is isolated and provided in the form of an RNA sequence, a complementary polynucleotide sequence (cDNA), a genomic polynucleotide sequence and/or a composite polynucleotide sequences (e.g., a combination of the above).

The term “isolated” refers to at least partially separated from the natural environment e.g., from a plant cell.

As used herein the phrase “complementary polynucleotide sequence” refers to a sequence, which results from reverse transcription of messenger RNA using a reverse transcriptase or any other RNA dependent DNA polymerase. Such a sequence can be subsequently amplified in vivo or in vitro using a DNA dependent DNA polymerase.

As used herein the phrase “genomic polynucleotide sequence” refers to a sequence derived (isolated) from a chromosome and thus it represents a contiguous portion of a chromosome.

As used herein the phrase “composite polynucleotide sequence” refers to a sequence, which is at least partially complementary and at least partially genomic. A composite sequence can include some exonal sequences required to encode the polypeptide of the present invention, as well as some intronic sequences interposing therebetween. The intronic sequences can be of any source, including of other genes, and typically will include conserved splicing signal sequences. Such intronic sequences may further include cis acting expression regulatory elements.

Nucleic acid sequences encoding the polypeptides of the present invention may be optimized for expression. Examples of such sequence modifications include, but are not limited to, an altered G/C content to more closely approach that typically found in the plant species of interest, and the removal of codons atypically found in the plant species commonly referred to as codon optimization.

The phrase “codon optimization” refers to the selection of appropriate DNA nucleotides for use within a structural gene or fragment thereof that approaches codon usage within the plant of interest. Therefore, an optimized gene or nucleic acid sequence refers to a gene in which the nucleotide sequence of a native or naturally occurring gene has been modified in order to utilize statistically-preferred or statistically-favored codons within the plant. The nucleotide sequence typically is examined at the DNA level and the coding region optimized for expression in the plant species determined using any suitable procedure, for example as described in Sardana et al. (1996, Plant Cell Reports 15:677-681). In this method, the standard deviation of codon usage, a measure of codon usage bias, may be calculated by first finding the squared proportional deviation of usage of each codon of the native gene relative to that of highly expressed plant genes, followed by a calculation of the average squared deviation. The formula used is: 1 SDCU=n=1 N [(Xn−Yn)/Yn] 2/N, where Xn refers to the frequency of usage of codon n in highly expressed plant genes, where Yn to the frequency of usage of codon n in the gene of interest and N refers to the total number of codons in the gene of interest. A Table of codon usage from highly expressed genes of dicotyledonous plants is compiled using the data of Murray et al. (1989, Nuc Acids Res. 17:477-498).

One method of optimizing the nucleic acid sequence in accordance with the preferred codon usage for a particular plant cell type is based on the direct use, without performing any extra statistical calculations, of codon optimization Tables such as those provided on-line at the Codon Usage Database through the NIAS (National Institute of Agrobiological Sciences) DNA bank in Japan (kazusa (dot) or (dot) jp/codon/). The Codon Usage Database contains codon usage tables for a number of different species, with each codon usage Table having been statistically determined based on the data present in Genbank.

By using the above Tables to determine the most preferred or most favored codons for each amino acid in a particular species (for example, rice), a naturally-occurring nucleotide sequence encoding a protein of interest can be codon optimized for that particular plant species. This is effected by replacing codons that may have a low statistical incidence in the particular species genome with corresponding codons, in regard to an amino acid, that are statistically more favored. However, one or more less-favored codons may be selected to delete existing restriction sites, to create new ones at potentially useful junctions (5′ and 3′ ends to add signal peptide or termination cassettes, internal sites that might be used to cut and splice segments together to produce a correct full-length sequence), or to eliminate nucleotide sequences that may negatively effect mRNA stability or expression.

The naturally-occurring encoding nucleotide sequence may already, in advance of any modification, contain a number of codons that correspond to a statistically-favored codon in a particular plant species. Therefore, codon optimization of the native nucleotide sequence may comprise determining which codons, within the native nucleotide sequence, are not statistically-favored with regards to a particular plant, and modifying these codons in accordance with a codon usage table of the particular plant to produce a codon optimized derivative. A modified nucleotide sequence may be fully or partially optimized for plant codon usage provided that the protein encoded by the modified nucleotide sequence is produced at a level higher than the protein encoded by the corresponding naturally occurring or native gene. Construction of synthetic genes by altering the codon usage is described in for example PCT Patent Application 93/07278.

According to some embodiments of the invention, the exogenous polynucleotide is a non-coding RNA.

As used herein the phrase ‘non-coding RNA” refers to an RNA molecule which does not encode an amino acid sequence (a polypeptide). Examples of such non-coding RNA molecules include, but are not limited to, an antisense RNA, a pre-miRNA (precursor of a microRNA), or a precursor of a Piwi-interacting RNA (piRNA).

Non-limiting examples of non-coding RNA polynucleotides are provided in SEQ ID NOs: 251-261, 305-310, 547-551, 2495, 3836, 4999, and 5255.

Thus, the invention encompasses nucleic acid sequences described hereinabove; fragments thereof, sequences hybridizable therewith, sequences homologous thereto, sequences encoding similar polypeptides with different codon usage, altered sequences characterized by mutations, such as deletion, insertion or substitution of one or more nucleotides, either naturally occurring or man induced, either randomly or in a targeted fashion.

According to some embodiments of the invention, the exogenous polynucleotide encodes a polypeptide comprising an amino acid sequence at least 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the amino acid sequence of a naturally occurring plant orthologue of the polypeptide selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to some embodiments of the invention, the polypeptide comprising an amino acid sequence at least 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the amino acid sequence of a naturally occurring plant orthologue of the polypeptide selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

The invention provides an isolated polynucleotide comprising a nucleic acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the polynucleotide selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028.

According to some embodiments of the invention the nucleic acid sequence is capable of increasing nitrogen use efficiency, fertilizer use efficiency, yield (e.g., seed yield, oil yield), growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance and/or water use efficiency of a plant.

According to some embodiments of the invention the isolated polynucleotide comprising the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

According to some embodiments of the invention the isolated polynucleotide is set forth by SEQ ID NO: 1-551, 898-6027 or 6028.

The invention provides an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises an amino acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629.

According to some embodiments of the invention the amino acid sequence is capable of increasing nitrogen use efficiency, fertilizer use efficiency, yield, seed yield, growth rate, vigor, biomass, oil content, fiber yield, fiber quality, fiber length, photosynthetic capacity, abiotic stress tolerance and/or water use efficiency of a plant.

The invention provides an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to an aspect of some embodiments of the invention, there is provided a nucleic acid construct comprising the isolated polynucleotide of the invention, and a promoter for directing transcription of the nucleic acid sequence in a host cell.

The invention provides an isolated polypeptide comprising an amino acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous to an amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629.

According to some embodiments of the invention, the polypeptide comprising an amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to some embodiments of the invention, the polypeptide is set forth by SEQ ID NO: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 or 10629.

The invention also encompasses fragments of the above described polypeptides and polypeptides having mutations, such as deletions, insertions or substitutions of one or more amino acids, either naturally occurring or man induced, either randomly or in a targeted fashion.

The term “plant” as used herein encompasses a whole plant, a grafted plant, ancestor(s) and progeny of the plants and plant parts, including seeds, shoots, stems, roots (including tubers), rootstock, scion, and plant cells, tissues and organs. The plant may be in any form including suspension cultures, embryos, meristematic regions, callus tissue, leaves, gametophytes, sporophytes, pollen, and microspores. Plants that are particularly useful in the methods of the invention include all plants which belong to the superfamily Viridiplantae, in particular monocotyledonous and dicotyledonous plants including a fodder or forage legume, ornamental plant, food crop, tree, or shrub selected from the list comprising Acacia spp., Acer spp., Actinidia spp., Aesculus spp., Agathis australis, Albizia amara, Alsophila tricolor, Andropogon spp., Arachis spp, Areca catechu, Astelia fragrans. Astragalus cicer, Baikiaea plurijuga, Betula spp., Brassica spp., Bruguiera gymnorrhiza, Burkea africana, Butea frondosa, Cadaba farinosa, Calliandra spp. Camellia sinensis, Canna indica, Capsicum spp., Cassia spp., Centroema pubescens, Chacoomeles spp., Cinnamomum cassia, Coffea arabica, Colophospermum mopane, Coronillia varia, Cotoneaster serotina, Crataegus spp., Cucumis spp., Cupressus spp., Cyathea dealbata, Cydonia oblonga, Cryptomeria japonica, Cymbopogon spp., Cynthea dealbata, Cydonia oblonga, Dalbergia monetaria, Davallia divaricata, Desmodium spp., Dicksonia squarosa, Dibeteropogon amplectens, Dioclea spp, Dolichos spp., Dorycnium rectum, Echinochloa pyramidalis, Ehraffia spp., Eleusine coracana, Eragrestis spp., Erythrina spp., Eucalypfus spp., Euclea schimperi, Eulalia vi/losa, Pagopyrum spp., Feijoa sellowlana, Fragaria spp., Flemingia spp, Freycinetia banksli, Geranium thunbergii, GinAgo biloba, Glycine javanica, Gliricidia spp. Gossypium hirsutum, Grevillea spp., Guibourtia coleosperma, Hedysarum spp., Hemaffhia altissima, Heteropogon contoffus, Hordeum vulgare, Hyparrhenia rufa, Hypericum erectum, Hypeffhelia dissolute, Indigo incamata, Iris spp., Leptarrhena pyrolifolia, Lespediza spp., Lettuca spp., Leucaena leucocephala, Loudetia simplex, Lotonus bainesli, Lotus spp., Macrotyloma axillare, Malus spp., Manihot esculenta, Medicago saliva, Metasequoia glyptostroboides, Musa sapientum, Nicotianum spp., Onobrychis spp., Omithopus spp., Oryza spp., Peltophorum africanum, Pennisetum spp., Persea gratissima, Petunia spp., Phaseolus spp., Phoenix canariensis, Phormium cookianum, Photinia spp., Picea glauca, Pinus spp., Pisum sativam, Podocarpus totara, Pogonarthria fleckii, Pogonaffhria squarrosa, Populus spp., Prosopis cineraria, Pseudotsuga menziesii, Pterolobium stellatum, Pyrus communis, Quercus spp., Rhaphiolepsis umbellata, Rhopalostylis sapida, Rhus natalensis, Ribes grossularia, Ribes spp., Robinia pseudoacacia, Rosa spp., Rubus spp., Salix spp., Schyzachyrium sanguineum, Sciadopitys vefficillata, Sequoia sempervirens, Sequoiadendron giganteum, Sorghum bicolor, Spinacia spp., Sporobolus fimbriatus, Stiburus alopecuroides, Stylosanthos humilis, Tadehagi spp. Taxodium distichum, Themeda triandra, Trifolium spp., Triticum spp., Tsuga heterophylla, Vaccinium spp., Vicia spp., Vitis vinifera, Watsonia pyramidata, Zantedeschia aethiopica, Zea mays, amaranth, artichoke, asparagus, broccoli, Brussels sprouts, cabbage, canola, carrot, cauliflower, celery, collard greens, flax, kale, lentil, oilseed rape, okra, onion, potato, rice, soybean, straw, sugar beet, sugar cane, sunflower, tomato, squash tea, maize, wheat, barley, rye, oat, peanut, pea, lentil and alfalfa, cotton, rapeseed, canola, pepper, sunflower, tobacco, eggplant, eucalyptus, a tree, an ornamental plant, a perennial grass and a forage crop. Alternatively algae and other non-Viridiplantae can be used for the methods of the present invention.

According to some embodiments of the invention, the plant used by the method of the invention is a crop plant such as rice, maize, wheat, barley, peanut, potato, sesame, olive tree, palm oil, banana, soybean, sunflower, canola, sugarcane, alfalfa, millet, leguminosae (bean, pea), flax, lupinus, rapeseed, tobacco, poplar and cotton.

According to some embodiments of the invention the plant is a dicotyledonous plant.

According to some embodiments of the invention the plant is a monocotyledonous plant.

According to some embodiments of the invention, there is provided a plant cell exogenously expressing the polynucleotide of some embodiments of the invention, the nucleic acid construct of some embodiments of the invention and/or the polypeptide of some embodiments of the invention.

According to some embodiments of the invention, expressing the exogenous polynucleotide of the invention within the plant is effected by transforming one or more cells of the plant with the exogenous polynucleotide, followed by generating a mature plant from the transformed cells and cultivating the mature plant under conditions suitable for expressing the exogenous polynucleotide within the mature plant.

According to some embodiments of the invention, the transformation is effected by introducing to the plant cell a nucleic acid construct which includes the exogenous polynucleotide of some embodiments of the invention and at least one promoter for directing transcription of the exogenous polynucleotide in a host cell (a plant cell). Further details of suitable transformation approaches are provided hereinbelow.

As mentioned, the nucleic acid construct according to some embodiments of the invention comprises a promoter sequence and the isolated polynucleotide of some embodiments of the invention.

According to some embodiments of the invention, the isolated polynucleotide is operably linked to the promoter sequence.

A coding nucleic acid sequence is “operably linked” to a regulatory sequence (e.g., promoter) if the regulatory sequence is capable of exerting a regulatory effect on the coding sequence linked thereto.

As used herein, the term “promoter” refers to a region of DNA which lies upstream of the transcriptional initiation site of a gene to which RNA polymerase binds to initiate transcription of RNA. The promoter controls where (e.g., which portion of a plant) and/or when (e.g., at which stage or condition in the lifetime of an organism) the gene is expressed.

According to some embodiments of the invention, the promoter is heterologous to the isolated polynucleotide and/or to the host cell.

As used herein the phrase “heterologous promoter” refers to a promoter from a different species or from the same species but from a different gene locus as of the isolated polynucleotide sequence.

According to some embodiments of the invention, the isolated polynucleotide is heterologous to the plant cell (e.g., the polynucleotide is derived from a different plant species when compared to the plant cell, thus the isolated polynucleotide and the plant cell are not from the same plant species).

Any suitable promoter sequence can be used by the nucleic acid construct of the present invention. Preferably the promoter is a constitutive promoter, a tissue-specific, or an abiotic stress-inducible promoter.

According to some embodiments of the invention, the promoter is a plant promoter, which is suitable for expression of the exogenous polynucleotide in a plant cell.

Suitable promoters for expression in wheat include, but are not limited to, Wheat SPA promoter (SEQ ID NO: 10630; Albani et al. Plant Cell, 9: 171-184, 1997, which is fully incorporated herein by reference), wheat LMW (SEQ ID NO: 10631 (longer LMW promoter), and SEQ ID NO: 10632 (LMW promoter) and HMW glutenin-1 (SEQ ID NO: 10633 (Wheat HMW glutenin-1 longer promoter); and SEQ ID NO: 10634 (Wheat HMW glutenin-1 Promoter); Thomas and Flavell, The Plant Cell 2:1171-1180; Furtado et al., 2009 Plant Biotechnology Journal 7:240-253, each of which is fully incorporated herein by reference), wheat alpha, beta and gamma gliadins [e.g., SEQ ID NO: 10635 (wheat alpha gliadin, B genome, promoter); SEQ ID NO: 10636 (wheat gamma gliadin promoter); EMBO 3:1409-15, 1984, which is fully incorporated herein by reference], wheat TdPR60 [SEQ ID NO: 10637 (wheat TdPR60 longer promoter) or SEQ ID NO: 10638 (wheat TdPR60 promoter); Kovalchuk et al., Plant Mol Biol 71:81-98, 2009, which is fully incorporated herein by reference], maize Ubl Promoter [cultivar Nongda 105 (SEQ ID NO: 10639); GenBank: DQ141598.1; Taylor et al., Plant Cell Rep 1993 12: 491-495, which is fully incorporated herein by reference; and cultivar B73 (SEQ ID NO: 10640); Christensen. A H, et al. Plant Mol. Biol. 18 (4), 675-689 (1992), which is fully incorporated herein by reference]; rice actin 1 (SEQ ID NO: 10641; Mc Elroy et al. 1990, The Plant Cell, Vol. 2, 163-171, which is fully incorporated herein by reference), rice GOS2 [SEQ ID NO: 10642 (rice GOS2 longer promoter) and SEQ ID NO: 10643 (rice GOS2 Promoter); De Pater et al. Plant J. 1992; 2: 837-44, which is fully incorporated herein by reference], arabidopsis Pho1 [SEQ ID NO: 10644 (arabidopsis Pho1 Promoter); Hamburger et al., Plant Cell. 2002; 14: 889-902, which is fully incorporated herein by reference]. Expansin B promoters, e.g., rice ExpB5 [SEQ ID NO: 10645 (rice ExpB5 longer promoter) and SEQ ID NO: 10646 (rice ExpB5 promoter)] and Barley ExpB1 [SEQ ID NO: 10647 (barley ExpB1 Promoter). Won et al. Mol Cells. 2010; 30:369-76, which is fully incorporated herein by reference], barley SS2 (sucrose synthase 2) [(SEQ ID NO: 10648). Guerin and Carbonero. Plant Physiology May 1997 vol. 114 no. 1 55-62, which is fully incorporated herein by reference], and rice PG5a [SEQ ID NO: 10649. U.S. Pat. No. 7,700,835. Nakase et al., Plant Mol Biol. 32:621-30, 1996, each of which is fully incorporated herein by reference].

Suitable constitutive promoters include, for example. CaMV 35S promoter [SEQ ID NO: 10650 (CaMV 35S (pQXNc) Promoter); SEQ ID NO: 10651 (PJJ 35S from Brachypodium); SEQ ID NO: 10652 (CaMV 35S (OLD) Promoter) (Odell et al., Nature 313:810-812, 1985)], Arabidopsis At6669 promoter (SEQ ID NO: 10653 (Arabidopsis At6669 (OLD) Promoter); see PCT Publication No. WO004081173A2 or the new At6669 promoter (SEQ ID NO: 10654 (Arabidopsis At6669 (NEW) Promoter)); maize Ubl Promoter [cultivar Nongda 105 (SEQ ID NO: 10639); GenBank: DQ141598.1; Taylor et al., Plant Cell Rep 1993 12: 491-495, which is fully incorporated herein by reference; and cultivar B73 (SEQ ID NO: 10640); Christensen, A H, et al. Plant Mol. Biol. 18 (4), 675-689 (1992), which is fully incorporated herein by reference]; rice actin 1 (SEQ ID NO: 10641, McElroy et al., Plant Cell 2:163-171, 1990); pEMU (Last et al., Theor. Appl. Genet. 81:581-588, 1991); CaMV 19S (Nilsson et al., Physiol. Plant 100:456-462, 1997); rice GOS2 [SEQ ID NO: 10642 (rice GOS2 longer Promoter) and SEQ ID NO: 10643 (rice GOS2 Promoter), de Pater et al. Plant J Nov; 2(6):837-44, 1992]; RBCS promoter (SEQ ID NO: 10655); Rice cyclophilin (Bucholz et al, Plant Mol Biol. 25(5):837-43, 1994); Maize H3 histone (Lepetit et al, Mol. Gen. Genet. 231: 276-285, 1992); Actin 2 (An et al, Plant J. 10(1):107-121, 1996) and Synthetic Super MAS (Ni et al., The Plant Journal 7: 661-76, 1995). Other constitutive promoters include those in U.S. Pat. Nos. 5,659,026, 5,608,149; 5,608,144; 5,604,121; 5,569,597; 5,466,785; 5,399,680; 5,268,463; and 5,608,142.

Suitable tissue-specific promoters include, but not limited to, leaf-specific promoters [e.g., AT5G06690 (Thioredoxin) (high expression, SEQ ID NO: 10656). AT5G61520 (AtSTP3) (low expression, SEQ ID NO: 10657) described in Buttner et al 2000 Plant, Cell and Environment 23, 175-184, or the promoters described in Yamamoto et al., Plant J. 12:255-265, 1997; Kwon et al., Plant Physiol. 105:357-67, 1994: Yamamoto et al., Plant Cell Physiol. 35:773-778, 1994; Gotor et al., Plant J. 3:509-18, 1993; Orozco et al., Plant Mol. Biol. 23:1129-1138, 1993; and Matsuoka et al., Proc. Natl. Acad. Sci. USA 90:9586-9590, 1993; as well as Arabidopsis STP3 (AT5G61520) promoter (Buttner et al., Plant. Cell and Environment 23:175-184, 2000)], seed-preferred promoters [e.g., Napin (originated from Brassica napus which is characterized by a seed specific promoter activity: Stuitje A. R. et. al. Plant Biotechnology Journal 1 (4): 301-309; SEQ ID NO: 10658 (Brassica napus NAPIN Promoter) from seed specific genes (Simon. et al., Plant Mol. Biol. 5, 191, 1985; Scofield, et al., J. Biol. Chem. 262: 12202, 1987; Baszczynski, et al., Plant Mol. Biol. 14: 633, 1990), rice PG5a (SEQ ID NO: 10649; U.S. Pat. No. 7,700,835), early seed development Arabidopsis BAN (AT1G61720) (SEQ ID NO: 10659. US 2009/0031450 A1), late seed development Arabidopsis ABI3 (AT3G24650) (SEQ ID NO: 10660 (Arabidopsis ABI3 (AT3G24650) longer Promoter) or 10661 (Arabidopsis ABI3 (AT3G24650) Promoter)) (Ng et al., Plant Molecular Biology 54: 25-38, 2004), Brazil Nut albumin (Pearson et al., Plant Mol. Biol. 18: 235-245, 1992), legumin (Ellis. et al. Plant Mol. Biol. 10: 203-214, 1988). Glutelin (rice) (Takaiwa, et al., Mol. Gen. Genet. 208: 15-22, 1986; Takaiwa, et al., FEBS Letts. 221: 43-47, 1987), Zein (Matzke et al Plant Mol Biol, 143:323-32 1990), napA (Stalberg, et al, Planta 199: 515-519, 1996), Wheat SPA (SEQ ID NO: 10630; Albani et al, Plant Cell, 9: 171-184, 1997), sunflower oleosin (Cummins, et al., Plant Mol. Biol. 19: 873-876, 1992)], endosperm specific promoters [e.g., wheat LMW (SEQ ID NO: 10631 (Wheat LMW Longer Promoter), and SEQ ID NO: 10632 (Wheat LMW Promoter) and HMW glutenin-1](SEQ ID NO: 10633 (Wheat HMW glutenin-1 longer Promoter)); and SEQ ID NO: 10634 (Wheat HMW glutenin-1 Promoter), Thomas and Flavell, The Plant Cell 2:1171-1180, 1990; Mol Gen Genet 216:81-90, 1989: NAR 17:461-2), wheat alpha, beta and gamma gliadins (SEQ ID NO: 10635 (wheat alpha gliadin (B genome) promoter); SEQ ID NO: 10636 (wheat gamma gliadin promoter): EMBO 3:1409-15, 1984), Barley Itr1 promoter, barley B1, C, D hordein (Theor Appl Gen 98:1253-62, 1999; Plant J 4:343-55, 1993; Mol Gen Genet 250:750-60, 1996), Barley DOF (Mena et al. The Plant Journal. 116(1): 53-62, 1998). Biz2 (EP99106056.7). Barley SS2 (SEQ ID NO: 10648 (Barley SS2 Promoter); Guerin and Carbonero Plant Physiology 114: 1 55-62, 1997), wheat Tarp60 (Kovalchuk et al., Plant Mol Biol 71:81-98, 2009), barley D-hordein (D-Hor) and B-hordein (B-Hor) (Agnelo Furtado, Robert J. Henry and Alessandro Pellegrineschi (2009)], Synthetic promoter (Vicente-Carbajosa et al., Plant J. 13: 629-640, 1998), rice prolamin NRP33, rice-globulin Glb-1 (Wu et al, Plant Cell Physiology 39(8) 885-889, 1998), rice alpha-globulin REB/OHP-1 (Nakase et al. Plant Mol. Biol. 33: 513-S22, 1997), rice ADP-glucose PP (Trans Res 6:157-68, 1997), maize ESR gene family (Plant J 12:235-46, 1997), sorgum gamma-kafirin (PMB 32:1029-35, 1996)], embryo specific promoters [e.g., rice OSH1 (Sato et al. Proc. Natl. Acad. Sci. USA. 93: 8117-8122), KNOX (Postma-Haarsma et al, Plant Mol. Biol. 39:257-71, 1999), rice oleosin (Wu et at, J. Biochem., 123:386, 1998)], and flower-specific promoters [e.g., AtPRP4, chalene synthase (chsA) (Van der Meer, et al., Plant Mol. Biol. 15, 95-109, 1990). LAT52 (Twell et al Mol. Gen Genet. 217:240-245; 1989), Arabidopsis apetala-3 (Tilly et al., Development. 125:1647-57, 1998). Arabidopsis APETALA 1 (AT1G69120, API) (SEQ ID NO: 10662 (Arabidopsis (AT1G69120) APETALA 1)) (Hempel et al., Development 124:3845-3853, 1997)], and root promoters [e.g., the ROOTP promoter [SEQ ID NO: 10663]; rice ExpB5 (SEQ ID NO: 10646 (rice ExpB5 Promoter); or SEQ ID NO: 10645 (rice ExpB5 longer Promoter)) and barley ExpB1 promoter (SEQ ID NO: 10647) (Won et al. Mol. Cells 30: 369-376, 2010); arabidopsis ATTPS-CIN (AT3G25820) promoter (SEQ ID NO: 10664; Chen et al., Plant Phys 135:1956-66, 2004); arabidopsis Pho1 promoter (SEQ ID NO: 10644, Hamburger et al., Plant Cell. 14: 889-902, 2002), which is also slightly induced by stress].

Suitable abiotic stress-inducible promoters include, but not limited to, salt-inducible promoters such as RD29A (Yamaguchi-Shinozalei et al., Mol. Gen. Genet. 236:331-340, 1993); drought-inducible promoters such as maize rab17 gene promoter (Pla et. al., Plant Mol. Biol. 21:259-266, 1993), maize rab28 gene promoter (Busk et. al., Plant J. 11:1285-1295, 1997) and maize Ivr2 gene promoter (Pelleschi et. al., Plant Mol. Biol. 39:373-380, 1999); heat-inducible promoters such as heat tomato hsp80-promoter from tomato (U.S. Pat. No. 5,187,267).

The nucleic acid construct of some embodiments of the invention can further include an appropriate selectable marker and/or an origin of replication. According to some embodiments of the invention, the nucleic acid construct utilized is a shuttle vector, which can propagate both in E. coli (wherein the construct comprises an appropriate selectable marker and origin of replication) and be compatible with propagation in cells. The construct according to the present invention can be, for example, a plasmid, a bacmid, a phagemid, a cosmid, a phage, a virus or an artificial chromosome.

The nucleic acid construct of some embodiments of the invention can be utilized to stably or transiently transform plant cells. In stable transformation, the exogenous polynucleotide is integrated into the plant genome and as such it represents a stable and inherited trait. In transient transformation, the exogenous polynucleotide is expressed by the cell transformed but it is not integrated into the genome and as such it represents a transient trait.

There are various methods of introducing foreign genes into both monocotyledonous and dicotyledonous plants (Potrykus. I., Annu. Rev. Plant. Physiol., Plant. Mol. Biol. (1991) 42:205-225; Shimamoto et al., Nature (1989) 338:274-276).

The principle methods of causing stable integration of exogenous DNA into plant genomic DNA include two main approaches:

(i) Agrobacterium-mediated gene transfer: Klee et al. (1987) Annu. Rev. Plant Physiol. 38:467-486; Klee and Rogers in Cell Culture and Somatic Cell Genetics of Plants. Vol. 6, Molecular Biology of Plant Nuclear Genes, eds. Schell, J., and Vasil, L. K., Academic Publishers. San Diego, Calif. (1989) p. 2-25: Gatenby, in Plant Biotechnology, eds. Kung. S. and Amtzen, C. J., Butterworth Publishers. Boston, Mass. (1989) p. 93-112.

(ii) Direct DNA uptake: Paszkowski et al., in Cell Culture and Somatic Cell Genetics of Plants, Vol. 6. Molecular Biology of Plant Nuclear Genes eds. Schell. J., and Vasil. L. K., Academic Publishers. San Diego. Calif. (1989) p. 52-68; including methods for direct uptake of DNA into protoplasts. Toriyama, K. et al. (1988) Bio/Technology 6:1072-1074. DNA uptake induced by brief electric shock of plant cells: Zhang et al. Plant Cell Rep. (1988) 7:379-384. Fromm et al. Nature (1986) 319:791-793. DNA injection into plant cells or tissues by particle bombardment. Klein et al. Bio/Technology (1988) 6:559-563; McCabe et al. Bio/Technology (1988) 6:923-926; Sanford, Physiol. Plant. (1990) 79:206-209; by the use of micropipette systems: Neuhaus et al., Theor. Appl. Genet. (1987) 75:30-36; Neuhaus and Spangenberg. Physiol. Plant. (1990) 79:213-217: glass fibers or silicon carbide whisker transformation of cell cultures, embryos or callus tissue. U.S. Pat. No. 5,464,765 or by the direct incubation of DNA with germinating pollen, DeWet et al. in Experimental Manipulation of Ovule Tissue. eds. Chapman, G. P, and Mantell, S. H. and Daniels. W. Longman, London, (1985) p. 197-209; and Ohta, Proc. Natl. Acad. Sci. USA (1986) 83:715-719.

The Agrobacterium system includes the use of plasmid vectors that contain defined DNA segments that integrate into the plant genomic DNA. Methods of inoculation of the plant tissue vary depending upon the plant species and the Agrobacterium delivery system. A widely used approach is the leaf disc procedure which can be performed with any tissue explant that provides a good source for initiation of whole plant differentiation. See, e.g., Horsch et al. in Plant Molecular Biology Manual A5, Kluwer Academic Publishers. Dordrecht (1988) p. 1-9. A supplementary approach employs the Agrobacterium delivery system in combination with vacuum infiltration. The Agrobacterium system is especially viable in the creation of transgenic dicotyledonous plants.

There are various methods of direct DNA transfer into plant cells. In electroporation, the protoplasts are briefly exposed to a strong electric field. In microinjection, the DNA is mechanically injected directly into the cells using very small micropipettes. In microparticle bombardment, the DNA is adsorbed on microprojectiles such as magnesium sulfate crystals or tungsten particles, and the microprojectiles are physically accelerated into cells or plant tissues.

Following stable transformation plant propagation is exercised. The most common method of plant propagation is by seed. Regeneration by seed propagation, however, has the deficiency that due to heterozygosity there is a lack of uniformity in the crop, since seeds are produced by plants according to the genetic variances governed by Mendelian rules. Basically, each seed is genetically different and each will grow with its own specific traits. Therefore, it is preferred that the transformed plant be produced such that the regenerated plant has the identical traits and characteristics of the parent transgenic plant. Therefore, it is preferred that the transformed plant be regenerated by micropropagation which provides a rapid, consistent reproduction of the transformed plants.

Micropropagation is a process of growing new generation plants from a single piece of tissue that has been excised from a selected parent plant or cultivar. This process permits the mass reproduction of plants having the preferred tissue expressing the fusion protein. The new generation plants which are produced are genetically identical to, and have all of the characteristics of, the original plant. Micropropagation allows mass production of quality plant material in a short period of time and offers a rapid multiplication of selected cultivars in the preservation of the characteristics of the original transgenic or transformed plant. The advantages of cloning plants are the speed of plant multiplication and the quality and uniformity of plants produced.

Micropropagation is a multi-stage procedure that requires alteration of culture medium or growth conditions between stages. Thus, the micropropagation process involves four basic stages: Stage one, initial tissue culturing; stage two, tissue culture multiplication; stage three, differentiation and plant formation; and stage four, greenhouse culturing and hardening. During stage one, initial tissue culturing, the tissue culture is established and certified contaminant-free. During stage two, the initial tissue culture is multiplied until a sufficient number of tissue samples are produced from the seedlings to meet production goals. During stage three, the tissue samples grown in stage two are divided and grown into individual plantlets. At stage four, the transformed plantlets are transferred to a greenhouse for hardening where the plants' tolerance to light is gradually increased so that it can be grown in the natural environment.

According to some embodiments of the invention, the transgenic plants are generated by transient transformation of leaf cells, meristematic cells or the whole plant.

Transient transformation can be effected by any of the direct DNA transfer methods described above or by viral infection using modified plant viruses.

Viruses that have been shown to be useful for the transformation of plant hosts include CaMV. Tobacco mosaic virus (TMV), brome mosaic virus (BMV) and Bean Common Mosaic Virus (BV or BCMV). Transformation of plants using plant viruses is described in U.S. Pat. No. 4,855,237 (bean golden mosaic virus; BGV), EP-A 67,553 (TMV), Japanese Published Application No. 63-14693 (TMV). EPA 194,809 (BV), EPA 278.667 (BV); and Gluzman, Y. et al., Communications in Molecular Biology: Viral Vectors. Cold Spring Harbor Laboratory, New York, pp. 172-189 (1988). Pseudovirus particles for use in expressing foreign DNA in many hosts, including plants are described in WO 87/06261.

According to some embodiments of the invention, the virus used for transient transformations is avirulent and thus is incapable of causing severe symptoms such as reduced growth rate, mosaic, ring spots, leaf roll, yellowing, streaking, pox formation, tumor formation and pitting. A suitable avirulent virus may be a naturally occurring avirulent virus or an artificially attenuated virus. Virus attenuation may be effected by using methods well known in the art including, but not limited to, sub-lethal heating, chemical treatment or by directed mutagenesis techniques such as described, for example, by Kurihara and Watanabe (Molecular Plant Pathology 4:259-269, 2003), Gal-on et al. (1992), Atreya et al. (1992) and Huet et al. (1994).

Suitable virus strains can be obtained from available sources such as, for example, the American Type culture Collection (ATCC) or by isolation from infected plants. Isolation of viruses from infected plant tissues can be effected by techniques well known in the art such as described, for example by Foster and Taylor, Eds. “Plant Virology Protocols: From Virus Isolation to Transgenic Resistance (Methods in Molecular Biology (Humana Pr), Vol 81)”, Humana Press. 1998. Briefly, tissues of an infected plant believed to contain a high concentration of a suitable virus, preferably young leaves and flower petals, are ground in a buffer solution (e.g., phosphate buffer solution) to produce a virus infected sap which can be used in subsequent inoculations.

Construction of plant RNA viruses for the introduction and expression of non-viral exogenous polynucleotide sequences in plants is demonstrated by the above references as well as by Dawson, W. O. et al., Virology (1989) 172:285-292; Takamatsu et al. EMBO J. (1987) 6:307-311: French et al. Science (1986) 231:1294-1297; Takamatsu et al. FEBS Letters (1990) 269:73-76; and U.S. Pat. No. 5,316,931.

When the virus is a DNA virus, suitable modifications can be made to the virus itself. Alternatively, the virus can first be cloned into a bacterial plasmid for ease of constructing the desired viral vector with the foreign DNA. The virus can then be excised from the plasmid. If the virus is a DNA virus, a bacterial origin of replication can be attached to the viral DNA, which is then replicated by the bacteria. Transcription and translation of this DNA will produce the coat protein which will encapsidate the viral DNA. If the virus is an RNA virus, the virus is generally cloned as a cDNA and inserted into a plasmid. The plasmid is then used to make all of the constructions. The RNA virus is then produced by transcribing the viral sequence of the plasmid and translation of the viral genes to produce the coat protein(s) which encapsidate the viral RNA.

In one embodiment, a plant viral polynucleotide is provided in which the native coat protein coding sequence has been deleted from a viral polynucleotide, a non-native plant viral coat protein coding sequence and a non-native promoter, preferably the subgenomic promoter of the non-native coat protein coding sequence, capable of expression in the plant host, packaging of the recombinant plant viral polynucleotide, and ensuring a systemic infection of the host by the recombinant plant viral polynucleotide, has been inserted. Alternatively, the coat protein gene may be inactivated by insertion of the non-native polynucleotide sequence within it, such that a protein is produced. The recombinant plant viral polynucleotide may contain one or more additional non-native subgenomic promoters. Each non-native subgenomic promoter is capable of transcribing or expressing adjacent genes or polynucleotide sequences in the plant host and incapable of recombination with each other and with native subgenomic promoters. Non-native (foreign) polynucleotide sequences may be inserted adjacent the native plant viral subgenomic promoter or the native and a non-native plant viral subgenomic promoters if more than one polynucleotide sequence is included. The non-native polynucleotide sequences are transcribed or expressed in the host plant under control of the subgenomic promoter to produce the desired products.

In a second embodiment, a recombinant plant viral polynucleotide is provided as in the first embodiment except that the native coat protein coding sequence is placed adjacent one of the non-native coat protein subgenomic promoters instead of a non-native coat protein coding sequence.

In a third embodiment, a recombinant plant viral polynucleotide is provided in which the native coat protein gene is adjacent its subgenomic promoter and one or more non-native subgenomic promoters have been inserted into the viral polynucleotide. The inserted non-native subgenomic promoters are capable of transcribing or expressing adjacent genes in a plant host and are incapable of recombination with each other and with native subgenomic promoters. Non-native polynucleotide sequences may be inserted adjacent the non-native subgenomic plant viral promoters such that the sequences are transcribed or expressed in the host plant under control of the subgenomic promoters to produce the desired product.

In a fourth embodiment, a recombinant plant viral polynucleotide is provided as in the third embodiment except that the native coat protein coding sequence is replaced by a non-native coat protein coding sequence.

The viral vectors are encapsidated by the coat proteins encoded by the recombinant plant viral polynucleotide to produce a recombinant plant virus. The recombinant plant viral polynucleotide or recombinant plant virus is used to infect appropriate host plants. The recombinant plant viral polynucleotide is capable of replication in the host, systemic spread in the host, and transcription or expression of foreign gene(s) (exogenous polynucleotide) in the host to produce the desired protein.

Techniques for inoculation of viruses to plants may be found in Foster and Taylor, eds. “Plant Virology Protocols: From Virus Isolation to Transgenic Resistance (Methods in Molecular Biology (Humana Pr), Vol 81)”. Humana Press, 1998; Maramorosh and Koprowski, eds. “Methods in Virology” 7 vols, Academic Press. New York 1967-1984; Hill, S. A. “Methods in Plant Virology”, Blackwell. Oxford, 1984; Walkey, D. G. A. “Applied Plant Virology”, Wiley, New York. 1985: and Kado and Agrawa, eds. “Principles and Techniques in Plant Virology”, Van Nostrand-Reinhold, New York.

In addition to the above, the polynucleotide of the present invention can also be introduced into a chloroplast genome thereby enabling chloroplast expression.

A technique for introducing exogenous polynucleotide sequences to the genome of the chloroplasts is known. This technique involves the following procedures. First, plant cells are chemically treated so as to reduce the number of chloroplasts per cell to about one. Then, the exogenous polynucleotide is introduced via particle bombardment into the cells with the aim of introducing at least one exogenous polynucleotide molecule into the chloroplasts. The exogenous polynucleotides selected such that it is integratable into the chloroplast's genome via homologous recombination which is readily effected by enzymes inherent to the chloroplast. To this end, the exogenous polynucleotide includes, in addition to a gene of interest, at least one polynucleotide stretch which is derived from the chloroplast's genome. In addition, the exogenous polynucleotide includes a selectable marker, which serves by sequential selection procedures to ascertain that all or substantially all of the copies of the chloroplast genomes following such selection will include the exogenous polynucleotide. Further details relating to this technique are found in U.S. Pat. Nos. 4,945,050; and 5,693,507 which are incorporated herein by reference. A polypeptide can thus be produced by the protein expression system of the chloroplast and become integrated into the chloroplast's inner membrane.

According to some embodiments, there is provided a method of improving nitrogen use efficiency, yield, growth rate, biomass, vigor, oil content, oil yield, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, and/or abiotic stress tolerance of a grafted plant, the method comprising providing a scion that does not transgenically express a polynucleotide encoding a polypeptide at least 80% homologous to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629 and a plant rootstock that transgenically expresses a polynucleotide encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% homologous (or identical) to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629 (e.g., in a constitutive, tissue specific or inducible, e.g., in an abiotic stress responsive manner), thereby improving the nitrogen use efficiency, yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, and/or abiotic stress tolerance of the grafted plant.

In some embodiments, the plant scion is non-transgenic.

Several embodiments relate to a grafted plant exhibiting improved nitrogen use efficiency, yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, and/or abiotic stress tolerance, comprising a scion that does not transgenically express a polynucleotide encoding a polypeptide at least 80% homologous to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629 and a plant rootstock that transgenically expresses a polynucleotide encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% homologous (or identical) to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629.

In some embodiments, the plant root stock transgenically expresses a polynucleotide encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% homologous (or identical) to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629 in a stress responsive manner.

According to some embodiments of the invention, the plant root stock transgenically expresses a polynucleotide encoding a polypeptide selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to some embodiments of the invention, the plant root stock transgenically expresses a polynucleotide comprising a nucleic acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the polynucleotide selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028.

According to some embodiments of the invention, the plant root stock transgenically expresses a polynucleotide selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

Since processes which increase nitrogen use efficiency, fertilizer use efficiency, oil content, yield, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, growth rate, biomass, vigor and/or abiotic stress tolerance of a plant can involve multiple genes acting additively or in synergy (see, for example, in Quesda et al., Plant Physiol. 130:951-063, 2002), the present invention also envisages expressing a plurality of exogenous polynucleotides in a single host plant to thereby achieve superior effect on nitrogen use efficiency, fertilizer use efficiency, oil content, yield, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, growth rate, biomass, vigor and/or abiotic stress tolerance.

Expressing a plurality of exogenous polynucleotides in a single host plant can be effected by co-introducing multiple nucleic acid constructs, each including a different exogenous polynucleotide, into a single plant cell. The transformed cell can then be regenerated into a mature plant using the methods described hereinabove.

Alternatively, expressing a plurality of exogenous polynucleotides in a single host plant can be effected by co-introducing into a single plant-cell a single nucleic-acid construct including a plurality of different exogenous polynucleotides. Such a construct can be designed with a single promoter sequence which can transcribe a polycistronic messenger RNA including all the different exogenous polynucleotide sequences. To enable co-translation of the different polypeptides encoded by the polycistronic messenger RNA, the polynucleotide sequences can be inter-linked via an internal ribosome entry site (IRES) sequence which facilitates translation of polynucleotide sequences positioned downstream of the IRES sequence. In this case, a transcribed polycistronic RNA molecule encoding the different polypeptides described above will be translated from both the capped 5′ end and the two internal IRES sequences of the polycistronic RNA molecule to thereby produce in the cell all different polypeptides. Alternatively, the construct can include several promoter sequences each linked to a different exogenous polynucleotide sequence.

The plant cell transformed with the construct including a plurality of different exogenous polynucleotides, can be regenerated into a mature plant, using the methods described hereinabove.

Alternatively, expressing a plurality of exogenous polynucleotides in a single host plant can be effected by introducing different nucleic acid constructs, including different exogenous polynucleotides, into a plurality of plants. The regenerated transformed plants can then be cross-bred and resultant progeny selected for superior abiotic stress tolerance, water use efficiency, fertilizer use efficiency, growth, biomass, yield and/or vigor traits, using conventional plant breeding techniques.

According to some embodiments of the invention, the method further comprising growing the plant expressing the exogenous polynucleotide under the abiotic stress.

Non-limiting examples of abiotic stress conditions include, salinity, osmotic stress, drought, water deprivation, excess of water (e.g., flood, waterlogging), etiolation, low temperature (e.g., cold stress), high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency (e.g., nitrogen deficiency or nitrogen limitation), nutrient excess, atmospheric pollution and UV irradiation.

According to some embodiments of the invention, the method further comprising growing the plant expressing the exogenous polynucleotide under fertilizer limiting conditions (e.g., nitrogen-limiting conditions). Non-limiting examples include growing the plant on soils with low nitrogen content (40-50% Nitrogen of the content present under normal or optimal conditions), or even under sever nitrogen deficiency (0-10% Nitrogen of the content present under normal or optimal conditions), wherein the normal or optimal conditions include about 6-15 mM Nitrogen, e.g., 6-10 mM Nitrogen).

Thus, the invention encompasses plants exogenously expressing the polynucleotide(s), the nucleic acid constructs and/or polypeptide(s) of the invention.

Once expressed within the plant cell or the entire plant, the level of the polypeptide encoded by the exogenous polynucleotide can be determined by methods well known in the art such as, activity assays, Western blots using antibodies capable of specifically binding the polypeptide. Enzyme-Linked Immuno Sorbent Assay (ELISA), radio-immuno-assays (RIA), immunohistochemistry, immunocytochemistry, immunofluorescence and the like.

Methods of determining the level in the plant of the RNA transcribed from the exogenous polynucleotide are well known in the art and include, for example, Northern blot analysis, reverse transcription polymerase chain reaction (RT-PCR) analysis (including quantitative, semi-quantitative or real-time RT-PCR) and RNA-in situ hybridization.

The sequence information and annotations uncovered by the present teachings can be harnessed in favor of classical breeding. Thus, sub-sequence data of those polynucleotides described above, can be used as markers for marker assisted selection (MAS), in which a marker is used for indirect selection of a genetic determinant or determinants of a trait of interest (e.g., biomass, growth rate, oil content, yield, abiotic stress tolerance, water use efficiency, nitrogen use efficiency and/or fertilizer use efficiency). Nucleic acid data of the present teachings (DNA or RNA sequence) may contain or be linked to polymorphic sites or genetic markers on the genome such as restriction fragment length polymorphism (RFLP), microsatellites and single nucleotide polymorphism (SNP), DNA fingerprinting (DFP), amplified fragment length polymorphism (AFLP), expression level polymorphism, polymorphism of the encoded polypeptide and any other polymorphism at the DNA or RNA sequence.

Examples of marker assisted selections include, but are not limited to, selection for a morphological trait (e.g., a gene that affects form, coloration, male sterility or resistance such as the presence or absence of awn, leaf sheath coloration, height, grain color, aroma of rice); selection for a biochemical trait (e.g., a gene that encodes a protein that can be extracted and observed; for example, isozymes and storage proteins); selection for a biological trait (e.g., pathogen races or insect biotypes based on host pathogen or host parasite interaction can be used as a marker since the genetic constitution of an organism can affect its susceptibility to pathogens or parasites).

The polynucleotides and polypeptides described hereinabove can be used in a wide range of economical plants, in a safe and cost effective manner.

Plant lines exogenously expressing the polynucleotide or the polypeptide of the invention are screened to identify those that show the greatest increase of the desired plant trait.

Thus, according to an additional embodiment of the present invention, there is provided a method of evaluating a trait of a plant, the method comprising: (a) expressing in a plant or a portion thereof the nucleic acid construct of some embodiments of the invention; and (b) evaluating a trait of a plant as compared to a wild type plant of the same type (e.g., a plant not transformed with the claimed biomolecules); thereby evaluating the trait of the plant.

According to an aspect of some embodiments of the invention there is provided a method of producing a crop comprising growing a crop of a plant expressing an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous (e.g., identical) to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629, wherein the plant is derived from a plant (parent plant) that has been transformed to express the exogenous polynucleotide and that has been selected for increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency) as compared to a control plant, thereby producing the crop.

According to an aspect of some embodiments of the present invention there is provided a method of producing a crop comprising growing a crop plant transformed with an exogenous polynucleotide encoding a polypeptide at least 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% homologous (e.g., identical) to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629, wherein the crop plant is derived from plants which have been transformed with the exogenous polynucleotide and which have been selected for increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency) as compared to a wild type plant of the same species which is grown under the same growth conditions, and the crop plant having the increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency), thereby producing the crop.

According to some embodiments of the invention the polypeptide is selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to an aspect of some embodiments of the invention there is provided a method of producing a crop comprising growing a crop of a plant expressing an exogenous polynucleotide which comprises a nucleic acid sequence which is at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028, wherein the plant is derived from a plant selected for increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency) as compared to a control plant, thereby producing the crop.

According to an aspect of some embodiments of the present invention there is provided a method of producing a crop comprising growing a crop plant transformed with an exogenous polynucleotide at least 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, or more say 100% identical to the nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028, wherein the crop plant is derived from plants which have been transformed with the exogenous polynucleotide and which have been selected for increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency) as compared to a wild type plant of the same species which is grown under the same growth conditions, and the crop plant having the increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency), thereby producing the crop.

According to some embodiments of the invention the exogenous polynucleotide is selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

According to an aspect of some embodiments of the invention there is provided a method of growing a crop comprising seeding seeds and/or planting plantlets of a plant transformed with the exogenous polynucleotide of the invention, e.g., the polynucleotide which encodes the polypeptide of some embodiments of the invention, wherein the plant is derived from plants which have been transformed with the exogenous polynucleotide and which have been selected for at least one trait selected from the group consisting of increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency) as compared to a non-transformed plant.

According to some embodiments of the invention the method of growing a crop comprising seeding seeds and/or planting plantlets of a plant transformed with an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to SEQ ID NO: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629, wherein the plant is derived from plants which have been transformed with the exogenous polynucleotide and which have been selected for at least one trait selected from the group consisting of increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency) as compared to a non-transformed plant, thereby growing the crop.

According to some embodiments of the invention the polypeptide is selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

According to some embodiments of the invention the method of growing a crop comprising seeding seeds and/or planting plantlets of a plant transformed with an exogenous polynucleotide comprising the nucleic acid sequence at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to SEQ ID NO: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 and 6028, wherein the plant is derived from plants which have been transformed with the exogenous polynucleotide and which have been selected for at least one trait selected from the group consisting of increased abiotic stress tolerance, increased water use efficiency, increased growth rate, increased vigor, increased biomass, increased oil content, increased yield, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and/or increased fertilizer use efficiency (e.g., increased nitrogen use efficiency) as compared to a non-transformed plant, thereby growing the crop.

According to some embodiments of the invention the exogenous polynucleotide is selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

According to an aspect of some embodiments of the present invention there is provided a method of growing a crop comprising:

(a) selecting a parent plant transformed with an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the polypeptide selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629 for at least one trait selected from the group consisting of: increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and increased abiotic stress tolerance as compared to a non-transformed plant of the same species which is grown under the same growth conditions, and

(b) growing a progeny crop plant of the parent plant, wherein the progeny crop plant which comprises the exogenous polynucleotide has the increased yield, the increased growth rate, the increased biomass, the increased vigor, the increased oil content, the increased seed yield, the increased fiber yield, the increased fiber quality, the increased fiber length, the increased photosynthetic capacity, the increased nitrogen use efficiency, and/or the increased abiotic stress,

thereby growing the crop.

According to an aspect of some embodiments of the present invention there is provided a method of producing seeds of a crop comprising:

(a) selecting parent plant transformed with an exogenous polynucleotide comprising a nucleic acid sequence encoding a polypeptide at least about 80%, at least about 81%, at least about 82%, at least about 83%, at least about 84%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, e.g., 100% identical to the polypeptide selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 and 10629 for at least one trait selected from the group consisting of: increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and increased abiotic stress as compared to a non-transformed plant of the same species which is grown under the same growth conditions,

(b) growing a seed producing plant from the parent plant resultant of step (a), wherein the seed producing plant which comprises the exogenous polynucleotide having the increased yield, the increased growth rate, the increased biomass, the increased vigor, the increased oil content, the increased seed yield, the increased fiber yield, the increased fiber quality, the increased fiber length, the increased photosynthetic capacity, the increased nitrogen use efficiency, and/or the increased abiotic stress, and

(c) producing seeds from the seed producing plant resultant of step (b), thereby producing seeds of the crop.

According to some embodiments of the invention, the seeds produced from the seed producing plant comprise the exogenous polynucleotide.

According to an aspect of some embodiments of the present invention there is provided a method of growing a crop comprising:

(a) selecting a parent plant transformed with an exogenous polynucleotide comprising a nucleic acid sequence encoding the polypeptide selected from the group consisting of set forth in SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629, for at least one trait selected from the group consisting of: increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and increased abiotic stress tolerance as compared to a non-transformed plant of the same species which is grown under the same growth conditions, and

(b) growing progeny crop plant of the parent plant, wherein the progeny crop plant which comprises the exogenous polynucleotide has the increased yield, the increased growth rate, the increased biomass, the increased vigor, the increased oil content, the increased seed yield, the increased fiber yield, the increased fiber quality, the increased fiber length, the increased photosynthetic capacity, the increased nitrogen use efficiency, and/or the increased abiotic stress.

thereby growing the crop.

According to an aspect of some embodiments of the present invention there is provided a method of producing seeds of a crop comprising:

(a) selecting parent plant transformed with an exogenous polynucleotide comprising a nucleic acid sequence encoding the polypeptide selected from the group consisting of set forth in SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629 for at least one trait selected from the group consisting of: increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and increased abiotic stress as compared to a non-transformed plant of the same species which is grown under the same growth conditions.

(b) growing a seed producing plant from the parent plant resultant of step (a), wherein the seed producing plant which comprises the exogenous polynucleotide having the increased yield, the increased growth rate, the increased biomass, the increased vigor, the increased oil content, the increased seed yield, the increased fiber yield, the increased fiber quality, the increased fiber length, the increased photosynthetic capacity, the increased nitrogen use efficiency, and/or the increased abiotic stress, and

(c) producing seeds from the seed producing plant resultant of step (b).

thereby producing seeds of the crop.

According to some embodiments of the invention the exogenous polynucleotide is selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

The effect of the transgene (the exogenous polynucleotide encoding the polypeptide) on abiotic stress tolerance can be determined using known methods such as detailed below and in the Examples section which follows.

Abiotic stress tolerance—Transformed (i.e., expressing the transgene) and non-transformed (wild type) plants are exposed to an abiotic stress condition, such as water deprivation, suboptimal temperature (low temperature, high temperature), nutrient deficiency (e.g., nitrogen deficiency or limiting nitrogen conditions), nutrient excess, a salt stress condition, osmotic stress, heavy metal toxicity, anaerobiosis, atmospheric pollution and UV irradiation.

Salinity tolerance assay—Transgenic plants with tolerance to high salt concentrations are expected to exhibit better germination, seedling vigor or growth in high salt. Salt stress can be effected in many ways such as, for example, by irrigating the plants with a hyperosmotic solution, by cultivating the plants hydroponically in a hyperosmotic growth solution (e.g., Hoagland solution), or by culturing the plants in a hyperosmotic growth medium [e.g., 50% Murashige-Skoog medium (MS medium)]. Since different plants vary considerably in their tolerance to salinity, the salt concentration in the irrigation water, growth solution, or growth medium can be adjusted according to the specific characteristics of the specific plant cultivar or variety, so as to inflict a mild or moderate effect on the physiology and/or morphology of the plants (for guidelines as to appropriate concentration see, Bernstein and Kafkafi, Root Growth Under Salinity Stress In: Plant Roots, The Hidden Half 3rd ed. Waisel Y, Eshel A and Kafkafi U. (editors) Marcel Dekker Inc., New York, 2002, and reference therein).

For example, a salinity tolerance test can be performed by irrigating plants at different developmental stages with increasing concentrations of sodium chloride (for example 50 mM, 100 mM, 200 mM, 400 mM NaCl) applied from the bottom and from above to ensure even dispersal of salt. Following exposure to the stress condition the plants are frequently monitored until substantial physiological and/or morphological effects appear in wild type plants. Thus, the external phenotypic appearance, degree of wilting and overall success to reach maturity and yield progeny are compared between control and transgenic plants.

Quantitative parameters of tolerance measured include, but are not limited to, the average wet and dry weight, growth rate, leaf size, leaf coverage (overall leaf area), the weight of the seeds yielded, the average seed size and the number of seeds produced per plant. Transformed plants not exhibiting substantial physiological and/or morphological effects, or exhibiting higher biomass than wild-type plants, are identified as abiotic stress tolerant plants.

Osmotic tolerance test—Osmotic stress assays (including sodium chloride and mannitol assays) are conducted to determine if an osmotic stress phenotype was sodium chloride-specific or if it was a general osmotic stress related phenotype. Plants which are tolerant to osmotic stress may have more tolerance to drought and/or freezing. For salt and osmotic stress germination experiments, the medium is supplemented for example with 50 mM, 100 mM, 200 mM NaCl or 100 mM, 200 mM NaCl, 400 mM mannitol.

Drought tolerance assay/Osmoticum assay—Tolerance to drought is performed to identify the genes conferring better plant survival after acute water deprivation. To analyze whether the transgenic plants are more tolerant to drought, an osmotic stress produced by the non-ionic osmolyte sorbitol in the medium can be performed. Control and transgenic plants are germinated and grown in plant-agar plates for 4 days, after which they are transferred to plates containing 500 mM sorbitol. The treatment causes growth retardation, then both control and transgenic plants are compared, by measuring plant weight (wet and dry), yield, and by growth rates measured as time to flowering.

Conversely, soil-based drought screens are performed with plants overexpressing the polynucleotides detailed above. Seeds from control Arabidopsis plants, or other transgenic plants overexpressing the polypeptide of the invention are germinated and transferred to pots. Drought stress is obtained after irrigation is ceased accompanied by placing the pots on absorbent paper to enhance the soil-drying rate. Transgenic and control plants are compared to each other when the majority of the control plants develop severe wilting. Plants are re-watered after obtaining a significant fraction of the control plants displaying a severe wilting. Plants are ranked comparing to controls for each of two criteria: tolerance to the drought conditions and recovery (survival) following re-watering. Additional drought assays are described in the Examples section which follows (e.g., Examples 29 and 30 below).

Cold stress tolerance—To analyze cold stress, mature (25 day old) plants are transferred to 4° C. chambers for 1 or 2 weeks, with constitutive light. Later on plants are moved back to greenhouse. Two weeks later damages from chilling period, resulting in growth retardation and other phenotypes, are compared between both control and transgenic plants, by measuring plant weight (wet and dry), and by comparing growth rates measured as time to flowering, plant size, yield, and the like.

Heat stress tolerance—Heat stress tolerance is achieved by exposing the plants to temperatures above 34° C. for a certain period. Plant tolerance is examined after transferring the plants back to 22° C. for recovery and evaluation after 5 days relative to internal controls (non-transgenic plants) or plants not exposed to neither cold or heat stress.

Water use efficiency—can be determined as the biomass produced per unit transpiration. To analyze WUE, leaf relative water content can be measured in control and transgenic plants. Fresh weight (FW) is immediately recorded; then leaves are soaked for 8 hours in distilled water at room temperature in the dark, and the turgid weight (TW) is recorded. Total dry weight (DW) is recorded after drying the leaves at 60° C. to a constant weight. Relative water content (RWC) is calculated according to the following Formula I:

Formula I

RWC=[(FW−DW)/(TW−DW)]×100

Fertilizer use efficiency—To analyze whether the transgenic plants are more responsive to fertilizers, plants are grown in agar plates or pots with a limited amount of fertilizer, as described, for example, in Yanagisawa et al (Proc Natl Acad Sci USA. 2004; 101:7833-8). The plants are analyzed for their overall size, time to flowering, yield, protein content of shoot and/or grain. The parameters checked are the overall size of the mature plant, its wet and dry weight, the weight of the seeds yielded, the average seed size and the number of seeds produced per plant. Other parameters that may be tested are: the chlorophyll content of leaves (as nitrogen plant status and the degree of leaf verdure is highly correlated), amino acid and the total protein content of the seeds or other plant parts such as leaves or shoots, oil content, etc. Similarly, instead of providing nitrogen at limiting amounts, phosphate or potassium can be added at increasing concentrations. Again, the same parameters measured are the same as listed above. In this way, nitrogen use efficiency (NUE), phosphate use efficiency (PUE) and potassium use efficiency (KUE) are assessed, checking the ability of the transgenic plants to thrive under nutrient restraining conditions.

Nitrogen use efficiency—To analyze whether the transgenic plants (e.g., Arabidopsis plants) are more responsive to nitrogen, plant are grown in 0.75-3 mM (nitrogen deficient conditions) or 6-10 mM (optimal nitrogen concentration). Plants are allowed to grow for additional 25 days or until seed production. The plants are then analyzed for their overall size, time to flowering, yield, protein content of shoot and/or grain/seed production. The parameters checked can be the overall size of the plant, wet and dry weight, the weight of the seeds yielded, the average seed size and the number of seeds produced per plant. Other parameters that may be tested are: the chlorophyll content of leaves (as nitrogen plant status and the degree of leaf greenness is highly correlated), amino acid and the total protein content of the seeds or other plant parts such as leaves or shoots and oil content. Transformed plants not exhibiting substantial physiological and/or morphological effects, or exhibiting higher measured parameters levels than wild-type plants, are identified as nitrogen use efficient plants.

Nitrogen limiting conditions and nitrogen use efficiency assay using plantlets—The assay is done according to Yanagisawa-S. et al. with minor modifications (“Metabolic engineering with Dof1 transcription factor in plants: Improved nitrogen assimilation and growth under low-nitrogen conditions” Proc. Natl. Acad. Sci. USA 101, 7833-7838). Briefly, transgenic plants which are grown for 7-10 days in 0.5×MS [Murashige-Skoog] supplemented with a selection agent are transferred to two nitrogen-limiting conditions: MS media in which the combined nitrogen concentration (NH₄NO₃ and KNO₃) was 0.75 mM (nitrogen deficient conditions) or 6-15 mM (optimal nitrogen concentration). Plants are allowed to grow for additional 30-40 days and then photographed, individually removed from the Agar (the shoot without the roots) and immediately weighed (fresh weight) for later statistical analysis. Constructs for which only T1 seeds are available are sown on selective media and at least 20 seedlings (each one representing an independent transformation event) are carefully transferred to the nitrogen-limiting media. For constructs for which T2 seeds are available, different transformation events are analyzed. Usually, 20 randomly selected plants from each event are transferred to the nitrogen-limiting media allowed to grow for 3-4 additional weeks and individually weighed at the end of that period. Transgenic plants are compared to control plants grown in parallel under the same conditions. Mock-transgenic plants expressing the uidA reporter gene (GUS) under the same promoter or transgenic plants carrying the same promoter but lacking a reporter gene are used as control. Additional assays for measuring tolerance to nitrogen limiting (deficient) conditions are described in Examples 29-32 in the Examples section which follows).

Nitrogen determination—The procedure for N (nitrogen) concentration determination in the structural parts of the plants involves the potassium persulfate digestion method to convert organic N to NO₃⁻ (Purcell and King 1996 Argon. J. 88:111-113, the modified Cd⁻ mediated reduction of NO₃⁻ to NO₂⁻ (Vodovotz 1996 Biotechniques 20:390-394) and the measurement of nitrite by the Griess assay (Vodovotz 1996, supra). The absorbance values are measured at 550 nm against a standard curve of NaNO₂. The procedure is described in details in Samonte et al. 2006 Agron. J. 98:168-176.

Germination tests—Germination tests compare the percentage of seeds from transgenic plants that could complete the germination process to the percentage of seeds from control plants that are treated in the same manner. Normal conditions are considered for example, incubations at 22° C. under 22-hour light 2-hour dark daily cycles. Evaluation of germination and seedling vigor is conducted between 4 and 14 days after planting. The basal media is 50% MS medium (Murashige and Skoog. 1962 Plant Physiology 15, 473-497).

Germination is checked also at unfavorable conditions such as cold (incubating at temperatures lower than 10° C. instead of 22° C.) or using seed inhibition solutions that contain high concentrations of an osmolyte such as sorbitol (at concentrations of 50 mM, 100 mM, 200 mM, 300 mM, 500 mM, and up to 1000 mM) or applying increasing concentrations of salt (of 50 mM, 100 mM, 200 mM, 300 mM, 500 mM NaCl).

The effect of the transgene on plant's vigor, growth rate, biomass, yield and/or oil content can be determined using known methods.

Plant vigor—The plant vigor can be calculated by the increase in growth parameters such as leaf area, fiber length, rosette diameter, plant fresh weight and the like per time.

Growth rate—The growth rate can be measured using digital analysis of growing plants. For example, images of plants growing in greenhouse on plot basis can be captured every 3 days and the rosette area can be calculated by digital analysis. Rosette area growth is calculated using the difference of rosette area between days of sampling divided by the difference in days between samples.

It should be noted that an increase in rosette parameters such as rosette area, rosette diameter and/or rosette growth rate in a plant model such as Arabidopsis predicts an increase in canopy coverage and/or plot coverage in a target plant such as Brassica sp., soy, corn, wheat, Barley, oat, cotton, rice, tomato, sugar beet, and vegetables such as lettuce.

Evaluation of growth rate can be done by measuring plant biomass produced, rosette area, leaf size or root length per time (can be measured in cm² per day of leaf area).

Relative growth area can be calculated using Formula II.

Formula II:

Relative growth rate area=Regression coefficient of area along time course

Thus, the relative growth area rate is in units of area units (e.g., mm²/day or cm²/day) and the relative length growth rate is in units of length units (e.g., cm/day or mm/day).

For example, RGR can be determined for plant height (Formula III), SPAD (Formula IV), Number of tillers (Formula V), root length (Formula VI), vegetative growth (Formula VII), leaf number (Formula VIII), rosette area (Formula IX), rosette diameter (Formula X), plot coverage (Formula XI), leaf blade area (Formula XII), and leaf area (Formula XIII).

Formula III: Relative growth rate of Plant height=Regression coefficient of Plant height along time course (measured in cm/day).

Formula IV: Relative growth rate of SPAD=Regression coefficient of SPAD measurements along time course.

Formula V: Relative growth rate of Number of tillers=Regression coefficient of Number of tillers along time course (measured in units of “number of tillers/day”).

Formula VI: Relative growth rate of root length=Regression coefficient of root length along time course (measured in cm per day).

Vegetative growth rate analysis—was calculated according to Formula VII below.

Formula VII: Relative growth rate of vegetative growth=Regression coefficient of vegetative dry weight along time course (measured in grams per day).

Formula VIII: Relative growth rate of leaf number=Regression coefficient of leaf number along time course (measured in number per day).

Formula IX: Relative growth rate of rosette area=Regression coefficient of rosette area along time course (measured in cm² per day).

Formula X: Relative growth rate of rosette diameter=Regression coefficient of rosette diameter along time course (measured in cm per day).

Formula XI: Relative growth rate of plot coverage=Regression coefficient of plot (measured in cm² per day).

Formula XII: Relative growth rate of leaf blade area=Regression coefficient of leaf area along time course (measured in cm² per day).

Formula XIII: Relative growth rate of leaf area=Regression coefficient of leaf area along time course (measured in cm² per day).

Formula XIV: 1000 Seed Weight=number of seed in sample/sample weight X 1000 The Harvest Index can be calculated using Formulas XV. XVI, XVII, XVIII and LXV below.

Formula XV: Harvest Index (seed)=Average seed yield per plant/Average dry weight.

Formula XVI: Harvest Index (Sorghum)=Average grain dry weight per Head/(Average vegetative dry weight per Head+Average Head dry weight) Formula XVII: Harvest Index (Maize)=Average grain weight per plant/(Average vegetative dry weight per plant plus Average grain weight per plant)

Harvest Index (for barley)—The harvest index is calculated using Formula XVIII.

Formula XVIII: Harvest Index (for barley and wheat)=Average spike dry weight per plant/(Average vegetative dry weight per plant+Average spike dry weight per plant)

Following is a non-limited list of additional parameters which can be detected in order to show the effect of the transgene on the desired plant's traits:

Formula XIX: Grain circularity=4×3.14 (grain area/perimeter²)

Formula XX: Internode volume=3.14×(d/2)²×1

Formula XXI: Total dry matter (kg)=Normalized head weight per plant+vegetative dry weight.

Formula XXII: Root/Shoot Ratio=total weight of the root at harvest/total weight of the vegetative portion above ground at harvest. (=RBiH/BiH)

Formula XXIII: Ratio of the number of pods per node on main stem at pod set=Total number of pods on main stem/Total number of nodes on main stem.

Formula XXIV: Ratio of total number of seeds in main stem to number of seeds on lateral branches=Total number of seeds on main stem at pod set/Total number of seeds on lateral branches at pod set.

Formula XXV: Petiole Relative Area=(Petiole area)/Rosette area (measured in %).

Formula XXVI: percentage of reproductive tiller=Number of Reproductive tillers/number of tillers)×100.

Formula XXVII: Spikes Index=Average Spikes weight per plant/(Average vegetative dry weight per plant plus Average Spikes weight per plant).

Formula XXVIII:

Relative growth rate of root coverage=Regression coefficient of root coverage along time course.

Formula XXIX:

Seed Oil yield=Seed yield per plant (gr.)*Oil % in seed.

Formula XXX: shoot/root Ratio=total weight of the vegetative portion above ground at harvest/total weight of the root at harvest.

Formula XXXI: Spikelets Index=Average Spikelets weight per plant/(Average vegetative dry weight per plant plus Average Spikelets weight per plant).

Formula XXXII: % Canopy coverage=(1−(PAR_DOWN/PAR_UP))×100 measured using AccuPAR Ceptometer Model LP-80.

Formula XXXIII: leaf mass fraction=Leaf area/shoot FW.

Formula XXXIV: Relative growth rate based on dry weight=Regression coefficient of dry weight along time course.

Formula XXXV: Dry matter partitioning (ratio)—At the end of the growing period 6 plants heads as well as the rest of the plot heads were collected, threshed and grains were weighted to obtain grains yield per plot. Dry matter partitioning was calculated by dividing grains yield per plot to vegetative dry weight per plot.

Formula XXXVI: 1000 grain weight filling rate (gr/day)—The rate of grain filling was calculated by dividing 1000 grain weight by grain fill duration.

Formula XXXVII: Specific leaf area (cm²/gr)—Leaves were scanned to obtain leaf area per plant, and then were dried in an oven to obtain the leaves dry weight. Specific leaf area was calculated by dividing the leaf area by leaf dry weight.

Formula XXXVIII: Vegetative dry weight per plant at flowering/water until flowering (gr/lit)—Calculated by dividing vegetative dry weight (excluding roots and reproductive organs) per plant at flowering by the water used for irrigation up to flowering

Formula XXXIX: Yield filling rate (gr/day)—The rate of grain filling was calculated by dividing grains Yield by grain fill duration.

Formula XXXX: Yield per dunam/water until tan (kg/lit)—Calculated by dividing Grains yield per dunam by water used for irrigation until tan.

Formula XXXXI: Yield per plant/water until tan (gr/lit)—Calculated by dividing Grains yield per plant by water used for irrigation until tan

Formula XXXXII: Yield per dunam/water until maturity (gr/lit)—Calculated by dividing grains yield per dunam by the water used for irrigation up to maturity. “Lit”=Liter.

Formula XXXXIII: Vegetative dry weight per plant/water until maturity (gr/lit): Calculated by dividing vegetative dry weight per plant (excluding roots and reproductive organs) at harvest by the water used for irrigation up to maturity.

Formula XXXXIV: Total dry matter per plant/water until maturity (gr/lit): Calculated by dividing total dry matter at harvest (vegetative and reproductive, excluding roots) per plant by the water used for irrigation up to maturity.

Formula XXXXV: Total dry matter per plant/water until flowering (gr/lit): Calculated by dividing total dry matter at flowering (vegetative and reproductive, excluding roots) per plant by the water used for irrigation up to flowering.

Formula XXXXVI: Heads index (ratio): Average heads weight/(Average vegetative dry weight per plant plus Average heads weight per plant).

Formula XXXXVII: Yield/SPAD (kg/SPAD units)—Calculated by dividing grains yield by average SPAD measurements per plot.

Formula XXXXVIII: Stem water content (percentage)—stems were collected and fresh weight (FW) was weighted. Then the stems were oven dry and dry weight (DW) was recorded. Stems dry weight was divided by stems fresh weight, subtracted from 1 and multiplied by 100.

Formula XXXXIX: Leaf water content (percentage)—Leaves were collected and fresh weight (FW) was weighted. Then the leaves were oven dry and dry weight (DW) was recorded. Leaves dry weight was divided by leaves fresh weight, subtracted from 1 and multiplied by 100.

Formula L: stem volume (cm³)—The average stem volume was calculated by multiplying the average stem length by (3.14*((mean lower and upper stem width)/2)̂2).

Formula LI: NUE—is the ratio between total grain yield per total nitrogen (applied+content) in soil.

Formula LII: NUpE—Is the ratio between total plant N content per total N (applied+content) in soil.

Formula LIII: Total NUtE—Is the ratio between total dry matter per N content of total dry matter.

Formula LIV: Stem density—is the ratio between internode dry weight and internode volume.

Formula LV: Grain NUtE—Is the ratio between grain yield per N content of total dry matter

Formula LVI: N harvest index (Ratio)—Is the ratio between nitrogen content in grain per plant and the nitrogen of whole plant at harvest.

Formula LVII: Biomass production efficiency—is the ratio between plant biomass and total shoot N.

Formula LVIII: Harvest index (plot) (ratio)—Average seed yield per plot/Average dry weight per plot.

Formula LIX: Relative growth rate of petiole relative area—Regression coefficient of petiole relative area along time course (measured in cm² per day).

Formula LX: Yield per spike filling rate (gr/day)—spike filling rate was calculated by dividing grains yield per spike to grain fill duration.

Formula LXI: Yield per micro plots filling rate (gr/day)—micro plots filling rate was calculated by dividing grains yield per micro plots to grain fill duration.

Formula LXII: Grains yield per hectare [ton/ha]—all spikes per plot were harvested threshed and grains were weighted after sun dry. The resulting value was divided by the number of square meters and multiplied by 10,000 (10,000 square meters=1 hectare).

Formula LXIII: Total dry matter (for Maize)=Normalized ear weight per plant+vegetative dry weight.

$\mathrm{Formula}\mathrm{LXIV}\text{::}$ $\mathrm{Agronomical}\mathrm{NUE}=\frac{\begin{array}{c}\mathrm{Yield}\mathrm{per}\mathrm{plant}{\left(\mathrm{Kg}.\right)}^{X\mathrm{Nitrogen}\mathrm{Fertilization}}-\\ \mathrm{Yield}\mathrm{per}\mathrm{plant}{\left(\mathrm{Kg}.\right)}^{0\%\mathrm{Nitrogen}\mathrm{Fertilization}}\end{array}}{{\mathrm{Fertilizer}}^X}$

Formula LXV: Harvest Index (brachypodium)=Average grain weight/average dry (vegetative+spikelet) weight per plant.

Formula LXVI: Harvest Index for Sorghum* (* when the plants were not dried)=FW (fresh weight) Heads/(FW Heads+FW Plants)

Grain protein concentration—Grain protein content (g grain protein m⁻²) is estimated as the product of the mass of grain N (g grain N m⁻²) multiplied by the N/protein conversion ratio of k-5.13 (Mosse 1990, supra). The grain protein concentration is estimated as the ratio of grain protein content per unit mass of the grain (g grain protein kg⁻¹ grain).

Fiber length—Fiber length can be measured using fibrograph. The fibrograph system was used to compute length in terms of “Upper Half Mean” length. The upper half mean (UHM) is the average length of longer half of the fiber distribution. The fibrograph measures length in span lengths at a given percentage point (cottoninc (dot) com/ClassificationofCotton/?Pg=4#Length).

According to some embodiments of the invention, increased yield of corn may be manifested as one or more of the following: increase in the number of plants per growing area, increase in the number of ears per plant, increase in the number of rows per ear, number of kernels per ear row, kernel weight, thousand kernel weight (1000-weight), ear length/diameter, increase oil content per kernel and increase starch content per kernel.

As mentioned, the increase of plant yield can be determined by various parameters. For example, increased yield of rice may be manifested by an increase in one or more of the following: number of plants per growing area, number of panicles per plant, number of spikelets per panicle, number of flowers per panicle, increase in the seed filling rate, increase in thousand kernel weight (1000-weight), increase oil content per seed, increase starch content per seed, among others. An increase in yield may also result in modified architecture, or may occur because of modified architecture.

Similarly, increased yield of soybean may be manifested by an increase in one or more of the following: number of plants per growing area, number of pods per plant, number of seeds per pod, increase in the seed filling rate, increase in thousand seed weight (1000-weight), reduce pod shattering, increase oil content per seed, increase protein content per seed, among others. An increase in yield may also result in modified architecture, or may occur because of modified architecture.

Increased yield of canola may be manifested by an increase in one or more of the following: number of plants per growing area, number of pods per plant, number of seeds per pod, increase in the seed filling rate, increase in thousand seed weight (1000-weight), reduce pod shattering, increase oil content per seed, among others. An increase in yield may also result in modified architecture, or may occur because of modified architecture.

Increased yield of cotton may be manifested by an increase in one or more of the following: number of plants per growing area, number of bolls per plant, number of seeds per boll, increase in the seed filling rate, increase in thousand seed weight (1000-weight), increase oil content per seed, improve fiber length, fiber strength, among others. An increase in yield may also result in modified architecture, or may occur because of modified architecture.

Oil content—The oil content of a plant can be determined by extraction of the oil from the seed or the vegetative portion of the plant. Briefly, lipids (oil) can be removed from the plant (e.g., seed) by grinding the plant tissue in the presence of specific solvents (e.g., hexane or petroleum ether) and extracting the oil in a continuous extractor. Indirect oil content analysis can be carried out using various known methods such as Nuclear Magnetic Resonance (NMR) Spectroscopy, which measures the resonance energy absorbed by hydrogen atoms in the liquid state of the sample [See for example, Conway T F. and Earle F R., 1963, Journal of the American Oil Chemists' Society; Springer Berlin/Heidelberg, ISSN: 0003-021X (Print) 1558-9331 (Online)]; the Near Infrared (NI) Spectroscopy, which utilizes the absorption of near infrared energy (1100-2500 nm) by the sample; and a method described in WO/2001/023884, which is based on extracting oil a solvent, evaporating the solvent in a gas stream which forms oil particles, and directing a light into the gas stream and oil particles which forms a detectable reflected light.

Thus, the present invention is of high agricultural value for promoting the yield of commercially desired crops (e.g., biomass of vegetative organ such as poplar wood, or reproductive organ such as number of seeds or seed biomass).

Any of the transgenic plants described hereinabove or parts thereof may be processed to produce a feed, meal, protein or oil preparation, such as for ruminant animals.

The transgenic plants described hereinabove, which exhibit an increased oil content can be used to produce plant oil (by extracting the oil from the plant).

The plant oil (including the seed oil and/or the vegetative portion oil) produced according to the method of the invention may be combined with a variety of other ingredients. The specific ingredients included in a product are determined according to the intended use. Exemplary products include animal feed, raw material for chemical modification, biodegradable plastic, blended food product, edible oil, biofuel, cooking oil, lubricant, biodiesel, snack food, cosmetics, and fermentation process raw material. Exemplary products to be incorporated to the plant oil include animal feeds, human food products such as extruded snack foods, breads, as a food binding agent, aquaculture feeds, fermentable mixtures, food supplements, sport drinks, nutritional food bars, multi-vitamin supplements, diet drinks, and cereal foods.

According to some embodiments of the invention, the oil comprises a seed oil.

According to some embodiments of the invention, the oil comprises a vegetative portion oil (oil of the vegetative portion of the plant).

According to some embodiments of the invention, the plant cell forms a part of a plant.

According to another embodiment of the present invention, there is provided a food or feed comprising the plants or a portion thereof of the present invention.

As used herein the term “about” refers to ±10%.

The terms “comprises”, “comprising”, “includes”. “including”, “having” and their conjugates mean “including but not limited to”.

The term “consisting of” means “including and limited to”.

The term “consisting essentially of” means that the composition, method or structure may include additional ingredients, steps and/or parts, but only if the additional ingredients, steps and/or parts do not materially alter the basic and novel characteristics of the claimed composition, method or structure.

As used herein, the singular form “a”, “an” and “the” include plural references unless the context clearly dictates otherwise. For example, the term “a compound” or “at least one compound” may include a plurality of compounds, including mixtures thereof.

Throughout this application, various embodiments of this invention may be presented in a range format. It should be understood that the description in range format is merely for convenience and brevity and should not be construed as an inflexible limitation on the scope of the invention. Accordingly, the description of a range should be considered to have specifically disclosed all the possible subranges as well as individual numerical values within that range. For example, description of a range such as from 1 to 6 should be considered to have specifically disclosed subranges such as from 1 to 3, from 1 to 4, from 1 to 5, from 2 to 4, from 2 to 6, from 3 to 6 etc., as well as individual numbers within that range, for example, 1, 2, 3, 4, 5, and 6. This applies regardless of the breadth of the range.

Whenever a numerical range is indicated herein, it is meant to include any cited numeral (fractional or integral) within the indicated range. The phrases “ranging/ranges between” a first indicate number and a second indicate number and “ranging/ranges from” a first indicate number “to” a second indicate number are used herein interchangeably and are meant to include the first and second indicated numbers and all the fractional and integral numerals therebetween.

As used herein the term “method” refers to manners, means, techniques and procedures for accomplishing a given task including, but not limited to, those manners, means, techniques and procedures either known to, or readily developed from known manners, means, techniques and procedures by practitioners of the chemical, pharmacological, biological, biochemical and medical arts.

When reference is made to particular sequence listings, such reference is to be understood to also encompass sequences that substantially correspond to its complementary sequence as including minor sequence variations, resulting from, e.g., sequencing errors, cloning errors, or other alterations resulting in base substitution, base deletion or base addition, provided that the frequency of such variations is less than 1 in 50 nucleotides, alternatively, less than 1 in 100 nucleotides, alternatively, less than 1 in 200 nucleotides, alternatively, less than 1 in 500 nucleotides, alternatively, less than 1 in 1000 nucleotides, alternatively, less than 1 in 5,000 nucleotides, alternatively, less than 1 in 10.000 nucleotides.

It is appreciated that certain features of the invention, which are, for clarity, described in the context of separate embodiments, may also be provided in combination in a single embodiment. Conversely, various features of the invention, which are, for brevity, described in the context of a single embodiment, may also be provided separately or in any suitable subcombination or as suitable in any other described embodiment of the invention. Certain features described in the context of various embodiments are not to be considered essential features of those embodiments, unless the embodiment is inoperative without those elements.

Various embodiments and aspects of the present invention as delineated hereinabove and as claimed in the claims section below find experimental support in the following examples.

EXAMPLES

Reference is now made to the following examples, which together with the above descriptions illustrate some embodiments of the invention in a non limiting fashion.

Generally, the nomenclature used herein and the laboratory procedures utilized in the present invention include molecular, biochemical, microbiological and recombinant DNA techniques. Such techniques are thoroughly explained in the literature. See, for example, “Molecular Cloning: A laboratory Manual” Sambrook et al., (1989); “Current Protocols in Molecular Biology” Volumes I-III Ausubel, R. M., ed. (1994); Ausubel et al., “Current Protocols in Molecular Biology”. John Wiley and Sons, Baltimore, Md. (1989); Perbal. “A Practical Guide to Molecular Cloning”, John Wiley & Sons, New York (1988); Watson et al., “Recombinant DNA”. Scientific American Books, New York; Birren et al. (eds) “Genome Analysis: A Laboratory Manual Series”, Vols. 1-4. Cold Spring Harbor Laboratory Press, New York (1998); methodologies as set forth in U.S. Pat. Nos. 4,666,828; 4,683,202; 4,801,531; 5,192,659 and 5,272,057; “Cell Biology: A Laboratory Handbook”, Volumes I-III Cellis, J. E., ed. (1994); “Current Protocols in Immunology” Volumes I-III Coligan J. E., ed. (1994); Stites et al. (eds), “Basic and Clinical Immunology” (8th Edition), Appleton & Lange. Norwalk, Conn. (1994); Mishell and Shiigi (eds), “Selected Methods in Cellular Immunology”, W. H. Freeman and Co., New York (1980): available immunoassays are extensively described in the patent and scientific literature, see, for example, U.S. Pat. Nos. 3,791,932; 3,839,153; 3,850,752; 3,850,578; 3,853,987; 3,867,517; 3,879,262; 3,901,654; 3,935,074; 3,984,533; 3,996,345; 4,034,074; 4,098,876; 4,879,219; 5,011,771 and 5,281,521; “Oligonucleotide Synthesis” Gait. M. J., ed. (1984); “Nucleic Acid Hybridization” Hames. B. D., and Higgins S. J., eds. (1985); “Transcription and Translation” Hames, B. D., and Higgins S. J., Eds. (1984): “Animal Cell Culture” Freshney. R. I., ed. (1986); “Immobilized Cells and Enzymes” IRL Press. (1986); “A Practical Guide to Molecular Cloning” Perbal. B., (1984) and “Methods in Enzymology” Vol. 1-317, Academic Press; “PCR Protocols: A Guide To Methods And Applications”. Academic Press, San Diego, Calif. (1990); Marshak et al., “Strategies for Protein Purification and Characterization—A Laboratory Course Manual” CSHL Press (1996); all of which are incorporated by reference as if fully set forth herein. Other general references are provided throughout this document. The procedures therein are believed to be well known in the art and are provided for the convenience of the reader.

All the information contained therein is incorporated herein by reference.

General Experimental and Bioinformatics Methods

RNA extraction—Tissues growing at various growth conditions (as described below) were sampled and RNA was extracted using TRIzol Reagent from Invitrogen [invitrogen (dot) corn/content (dot)cfm?pageid=469]. Approximately 30-50 mg of tissue was taken from samples. The weighed tissues were ground using pestle and mortar in liquid nitrogen and resuspended in 500 μl of TRIzol Reagent. To the homogenized lysate, 100 μl of chloroform was added followed by precipitation using isopropanol and two washes with 75% ethanol. The RNA was eluted in 30 μl of RNase-free water. RNA samples were cleaned up using Qiagen's RNeasy minikit clean-up protocol as per the manufacturer's protocol (QIAGEN Inc, CA USA). For convenience, each micro-array expression information tissue type has received an expression Set ID.

Correlation analysis—was performed for selected genes according to some embodiments of the invention, in which the characterized parameters (measured parameters according to the correlation IDs) were used as “X axis” for correlation with the tissue transcriptome, which was used as the “Y axis”. For each gene and measured parameter a correlation coefficient “R” was calculated (using Pearson correlation) along with a p-value for the significance of the correlation. When the correlation coefficient (R) between the levels of a gene's expression in a certain tissue and a phenotypic performance across ecotypes/variety/hybrid is high in absolute value (between 0.5-1), there is an association between the gene (specifically the expression level of this gene) and the phenotypic characteristic (e.g., improved yield, growth rate, nitrogen use efficiency, abiotic stress tolerance and the like).

Example 1

Identifying Genes which Improve Yield and Agronomical Important Traits in Plants

The present inventors have identified polynucleotides which expression thereof in plants can increase yield, seed yield, fiber yield, fiber quality, growth rate, vigor, biomass, growth rate, oil content, abiotic stress tolerance (ABST), fertilizer use efficiency (FUE) such as nitrogen use efficiency (NUE), and water use efficiency (WUE) of a plant, as follows.

All nucleotide sequence datasets used here were originated from publicly available databases or from performing sequencing using the Solexa technology (e.g. Barley and Sorghum). Sequence data from 100 different plant species was introduced into a single, comprehensive database. Other information on gene expression, protein annotation, enzymes and pathways were also incorporated.

Major databases used include:

Genomes

Arabidopsis genome [TAIR genome version 6 (arabidopsis (dot) org/)];

Rice genome [IRGSP build 4.0 (rgp (dot) dna (dot) affrc (dot) go (dot) jp/IRGSP/)];

Poplar [Populus trichocarpa release 1.1 from JGI (assembly release v1.0) genome (dot) jgi-psf (dot) org/)];

Brachypodium [JGI 4× assembly, brachpodium (dot) org)];

Soybean [DOE-JGI SCP, version Glyma0 (phytozome (dot) net/)];

Grape [French-Italian Public Consortium for Grapevine Genome Characterization grapevine genome (genoscope (dot) cns (dot) fr/)];

Castobean [TIGR/J Craig Venter Institute 4× assembly [msc (dot) jcvi (dot) org/r communis];

Sorghum [DOE-JGI SCP, version Sbi1 [phytozome (dot) net/)];

Partially assembled genome of Maize [maizesequence (dot) org/];

Expressed EST and mRNA sequences were extracted from the following databases:

GenBank ncbi (dot) nlm (dot) nih (dot) gov/dbEST:

RefSeq (ncbi (dot) nlm (dot) nih (dot) gov/RefScq/);

TAIR (arabidopsis (dot) org/);

Protein and Pathway Databases

Uniprot [uniprot (dot) org/];

AraCyc [arabidopsis (dot) org/biocyc/index (dot) jsp];

ENZYME [expasy (dot) org/enzyme/];

Microarray datasets were downloaded from:

GEO (ncbi (dot) nlm (dot) nih (dot) gov/geo/);

TAIR (Arabidopsis (dot) org/);

Proprietary microarray data (WO2008/122980);

QTL and SNPs Information

Gramene [gramene (dot) org/qtl/];

Panzea [panzea (dot) org/index (dot) html];

Database assembly—was performed to build a wide, rich, reliable annotated and easy to analyze database comprised of publicly available genomic mRNA. ESTs DNA sequence, data from various crops as well as gene expression, protein annotation and pathway data QTLs, and other relevant information.

Database assembly is comprised of a toolbox of gene refining, structuring, annotation and analysis tools enabling to construct a tailored database for each gene discovery project. Gene refining and structuring tools enable to reliably detect splice variants and antisense transcripts, generating understanding of various potential phenotypic outcomes of a single gene. The capabilities of the “LEADS” platform of Compugen LTD for analyzing human genome have been confirmed and accepted by the scientific community [see e.g., “Widespread Antisense Transcription”, Yelin. et al. (2003) Nature Biotechnology 21, 379-85; “Splicing of Alu Sequences”, Lev-Maor, et al. (2003) Science 300 (5623), 1288-91; “Computational analysis of alternative splicing using EST tissue information”. Xie H et al. Genomics 2002], and have been proven most efficient in plant genomics as well.

EST clustering and gene assembly—For gene clustering and assembly of organisms with available genome sequence data (arabidopsis, rice, castorbean, grape, brachypodium, poplar, soybean, sorghum) the genomic LEADS version (GANG) was employed. This tool allows most accurate clustering of ESTs and mRNA sequences on genome, and predicts gene structure as well as alternative splicing events and anti-sense transcription.

For organisms with no available full genome sequence data, “expressed LEADS” clustering software was applied.

Gene annotation—Predicted genes and proteins were annotated as follows: Blast search [blast (dot) ncbi (dot) nlm (dot) nih (dot) gov/Blast (dot) cgi]against all plant UniProt [uniprot (dot) org/] sequences was performed. Open reading frames of each putative transcript were analyzed and longest ORF with higher number of homologues was selected as predicted protein of the transcript. The predicted proteins were analyzed by InterPro [ebi (dot) ac (dot) uk/interpro/].

Blast against proteins from AraCyc and ENZYME databases was used to map the predicted transcripts to AraCyc pathways.

Predicted proteins from different species were compared using blast algorithm [ncbi (dot) nlm (dot) nih (dot) gov/Blast (dot) cgi] to validate the accuracy of the predicted protein sequence, and for efficient detection of orthologs.

Gene expression profiling—Several data sources were exploited for gene expression profiling, namely microarray data and digital expression profile (see below). According to gene expression profile, a correlation analysis was performed to identify genes which are co-regulated under different development stages and environmental conditions and associated with different phenotypes.

Publicly available microarray datasets were downloaded from TAIR and NCBI GEO sites, renormalized, and integrated into the database. Expression profiling is one of the most important resource data for identifying genes important for yield.

A digital expression profile summary was compiled for each cluster according to all keywords included in the sequence records comprising the cluster. Digital expression, also known as electronic Northern Blot, is a tool that displays virtual expression profile based on the EST sequences forming the gene cluster. The tool provides the expression profile of a cluster in terms of plant anatomy (e.g., the tissue/organ in which the gene is expressed), developmental stage (the developmental stages at which a gene can be found) and profile of treatment (provides the physiological conditions under which a gene is expressed such as drought, cold, pathogen infection, etc). Given a random distribution of ESTs in the different clusters, the digital expression provides a probability value that describes the probability of a cluster having a total of N ESTs to contain X ESTs from a certain collection of libraries. For the probability calculations, the following is taken into consideration: a) the number of ESTs in the cluster, b) the number of ESTs of the implicated and related libraries, c) the overall number of ESTs available representing the species. Thereby clusters with low probability values are highly enriched with ESTs from the group of libraries of interest indicating a specialized expression.

Recently, the accuracy of this system was demonstrated by Portnoy et al., 2009 (Analysis Of The Melon Fruit Transcriptome Based On 454 Pyrosequencing) in: Plant & Animal Genomes XVII Conference. San Diego, Calif. Transcriptomeic analysis, based on relative EST abundance in data was performed by 454 pyrosequencing of cDNA representing mRNA of the melon fruit. Fourteen double strand cDNA samples obtained from two genotypes, two fruit tissues (flesh and rind) and four developmental stages were sequenced. GS FLX pyrosequencing (Roche/454 Life Sciences) of non-normalized and purified cDNA samples yielded 1,150,657 expressed sequence tags, that assembled into 67,477 unigenes (32,357 singletons and 35,120 contigs). Analysis of the data obtained against the Cucurbit Genomics Database [icugi (dot) org/] confirmed the accuracy of the sequencing and assembly. Expression patterns of selected genes fitted well their qRT-PCR data.

The genes listed in Table 1 below were identified to have a major impact on plant yield, seed yield, fiber yield, fiber quality, growth rate, photosynthetic capacity, vigor, biomass, growth rate, oil content, abiotic stress tolerance, nitrogen use efficiency, water use efficiency and/or fertilizer use efficiency when expression thereof is increased in plants. The identified genes, their curated polynucleotide and polypeptide sequences, their updated sequences according to Genbank database and the sequences of the cloned genes and proteins are summarized in Table 1, hereinbelow.

TABLE 1
Identified genes for increasing yield, seed yield, growth rate, vigor, biomass, growth rate, oil
content, fiber yield, fiber quality, photosynthetic capacity, abiotic stress tolerance, nitrogen
use efficiency, water use efficiency and fertilizer use efficiency of a plant
Gene			Polyn. SEQ	Polyp. SEQ
Name	Cluster Name	Organism	ID NO:	ID NO:
LBY16	arabidopsis|13v2|AT1G22970	arabidopsis	1	552
LBY17	arabidopsis|13v2|AT2G33210	arabidopsis	2	553
LBY18	barley|12v1|AJ461405	barley	3	554
LBY19	barley|12v1|AJ480517	barley	4	555
LBY20	barley|12v1|AV833663	barley	5	556
LBY21	barley|12v1|BE602565	barley	6	557
LBY22	barley|12v1|BE603141	barley	7	558
LBY23	barley|12v1|BF260749	barley	8	559
LBY24	barley|12v1|BF623324	barley	9	560
LBY25	barley|12v1|BF628509	barley	10	561
LBY26	barley|12v1|BG309426	barley	11	562
LBY27	barley|12v1|BG414966	barley	12	563
LBY28	barley|12v1|BI947919	barley	13	564
LBY29	barley|12v1|BI950637	barley	14	565
LBY30	barley|12v1|BI957144	barley	15	566
LBY31	barley|12v1|BM370880	barley	16	567
LBY31	barley|12v1|BU981749	barley	17	568
LBY33	bean|13v1|CA912900	bean	18	569
LBY34	bean|13v1|HO799852	bean	19	570
LBY35	bean|13v1|SRR001335X308983	bean	20	571
LBY36	bean|13v1|SRR001335X369026	bean	21	572
LBY37	brachypodium|13v2|BRADI1G10360	brachypodium	22	573
LBY39	chlamydomonas|13v1|AF016902	chlamydomonas	23	574
LBY40	chlamydomonas|13v1|AV389131	chlamydomonas	24	575
LBY41	chlamydomonas|13v1|BE024238	chlamydomonas	25	576
LBY42	chlamydomonas|13v1|BE056699	chlamydomonas	26	577
LBY43	chlamydomonas|13v1|BE238232	chlamydomonas	27	578
LBY44	chlamydomonas|13v1|BG859395	chlamydomonas	28	579
LBY45	cotton|11v1|AI728213	cotton	29	580
LBY46	cotton|11v1|AW187962	cotton	30	581
LBY47	cotton|11v1|BE054714	cotton	31	582
LBY48	cotton|11v1|CA992719	cotton	32	583
LBY49	cotton|11v1|CD485858	cotton	33	584
LBY50	cotton|11v1|CO094458	cotton	34	585
LBY51	cotton|11v1|CO097155XX2	cotton	35	586
LBY52	cotton|11v1|DT048759XX2	cotton	36	587
LBY53	cotton|11v1|DT551860	cotton	37	588
LBY54	cotton|11v1|DT569254	cotton	38	589
LBY55	foxtail_millet|13v2|EC612531	foxtail_millet	39	590
LBY56	foxtail_millet|13v2|PHY7SI011949M	foxtail_millet	40	591
LBY57	foxtail_millet|13v2|PHY7SI024118M	foxtail_millet	41	592
LBY58	foxtail_millet|13v2|PHY7SI031876M	foxtail_millet	42	593
LBY59	foxtail_millet|13v2|PHY7SI032418M	foxtail_millet	43	594
LBY61	foxtail_millet|13v2|SRR350548X103005	foxtail_millet	44	595
LBY62	foxtail_millet|13v2|SRR350548X10518	foxtail_millet	45	596
LBY63	foxtail_millet|13v2|SRR350548X107681	foxtail_millet	46	597
LBY64	foxtail_millet|13v2|SRR350548X10799	foxtail_millet	47	598
LBY65	foxtail_millet|13v2|SRR350548X10909	foxtail_millet	48	599
LBY66	foxtail_millet|13v2|SRR350548X113858	foxtail_millet	49	600
LBY67	foxtail_millet|13v2|SRR350548X115271	foxtail_millet	50	601
LBY68	foxtail_millet|13v2|SRR350548X117047	foxtail_millet	51	602
LBY69	foxtail_millet|13v2|SRR350548X122695	foxtail_millet	52	603
LBY70	foxtail_millet|13v2|SRR350548X123794	foxtail_millet	53	604
LBY71	foxtail_millet|13v2|SRR350548X12932	foxtail_millet	54	605
LBY72	foxtail_millet|13v2|SRR350548X130312	foxtail_millet	55	606
LBY73	foxtail_millet|13v2|SRR350548X132820	foxtail_millet	56	607
LBY74	foxtail_millet|13v2|SRR350548X135074	foxtail_millet	57	608
LBY75	foxtail_millet|13v2|SRR350548X141269	foxtail_millet	58	609
LBY76	foxtail_millet|13v2|SRR350548X15437	foxtail_millet	59	610
LBY77	foxtail_millet|13v2|SRR350548X157828	foxtail_millet	60	611
LBY78	foxtail_millet|13v2|SRR350548X17296	foxtail_millet	61	612
LBY79	foxtail_millet|13v2|SRR350548X177567	foxtail_millet	62	613
LBY80	foxtail_millet|13v2|SRR350548X191757	foxtail_millet	63	614
LBY81	foxtail_millet|13v2|SRR350548X196210	foxtail_millet	64	615
LBY82	foxtail_millet|13v2|SRR350548X196859	foxtail_millet	65	616
LBY83	foxtail_millet|13v2|SRR350548X218671	foxtail_millet	66	617
LBY84	foxtail_millet|13v2|SRR350548X306788	foxtail_millet	67	618
LBY85	foxtail_millet|13v2|SRR350548X349819	foxtail_millet	68	619
LBY86	foxtail_millet|13v2|SRR350548X406093	foxtail_millet	69	620
LBY87	foxtail_millet|13v2|SRR350548X410798	foxtail_millet	70	621
LBY88	foxtail_millet|13v2|SRR350548X59197	foxtail_millet	71	622
LBY89	foxtail_millet|13v2|SRR350548X77704	foxtail_millet	72	623
LBY90	foxtail_millet|13v2|SRR350549X116153	foxtail_millet	73	624
LBY91	foxtail_millet|13v2|SRR350549X131202	foxtail_millet	74	625
LBY92	foxtail_millet|13v2|SRR350549X154401	foxtail_millet	75	626
LBY93	gossypium_raimondii|13v1|AI055109	gossypium_raimondii	76	627
LBY94	gossypium_raimondii|13v1|AW187415	gossypium_raimondii	77	628
LBY95	gossypium_raimondii|13v1|BG440368	gossypium_raimondii	78	629
LBY96	gossypium_raimondii|13v1|CA993797	gossypium_raimondii	79	630
LBY97	gossypium_raimondii|13v1|DW518098	gossypium_raimondii	80	631
LBY98	grape|13v1|CSVIVT01008767001	grape	81	632
LBY99	grape|13v1|GSVIVT01022545001	grape	82	633
LBY100	grape|13v1|GSVIVT01027185001	grape	83	634
LBY102	grape|13v1|GSVIVT01033774001	grape	84	635
LBY103	maize|13v2|AI391771	maize	85	636
LBY104	maize|13v2|AI391832	maize	86	637
LBY105	maize|13v2|AI629879	maize	87	638
LBY106	maize|13v2|AI629976	maize	88	639
LBY107	maize|13v2|AI649422	maize	89	640
LBY108	maize|13v2|AI665281	maize	90	641
LBY109	maize|13v2|AI714974	maize	91	642
LBY110	maize|13v2|AI783421	maize	92	643
LBY111	maize|13v2|AI857222	maize	93	644
LBY112	maize|13v2|AW066591	maize	94	645
LBY113	maize|13v2|BE511523	maize	95	646
LBY114	maize|13v2|BG320464	maize	96	647
LBY115	maize|13v2|BG836613	maize	97	648
LBY116	maize|13v2|BM416753	maize	98	649
LBY117	maize|13v2|BM895232	maize	99	650
LBY118	maize|13v2|CF648041	maize	100	651
LBY119	maize|13v2|DW918922	maize	101	652
LBY120	maize|13v2|W21655	maize	102	653
LBY121	maize|13v2|W21748	maize	103	654
LBY122	maize|13v2|W49461	maize	104	655
LBY123	maize|13v2|X81831	maize	105	656
LBY125	medicago|13v1|AW696074	medicago	106	657
LBY126	medicago|13v1|BG457785	medicago	107	658
LBY127	medicago|13v1|BQ147900	medicago	108	659
LBY128	peanut|13v1|EE125510	peanut	109	660
LBY129	peanut|13v1|ES722517	peanut	110	661
LBY131	physcomitrella|13v1|AW738860	physcomitrella	111	662
LBY132	pine|10v2|BM492830	pine	112	663
LBY133	plantago|11v2|SRR066373X397343	plantago	113	664
LBY134	poplar|13v1|AI164180	poplar	114	665
LBY135	potato|10v1|BE919981	potato	115	666
LBY136	potato|10v1|BF460221	potato	116	667
LBY137	potato|10v1|BG595100	potato	117	668
LBY138	rice|11v1|AU069467	rice	118	669
LBY139	rice|13v2|AA750185	rice	119	670
LBY140	rice|13v2|AA750741	rice	120	671
LBY141	rice|13v2|AU077650	rice	121	672
LBY142	rice|13v2|AU173280	rice	122	673
LBY143	rice|13v2|BI796376	rice	123	674
LBY144	rice|13v2|BQ907720	rice	124	675
LBY145	rice|13v2|C28519	rice	125	676
LBY146	rice|13v2|GFXAC018727X13	rice	126	677
LBY147	rice|13v2|GFXAC090120X15	rice	127	678
LBY148	sorghum|12v1|SB03G032710	sorghum	128	679
LBY149	sorghum|13v2|AI723863	sorghum	129	680
LBY150	sorghum|13v2|AI723986	sorghum	130	681
LBY151	sorghum|13v2|AI724085	sorghum	131	682
LBY152	sorghum|13v2|AI724262	sorghum	132	683
LBY153	sorghum|13v2|AW283496	sorghum	133	684
LBY154	sorghum|13v2|AW285663	sorghum	134	685
LBY155	sorghum|13v2|AW564408	sorghum	135	686
LBY156	sorghum|13v2|AW565627	sorghum	136	687
LBY157	sorghum|13v2|AW671774	sorghum	137	688
LBY158	sorghum|13v2|AW676719	sorghum	138	689
LBY159	sorghum|13v2|AW679798	sorghum	139	690
LBY160	sorghum|13v2|AW746324	sorghum	140	691
LBY161	sorghum|13v2|AW747557	sorghum	141	692
LBY162	sorghum|13v2|BE126058	sorghum	142	693
LBY163	sorghum|13v2|BE355844	sorghum	143	694
LBY164	sorghum|13v2|BE356001	sorghum	144	695
LBY165	sorghum|13v2|BE357267	sorghum	145	696
LBY166	sorghum|13v2|BE358756	sorghum	146	697
LBY167	sorghum|13v2|BE360790	sorghum	147	698
LBY168	sorghum|13v2|BE364917	sorghum	148	699
LBY170	sorghum|13v2|BE594760	sorghum	149	700
LBY171	sorghum|13v2|BE597213	sorghum	150	701
LBY173	sorghum|13v2|BF421040	sorghum	151	702
LBY174	sorghum|13v2|BF585682	sorghum	152	703
LBY175	sorghum|13v2|BF586554	sorghum	153	704
LBY176	sorghum|13v2|BG049624	sorghum	154	705
LBY177	sorghum|13v2|BG050660	sorghum	155	706
LBY178	sorghum|13v2|BG053630	sorghum	156	707
LBY179	sorghum|13v2|BG411492	sorghum	157	708
LBY180	sorghum|13v2|BG488154	sorghum	158	709
LBY181	sorghum|13v2|BM322245	sorghum	159	710
LBY182	sorghum|13v2|CD222102	sorghum	160	711
LBY183	sorghum|13v2|CD223986	sorghum	161	712
LBY184	sorghum|13v2|CD224850	sorghum	162	713
LBY185	sorghum|13v2|CD226020	sorghum	163	714
LBY186	sorghum|13v2|CD227545	sorghum	164	715
LBY187	sorghum|13v2|CD431650	sorghum	165	716
LBY188	sorghum|13v2|CF757269	sorghum	166	717
LBY189	sorghum|13v2|CF760555	sorghum	167	718
LBY190	sorghum|13v2|CF761959	sorghum	168	719
LBY191	sorghum|13v2|XM_002441241	sorghum	169	720
LBY192	sorghum|13v2|XM_002457915	sorghum	170	721
LBY193	soybean|13v2|GLYMA05G34360	soybean	171	722
LBY194	soybean|13v2|GLYMA15G30610	soybean	172	723
LBY195	soybean|13v2|GLYMA19G40920T2	soybean	173	724
LBY196	spruce|11v1|ES252179	spruce	174	725
LBY197	sunflower|12v1|AJ829034	sunflower	175	726
LBY199	sunflower|12v1|BU021733	sunflower	176	727
LBY200	sunflower|12v1|CD847948	sunflower	177	728
LBY201	sunflower|12v1|CD852615	sunflower	178	729
LBY202	sunflower|12v1|CD853598	sunflower	179	730
LBY203	sunflower|12v1|CX948055	sunflower	180	731
LBY204	sunflower|12v1|DY904031	sunflower	181	732
LBY205	sunflower|12v1|DY904769	sunflower	182	733
LBY206	sunflower|12v1|DY914980	sunflower	183	734
LBY207	sunflower|12v1|DY918107	sunflower	184	735
LBY208	sunflower|12v1|DY928062	sunflower	185	736
LBY209	sunflower|12v1|EE609275	sunflower	186	737
LBY210	sunflower|12v1|EE613413	sunflower	187	738
LBY211	sunflower|12v1|EE625930	sunflower	188	739
LBY212	tomato|13v1|BG123297	tomato	189	740
LBY213	tomato|13v1|BG129885	tomato	190	741
LBY214	wheat|12v3|AL820463	wheat	191	742
LBY215	wheat|12v3|AL821230	wheat	192	743
LBY216	wheat|12v3|BE402170	wheat	193	744
LBY217	wheat|12v3|BE402302	wheat	194	745
LBY218	wheat|12v3|BE413931	wheat	195	746
LBY219	wheat|12v3|BE415435	wheat	196	747
LBY220	wheat|12v3|BE419175	wheat	197	748
LBY221	wheat|12v3|BE419414	wheat	198	749
LBY222	wheat|12v3|BE422621	wheat	199	750
LBY224	wheat|12v3|BE442666	wheat	200	751
LBY225	wheat|12v3|BE446154	wheat	201	757
LBY227	wheat|12v3|BE515516	wheat	202	753
LBY228	wheat|12v3|BE516296	wheat	203	754
LBY230	wheat|12v3|CA608701	wheat	204	755
LBY231	wheat|12v3|CA662849	wheat	205	756
LBY232	wheat|12v3|CA706141	wheat	206	757
LBY233	maize|13v2|AI939887	maize	207	758
LBY106_H3	maize|13v2|BG320823	maize	208	759
LBY119_H1	sorghum|13v2|XM_002458388	sorghum	209	760
LBY219_H9	rice|13v2|BM422078	rice	210	761
LBY27_H4	maize|13v2|BE050333	maize	211	762
LBY34_H2	soybean|13v2|GLYMA09G42190	soybean	212	763
LGN1	wheat|12v3|BE405890	wheat	213	764
LGN2	soybean|12v1|GLYMA16G27050	soybean	214	765
LGN3	sorghum|13v2|CN131173	sorghum	215	766
LGN4	sorghum|13v2|BF587229	sorghum	216	767
LGN5	sorghum|13v2|BI643690	sorghum	217	768
LGN6	sorghum|13v2|BE598356	sorghum	218	769
LGN7	sorghum|13v2|BE363875	sorghum	219	770
LGN9	rice|gb170|OS02G48000	rice	220	771
LGN13	rice|11v1|CV722121	rice	221	772
LGN14	rice|11v1|CB663201	rice	222	773
LGN17	maize|13v2|CF647382	maize	223	774
LGN18	maize|13v2|AW562670	maize	224	775
LGN20	maize|13v2|AI920382	maize	225	776
LGN23	maize|10v1|CF011727	maize	226	777
LGN24	maize|10v1|CD943107	maize	227	778
LGN26	maize|10v1|BE051266	maize	228	779
LGN33	maize|10v1|AI857219	maize	229	780
LGN34	maize|10v1|AI691183	maize	230	781
LGN35	maize|10v1|AI668189	maize	231	782
LGN36	maize|10v1|AI666136	maize	232	783
LGN39	maize|10v1|AA979848	maize	233	784
LGN40	cotton|11v1|BG446873	cotton	234	785
LGN41	brachypodium|12v1|BRADI1G64560	brachypodium	235	786
LGN42	barley|12v1|BI951707	barley	236	787
LGN43	barley|12v1|BI946826	barley	237	788
LGN44	barley|12v1|BF626012	barley	238	789
LGN45	barley|12v1|BF624588	barley	239	790
LGN46	barley|12v1|BF619715	barley	240	791
LGN47	barley|10v2|BI948139	barley	241	792
LGN48	barley|10v2|AV833757	barley	242	793
LGN49	maize|10v1|AI901839	maize	243	794
LGN52	foxtail_millet|11v3|SOLX00022696	foxtail_millet	244	795
LGN54	sorghum|12v1|SB01G028500	sorghum	245	796
LGN57	sorghum|13v2|BE596729	sorghum	246	797
LGN60	foxtail_millet|13v2|SRR350548X10009	foxtail_millet	247	798
LGN61	maize|13v2|AI941989	maize	248	799
LGN62	maize|13v2|CF626471	maize	249	800
LGN62_H2	foxtail_millet|13v2|SRR350548X213481	foxtail_millet	250	801
LBY1	barley|12v1|BU976513	barley	251	—
LBY2	cotton|11v1|DW509834XX1	cotton	252	—
LBY3	foxtail_millet|11v3|PHY7SI024106M	foxtail_millet	253	—
LBY4	gossypium_raimondii|13v1|GR13V1PRD019042	gossypium_raimondii	254	—
LBY5	maize|13v2|AI001271	maize	255	—
LBY6	maize|13v2|BQ528930	maize	256	—
LBY10	maize|13v2|EXP1208S11302X009072496D1	maize	257	—
LBY12	maize|13v2|SRR014549X246688	maize	258	—
LBY13	maize|13v2|SRR014549X57533	maize	259	—
LBY14	sorghum|13v2|BE359338	sorghum	260	—
LBY15	maize|13v2|ZM13V1RFAM401	maize	261	—
LBY216	wheat|12v3|BE402170	wheat	193	813
LBY20	barley|12v1|AV833663	barley	262	556
LBY33	bean|13v1|CA912900	bean	263	802
LBY36	bean|13v1|SRR001335X369026	bean	264	803
LBY43	chlamydomonas|13v1|BE238232	chlamydomonas	265	804
LBY52	cotton|11v1|DT048759XX2	cotton	266	805
LBY61	foxtail_millet|13v2|SRR350548X103005	foxtail_millet	267	595
LBY68	foxtail_millet|13v2|SRR350548X117047	foxtail_millet	268	602
LBY69	foxtail_millet|13v2|SRR350548X122695	foxtail_millet	269	806
LBY70	foxtail_millet|13v2|SRR350548X123794	foxtail_millet	270	604
LBY72	foxtail_millet|13v2|SRR350548X130312	foxtail_millet	271	606
LBY73	foxtail_millet|13v2|SRR350548X132820	foxtail_millet	272	807
LBY74	foxtail_millet|13v2|SRR350548X135074	foxtail_millet	273	608
LBY80	foxtail_millet|13v2|SRR350548X191757	foxtail_millet	274	808
LBY84	foxtail_millet|13v2|SRR350548X306788	foxtail_millet	275	618
LBY86	foxtail_millet|13v2|SRR350548X406093	foxtail_millet	276	620
LBY92	foxtail_millet|13v2|SRR350549X154401	foxtail_millet	277	809
LBY93	gossypium_raimondii|13v1|AI055109	gossypium_raimondii	278	627
LBY95	gossypium_raimondii|13v1|BG440368	gossypium_raimondii	279	629
LBY106	maize|13v2|AI629976	maize	280	639
LBY135	potato|10v1|BE919981	potato	281	666
LBY140	rice|13v2|AA750741	rice	282	671
LBY145	rice|13v2|C28519	rice	283	676
LBY151	sorghum|13v2|AI724085	sorghum	284	682
LBY156	sorghum|13v2|AW565627	sorghum	285	687
LBY157	sorghum|13v2|AW671774	sorghum	286	688
LBY159	sorghum|13v2|AW679798	sorghum	287	810
LBY165	sorghum|13v2|BE357267	sorghum	288	696
LBY178	sorghum|13v2|BG053630	sorghum	289	707
LBY201	sunflower|12v1|CD852615	sunflower	290	729
LBY204	sunflower|12v1|DY904031	sunflower	291	811
LBY206	sunflower|12v1|DY914980	sunflower	292	734
LBY208	sunflower|12v1|DY928062	sunflower	293	812
LBY215	wheat|12v3|AL821230	wheat	294	743
LBY106_H3	maize|13v2|BG320823	maize	295	759
LBY119_H1	sorghum|13v2|XM_002458388	sorghum	296	814
LBY219_H9	rice|13v2|BM422078	rice	297	761
LBY27_H4	maize|13v2|BE050333	maize	298	815
LBY34_H2	soybean|13v2|GLYMA09G42190	soybean	299	763
LGN1	wheat|12v3|BE405890	wheat	300	764
LGN18	maize|13v2|AW562670	maize	301	816
LGN23	maize|10v1|CF011727	maize	302	777
LGN42	barley|12v1|BI951707	barley	303	787
LGN62_H2	foxtail_millet|13v2|SRR350548X213481	foxtail_millet	304	801
LBY2	cotton|11v1|DW509834XX1	cotton	305	—
LBY3	foxtail_millet|11v3|PHY7SI024106M	foxtail_millet	306	—
LBY4	gossypium_raimondii|13v1|GR13V1PRD019042	gossypium_raimondii	307	—
LBY5	maize|13v2|AI001271	maize	308	—
LBY6	maize|13v2|BQ528930	maize	309	—
LBY14	sorghum|13v2|BE359338	sorghum	310	—
LBY15	maize|13v2|ZM13V1RFAM401	maize	261	—
LBY16	arabidopsis|13v2|AT1G22970	arabidopsis	311	552
LBY17	arabidopsis|13v2|AT2G33210	arabidopsis	312	553
LBY18	barley|12v1|AJ461405	barley	313	554
LBY20	barley|12v1|AV833663	barley	314	817
LBY21	barley|12v1|BE602565	barley	315	557
LBY22	barley|12v1|BE603141	barley	316	558
LBY23	barley|12v1|BF260749	barley	317	559
LBY24	barley|12v1|BF623324	barley	318	818
LBY25	barley|12v1|BF628509	barley	319	561
LBY26	barley|12v1|BG309426	barley	320	562
LBY28	barley|12v1|BI947919	barley	321	819
LBY29	barley|12v1|BI950637	barley	322	565
LBY30	barley|12v1|BI957144	barley	323	566
LBY31	barley|12v1|BM370880	barley	324	820
LBY32	barley|12v1|BU981749	barley	325	568
LBY33	bean|13v1|CA912900	bean	326	821
LBY35	bean|13v1|SRR001335X308983	bean	327	822
LBY36	bean|13v1|SRR001335X369026	bean	328	823
LBY37	brachypodium|13v2|BRADI1G10360	brachypodium	329	573
LBY39	chlamydomonas|13v1|AF016902	chlamydomonas	330	574
LBY40	chlamydomonas|13v1|AV389131	chlamydomonas	331	575
LBY41	chlamydomonas|13v1|BE024238	chlamydomonas	332	576
LBY43	chlamydomonas|13v1|BE238232	chlamydomonas	333	578
LBY44	chlamydomonas|13v1|BG859395	chlamydomonas	334	579
LBY45	cotton|11v1|AI728213	cotton	335	580
LBY46	cotton|11v1|AW187962	cotton	336	824
LBY47	cotton|11v1|BE054714	cotton	337	825
LBY48	cotton|11v1|CA992719	cotton	338	826
LBY49	cotton|11v1|CD485858	cotton	339	827
LBY50	cotton|11v1|CO094458	cotton	340	828
LBY51	cotton|11v1|CO097155XX2	cotton	341	586
LBY52	cotton|11v1|DT048759XX2	cotton	342	829
LBY53	cotton|11v1|DT551860	cotton	343	830
LBY54	cotton|11v1|DT569254	cotton	344	589
LBY55	foxtail_millet|13v2|EC612531	foxtail_millet	345	590
LBY56	foxtail_millet|13v2|PHY7SI011949M	foxtail_millet	346	591
LBY57	foxtail_millet|13v2|PHY7SI024118M	foxtail_millet	347	592
LBY58	foxtail_millet|13v2|PHY7SI031876M	foxtail_millet	348	593
LBY59	foxtail_millet|13v2|PHY7SI032418M	foxtail_millet	349	594
LBY61	foxtail_millet|13v2|SRR350548X103005	foxtail_millet	350	595
LBY62	foxtail_millet|13v2|SRR350548X10518	foxtail_millet	351	596
LBY63	foxtail_millet|13v2|SRR350548X107681	foxtail_millet	352	597
LBY64	foxtail_millet|13v2|SRR350548X10799	foxtail_millet	353	598
LBY65	foxtail_millet|13v2|SRR350548X10909	foxtail_millet	354	599
LBY66	foxtail_millet|13v2|SRR350548X113858	foxtail_millet	355	600
LBY68	foxtail_millet|13v2|SRR350548X117047	foxtail_millet	356	602
LBY69	foxtail_millet|13v2|SRR350548X122695	foxtail_millet	357	831
LBY70	foxtail_millet|13v2|SRR350548X123794	foxtail_millet	358	604
LBY71	foxtail_millet|13v2|SRR350548X12932	foxtail_millet	359	605
LBY72	foxtail_millet|13v2|SRR350548X130312	foxtail_millet	360	832
LBY73	foxtail_millet|13v2|SRR350548X132820	foxtail_millet	361	607
LBY74	foxtail_millet|13v2|SRR350548X135074	foxtail_millet	362	833
LBY75	foxtail_millet|13v2|SRR350548X141269	foxtail_millet	363	609
LBY76	foxtail_millet|13v2|SRR350548X15437	foxtail_millet	364	610
LBY77	foxtail_millet|13v2|SRR350548X157828	foxtail_millet	365	611
LBY78	foxtail_millet|13v2|SRR350548X17296	foxtail_millet	366	612
LBY79	foxtail_millet|13v2|SRR350548X177567	foxtail_millet	367	613
LBY80	foxtail_millet|13v2|SRR350548X191757	foxtail_millet	368	614
LBY81	foxtail_millet|13v2|SRR350548X196210	foxtail_millet	369	615
LBY82	foxtail_millet|13v2|SRR350548X196859	foxtail_millet	370	616
LBY83	foxtail_millet|13v2|SRR350548X218671	foxtail_millet	371	617
LBY84	foxtail_millet|13v2|SRR350548X306788	foxtail_millet	372	618
LBY85	foxtail_millet|13v2|SRR350548X349819	foxtail_millet	373	619
LBY86	foxtail_millet|13v2|SRR350548X406093	foxtail_millet	374	620
LBY87	foxtail_millet|13v2|SRR350548X410798	foxtail_millet	375	621
LBY88	foxtail_millet|13v2|SRR350548X59197	foxtail_millet	376	622
LBY89	foxtail_millet|13v2|SRR350548X77704	foxtail_millet	377	623
LBY90	foxtail_millet|13v2|SRR350549X116153	foxtail_millet	378	624
LBY91	foxtail_millet|13v2|SRR350549X131202	foxtail_millet	379	625
LBY92	foxtail_millet|13v2|SRR350549X154401	foxtail_millet	380	626
LBY93	gossypium_raimondii|13v1|AI055109	gossypium_raimondii	381	834
LBY94	gossypium_raimondii|13v1|AW187415	gossypium_raimondii	382	835
LBY95	gossypium_raimondii|13v1|BG440368	gossypium_raimondii	383	836
LBY96	gossypium_raimondii|13v1|CA993797	gossypium_raimondii	384	630
LBY97	gossypium_raimondii|13v1|DW518098	gossypium_raimondii	385	837
LBY98	grape|13v1|GSVIVT01008767001	grape	386	632
LBY99	grape|13v1|GSVIVT01022545001	grape	387	633
LBY100	grape|13v1|GSVIVT01027185001	grape	388	634
LBY102	grape|13v1|GSVIVT01033774001	grape	389	635
LBY103	maize|13v2|AI391771	maize	390	636
LBY104	maize|13v2|AI391832	maize	391	637
LBY105	maize|13v2|AI629879	maize	392	638
LBY107	maize|13v2|AI649422	maize	393	640
LBY108	maize|13v2|AI665281	maize	394	838
LBY109	maize|13v2|AI714974	maize	395	642
LBY110	maize|13v2|AI783421	maize	396	643
LBY111	maize|13v2|AI857222	maize	397	644
LBY112	maize|13v2|AW066591	maize	398	645
LBY113	maize|13v2|BE511523	maize	399	646
LBY114	maize|13v2|BG320464	maize	400	647
LBY115	maize|13v2|BG836613	maize	401	648
LBY116	maize|13v2|BM416753	maize	402	839
LBY117	maize|13v2|BM895232	maize	403	650
LBY118	maize|13v2|CF648041	maize	404	651
LBY120	maize|13v2|W21655	maize	405	840
LBY121	maize|13v2|W21748	maize	406	841
LBY122	maize|13v2|W49461	maize	407	842
LBY123	maize|13v2|X81831	maize	408	656
LBY125	medicago|13v1|AW696074	medicago	409	657
LBY126	medicago|13v1|BG457785	medicago	410	658
LBY127	medicago|13v1|BQ147900	medicago	411	843
LBY128	peanut|13v1|EE125510	peanut	412	660
LBY129	peanut|13v1|ES722517	peanut	413	661
LBY132	pine|10v2|BM492830	pine	414	663
LBY133	plantago|11v2|SRR066373X397343	plantago	415	664
LBY134	poplar|13v1|AI164180	poplar	416	665
LBY135	potato|10v1|BE919981	potato	417	666
LBY136	potato|10v1|BF460221	potato	418	844
LBY137	potato|10v1|BG595100	potato	419	845
LBY138	rice|11v1|AU069467	rice	420	669
LBY139	rice|13v2|AA750185	rice	421	846
LBY140	rice|13v2|AA750741	rice	422	671
LBY141	rice|13v2|AU077650	rice	423	672
LBY142	rice|13v2|AU173280	rice	424	673
LBY143	rice|13v2|BI796376	rice	425	674
LBY144	rice|13v2|BQ907720	rice	426	847
LBY145	rice|13v2|C28519	rice	427	676
LBY146	rice|13v2|GFXAC018727X13	rice	428	848
LBY148	sorghum|12v1|SB03G032710	sorghum	429	679
LBY149	sorghum|13v2|AI723863	sorghum	430	680
LBY150	sorghum|13v2|AI723986	sorghum	431	681
LBY151	sorghum|13v2|AI724085	sorghum	432	682
LBY152	sorghum|13v2|AI724262	sorghum	433	683
LBY153	sorghum|13v2|AW283496	sorghum	434	684
LBY154	sorghum|13v2|AW285663	sorghum	435	685
LBY155	sorghum|13v2|AW564408	sorghum	436	849
LBY156	sorghum|13v2|AW565627	sorghum	437	850
LBY157	sorghum|13v2|AW671774	sorghum	438	688
LBY158	sorghum|13v2|AW676719	sorghum	439	851
LBY159	sorghum|13v2|AW679798	sorghum	440	690
LBY160	sorghum|13v2|AW746324	sorghum	441	691
LBY161	sorghum|13v2|AW747557	sorghum	442	692
LBY162	sorghum|13v2|BE126058	sorghum	443	693
LBY163	sorghum|13v2|BE355844	sorghum	444	694
LBY164	sorghum|13v2|BE356001	sorghum	445	852
LBY165	sorghum|13v2|BE357267	sorghum	446	853
LBY166	sorghum|13v2|BE358756	sorghum	447	697
LBY167	sorghum|13v2|BE360790	sorghum	448	698
LBY170	sorghum|13v2|BE594760	sorghum	449	700
LBY171	sorghum|13v2|BE597213	sorghum	450	701
LBY173	sorghum|13v2|BF421040	sorghum	451	702
LBY174	sorghum|13v2|BF585682	sorghum	452	703
LBY175	sorghum|13v2|BF586554	sorghum	453	704
LBY176	sorghum|13v2|BG049624	sorghum	454	705
LBY177	sorghum|13v2|BG050660	sorghum	455	706
LBY178	sorghum|13v2|BG053630	sorghum	456	707
LBY179	sorghum|13v2|BG411492	sorghum	457	708
LBY180	sorghum|13v2|BG488154	sorghum	458	854
LBY181	sorghum|13v2|BM322245	sorghum	459	855
LBY182	sorghum|13v2|CD222102	sorghum	460	856
LBY183	sorghum|13v2|CD223986	sorghum	461	712
LBY184	sorghum|13v2|CD224850	sorghum	462	713
LBY185	sorghum|13v2|CD226020	sorghum	463	857
LBY186	sorghum|13v2|CD227545	sorghum	464	715
LBY187	sorghum|13v2|CD431650	sorghum	465	858
LBY188	sorghum|13v2|CF757269	sorghum	466	717
LBY190	sorghum|13v2|CF761959	sorghum	467	719
LBY191	sorghum|13v2|XM_002441241	sorghum	468	720
LBY192	sorghum|13v2|XM_002457915	sorghum	469	859
LBY193	soybean|13v2|GLYMA05G34360	soybean	470	860
LBY194	soybean|13v2|GLYMA15G30610	soybean	471	723
LBY195	soybean|13v2|GLYMA19G40920T2	soybean	472	861
LBY196	spruce|11v1|ES252179	spruce	473	725
LBY197	sunflower|12v1|AJ829034	sunflower	474	726
LBY199	sunflower|12v1|BU021733	sunflower	475	862
LBY200	sunflower|12v1|CD847948	sunflower	476	863
LBY201	sunflower|12v1|CD852615	sunflower	477	864
LBY202	sunflower|12v1|CD853598	sunflower	478	865
LBY203	sunflower|12v1|CX948055	sunflower	479	866
LBY204	sunflower|12v1|DY904031	sunflower	480	732
LBY205	sunflower|12v1|DY904769	sunflower	481	867
LBY206	sunflower|12v1|DY914980	sunflower	482	868
LBY207	sunflower|12v1|DY918107	sunflower	483	869
LBY208	sunflower|12v1|DY928062	sunflower	484	736
LBY209	sunflower|12v1|EE609275	sunflower	485	870
LBY210	sunflower|12v1|EE613413	sunflower	486	871
LBY211	sunflower|12v1|EE625930	sunflower	487	872
LBY212	tomato|13v1|BG123297	tomato	488	873
LBY213	tomato|13v1|BG129885	tomato	489	874
LBY214	wheat|12v3|AL820463	wheat	490	742
LBY216	wheat|12v3|BE402170	wheat	491	875
LBY217	wheat|12v3|BE402302	wheat	492	876
LBY218	wheat|12v3|BE413931	wheat	493	877
LBY220	wheat|12v3|BE419175	wheat	494	748
LBY221	wheat|12v3|BE419414	wheat	495	749
LBY222	wheat|12v3|BE422621	wheat	496	878
LBY224	wheat|12v3|BE442666	wheat	497	751
LBY225	wheat|12v3|BE446154	wheat	498	879
LBY227	wheat|12v3|BE515516	wheat	499	753
LBY228	wheat|12v3|BE516296	wheat	500	880
LBY230	wheat|12v3|CA608701	wheat	501	881
LBY231	wheat|12v3|CA662849	wheat	502	882
LBY232	wheat|12v3|CA706141	wheat	503	883
LBY233	maize|13v2|AI939887	maize	504	758
LBY106_H3	maize|13v2|BG320823	maize	505	884
LBY119_H1	sorghum|13v2|XM_002458388	sorghum	506	885
LBY219_H9	rice|13v2|BM422078	rice	507	761
LBY27_H4	maize|13v2|BE050333	maize	508	762
LBY34_H2	soybean|13v2|GLYMA09G42190	soybean	509	763
LGN1	wheat|12v3|BE405890	wheat	510	764
LGN2	soybean|12v1|GLYMA16G27050	soybean	511	765
LGN3	sorghum|13v2|CN131173	sorghum	512	766
LGN4	sorghum|13v2|BF587229	sorghum	513	767
LGN5	sorghum|13v2|BI643690	sorghum	514	768
LGN6	sorghum|13v2|BE598356	sorghum	515	769
LGN7	sorghum|13v2|BE363875	sorghum	516	770
LGN9	rice|gb170|OS02G48000	rice	517	771
LGN13	rice|11v1|CV722121	rice	518	772
LGN14	rice|11v1|CB663201	rice	519	773
LGN17	maize|13v2|CF647382	maize	520	886
LGN18	maize|13v2|AW562670	maize	521	887
LGN20	maize|13v2|AI920382	maize	522	888
LGN23	maize|10v1|CF011727	maize	523	777
LGN24	maize|10v1|CD943107	maize	524	889
LGN26	maize|10v1|BE051266	maize	525	779
LGN33	maize|10v1|AI857219	maize	526	780
LGN34	maize|10v1|AI691183	maize	527	890
LGN35	maize|10v1|AI668189	maize	528	782
LGN36	maize|10v1|AI666136	maize	529	783
LGN39	maize|10v1|AA979848	maize	530	891
LGN40	cotton|11v1|BG446873	cotton	531	785
LGN41	brachypodium|12v1|BRADI1G64560	brachypodium	532	786
LGN42	barley|12v1|BI951707	barley	533	787
LGN43	barley|12v1|BI946826	barley	534	788
LGN44	barley|12v1|BF626012	barley	535	789
LGN45	barley|12v1|BF624588	barley	536	892
LGN46	barley|12v1|BF619715	barley	537	791
LGN47	barley|10v2|BI948139	barley	538	893
LGN48	barley|10v2|AV833757	barley	539	793
LGN49	maize|10v1|AI901839	maize	540	894
LGN52	foxtail_millet|11v3|SOLX00022696	foxtail_millet	541	795
LGN54	sorghum|12v1|SB01G028500	sorghum	542	796
LGN57	sorghum|13v2|BE596729	sorghum	543	895
LGN60	foxtail_millet|13v2|SRR350548X10009	foxtail_millet	544	798
LGN61	maize|13v2|AI941989	maize	545	896
LGN62_H2	foxtail_millet|13v2|SRR350548X213481	foxtail_millet	546	897
LBY3	foxtail_millet|11v3|PHY7SI024106M	foxtail_millet	547	—
LBY4	gossypium_raimondii|13v1|GR13V1PRD019042	gossypium_raimondii	548	—
LBY5	maize|13v2|AI001271	maize	549	—
LBY6	maize|13v2|BQ528930	maize	550	—
LBY14	sorghum|13v2|BE359338	sorghum	551	—

Table 1: Provided are the identified genes, their annotation, organism and polynucleotide and polypeptide sequence identifiers. “polyn.”=polynucleotide; “polyp.”=polypeptide.

Example 2

Identification of Homologous (e.g., Orthologous) Sequences that Increase Yield, Seed Yield, Fiber Yield, Fiber Quality, Growth Rate, Biomass, Oil Content, Vigor, Abst, and/or Nue of a Plant

The concepts of orthology and paralogy have recently been applied to functional characterizations and classifications on the scale of whole-genome comparisons. Orthologs and paralogs constitute two major types of homologs: The first evolved from a common ancestor by specialization, and the latter is related by duplication events. It is assumed that paralogs arising from ancient duplication events are likely to have diverged in function while true orthologs are more likely to retain identical function over evolutionary time.

To further investigate and identify putative orthologs of the genes affecting plant yield, seed yield, fiber yield, fiber quality, oil yield, oil content, seed yield, growth rate, vigor, biomass, abiotic stress tolerance, and fertilizer use efficiency (FUE) and/or nitrogen use efficiency of a plant, all sequences were aligned using the BLAST (Basic Local Alignment Search Tool). Sequences sufficiently similar were tentatively grouped. These putative orthologs were further organized under a Phylogram—a branching diagram (tree) assumed to be a representation of the evolutionary relationships among the biological taxa. Putative ortholog groups were analyzed as to their agreement with the phylogram and in cases of disagreements these ortholog groups were broken accordingly.

Expression data was analyzed and the EST libraries were classified using a fixed vocabulary of custom terms such as developmental stages (e.g., genes showing similar expression profile through development with up regulation at specific stage, such as at the seed filling stage) and/or plant organ (e.g., genes showing similar expression profile across their organs with up regulation at specific organs such as seed). The annotations from all the ESTs clustered to a gene were analyzed statistically by comparing their frequency in the cluster versus their abundance in the database, allowing the construction of a numeric and graphic expression profile of that gene, which is termed “digital expression”. The rationale of using these two complementary methods with methods of phenotypic association studies of QTLs, SNPs and phenotype expression correlation is based on the assumption that true orthologs are likely to retain identical function over evolutionary time. These methods provide different sets of indications on function similarities between two homologous genes, similarities in the sequence level —identical amino acids in the protein domains and similarity in expression profiles.

The search and identification of homologous genes involves the screening of sequence information available, for example, in public databases such as the DNA Database of Japan (DDBJ), Genbank, and the European Molecular Biology Laboratory Nucleic Acid Sequence Database (EMBL) or versions thereof or the MIPS database. A number of different search algorithms have been developed, including but not limited to the suite of programs referred to as BLAST programs. There are five implementations of BLAST, three designed for nucleotide sequence queries (BLASTN. BLASTX, and TBLASTX) and two designed for protein sequence queries (BLASTP and TBLASTN) (Coulson, Trends in Biotechnology: 76-80, 1994; Birren et al., Genome Analysis, I: 543, 1997). Such methods involve alignment and comparison of sequences. The BLAST algorithm calculates percent sequence identity and performs a statistical analysis of the similarity between the two sequences. The software for performing BLAST analysis is publicly available through the National Centre for Biotechnology Information. Other such software or algorithms are GAP. BESTFIT, FASTA and TFASTA. GAP uses the algorithm of Needleman and Wunsch (J. Mol. Biol. 48: 443-453, 1970) to find the alignment of two complete sequences that maximizes the number of matches and minimizes the number of gaps.

The homologous genes may belong to the same gene family. The analysis of a gene family may be carried out using sequence similarity analysis. To perform this analysis one may use standard programs for multiple alignments e.g. Clustal W. A neighbour-joining tree of the proteins homologous to the genes in this invention may be used to provide an overview of structural and ancestral relationships. Sequence identity may be calculated using an alignment program as described above. It is expected that other plants will carry a similar functional gene (ortholog) or a family of similar genes and those genes will provide the same preferred phenotype as the genes presented here.

Advantageously, these family members may be useful in the methods of the invention. Example of other plants are included here but not limited to, barley (Hordeum vulgare), Arabidopsis (Arabidopsis thaliana), maize (Zea mays), cotton (Gossypium), Oilseed rape (Brassica napus). Rice (Oryza sativa). Sugar cane (Saccharum officinarum). Sorghum (Sorghum bicolor), Soybean (Glycine max), Sunflower (Helianthus annuus), Tomato (Lycopersicon esculentum). Wheat (Triticum aestivum).

The above-mentioned analyses for sequence homology can be carried out on a full-length sequence, but may also be based on a comparison of certain regions such as conserved domains. The identification of such domains, would also be well within the realm of the person skilled in the art and would involve, for example, a computer readable format of the nucleic acids of the present invention, the use of alignment software programs and the use of publicly available information on protein domains, conserved motifs and boxes. This information is available in the PRODOM (biochem (dot) ucl (dot) ac (dot) uk/bsm/dbbrowser/protocol/prodomqry (dot) html). PIR (pir (dot) Georgetown (dot) edu/) or Pfam (sanger (dot) ac (dot) uk/Software/Pfam/) database. Sequence analysis programs designed for motif searching may be used for identification of fragments, regions and conserved domains as mentioned above. Preferred computer programs include, but are not limited to, MEME, SIGNALSCAN, and GENESCAN.

A person skilled in the art may use the homologous sequences provided herein to find similar sequences in other species and other organisms. Homologues of a protein encompass, peptides, oligopeptides, polypeptides, proteins and enzymes having amino acid substitutions, deletions and/or insertions relative to the unmodified protein in question and having similar biological and functional activity as the unmodified protein from which they are derived. To produce such homologues, amino acids of the protein may be replaced by other amino acids having similar properties (conservative changes, such as similar hydrophobicity, hydrophilicity, antigenicity, propensity to form or break a-helical structures or 3-sheet structures). Conservative substitution tables are well known in the art (see for example Creighton (1984) Proteins. W.H. Freeman and Company). Homologues of a nucleic acid encompass nucleic acids having nucleotide substitutions, deletions and/or insertions relative to the unmodified nucleic acid in question and having similar biological and functional activity as the unmodified nucleic acid from which they are derived.

Polynucleotides and polypeptides with significant homology to the identified genes described in Table 1 (Example 1 above) were identified from the databases using BLAST software with the Blastp and tBlastn algorithms as filters for the first stage, and the needle (EMBOSS package) or Frame+algorithm alignment for the second stage. Local identity (Blast alignments) was defined with a very permissive cutoff—60% Identity on a span of 60% of the sequences lengths because it is used only as a filter for the global alignment stage. The default filtering of the Blast package was not utilized (by setting the parameter “-F F”).

In the second stage, homologs were defined based on a global identity of at least 80% to the core gene polypeptide sequence. Two distinct forms for finding the optimal global alignment for protein or nucleotide sequences were used in this application:

1. Between two proteins (following the blastp filter):

EMBOSS-6.0.1 Needleman-Wunsch algorithm with the following modified parameters: gapopen=8 gapextend=2. The rest of the parameters were unchanged from the default options described hereinabove.

2. Between a protein sequence and a nucleotide sequence (following the tblastn filter):

GenCore 6.0 OneModel application utilizing the Frame+algorithm with the following parameters: model=frame+_p2n.model mode-qglobal -q=protein.sequence -db=nucleotide.sequence. The rest of the parameters are unchanged from the default options described hereinabove.

The query polypeptide sequences were SEQ ID NOs: 552-897 and the query polynucleotides were SEQ ID NOs: 1-551 and the identified orthologous and homologous sequences having at least 80% global sequence identity are provided in Table 2, below. These homologous genes are expected to increase plant yield, seed yield, oil yield, oil content, growth rate, fiber yield, fiber quality, fiber length, photosynthetic capacity, biomass, vigor, ABST and/or NUE of a plant.

Lengthy table referenced here
US20170088852A1-20170330-T00001
Please refer to the end of the specification for access instructions.

Table 2: Provided are the homologous polypeptides and polynucleotides of the genes for increasing yield (e.g., oil yield, seed yield, fiber yield and/or quality), oil content, growth rate, photosynthetic capacity, vigor, biomass, abiotic stress tolerance, nitrogen use efficiency, water use efficiency and fertilizer use efficiency genes of a plant which are listed in Table 1 above. Homology was calculated as % of identity over the aligned sequences. The query sequences were the polypeptide sequences depicted in Table 1 above. The subject sequences are protein sequences identified in the database based on greater than 80% global identity to the predicted translated sequences of the query nucleotide sequences or to the polypeptide sequences. “p.n.”=polynucleotide; “p.p.”=polypeptide; “Algor.”=algorithm (used for sequence alignment and determination of percent homology); “Hom.”—homology; “iden.”—identity; “glob.”—global.

The output of the functional genomics approach described herein is a set of genes highly predicted to improve yield and/or other agronomic important traits such as growth rate, vigor, oil content, fiber yield and/or quality, biomass, photosynthetic capacity, growth rate, abiotic stress tolerance, nitrogen use efficiency, water use efficiency and fertilizer use efficiency of a plant by increasing their expression. Although each gene is predicted to have its own impact, modifying the mode of expression of more than one gene is expected to provide an additive or synergistic effect on the plant yield and/or other agronomic important yields performance. Altering the expression of each gene described here alone or set of genes together increases the overall yield and/or other agronomic important traits, hence expects to increase agricultural productivity.

Example 3

Production of Barley Transcriptome and High Throughput Correlation Analysis Using 44K Barley Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis, the present inventors utilized a Barley oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 47.500 Barley genes and transcripts. In order to define correlations between the levels of RNA expression and yield or vigor related parameters, various plant characteristics of 25 different Barley accessions were analyzed. Among them, 13 accessions encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Four tissues at different developmental stages [meristem, flower, booting spike, stem], representing different plant characteristics were sampled and RNA was extracted as described hereinabove under “GENERAL EXPERIMENTAL AND BIOINFORMATICS METHODS”.

For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 3 below.

TABLE 3
Barley transcriptome expression sets
Expression Set                   Set ID
Booting spike at flowering stage under normal conditions 1
Flowering spike at flowering stage under normal conditions 2
Meristem at flowering stage under normal conditions 3
Stem at flowering stage under normal conditions 4

Table 3: Provided are the identification (ID) letters of each of the Barley expression sets.

Barley yield components and vigor related parameters assessment—13 Barley accessions in 4 repetitive blocks (named A, B, C, and D), each containing 4 plants per plot were grown at net house under normal conditions as recommended for commercial growth [normal growth conditions included irrigation given 2-3 times a week, and fertilization given in the first 1.5 months of the growth period]; under low Nitrogen (80% percent less Nitrogen): or under drought stress (cycles of drought and re-irrigating were conducted throughout the whole experiment, overall 40% less water were given in the drought treatment). Plants were phenotyped on a daily basis following the standard descriptor of barley (Table 4, below). Harvest was conducted while 50% of the spikes were dry to avoid spontaneous release of the seeds. Plants were separated to the vegetative part and spikes, of them, 5 spikes were threshed (grains were separated from the glumes) for additional grain analysis such as size measurement, grain count per spike and grain yield per spike. All material was oven dried and the seeds were threshed manually from the spikes prior to measurement of the seed characteristics (weight and size) using scanning and image analysis. The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

TABLE 4
Barley standard descriptors
Trait	Parameter	Range	Description
Growth habit	Scoring	1-9	Prostrate (1) or Erect (9)
Hairiness of	Scoring	P (Presence)/A	Absence (1) or Presence (2)
basal leaves		(Absence)
Stem	Scoring	1-5	Green (1), Basal only or Half or more
pigmentation			(5)
Days to	Days		Days from sowing to emergence of
Flowering			awns
Plant height	Centimeter (cm)		Height from ground level to top of the
			longest spike excluding awns
Spikes per plant	Number		Terminal Counting
Spike length	Centimeter (cm)		Terminal Counting 5 spikes per plant
Grains per spike	Number		Terminal Counting 5 spikes per plant
Vegetative dry	Gram		Oven-dried for 48 hours at 70° C.
weight
Spikes dry	Gram		Oven-dried for 48 hours at 30° C.
weight

Table 4

At the end of the experiment (50% of the spikes were dry) all spikes from plots within blocks A-D were collected, and the following measurements were performed:

(i) Grains per spike—The total number of grains from 5 spikes that were manually threshed was counted. The average grain per spike was calculated by dividing the total grain number by the number of spikes.

(ii) Grain average size (cm)—The total grains from 5 spikes that were manually threshed were scanned and images were analyzed using the digital imaging system. Grain scanning was done using Brother scanner (model DCP-135), at the 200 dpi resolution and analyzed with Image J software. The average grain size was calculated by dividing the total grain size by the total grain number.

(iii) Grain average weight (mgr)—The total grains from 5 spikes that were manually threshed were counted and weight. The average weight was calculated by dividing the total weight by the total grain number.

(iv) Grain yield per spike (gr) (=seed yield of 5 spikes)—The total grains from 5 spikes that were manually threshed were weight. The grain yield was calculated by dividing the total weight by the spike number.

(v) Spike length analysis—The five chosen spikes per plant were measured using measuring tape excluding the awns.

(vi) Spike number analysis—The spikes per plant were counted.

Additional parameters were measured as follows:

Growth habit scoring—At growth stage 10 (booting), each of the plants was scored for its growth habit nature. The scale that was used was “1” for prostate nature till “9” for erect.

Hairiness of basal leaves—At growth stage 5 (leaf sheath strongly erect; end of tillering), each of the plants was scored for its hairiness nature of the leaf before the last. The scale that was used was “1” for prostate nature till “9” for erect.

Plant height—At harvest stage (50% of spikes were dry), each of the plants was measured for its height using measuring tape. Height was measured from ground level to top of the longest spike excluding awns.

Days to flowering—Each of the plants was monitored for flowering date. Days of flowering were calculated from sowing date till flowering date.

Stem pigmentation—At growth stage 10 (booting), each of the plants was scored for its stem color. The scale that was used was “1” for green till “5” for full purple.

Vegetative dry weight and spike yield—At the end of the experiment (50% of the spikes were dry) all spikes and vegetative material from plots within blocks A-D were collected. The biomass and spikes weight of each plot was separated, measured and divided by the number of plants.

Dry weight=Total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours;

Spike yield per plant=Total spike weight per plant (gr) after drying at 30° C., in oven for 48 hours.

TABLE 5
Barley correlated parameters (vectors)
Correlated parameter with        Correlation ID
Grain weight [milligrams]        1
Grains size [mm2]                2
Grains per spike [numbers]       3
Growth habit [scores 1-9]        4
Hairiness of basal leaves [scoring 1-2] 5
Plant height (cm)                6
Seed yield of 5 spikes [gr/spike] 7
Spike length [cm]                8
Spikes per plant [numbers]       9
Stem pigmentation [scoring 1-5]  10
Vegetative dry weight [gram]     11
Days to flowering [days]         12

Table 5. Provided are the Barley correlated parameters (vectors).

Experimental Results

13 different Barley accessions were grown and characterized for 12 parameters as described above. The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 6 and 7 below.

Subsequent correlation analysis between the various transcriptome expression sets (Table 3) and the average parameters was conducted. Follow, results were integrated to the database (Table 8 below).

TABLE 6
Measured parameters of correlation Ids in Barley accessions
Ecotype/Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	35.05	28.06	28.76	17.87	41.22	29.73	25.22
2	0.27	0.23	0.24	0.17	0.29	0.28	0.22
3	20.23	17.98	17.27	17.73	14.47	16.78	12.12
4	2.60	2.00	1.92	3.17	4.33	2.69	3.60
5	1.53	1.33	1.69	1.08	1.42	1.69	1.30
6	134.27	130.50	138.77	114.58	127.75	129.38	103.89
7	3.56	2.54	2.58	1.57	3.03	2.52	1.55
8	12.04	10.93	11.83	9.90	11.68	11.53	8.86
9	48.85	48.27	37.42	61.92	33.27	41.69	40.00
10	1.13	2.50	1.69	1.75	2.33	2.31	1.70
11	78.87	66.14	68.49	53.39	68.30	74.17	35.35
12	62.40	64.08	65.15	58.92	63.00	70.54	52.80

Table 6. Provided are the values of each of the parameters measured in Barley accessions (1-7) according to the correlation identifications (see Table 5).

TABLE 7
Barley accessions, additional measured parameters
Ecotype/
Treatment	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13
1	34.99	20.58	27.50	37.13	29.56	19.58
2	0.28	0.19	0.22	0.27	0.27	0.18
3	14.07	21.54	12.10	13.40	15.28	17.07
4	3.50	3.00	3.67	2.47	3.50	3.00
5	1.19	1.00	1.17	1.60	1.08	1.17
6	121.63	126.80	99.83	121.40	118.42	117.17
7	2.62	2.30	1.68	2.68	2.35	1.67
8	11.22	11.11	8.58	10.18	10.51	9.80
9	40.63	62.00	49.33	50.60	43.09	51.40
10	2.19	2.30	1.83	3.07	1.58	2.17
11	58.33	62.23	38.32	68.31	56.15	42.68
12	60.88	58.10	53.00	60.40	64.58	56.00

Table 7. Provided are the values of each of the parameters measured in Barley accessions (8-13) according to the correlation identifications (see Table 5).

TABLE 8
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal fertilization
conditions across barley accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY20	0.72	1.32E−02	3	9	LBY21	0.81	2.27E−03	1	2
LBY21	0.75	7.63E−03	1	1	LBY22	0.74	9.92E−03	3	7
LBY25	0.75	7.51E−03	3	9	LBY26	0.88	3.49E−04	3	2
LBY26	0.83	1.63E−03	3	1	LBY26	0.72	1.19E−02	3	7
LBY26	0.81	2.69E−03	3	12	LBY29	0.71	1.47E−02	3	12
LBY30	0.78	4.36E−03	3	9	LBY31	0.79	6.50E−03	2	10
LBY32	0.88	4.12E−04	1	2	LBY32	0.87	5.83E−04	1	1
LBY32	0.70	1.56E−02	3	9	LGN42	0.86	6.89E−04	3	9
LGN43	0.74	8.67E−03	1	9	LGN43	0.72	1.20E−02	1	3

Table 8. Provided are the correlations (R) between the gene expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 86. “Exp. Set”—Expression set specified in Table 84. “R”=Pearson correlation coefficient; “P”=p value.

Example 4

Production of Barley Transcriptome and High Throughput Correlation Analysis Using 60K Barley Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis comparing between plant phenotype and gene expression level, the present inventors utilized a Barley oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60K Barley genes and transcripts. In order to define correlations between the levels of RNA expression and yield or vigor related parameters, various plant characteristics of 15 different Barley accessions were analyzed. Among them, 10 accessions encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Analyzed barley tissues—Six tissues at different developmental stages [leaf, meristem, root tip, adventitious root, booting spike and stem], representing different plant characteristics, were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Tables 9-11 below.

TABLE 9
Barley transcriptome expression sets under
drought and recovery conditions
Expression Set                   Set ID
Booting spike under drought conditions 1
Leaf at reproductive stage under drought conditions 2
Leaf at vegetative stage under draught conditions 3
Meristem at vegetative stage under drought conditions 4
Root tip at vegetative stage under drought conditions 5
Root tip at vegetative stage under recovery from drought 6
conditions

Table 9. Provided are the barley transcriptome expression sets under drought and recovery conditions.

TABLE 10
Barley transcriptome expression sets under
normal and low nitrogen conditions (set 1)
Expression Set                   Set ID
Adventitious roots under low nitrogen conditions 1
Adventitious roots under normal conditions 2
Leaf under low nitrogen conditions 3
Leaf under normal conditions     4
Root tip under low nitrogen conditions 5
Root tip under normal conditions 6

Table 10. Provided are the barley transcriptome expression sets under normal and low nitrogen conditions (set 1—vegetative stage).

TABLE 11
Barley transcriptome expression sets under
normal and low nitrogen conditions (set 2)
                                 Set
Expression Set                   ID
Booting spike under low nitrogen conditions 1
Booting spike under normal conditions 2
Leaf under low nitrogen conditions 3
Leaf under normal conditions     4
Stem under low nitrogen conditions 5
Stem under normal conditions     6

Table 11. Provided are the barley transcriptome expression sets under normal and low nitrogen conditions (set 2—reproductive stage).

Barley yield components and vigor related parameters assessment—15 Barley accessions in 5 repetitive blocks, each containing 5 plants per pot were grown at net house. Three different treatments were applied: plants were regularly fertilized and watered during plant growth until harvesting as recommended for commercial growth under normal conditions [normal growth conditions included irrigation 2-3 times a week and fertilization given in the first 1.5 months of the growth period]; under low Nitrogen (80% percent less Nitrogen); or under drought stress (cycles of drought and re-irrigating were conducted throughout the whole experiment, overall 40% less water as compared to normal conditions were given in the drought treatment). Plants were phenotyped on a daily basis following the standard descriptor of barley (Tables 12-15, below). Harvest was conducted while all the spikes were dry. All material was oven dried and the seeds were threshed manually from the spikes prior to measurement of the seed characteristics (weight and size) using scanning and image analysis. The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Grain yield (gr.)—At the end of the experiment all spikes of the pots were collected. The total grains from all spikes that were manually threshed were weighted. The grain yield was calculated by per plot or per plant.

Spike length and width analysis—At the end of the experiment the length and width of five chosen spikes per plant were measured using measuring tape excluding the awns.

Spike number analysis—The spikes per plant were counted.

Plant height—Each of the plants was measured for its height using a measuring tape. Height was measured from ground level to top of the longest spike excluding awns at two time points at the Vegetative growth (30 days after sowing) and at harvest.

Spike weight—The biomass and spikes weight of each plot were separated, measured and divided by the number of plants.

Dry weight=Total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours at two time points at the Vegetative growth (30 days after sowing) and at harvest.

Spikelet per spike=number of spikelets per spike was counted.

Root/Shoot Ratio—The Root/Shoot Ratio is calculated using Formula XXII (above).

Total No. of tillers—all tillers were counted per plot at two time points at the Vegetative growth (30 days after sowing) and at harvest.

Percent of reproductive tillers—was calculated based on Formula XXVI (above).

SPAD [SPAD unit]—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at time of flowering. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Root FW (gr.), root length (cm) and No. of lateral roots—3 plants per plot were selected for measurement of root weight, root length and for counting the number of lateral roots formed.

Shoot FW (fresh weight)—weight of 3 plants per plot were recorded at different time-points.

Average Grain Area (cm²)—At the end of the growing period the grains were separated from the spike. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Average Grain Length and width (cm)—At the end of the growing period the grains were separated from the spike. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths or width (longest axis) was measured from those images and was divided by the number of grains

Average Grain perimeter (cm)—At the end of the growing period the grains were separated from the spike. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain perimeter was measured from those images and was divided by the number of grains.

Heading date—the day in which booting stage was observed was recorded and number of days from sowing to heading was calculated.

Relative water content—was calculated based on Formula I.

Harvest Index (for barley)—The harvest index is calculated using Formula XVIII (above).

Relative growth rate: the relative growth rates (RGR) of Plant Height, SPAD and number of tillers were calculated based on Formulas III, IV and V respectively.

RATIO Drought/Normal: Represent ratio for the specified parameter of Drought condition results divided by Normal conditions results (maintenance of phenotype under drought in comparison to normal conditions).

Data parameters collected are summarized in Table 12-15, hereinbelow

TABLE 12
Barley correlated parameters (vectors)
under drought and recovery conditions
                                 Correlation
Correlated parameter with        ID
Chlorophyll levels [SPAD unit]   1
Dry weight at harvest [gr]       2
Dry weight vegetative growth [gr/day] 3
Fresh weight [gr]                4
Grain number [num]               5
Grain weight [gr]                6
Harvest index [yield/(yield + biomass)] 7
Heading date [days]              8
Height Relative growth rate [cm/day] 9
Number of tillers Relative growth rate [num/day] 10
Plan height T2 [cm]              11
Root/shoot [ratio]               12
Relative water content [%]       13
Root dry weight [gr]             14
Root fresh weight [gr]           15
Root length [cm]                 16
SPAD Relative growth rate [SPAD unit/day] 17
Spike length [cm]                18
Spike number [num]               19
Spike weight per plant [gr]      20
Spike width [cm]                 21
Tillers number T2 [num]          22
Lateral root number [num]        23

Table 12. Provided are the barley correlated parameters.

TABLE 13
Barley correlated parameters (vectors) for maintenance
of performance under drought conditions
                                 Correlation
Correlated parameter with        ID
Chlorophyll levels [ratio]       1
Dry weight at harvest [ratio]    2
Dry weight vegetative growth [ratio] 3
Fresh weight [ratio]             4
Grain number [ratio]             5
Grain weight [ratio]             6
Harvest index [ratio]            7
Heading date [ratio]             8
Plant height [ratio]             9
Root/shoot [ratio]               10
Relative water content [ratio]   11
Root dry weight [ratio]          12
Root fresh weight [ratio]        13
Root length [ratio]              14
Spike length [ratio]             15
Spike number [ratio]             16
Spike weight per plant [ratio]   17
Spike width [ratio]              18
Tillers number [ratio]           19
Lateral root number [ratio]      20

Table 13. Provided are the barley correlated parameters. “ratio”—ratio for the specified parameter of Drought condition results divided by Normal conditions results (maintenance of phenotype under drought in comparison to normal conditions.

TABLE 14
Barley correlated parameters (vectors) under
low nitrogen and normal conditions (set 1)
                                 Correlation
Correlated parameter with        ID
Lateral Roots under Normal growth conditions 1
[number]
Leaf Area, under Normal growth conditions [mm2] 2
Leaf Number, TP4, under Low N growth conditions 3
[number]
Max Length, under Normal growth conditions [mm] 4
Max Width, under Normal growth conditions [mm] 5
Max Length, TP4, under Low N growth conditions [mm] 6
Max Width, TP4, under Low N growth conditions [mm] 7
No of lateral roots, under Low N growth conditions, 8
TP2 [number]
No of tillers, under Low N growth conditions, TP2 9
[number]
Num Leaves, under Normal growth conditions 10
[number]
Num Seeds, under Normal growth conditions 11
[number]
Number of Spikes, under Normal growth conditions 12
[number]
Num Tillers, under Normal growth conditions 13
[number]
Plant Height, under Normal growth conditions, T2 [cm] 14
Plant Height, under Low N growth conditions [cm] 15
Plant Height, under Low N growth conditions, TP2 [cm] 16
Root FW, under Normal growth conditions [gr.] 17
Root Length, under Normal growth conditions [cm] 18
Root FW, under Low N growth conditions, TP2 [gr.] 19
Root length, under Low N growth conditions, TP2 [cm] 20
SPAD, under Normal growth conditions [SPAD unit] 21
SPAD, under Low N growth conditions, TP2 [SPAD unit] 22
Seed Yield, under Normal growth conditions [gr.] 23
Seed Number (per plot) under Low N growth conditions 24
[number]
Seed Yield, under Low N growth conditions [gr.] 25
Seed Yield, under Normal growth conditions [gr.] 26
Shoot FW, under Normal growth conditions [gr.] 27
Spike Length, under Normal growth conditions [cm] 28
Spike Width, under Normal growth conditions [cm] 29
Spike weight, under Normal growth conditions [gr.] 30
Spike Length, under Low N growth conditions [cm] 31
Spike Width, under Low N growth conditions [cm] 32
Spike total weight ([per plot) under Low N growth 33
conditions [gr.]
Total Tillers, under Normal growth conditions 34
[number]
Total Leaf Area, TP4, under Low N growth conditions 35
[mm2]
Total No of Spikes (per plot) under Low N growth 36
conditions [number]
Total No of tillers (per plot) under Low N growth 37
conditions [number]
Shoot FW, under Low N growth conditions, TP2 [gr.] 38

Table 14. Provided are the barley correlated parameters. “TP”=time point; “DW”=dry weight; “FW”=fresh weight; “Low N”=Low Nitrogen; “Normal”=regular growth conditions. “Max”=maximum.

TABLE 15
Barley correlated parameters (vectors) under
low nitrogen and normal conditions (set 2)
                                 Correlation
Correlated parameter with        ID
Grain Perimeter (cm)             1
Grain area (cm2)                 2
Grain length (cm)                3
Grain width (cm)                 4
Grains DW/Shoots DW (ratio)      5
Grains per plot (number)         6
Grains weight per plant (gr.)    7
Grains weight per plot (gr.)     8
Plant Height (cm)                9
Roots DW (mg)                    10
Row number (number)              11
Spikes FW (Harvest) (gr.)        12
Spikes num (number)              13
Tillering (Harvest) (number)     14
Vegetative DW (Harvest) (gr.)    15
percent of reproductive tillers (%) 16
shoot/root ratio (ratio)         17

Table 15. Provided are the barley correlated parameters. “TP”=time point; “DW”=dry weight; “FW”=fresh weight: “Low N”=Low Nitrogen; “Normal”=regular growth conditions. “Max”=maximum. Note that each of the parameters described in this Table was measured under both low N growth conditions and normal growth conditions.

Experimental Results

15 different Barley accessions were grown and characterized for different parameters as described above. Tables 12-15 above describe the Barley correlated parameters. The average for each of the measured parameters was calculated using the JMP software and values are summarized in Tables 16-25 below. Subsequent correlation analysis between the various transcriptome sets and the average parameters (Tables 16-25) was conducted. Follow, results were integrated to the database (Tables 26-29).

TABLE 16
Measured parameters of correlation IDs in Barley accessions under drought and recovery
conditions
	Corr. ID
Line	1	2	3	4	5	6	7	8	9	10	11	12
Line-1	41.33	6.15	0.21	1.90	170.00	5.55	0.47	75.00	0.27	0.070	46.00	0.013
Line-2	33.57	5.05	0.21	1.52	267.50	9.80	0.66	71.00	0.86	0.097	52.80	0.012
Line-3	36.57	3.20		1.17	111.00	3.55	0.53	65.00	0.73	0.059	35.00	0.008
Line-4	40.50	3.28		1.95	205.33	7.20	0.69		0.88	0.071	38.00	0.006
Line-5	45.07	4.76		1.90	153.60	5.28	0.53	66.75	0.40	0.164	45.20	0.025
Line-6	39.73	3.55	0.17	1.22	252.50	7.75	0.69	90.00	0.94	0.061	48.00	0.020
Line-7	38.33	4.52		1.75	288.40	9.92	0.69	90.00	0.70	0.104	37.67	0.008
Line-8	36.17	3.38		1.58	274.50	10.25	0.75		0.71	0.049	41.20	0.008
Line-9	42.13	5.67	0.25	1.88	348.50	8.50	0.60	90.00	0.77	0.100	40.80	0.012
Line-10	31.77	3.31		1.73	358.00	14.03	0.81		0.80	0.061	49.86	0.007
Line-11	33.4	2.65		1.00	521.39	17.52	0.87		0.92	0.063	43.00	0.016
Line-12	42.37	5.12	0.13	0.90	71.50	2.05	0.29	90.00	0.39	0.183	47.40	0.023
Line-13	42.27	6.86	0.19	0.90	160.13	5.38	0.44	81.60	0.88	0.149	64.80	0.012
Line-14	36.77	3.11	0.22	1.43	376.67	11.00	0.78	90.00	−0.13	0.022	52.60	0.012
Line-15	40.63	3.74		0.83	105.0	2.56	0.41		0.20	0.442	32.00	0.026

Table 16. Provided are the values of each of the parameters (as described above in Table 12) measured in Barley accessions (line) under drought growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 17
Additional measured parameters of correlation IDs in Barley accessions under drought and
recovery conditions
	Corr. ID
Line	13	14	15	16	17	18	19	20	21	22	23
Line-1	80.60	77.52	2.07	21.67	0.087	16.70	4.20	17.72	8.64	11.68	8.33
Line-2	53.40	60.19	1.48	20.33	−0.123	16.85	4.36	24.24	9.07	9.04	8.67
Line-3	55.87	27.13	1.12	22.00	0.001	13.27	7.60	18.20	7.82	10.92	7.33
Line-4		18.62	1.87	24.00	0.010	13.55	8.44	18.00	7.32	10.16	7.67
Line-5	43.21	117.42	1.67	20.67	0.037	14.19	4.92	19.50	8.74	10.32	6.67
Line-6	69.78	70.72	1.68	18.33	−0.072	15.64	3.43	15.00	7.62	8.78	6.67
Line-7	45.49	37.34	1.62	21.00	0.013	15.66	6.90	23.40	6.98	13.00	7.67
Line-8	76.51	25.56	0.85	20.33	0.003	17.49	5.80	28.16	8.05	7.44	6.67
Line-9	87.41	66.18	1.45	21.67	−0.063	16.00	8.55	21.96	6.06	13.92	6.00
Line-10		22.13	1.38	19.67	0.035	18.31	9.67	33.03	6.73	11.00	8.67
Line-11		41.12	0.82	16.67	0.050	17.42	5.42	34.80	9.55	6.78	7.67
Line-12	58.32	116.95	0.58	17.00	−0.004	14.23	3.05	11.73	7.84	8.45	6.33
Line-13	80.58	84.10	0.63	15.17	−0.072	14.81	4.07	18.78	7.81	9.15	7.00
Line-14	73.09	37.46	1.07	27.00	0.025	16.54	3.72	21.00	8.35	5.12	7.00
Line-15		98.86	0.70	15.00	−0.063	12.72	3.21	9.88	5.47	16.13	6.67

Table 17. Provided are the values of each of the parameters (as described above in Table 12) measured in Barley accessions (line) under drought growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 18
Measured parameters of correlation IDs in Barley accessions) for maintenance of
performance under drought conditions
	Corr. ID
Line	1	2	3	4	5	6	7	8	9	10
Line-1	0.98	0.61	0.93	0.60	0.12	0.08	0.54	0.00	0.51	1.55
Line-2	0.72	0.45	0.71	0.50	0.22	0.17	0.79	1.12	0.61	0.97
Line-3	1.30	0.59	0.00	0.47	0.11	0.06	0.58	1.30	0.67	1.12
Line-4	1.06	0.67	0.00	0.68	0.19	0.14	0.75	0.00	0.72	0.56
Line-5	1.03	0.41	0.00	0.46	0.17	0.15	0.70	1.00	0.61	1.72
Line-6	0.95	0.54	0.65	0.47	0.21	0.14	0.77	1.06	0.59	1.97
Line-7	0.82	0.75	0.00	0.58	0.22	0.15	0.75	1.37	0.70	0.67
Line-8	0.93	0.65	0.92	0.62	0.24	0.20	0.83	1.22	0.63	0.96
Line-9	0.93	0.77	1.01	0.74	0.25	0.14	0.67	0.00	0.66	1.14
Line-10	0.80	0.80	0.00		0.58	0.47	0.92		0.87	1.08
Line-11	0.94	0.68	0.00	0.81	0.43	0.32	0.93		0.86	1.38
Line-12	0.96	0.42	0.94	0.72	0.10	0.07	0.41	1.20	0.64	1.84
Line-13	1.01	0.65	0.00	0.37	0.10	0.07	0.50	1.00	0.79	1.31
Line-14	0.93	0.52	0.70	0.40	0.28	0.20	0.87		0.56	2.06
Line-15	1.03	0.46	0.00		0.43	0.32	0.82		0.51	1.46

Table 18. Provided are the values of each of the parameters (as described above in Table 13) measured in Barley accessions (line) for maintenance of performance under drought (calculated as % of change under drought vs. normal growth conditions). Growth conditions are specified in the experimental procedure section.

TABLE 19
Additional measured parameters of correlation IDs in Barley accessions) for maintenance
of performance under drought conditions
	Corr. ID
Line	11	12	13	14	15	16	17	18	19	19	20
Line-1	0.78	0.94	1.10	0.66	0.83	0.73	0.16	0.75	1.87	1.87	1.09
Line-2	0.58	0.44	1.00	0.74	0.82	0.96	0.23	0.77	1.57	1.57	0.74
Line-3	0.90	0.66	1.02	1.16	0.86	1.11	0.19	0.68	1.72	1.72	0.79
Line-4	0.00	0.37	1.67	0.78	0.77	1.30	0.23	0.67	1.80	1.80	0.88
Line-5	0.65	0.71	0.80	0.76	0.78	0.83	0.25	0.87	1.60	1.60	0.71
Line-6	0.56	1.06	0.81	0.76	0.94	0.62	0.18	0.66	1.61	1.61	0.65
Line-7	0.78	0.50	1.13	0.68	0.83	0.87	0.23	0.75	1.63	1.63	0.85
Line-8	0.83	0.62	0.34	0.77	0.89	1.12	0.34	0.74	1.59	1.59	0.77
Line-9	0.50	0.88	0.85	1.12	0.78	1.09	0.22	0.74	1.75	1.75	0.58
Line-		0.87	0.58	0.56	0.94	1.09	0.68	0.86	1.33	1.33	0.96
10
Line-	0.00	0.94	0.07	0.42	0.88	0.92	0.55	0.85	1.62	1.62	0.88
11
Line-	0.00	0.77	1.06	0.82	0.77	0.49	0.18	0.79	1.33	1.33	0.95
12
Line-	0.78	0.85	0.30	0.43	0.86	0.65	0.18	0.72	1.40	1.40	0.78
13
Line-	0.55	1.06	0.44	0.71	0.97	0.99	0.27	0.72	1.22	1.22	0.66
14
Line-		0.68	0.93	0.80	0.78	0.52	0.25	0.88	1.96	1.96	0.87
15

Table 19. Provided are the values of each of the parameters (as described above in Table 13) measured in Barley accessions (line) for maintenance of performance under drought (calculated as % of change under drought vs. normal growth conditions). Growth conditions are specified in the experimental procedure section.

TABLE 20
Measured parameters of correlation IDs in Barley accessions) under low nitrogen and
normal conditions (set 1)
	Line
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9	Line-10
3	8.00	8.00	7.50	8.50	10.00	11.50	8.60	6.33	7.50	10.00
6	102.90	107.78	111.57	142.42	152.38	149.33	124.08	95.00	124.12	135.17
7	5.25	5.17	5.12	5.30	5.20	5.33	5.32	5.10	5.15	5.10
8	5.00	6.00	4.33	6.00	6.33	6.00	6.67	4.67	5.67	7.33
9	0.00	0.00	0.00	0.00	0.00	0.00	0.00	0.00	0.00	0.00
15	41.00	82.00	61.40	59.40	65.80	47.80	53.80	56.40	81.80	44.60
16	16.33	18.83	17.33	26.00	22.50	18.17	19.67	19.83	19.17	19.17
19	0.38	0.23	0.12	0.40	0.88	0.50	0.43	0.32	0.30	0.55
20	24.67	21.67	22.00	21.67	22.17	23.00	30.50	22.83	23.83	24.50
22	24.03	23.30	26.47	23.90	26.63	23.20	25.43	24.23	25.03	26.07
24	230.20	164.60	88.25	133.60	106.00	222.60	219.20	143.45	201.80	125.00
25	9.76	7.31	3.30	5.06	6.02	9.74	7.35	5.80	7.83	6.29
26	46.37	19.81	10.84	22.58	30.30	54.13	36.98	42.04	35.37	38.25
31	15.19	19.61	16.30	19.32	90.22	16.44	20.44	18.84	18.77	16.65
32	7.95	8.13	9.43	4.94	9.60	7.16	7.06	8.51	10.01	9.40
33	13.74	13.44	9.15	11.64	11.34	15.06	12.18	10.95	12.18	10.62
35	39.40	46.27	51.51	57.07	67.78	64.15	52.42	46.15	68.02	57.91
36	12.20	9.00	11.60	25.00	7.80	14.50	15.00	7.00	5.40	8.40
37	16.20	14.60	16.00	20.75	12.50	18.80	21.20	11.00	6.75	14.00
38	0.43	0.43	0.33	0.58	0.78	0.53	0.45	0.43	0.50	0.62

Table 20. Provided are the values of each of the parameters (as described above in Table 14) measured in Barley accessions (line) under low N and normal growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 21
Measured parameters of correlation IDs in Barley accessions) under normal conditions
(set 1)
	Line
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9	Line-10
1	7.00	8.67	8.33	9.67	10.70	9.67	9.67	8.67	10.00	9.67
2	294.0	199.0	273.0	276.0	313.0	309.0	259.0	291.0	299.0	296.0
4	502.0	348.0	499.0	594.0	535.0	551.0	479.0	399.0	384.0	470.0
5	5.77	5.45	5.80	6.03	4.63	5.33	5.83	5.43	5.75	6.03
10	24.2	18.2	22.7	25.5	23.2	28.3	22.2	19.0	17.3	22.0
11	1090.0	510.0	242.0	582.0	621.0	1070.0	903.0	950.0	984.0	768.0
12	41.5	32.0	36.0	71.4	34.2	45.6	49.8	28.0	19.3	38.0
13	2.00	2.00	1.00	2.33	2.33	3.33	2.33	1.33	1.33	1.67
14	64.7	84.0	67.4	82.0	72.0	56.6	65.8	62.8	91.6	66.2
17	0.27	0.27	0.25	0.35	0.62	0.27	0.35	0.32	0.23	0.27
18	21.30	15.00	21.80	20.30	27.20	16.00	24.00	13.50	21.50	15.20
21	39.10	41.40	35.20	33.70	34.20	42.80	37.00	36.90	35.00	36.80
23	46.4	19.8	10.8	22.6	30.3	54.1	37.0	42.0	35.4	38.3
27	2.17	1.90	1.25	3.00	15.60	3.02	2.58	1.75	2.18	1.82
28	16.5	19.2	18.3	20.4	17.2	19.1	20.3	21.7	16.5	16.1
29	9.54	9.05	8.25	6.55	10.50	8.83	7.38	10.40	10.20	10.30
30	69.40	39.40	34.90	50.30	60.80	79.10	62.70	60.00	55.90	59.70
34	46.7	41.6	40.0	48.8	34.6	48.6	49.2	29.0	27.5	38.8

Table 21. Provided are the values of each of the parameters (as described above in Table 15) measured in Barley accessions (line) under normal growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 22
Measured parameters of correlation IDs in Barley accessions)
under normal conditions (set 2)
	Line
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8
1	2.239	2.243	2.182	2.047	2.083	2.028	2.247	1.878
2	0.246	0.241	0.238	0.232	0.237	0.248	0.244	0.218
3	0.887	0.874	0.863	0.796	0.825	0.778	0.901	0.717
4	0.352	0.350	0.350	0.369	0.365	0.406	0.346	0.387
5	0.398	0.156	1.010	0.793	0.413	0.987	0.665	0.614
6	683.4	510.5	1093.5	767.6	621.0	1069.0	987.8	903.2
7	6.65	3.96	9.27	7.65	6.06	10.83	7.94	7.40
8	33.24	19.81	46.37	38.25	30.30	54.13	39.69	36.98
9	76.40	84.00	64.67	66.20	72.00	56.60	68.00	65.80
10	118.30	150.68	86.28	85.19	120.31	90.70	40.58	90.51
11	6.0	6.0	6.0	6.0	6.0	2.8	6.0	2.0
12	69.84	39.86	69.40	59.72	60.83	79.12	63.50	62.74
13	38.60	32.00	41.50	38.00	34.20	45.60	30.00	49.80
14	44.25	41.60	46.67	38.80	34.60	48.60	32.40	55.20
15	89.20	99.65	45.79	49.39	74.32	55.11	47.29	60.32
16	82.30	77.75	86.69	94.23	89.74	93.73	89.49	90.27
17	1.48	0.64	0.84	0.82	1.15	0.69	1.26	0.72

Table 22. Provided are the values of each of the parameters (as described above in Table 15) measured in Barley accessions (line) under normal growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 23
Additional measured parameters of correlation IDs in Barley accessions)
under normal conditions (set 2)
Corr.	Line
ID	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14	Line-15
1	2.094	2.028	2.018	1.984	1.688	1.979	1.891
2	0.232	0.223	0.235	0.213	0.177	0.191	0.174
3	0.823	0.794	0.797	0.799	0.650	0.824	0.773
4	0.359	0.356	0.374	0.337	0.346	0.294	0.287
5	0.282	1.037	0.116	0.859	0.576	0.050	0.079
6	581.8	904.4	242.4	928.4	984.2	157.7	263.3
7	4.52	8.41	2.00	8.05	7.07	0.75	1.14
8	22.58	39.68	10.84	40.26	35.37	3.73	5.68
9	82.00	62.80	67.40	76.20	91.60	44.00	52.75
10	92.59	63.95	286.63	95.79	34.04	121.27	206.75
11	2.0	5.2	6.0	6.0	6.0	4.7	4.0
12	50.30	59.95	34.92	60.08	55.88	16.93	21.70
13	71.40	28.00	36.00	27.60	23.60	54.67	48.00
14	50.60	29.00	40.00	28.50	27.50	26.00
15	88.01	38.89	97.71	48.33	62.52	57.97	72.78
16	91.21	92.50	91.73	85.31
17	1.17	0.71	0.38	0.51	2.16	0.67	0.39

Table 23. Provided are the values of each of the parameters (as described above in Table 15) measured in Barley accessions (line) under normal growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 24
Measured parameters of correlation IDs in Barley accessions)
under low nitrogen conditions (set 2)
Corr.	Line
ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	2.28	2.33	2.28	2.08	2.13	1.96	2.09
2	0.250	0.251	0.255	0.235	0.249	0.227	0.227
3	0.90	0.92	0.93	0.82	0.86	0.76	0.83
4	0.351	0.346	0.349	0.364	0.366	0.381	0.347
5	0.39	0.42	1.25	0.69	0.43	0.87	0.77
6	153.2	164.6	230.2	125.0	100.0	222.6	159.4
7	1.34	1.46	1.95	1.26	1.13	1.95	1.28
8	6.68	7.31	9.76	6.29	5.67	9.74	6.40
9	75.20	82.00	41.00	44.60	65.80	47.80	60.60
10	39.91	26.24	17.31	32.91	33.87	83.84	29.65
11	6.0	6.0	6.0	6.0	6.0	2.0	6.0
12	11.40	13.44	13.74	10.62	11.34	15.06	11.64
13	10.80	9.00	12.20	8.40	7.80	14.50	8.40
14	16.00	14.60	16.20	14.00	12.50	18.80	11.60
15	17.42	17.76	8.25	7.28	13.25	11.32	8.95
16	68.68	61.85	76.94	59.63	65.63	79.84	73.85
17	0.69	1.08	0.77	0.38	0.83	0.42	0.28

Table 24. Provided are the values of each of the parameters (as described above in Table 15) measured in Barley accessions (line) under low N growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 25
Additional measured parameters of correlation IDs in Barley accessions)
under low nitrogen conditions (set 2)
	Line
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14	Line-15
1	1.88	2.19	1.88	2.03	2.11	1.77	2.00	1.90
2	0.205	0.235	0.201	0.222	0.234	0.193	0.190	0.170
3	0.73	0.86	0.73	0.81	0.85	0.68	0.81	0.79
4	0.355	0.345	0.349	0.348	0.348	0.360	0.295	0.275
5	0.53	0.34	0.87	0.15	0.58	0.76	0.05	0.07
6	219.2	133.6	134.4	88.3	174.3	201.8	86.7	61.6
7	1.47	0.98	1.16	0.92	1.33	1.57	0.29	0.22
8	7.35	5.06	5.43	4.62	6.67	7.83	1.44	1.12
9	53.80	59.40	56.40	61.40	65.60	81.80	69.00	57.40
10	37.21	44.38	14.46	41.54	23.75	20.87	49.69	54.02
11	2.0	2.0	5.2	6.0	6.0	6.0	2.0	2.0
12	12.18	11.64	8.76	9.15	12.42	12.18	5.68	5.04
13	15.00	25.00	7.00	11.60	7.60	5.40	16.40	12.00
14	21.20	23.50	11.00	16.00	10.75	6.75	35.00
15	14.18	15.68	6.42	55.92	11.54	10.88	58.92	17.05
16	71.01	95.83	64.87	68.75	74.24	81.40	37.14
17	0.57	0.60	0.55	2.88	1.36	0.89	2.49	0.40

Table 25. Provided are the values of each of the parameters (as described above in Table 15) measured in Barley accessions (line) under low N growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 26
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under drought stress
conditions across Barley accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY18	0.73	1.00E−01	1	23	LBY18	0.70	5.29E−02	3	11
LBY18	0.79	2.04E−02	3	12	LBY18	0.77	4.21E−02	2	23
LBY18	0.82	1.32E−02	5	11	LBY18	0.80	1.75E−02	5	14
LBY19	0.82	1.19E−02	3	19	LBY19	0.75	5.33E−02	2	7
LBY19	0.75	5.10E−02	2	21	LBY19	0.82	2.51E−02	2	5
LBY19	0.83	2.12E−02	2	6	LBY19	0.71	7.32E−02	2	9
LBY19	0.77	4.11E−02	2	12	LBY19	0.74	5.55E−02	9	20
LBY20	0.75	8.51E−02	1	7	LBY20	0.89	1.89E−02	1	11
LBY20	0.89	1.78E−02	1	18	LBY20	0.71	1.15E−01	1	5
LBY20	0.79	6.03E−02	1	6	LBY20	0.86	2.77E−02	1	20
LBY20	0.91	4.26E−03	2	23	LBY21	0.74	9.14E−02	1	11
LBY21	0.78	6.50E−02	1	20	LBY21	0.75	1.94E−02	6	4
LBY22	0.88	4.03E−03	3	19	LBY22	0.84	1.87E−02	2	11
LBY22	0.72	6.63E−02	2	23	LBY22	0.74	5.84E−02	2	20
LBY22	0.76	1.66E−02	4	19	LBY23	0.90	1.56E−02	1	11
LBY23	0.80	5.62E−02	1	18	LBY23	0.91	1.09E−02	1	5
LBY23	0.82	4.70E−02	1	6	LBY23	0.75	8.69E−02	1	20
LBY23	0.83	2.12E−02	2	12	LBY23	0.75	4.98E−02	2	14
LBY24	0.82	4.61E−02	1	11	LBY24	0.77	7.62E−02	1	16
LBY24	0.74	8.98E−02	1	18	LBY24	0.76	7.93E−02	1	1
LBY24	0.72	1.06E−01	1	20	LBY24	0.76	1.81E−02	6	7
LBY24	0.80	1.01E−02	6	5	LBY24	0.81	7.77E−03	6	6
LBY24	0.72	2.75E−02	6	20	LBY24	0.81	5.18E−02	5	8
LBY24	0.80	9.03E−03	4	19	LBY24	0.80	9.83E−03	4	22
LBY24	0.71	3.05E−02	4	4	LBY25	0.76	7.88E−02	5	13
LBY26	0.82	4.74E−02	1	11	LBY26	0.82	4.40E−02	1	18
LBY26	0.70	1.20E−01	1	6	LBY26	0.95	3.89E−03	1	12
LBY26	0.83	4.04E−02	1	2	LBY26	0.93	6.61E−03	1	14
LBY26	0.77	7.07E−02	1	20	LBY26	0.76	4.81E−02	2	5
LBY26	0.75	4.99E−02	2	12	LBY26	0.75	5.45E−02	2	14
LBY26	0.71	4.76E−02	5	19	LBY26	0.77	7.38E−02	5	8
LBY26	0.80	1.73E−02	5	4	LBY26	0.84	4.32E−03	4	22
LBY26	0.80	9.77E−03	4	4	LBY26	0.74	2.27E−02	4	15
LBY27	0.92	1.01E−02	1	21	LBY27	0.78	3.87E−02	3	13
LBY27	0.75	5.29E−02	6	8	LBY28	0.79	6.17E−02	1	11
LBY28	0.80	5.60E−02	1	23	LBY28	0.77	7.31E−02	1	6
LBY28	0.73	9.69E−02	1	20	LBY28	0.82	1.34E−02	3	19
LBY28	0.76	2.86E−02	3	7	LBY28	0.83	2.22E−02	2	11
LBY28	0.77	2.68E−02	5	19	LBY28	0.83	5.45E−03	4	19
LBY28	0.75	1.89E−02	4	22	LBY29	0.72	1.10E−01	1	17
LBY29	0.72	4.59E−02	3	19	LBY29	0.73	2.52E−02	6	1
LBY29	0.80	3.08E−02	2	11	LBY29	0.80	3.11E−02	2	23
LBY30	0.87	2.34E−02	1	16	LBY30	0.75	8.62E−02	1	9
LBY30	0.77	7.08E−02	1	1	LBY30	0.75	3.10E−02	3	21
LBY30	0.78	1.30E−02	6	7	LBY30	0.87	2.10E−03	6	5
LBY30	0.90	9.76E−04	6	6	LBY30	0.91	5.90E−04	6	20
LBY30	0.80	3.14E−02	2	16	LBY30	0.81	2.64E−02	2	1
LBY31	0.85	7.08E−03	3	4	LBY31	0.75	2.03E−02	6	7
LBY31	0.88	1.74E−03	6	5	LBY31	0.89	1.41E−03	6	6
LBY31	0.84	1.87E−02	6	8	LBY31	0.74	2.29E−02	6	20
LBY31	0.75	5.39E−02	2	5	LBY31	0.95	1.31E−03	2	12
LBY31	0.80	1.63E−02	5	17	LBY31	0.77	1.62E−02	4	19
LBY32	0.71	4.86E−02	3	20	LBY32	0.85	1.61E−02	2	21
LBY32	0.85	1.58E−02	4	8	LGN42	0.80	5.78E−02	1	7
LGN42	0.79	6.30E−02	1	18	LGN42	0.75	8.76E−02	1	20
LGN42	0.86	6.55E−03	3	21	LGN42	0.71	3.31E−02	6	5
LGN42	0.71	3.13E−02	6	6	LGN42	0.83	1.07E−02	5	11
LGN42	0.73	3.93E−02	5	14	LGN42	0.77	4.47E−02	4	13
LGN43	0.74	9.43E−02	1	21	LGN43	0.86	2.70E−02	1	23
LGN43	0.81	4.93E−02	1	17	LGN43	0.82	1.34E−02	3	21
LGN43	0.74	2.25E−02	6	19	LGN43	0.76	4.63E−02	2	16
LGN44	0.92	1.02E−02	1	12	LGN44	0.87	2.37E−02	1	2
LGN44	0.92	8.31E−03	1	14	LGN44	0.77	2.62E−02	3	12
LGN44	0.71	3.34E−02	4	21	LGN45	0.79	1.19E−02	6	15
LGN45	0.95	8.48E−04	2	16	LGN45	0.71	7.10E−02	2	1
LGN46	0.90	1.32E−02	1	12	LGN46	0.88	2.20E−02	1	2
LGN46	0.92	8.53E−03	1	14	LGN46	0.72	4.39E−02	3	19
LGN46	0.79	1.98E−02	3	5	LGN46	0.86	1.24E−02	3	8
LGN46	0.73	3.86E−02	3	20	LGN46	0.81	2.88E−02	2	2
LGN46	0.89	6.58E−03	2	14	LGN46	0.73	2.43E−02	4	19
LGN47	0.83	4.18E−02	1	16	LGN47	0.82	1.20E−02	3	20
LGN47	0.75	2.07E−02	6	14	LGN47	0.73	2.66E−02	6	1
LGN47	0.71	7.40E−02	2	7	LGN47	0.87	1.16E−02	2	21
LGN47	0.74	5.78E−02	2	5	LGN47	0.77	4.14E−02	2	6
LGN47	0.71	7.14E−02	2	17	LGN47	0.85	1.45E−02	2	12
LGN47	0.83	1.97E−02	2	20	LGN47	0.73	4.03E−02	5	10
LGN47	0.77	7.12E−02	5	13	LGN47	0.76	2.91E−02	5	2
LGN47	0.97	4.74E−05	5	14	LGN47	0.73	3.92E−02	5	1
LGN47	0.85	1.64E−02	4	13	LGN47	0.80	1.00E−02	4	14
LGN47	0.93	3.28E−04	4	1	LGN48	0.72	4.35E−02	3	18
LGN48	0.72	4.29E−02	3	6	LGN48	0.87	5.41E−03	3	20
LGN48	0.74	5.87E−02	2	21	LGN48	0.83	4.06E−02	5	13

Table 26. Provided are the correlations (between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 12. “Exp. Set”—Expression set specified in Table 9. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 27
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance of maintenance of
performance under drought conditions across Barley accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY1	0.78	6.96E−02	1	15	LBY1	0.92	1.31E−03	3	15
LBY1	0.89	7.36E−03	2	16	LBY18	0.85	3.23E−02	1	1
LBY18	0.95	3.79E−03	1	14	LBY18	0.77	2.63E−02	3	10
LBY19	0.77	2.60E−02	3	16	LBY19	0.74	5.55E−02	2	9
LBY19	0.70	7.88E−02	2	18	LBY19	0.78	2.17E−02	5	1
LBY20	0.79	5.90E−02	1	6	LBY20	0.79	6.23E−02	1	17
LBY20	0.78	6.89E−02	1	5	LBY20	0.73	9.86E−02	1	18
LBY20	0.79	5.92E−02	1	7	LBY20	0.73	6.22E−02	2	6
LBY20	0.73	6.40E−02	2	17	LBY20	0.73	6.33E−02	2	15
LBY20	0.83	1.96E−02	2	20	LBY20	0.70	7.89E−02	2	9
LBY20	0.77	2.50E−02	5	6	LBY20	0.71	4.90E−02	5	17
LBY20	0.78	2.28E−02	5	5	LBY21	0.83	4.21E−02	1	6
LBY21	0.90	1.51E−02	1	17	LBY21	0.94	5.11E−03	1	15
LBY21	0.79	6.41E−02	1	5	LBY21	0.74	9.34E−02	1	9
LBY21	0.78	6.99E−02	1	18	LBY21	0.93	6.84E−04	3	15
LBY21	0.90	6.41E−03	2	16	LBY21	0.74	3.64E−02	5	5
LBY21	0.77	2.48E−02	5	12	LBY22	0.79	1.95E−02	3	2
LBY22	0.90	5.10E−03	2	6	LBY22	0.89	8.08E−03	2	17
LBY22	0.92	3.00E−03	2	5	LBY22	0.87	9.93E−03	2	9
LBY22	0.88	9.01E−03	2	18	LBY22	0.81	1.48E−02	5	15
LBY22	0.77	1.49E−02	4	6	LBY22	0.73	2.43E−02	4	17
LBY22	0.76	1.78E−02	4	5	LBY23	0.80	5.42E−02	1	6
LBY23	0.74	9.18E−02	1	17	LBY23	0.88	2.12E−02	1	5
LBY23	0.88	2.11E−02	1	18	LBY23	0.89	1.70E−02	1	2
LBY23	0.75	8.32E−02	1	12	LBY23	0.83	2.22E−02	3	4
LBY23	0.72	1.04E−01	2	4	LBY23	0.85	7.72E−03	5	1
LBY24	0.72	1.07E−01	1	17	LBY24	0.80	5.62E−02	1	19
LBY24	0.83	3.95E−02	1	13	LBY24	0.74	3.62E−02	3	14
LBY24	0.73	4.01E−02	3	13	LBY24	0.77	4.45E−02	6	8
LBY24	0.75	2.09E−02	6	7	LBY24	0.88	2.23E−02	2	11
LBY24	0.79	1.89E−02	5	19	LBY24	0.74	2.36E−02	4	2
LBY25	0.73	4.10E−02	5	12	LBY26	0.70	1.21E−01	1	6
LBY26	0.72	1.06E−01	1	7	LBY26	0.80	1.61E−02	3	15
LBY26	0.74	3.77E−02	3	14	LBY26	0.71	3.31E−02	6	13
LBY26	0.84	1.83E−02	2	16	LBY26	0.86	1.25E−02	2	12
LBY26	0.80	1.81E−02	5	6	LBY26	0.80	1.83E−02	5	5
LBY26	0.82	2.37E−02	5	4	LBY26	0.71	5.07E−02	5	2
LBY26	0.85	3.87E−03	4	19	LBY26	0.70	5.13E−02	4	4
LBY26	0.71	3.11E−02	4	3	LBY27	0.85	7.44E−03	5	1
LBY28	0.89	1.78E−02	1	6	LBY28	0.87	2.53E−02	1	17
LBY28	0.90	1.57E−02	1	5	LBY28	0.93	7.37E−03	1	9
LBY28	0.88	2.10E−02	1	18	LBY28	0.70	1.19E−01	1	7
LBY28	0.79	2.04E−02	3	6	LBY28	0.81	1.55E−02	3	17
LBY28	0.83	1.05E−02	3	5	LBY28	0.71	4.70E−02	3	2
LBY28	0.82	2.47E−02	2	6	LBY28	0.75	5.02E−02	2	17
LBY28	0.80	3.20E−02	2	5	LBY28	0.77	1.58E−02	4	2
LBY29	0.71	1.14E−01	1	15	LBY29	0.76	2.94E−02	3	17
LBY29	0.88	9.55E−03	2	6	LBY29	0.83	1.97E−02	2	17
LBY29	0.73	6.16E−02	2	15	LBY29	0.86	1.37E−02	2	5
LBY29	0.77	4.23E−02	2	9	LBY29	0.79	3.55E−02	2	18
LBY29	0.78	2.36E−02	5	15	LBY29	0.76	1.65E−02	4	10
LBY29	0.74	2.20E−02	4	1	LBY30	0.81	5.04E−02	1	16
LBY30	0.73	9.66E−02	1	19	LBY30	0.76	2.91E−02	3	3
LBY30	0.74	2.20E−02	6	6	LBY30	0.82	6.23E−03	6	17
LBY30	0.77	1.52E−02	6	5	LBY30	0.71	4.75E−02	6	4
LBY30	0.82	6.84E−03	6	9	LBY30	0.80	8.90E−03	6	18
LBY30	0.71	3.11E−02	6	7	LBY30	0.76	4.88E−02	2	19
LBY30	0.86	1.26E−02	2	14	LBY30	0.90	2.17E−03	5	1
LBY30	0.86	6.48E−03	5	3	LBY31	0.72	1.06E−01	1	9
LBY31	0.81	2.73E−02	3	4	LBY31	0.74	5.67E−02	2	10
LBY31	0.73	4.10E−02	5	6	LBY31	0.81	1.46E−02	5	17
LBY31	0.76	2.74E−02	5	5	LBY32	0.83	4.19E−02	1	16
LBY32	0.86	2.84E−02	1	1	LBY32	0.81	1.56E−02	3	6
LBY32	0.87	4.91E−03	3	17	LBY32	0.75	3.23E−02	3	5
LBY32	0.75	3.23E−02	3	18	LBY32	0.71	5.01E−02	5	6
LBY32	0.77	2.46E−02	5	10	LBY32	0.72	4.51E−02	5	17
LBY32	0.72	4.19E−02	5	15	LBY32	0.75	3.06E−02	5	5
LBY32	0.89	3.29E−03	5	12	LGN42	0.80	5.73E−02	1	7
LGN43	0.81	4.85E−02	1	16	LGN43	0.88	1.93E−02	1	20
LGN43	0.74	2.29E−02	6	16	LGN43	0.89	6.74E−03	2	1
LGN43	0.73	2.67E−02	4	15	LGN44	0.73	9.79E−02	1	3
LGN44	0.86	5.94E−03	3	10	LGN44	0.82	1.20E−02	3	12
LGN44	0.75	2.04E−02	6	9	LGN44	0.82	2.34E−02	2	19
LGN44	0.81	1.42E−02	5	1	LGN45	0.75	5.31E−02	2	16
LGN45	0.72	6.72E−02	2	14	LGN45	0.76	4.90E−02	2	13
LGN46	0.77	7.35E−02	1	12	LGN46	0.85	6.91E−03	3	6
LGN46	0.91	1.91E−03	3	17	LGN46	0.86	6.03E−03	3	5
LGN46	0.74	5.74E−02	3	4	LGN46	0.76	2.73E−02	3	2
LGN46	0.74	2.35E−02	6	10	LGN46	0.82	6.62E−03	6	15
LGN46	0.75	5.38E−02	6	8	LGN46	0.85	8.19E−03	5	1
LGN46	0.78	1.35E−02	4	2	LGN47	0.74	9.16E−02	1	19
LGN47	0.77	7.20E−02	1	13	LGN47	0.92	1.16E−03	3	6
LGN47	0.97	9.54E−05	3	17	LGN47	0.89	2.94E−03	3	5
LGN47	0.83	9.98E−03	3	18	LGN47	0.76	4.68E−02	2	6
LGN47	0.86	1.20E−02	2	10	LGN47	0.87	1.16E−02	2	17
LGN47	0.72	6.78E−02	2	15	LGN47	0.77	4.37E−02	2	5
LGN47	0.85	1.48E−02	2	9	LGN47	0.82	2.37E−02	2	18
LGN47	0.70	7.79E−02	2	7	LGN47	0.75	5.21E−02	2	12
LGN48	0.92	1.30E−03	3	6	LGN48	0.96	1.83E−04	3	17
LGN48	0.89	2.83E−03	3	5	LGN48	0.88	3.88E−03	3	18

Table 27. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 13. “Exp. Set”—Expression set specified in Table 9. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 28
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal and low
nitrogen growth conditions across Barley accessions (set 1)
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY1	0.71	3.15E−02	2	34	LBY1	0.70	3.44E−02	2	11
LBY18	0.77	2.51E−02	4	28	LBY18	0.71	3.32E−02	2	18
LBY18	0.90	1.05E−03	9	27	LBY18	0.86	3.24E−03	2	17
LBY19	0.70	2.36E−02	5	19	LBY19	0.83	3.14E−03	5	38
LBY19	0.72	2.90E−02	2	27	LBY19	0.78	1.30E−02	3	31
LBY19	0.80	9.83E−03	3	19	LBY19	0.89	1.28E−03	3	38
LBY19	0.85	4.12E−03	3	6	LBY19	0.71	3.25E−02	3	16
LBY20	0.71	3.15E−02	1	32	LBY21	0.83	5.99E−03	3	24
LBY21	0.73	2.69E−02	3	25	LBY21	0.82	6.55E−03	3	33
LBY22	0.74	3.63E−02	4	10	LBY22	0.85	3.54E−03	2	27
LBY22	0.87	2.26E−03	2	17	LBY23	0.79	1.20E−02	1	31
LBY23	0.81	8.03E−03	1	19	LBY23	0.80	9.98E−03	1	35
LBY23	0.87	2.05E−03	1	38	LBY23	0.78	1.26E−02	1	6
LBY23	0.92	4.36E−04	2	27	LBY23	0.84	4.29E−03	2	17
LBY24	0.77	2.63E−02	6	28	LBY24	0.73	4.06E−02	6	27
LBY24	0.77	2.56E−02	6	17	LBY24	0.73	2.67E−02	1	7
LBY24	0.71	5.06E−02	4	12	LBY24	0.74	1.42E−02	5	8
LBY24	0.80	5.91E−03	5	20	LBY25	0.88	1.81E−03	2	21
LBY26	0.71	3.17E−02	1	20	LBY26	0.82	7.15E−03	2	28
LBY26	0.80	9.94E−03	3	16	LBY27	0.73	4.17E−02	6	21
LBY27	0.81	1.59E−02	6	27	LBY27	0.97	6.16E−05	6	13
LBY27	0.70	2.40E−02	5	8	LBY27	0.74	1.38E−02	5	20
LBY27	0.90	8.31E−04	2	21	LBY27	0.82	6.71E−03	3	3
LBY27	0.78	1.26E−02	3	8	LBY28	0.76	2.89E−02	6	18
LBY28	0.86	1.35E−03	5	7	LBY28	0.75	1.31E−02	5	24
LBY28	0.70	2.36E−02	5	33	LBY28	0.99	1.21E−06	2	27
LBY28	0.93	3.28E−04	2	17	LBY28	0.85	3.52E−03	3	7
LBY28	0.78	1.38E−02	3	20	LBY29	0.70	2.31E−02	5	19
LBY29	0.93	2.63E−04	3	31	LBY29	0.86	3.19E−03	3	19
LBY29	0.72	2.74E−02	3	3	LBY29	0.82	7.14E−03	3	38
LBY30	0.80	1.81E−02	4	12	LBY30	0.71	2.12E−02	5	7
LBY30	0.77	1.60E−02	3	32	LBY31	0.81	1.44E−02	6	17
LBY31	0.79	7.10E−03	5	36	LBY32	0.72	4.35E−02	6	34
LBY32	0.74	3.75E−02	6	10	LBY32	0.70	5.14E−02	6	27
LBY32	0.85	8.13E−03	6	13	LBY32	0.83	5.58E−03	2	21
LGN42	0.75	1.32E−02	5	24	LGN42	0.73	1.67E−02	5	25
LGN43	0.79	1.93E−02	6	21	LGN43	0.81	1.50E−02	6	13
LGN43	0.88	1.66E−03	1	32	LGN43	0.70	3.41E−02	2	29
LGN43	0.86	3.26E−03	2	27	LGN43	0.81	8.55E−03	2	17
LGN43	0.87	2.05E−03	3	31	LGN43	0.78	1.37E−02	3	38
LGN44	0.76	1.14E−02	5	8	LGN44	0.72	2.92E−02	2	18
LGN44	0.97	1.76E−05	2	27	LGN44	0.94	1.29E−04	2	17
LGN45	0.71	4.90E−02	4	21	LGN46	0.79	2.04E−02	6	17
LGN46	0.88	1.77E−03	1	31	LGN46	0.84	4.20E−03	1	19
LGN46	0.86	3.14E−03	1	38	LGN46	0.80	1.67E−02	4	18
LGN46	0.84	2.44E−03	5	3	LGN46	0.74	2.24E−02	2	14
LGN46	0.75	2.09E−02	3	35	LGN46	0.79	1.17E−02	3	38
LGN47	0.94	4.33E−04	6	12	LGN47	0.72	4.30E−02	6	18
LGN47	0.77	2.68E−02	6	4	LGN47	0.78	2.28E−02	6	17
LGN47	1.00	3.30E−09	1	31	LGN47	0.79	1.08E−02	1	19
LGN47	0.76	1.78E−02	1	38	LGN47	0.72	2.86E−02	1	36
LGN47	0.84	4.27E−03	1	16	LGN47	0.73	4.11E−02	4	10
LGN47	0.83	1.15E−02	4	30	LGN47	0.91	1.52E−03	4	13
LGN47	0.74	3.45E−02	4	23	LGN47	0.82	3.71E−03	5	36
LGN47	0.80	9.17E−03	2	34	LGN47	0.90	9.98E−04	2	12
LGN47	0.70	3.45E−02	2	10	LGN47	0.71	3.16E−02	2	14
LGN47	0.73	2.51E−02	2	13	LGN47	0.83	5.37E−03	3	36
LGN47	0.75	1.97E−02	3	16	LGN48	0.80	5.58E−03	5	7
LGN48	0.72	1.84E−02	5	37	LGN48	0.81	8.00E−03	3	19
LGN48	0.72	2.86E−02	3	3	LGN48	0.75	2.08E−02	3	38

Table 28. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 14. “Exp. Set”—Expression set specified in Table 10. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 29
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under low nitrogen and
normal growth conditions across Barley accessions (set 2)
				Corr.
Gene			Exp.	Set	Gene			Exp.	Corr.
Name	R	P value	set	ID	Name	R	P value	set	Set ID
LBY1	0.77	9.07E−03	5	14	LBY1	0.73	1.68E−02	5	13
LBY18	0.81	4.82E−03	1	13	LBY18	0.76	1.10E−02	1	16
LBY19	0.71	2.06E−02	5	17	LBY19	0.77	9.36E−03	4	17
LBY20	0.80	5.61E−03	6	13	LBY21	0.70	2.35E−02	5	14
LBY21	0.74	1.46E−02	5	13	LBY21	0.74	1.53E−02	1	17
LBY22	0.81	4.84E−03	5	17	LBY23	0.74	1.51E−02	2	4
LBY24	0.71	2.12E−02	2	9	LBY25	0.71	2.26E−02	2	6
LBY26	0.74	1.52E−02	3	1	LBY26	0.80	5.88E−03	4	1
LBY26	0.78	7.38E−03	4	3	LBY27	0.81	4.78E−03	5	17
LBY32	0.81	4.28E−03	5	17	LGN42	0.76	1.07E−02	5	9
LGN42	0.73	1.58E−02	1	11	LGN43	0.75	1.24E−02	2	9
LGN43	0.70	2.38E−02	3	1	LGN44	0.76	1.09E−02	3	13
LGN44	0.74	1.36E−02	4	15	LGN45	0.72	1.96E−02	2	5
LGN45	0.74	1.35E−02	3	2	LGN45	0.72	1.82E−02	3	3
LGN46	0.83	3.08E−03	3	5	LGN47	0.74	1.38E−02	3	14
LGN47	0.81	4.94E−03	5	17	LGN48	0.93	1.22E−04	2	6
LGN48	0.72	2.00E−02	2	5	LGN48	0.74	1.51E−02	2	7
LGN48	0.73	1.72E−02	2	8	LGN48	0.80	5.51E−03	3	13
LGN48	0.78	8.39E−03	3	16	LGN48	0.79	6.04E−03	5	17

Table 29. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 15. “Exp. Set”—Expression set specified in Table 11 (Exp. Set 1, 3, 5 under low N growth conditions. Exp. Set 2, 4, 6 under normal growth conditions). “R”=Pearson correlation coefficient; “P”=p value.

Example 5

Production of Arabidopsis Transcriptome and High Throughput Correlation Analysis of Yield, Biomass and/or Vigor Related Parameters Using 44K Arabidopsis Full Genome Oligonucleotide Micro-Array

To produce a high throughput correlation analysis, the present inventors utilized an Arabidopsis thaliana oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 40,000 A. thaliana genes and transcripts designed based on data from the TIGR ATHI v.5 database and Arabidopsis MPSS (University of Delaware) databases. To define correlations between the levels of RNA expression and yield, biomass components or vigor related parameters, various plant characteristics of different Arabidopsis ecotypes were analyzed. Among them, nine ecotypes encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Analyzed Arabidopsis tissues—Five tissues at different developmental stages including root, leaf, flower at anthesis, seed at 5 days after flowering (DAF) and seed at 12 DAF, representing different plant characteristics, were sampled and RNA was extracted as described as described hereinabove under “GENERAL EXPERIMENTAL AND BIOINFORMATICS METHODS”. For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 30 below.

TABLE 30
Tissues used for Arabidopsis transcriptome expression sets
               Set
Expression Set ID
Leaf           1
Root           2
Seed 5 DAF     3
Flower         4
Seed 12 DAF    5

Table 30: Provided are the identification (ID) digits of each of the Arabidopsis expression sets (1-5). DAF=days after flowering.

Yield components and vigor related parameters assessment—Eight out of the nine Arabidopsis ecotypes were used in each of 5 repetitive blocks (named A, B, C, D and E), each containing 20 plants per plot. The plants were grown in a greenhouse at controlled conditions in 22° C., and the N:P:K [nitrogen (N), phosphorus (P) and potassium (K)] fertilizer (20:20:20; weight ratios) was added. During this time data was collected, documented and analyzed. Additional data was collected through the seedling stage of plants grown in a tissue culture in vertical grown transparent agar plates. Most of chosen parameters were analyzed by digital imaging.

Digital imaging in Tissue culture (seedling assay)—A laboratory image acquisition system was used for capturing images of plantlets sawn in square agar plates. The image acquisition system consists of a digital reflex camera (Canon EOS 300D) attached to a 55 mm focal length lens (Canon EF-S series), mounted on a reproduction device (Kaiser RS), which included 4 light units (4×150 Watts light bulb) and located in a darkroom.

Digital imaging in Greenhouse—The image capturing process was repeated every 3-4 days starting at day 7 till day 30. The same camera attached to a 24 mm focal length lens (Canon EF series), placed in a custom made iron mount, was used for capturing images of larger plants sawn in white tubs in an environmental controlled greenhouse. The white tubs were square shape with measurements of 36×26.2 cm and 7.5 cm deep. During the capture process, the tubs were placed beneath the iron mount, while avoiding direct sun light and casting of shadows. This process was repeated every 3-4 days for up to 30 days.

An image analysis system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing program, which was developed at the U.S National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 6 Mega Pixels (3072×2048 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Leaf analysis—Using the digital analysis leaves data was calculated, including leaf number, area, perimeter, length and width. On day 30, 3-4 representative plants were chosen from each plot of blocks A, B and C. The plants were dissected, each leaf was separated and was introduced between two glass trays, a photo of each plant was taken and the various parameters (such as leaf total area, laminar length etc.) were calculated from the images. The blade circularity was calculated as laminar width divided by laminar length.

Root analysis—During 17 days, the different ecotypes were grown in transparent agar plates. The plates were photographed every 3 days starting at day 7 in the photography room and the roots development was documented (see examples in FIGS. 3A-F). The growth rate of root coverage was calculated according to Formula XXVIII above.

Vegetative growth rate analysis—was calculated according to Formula VII above. The analysis was ended with the appearance of overlapping plants.

For comparison between ecotypes the calculated rate was normalized using plant developmental stage as represented by the number of true leaves. In cases where plants with 8 leaves had been sampled twice (for example at day 10 and day 13), only the largest sample was chosen and added to the Anova comparison.

Seeds in siliques analysis—On day 70, 15-17 siliques were collected from each plot in blocks D and E. The chosen siliques were light brown color but still intact. The siliques were opened in the photography room and the seeds were scatter on a glass tray, a high resolution digital picture was taken for each plot. Using the images the number of seeds per silique was determined.

Seeds average weight—At the end of the experiment all seeds from plots of blocks A-C were collected. An average weight of 0.02 grams was measured from each sample, the seeds were scattered on a glass tray and a picture was taken. Using the digital analysis, the number of seeds in each sample was calculated.

Oil percentage in seeds—At the end of the experiment all seeds from plots of blocks A-C were collected. Columbia seeds from 3 plots were mixed grounded and then mounted onto the extraction chamber. 210 ml of n-Hexane (Cat No. 080951 Biolab Ltd.) were used as the solvent. The extraction was performed for 30 hours at medium heat 50° C. Once the extraction has ended the n-Hexane was evaporated using the evaporator at 35° C. and vacuum conditions. The process was repeated twice. The information gained from the Soxhlet extractor (Soxhlet. F. Die gewichtsanalytische Bestimmung des Milchfettes. Polytechnisches J. (Dingler's) 1879, 232, 461) was used to create a calibration curve for the Low Resonance NMR. The content of oil of all seed samples was determined using the Low Resonance NMR (MARAN Ultra-Oxford Instrument) and its MultiQuant software package.

Silique length analysis—On day 50 from sowing, 30 siliques from different plants in each plot were sampled in block A. The chosen siliques were green-yellow in color and were collected from the bottom parts of a grown plant's stem. A digital photograph was taken to determine silique's length.

Dry weight and seed yield—On day 80 from sowing, the plants from blocks A-C were harvested and left to dry at 30° C. in a drying chamber. The vegetative portion above ground was separated from the seeds. The total weight of the vegetative portion above ground and the seed weight of each plot were measured and divided by the number of plants.

Dry weight (vegetative biomass)=total weight of the vegetative portion above ground (excluding roots) after drying at 30° C. in a drying chamber; all the above ground biomass that is not yield.

Seed yield per plant=total seed weight per plant (gr).

Oil yield—The oil yield was calculated using Formula XXIX above.

Harvest Index (seed)—The harvest index was calculated using Formula XV (described above).

Experimental Results

Nine different Arabidopsis ecotypes were grown and characterized for 18 parameters (named as vectors).

TABLE 31
Arabidopsis correlated parameters (vectors)
                                 Correlation
Correlated parameter with        ID
Blade circularity (cm)           1
Dry matter per plant (gr)        2
Harvest Index (value)            3
Lamina length (cm)               4
Lamina width (cm)                5
Leaf width/length (ratio)        6
Oil % per seed (percent)         7
Oil yield per plant (mg)         8
Seeds per silique (number)       9
Silique length (cm)              10
Total Leaf Area per plant (cm2)  11
Vegetative growth rate (cm2/day) Until 12
leaves were in overlap
Fresh weight (gr) (at bolting stage) 13
Relative root growth (cm/day) in early seedling stages 14
Root length day 13 (cm)          15
Root length day 7 (cm)           16
1000 Seed weight (gr)            17
Seed yield per plant (gr)        18

Table 31. Provided are the Arabidopsis correlated parameters (correlation ID Nos. 1-18). Abbreviations: Cm=centimeter(s); gr=gram(s); mg=milligram(s).

The characterized values are summarized in Table 32. Correlation analysis is provided in Table 52 below.

TABLE 32
Measured parameters in Arabidopsis ecotypes
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9
1	0.51	0.48	0.45	0.37	0.50	0.38	0.39	0.49	0.41
2	0.64	1.27	1.05	1.28	1.69	1.34	0.81	1.21	1.35
3	0.53	0.35	0.56	0.33	0.37	0.32	0.45	0.51	0.41
4	2.77	3.54	3.27	3.78	3.69	4.60	3.88	3.72	4.15
5	1.38	1.70	1.46	1.37	1.83	1.65	1.51	1.82	1.67
6	0.35	0.29	0.32	0.26	0.36	0.27	0.30	0.34	0.31
7	34.42	31.19	38.05	27.76	35.49	32.91	31.56	30.79	34.02
8	118.63	138.73	224.06	116.26	218.27	142.11	114.15	190.06	187.62
9	45.44	53.47	58.47	35.27	48.56	37.00	39.38	40.53	25.53
10	1.06	1.26	1.31	1.47	1.24	1.09	1.18	1.18	1.00
11	46.86	109.89	58.36	56.80	114.66	110.82	88.49	121.79	93.04
12	0.31	0.38	0.48	0.47	0.43	0.64	0.43	0.38	0.47
13	1.51	3.61	1.94	2.08	3.56	4.34	3.47	3.48	3.71
14	0.63	0.66	1.18	1.09	0.91	0.77	0.61	0.70	0.78
15	4.42	8.53	5.62	4.83	5.96	6.37	5.65	7.06	7.04
16	0.94	1.76	0.70	0.73	0.99	1.16	1.28	1.41	1.25
17	0.02	0.02	0.03	0.03	0.02	0.03	0.02	0.02	0.02
18	0.34	0.44	0.59	0.42	0.61	0.43	0.36	0.62	0.55

Table 32. Provided are the values of each of the parameters measured in Arabidopsis ecotypes.

TABLE 33
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions
across Arabidopsis accessions
				Corr.
Gene			Exp.	Set	Gene			Exp.	Corr.
Name	R	P value	set	ID	Name	R	P value	set	Set ID
LBY16	0.82	1.37E−02	5	4	LBY16	0.72	4.38E−02	5	12
LBY16	0.76	2.78E−02	1	18	LBY16	0.86	6.45E−03	1	7
LBY16	0.87	4.99E−03	1	8	LBY17	0.78	2.22E−02	2	17
LBY17	0.79	2.04E−02	2	14	LBY17	0.73	3.98E−02	1	1

Table 33. Provided are the correlations (R) between the expression levels of yield improving genes and their homologues in tissues [leaf, flower, seed and root; Expression sets (Exp)] and the phenotypic performance in various yield, biomass, growth rate and/or vigor components [Correlation vector (corr.)] under normal conditions across Arabidopsis accessions. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 31. “Exp. Set”—Expression set specified in Table 30. “R”=Pearson correlation coefficient; “P”=p value.

Example 6 Production of Sorghum Transcriptome and High Throughput Correlation Analysis with Abst Related Parameters Using 44K Sorghum Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a sorghum oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 44.000 sorghum genes and transcripts. In order to define correlations between the levels of RNA expression with ABST, yield and NUE components or vigor related parameters, various plant characteristics of 17 different sorghum hybrids were analyzed. Among them, 10 hybrids encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

I. Correlation of Sorghum Varieties Across Ecotypes Grown Under Regular Growth Conditions, Severe Drought Conditions and Low Nitrogen Conditions

Experimental Procedures

17 Sorghum varieties were grown in 3 repetitive plots, in field. Briefly, the growing protocol was as follows:

1. Regular growth conditions: Sorghum plants were grown in the field using commercial fertilization and irrigation protocols (370,000 liter per dunam (1000 square meters), fertilization of 14 units of nitrogen per dunam entire growth period).

2. Drought conditions: Sorghum seeds were sown in soil and grown under normal condition until around 35 days from sowing, around stage V8 (eight green leaves are fully expanded, booting not started yet). At this point, irrigation was stopped, and severe drought stress was developed.

3. Low Nitrogen fertilization conditions: Sorghum plants were fertilized with 50% less amount of nitrogen in the field than the amount of nitrogen applied in the regular growth treatment. All the fertilizer was applied before flowering.

Analyzed Sorghum tissues—All 10 selected Sorghum hybrids were sampled per each treatment. Tissues [Flag leaf. Flower meristem and Flower] from plants growing under normal conditions, severe drought stress and low nitrogen conditions were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 34 below.

TABLE 34
Sorghum transcriptome expression sets
                                 Set
Expression Set                   ID
Flag leaf at flowering stage under drought growth conditions 1
Flag leaf at flowering stage under low nitrogen growth 2
conditions
Flag leaf at flowering stage under normal growth conditions 3
Flower meristem at flowering stage under drought growth 4
conditions
Flower meristem at flowering stage under low nitrogen 5
growth conditions
Flower meristem at flowering stage under normal growth 6
conditions
Flower at flowering stage under drought growth conditions 7
Flower at flowering stage under low nitrogen growth 8
conditions
Flower at flowering stage under normal growth conditions 9

Table 34: Provided are the sorghum transcriptome expression sets 1-9. Flag leaf=the leaf below the flower; Flower meristem=Apical meristem following panicle initiation; Flower=the flower at the anthesis day. Expression sets 3, 6, and 9 are from plants grown under normal conditions; Expression sets 2, 5 and 8 are from plants grown under Nitrogen-limiting conditions; Expression sets 1, 4 and 7 are from plants grown under drought conditions.

The following parameters were collected using digital imaging system:

At the end of the growing period the grains were separated from the Plant ‘Head’ and the following parameters were measured and collected:

Average Grain Area (cm²)—A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Upper and Lower Ratio Average of Grain Area, width, length, diameter and perimeter—Grain projection of area, width, diameter and perimeter were extracted from the digital images using open source package imagej (nih). Seed data was analyzed in plot average levels as follows:

Average of all seeds;

Average of upper 20% fraction—contained upper 20% fraction of seeds;

Average of lower 20% fraction—contained lower 20% fraction of seeds; Further on, ratio between each fraction and the plot average was calculated for each of the data parameters.

At the end of the growing period 5 ‘Heads’ were photographed and images were processed using the below described image processing system.

(i) Head Average Area (cm²)—At the end of the growing period 5 ‘Heads’ were photographed and images were processed using the below described image processing system. The ‘Head’ area was measured from those images and was divided by the number of ‘Heads’.

(ii) Head Average Length (cm)—At the end of the growing period 5 ‘Heads’ were photographed and images were processed using the below described image processing system. The ‘Head’ length (longest axis) was measured from those images and was divided by the number of ‘Heads’.

(iii) Head Average width (cm)—At the end of the growing period 5 ‘Heads’ were photographed and images were processed using the below described image processing system. The ‘Head’ width was measured from those images and was divided by the number of ‘Heads’.

(iv) Head Average perimeter (cm)—At the end of the growing period 5 ‘Heads’ were photographed and images were processed using the below described image processing system. The ‘Head’ perimeter was measured from those images and was divided by the number of ‘Heads’.

The image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Additional parameters were collected either by sampling 5 plants per plot or by measuring the parameter across all the plants within the plot.

Total Grain Weight/Head (gr.) (grain yield)—At the end of the experiment (plant ‘Heads’) heads from plots within blocks A-C were collected. 5 heads were separately threshed and grains were weighted, all additional heads were threshed together and weighted as well. The average grain weight per head was calculated by dividing the total grain weight by number of total heads per plot (based on plot). In case of 5 heads, the total grains weight of 5 heads was divided by 5.

FW Head/Plant gram—At the end of the experiment (when heads were harvested) total and 5 selected heads per plots within blocks A-C were collected separately. The heads (total and 5) were weighted (gr.) separately and the average fresh weight per plant was calculated for total (FW Head/Plant gr. based on plot) and for 5 (FW Head/Plant gr. based on 5 plants) plants.

Plant height—Plants were characterized for height during growing period at 5 time points. In each measure, plants were measured for their height using a measuring tape. Height was measured from ground level to top of the longest leaf.

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 64 days post sowing. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Vegetative fresh weight and Heads—At the end of the experiment (when Inflorescence were dry) all Inflorescence and vegetative material from plots within blocks A-C were collected. The biomass and Heads weight of each plot was separated, measured and divided by the number of Heads.

Plant biomass (Fresh weight)—At the end of the experiment (when Inflorescence were dry) the vegetative material from plots within blocks A-C were collected. The plants biomass without the Inflorescence were measured and divided by the number of Plants.

FW Heads/(FW Heads+FW Plants)—The total fresh weight of heads and their respective plant biomass were measured at the harvest day. The heads weight was divided by the sum of weights of heads and plants.

Experimental Results

17 different sorghum varieties were grown and characterized for different parameters: The average for each of the measured parameters was calculated using the JMP software (Tables 36-37) and a subsequent correlation analysis between the various transcriptome sets (Table 34) and the average parameters, was conducted (Table 38). Results were then integrated to the database.

TABLE 35
Sorghum correlated parameters (vectors)
                                 Correlation
Correlated parameter with        ID
Average Grain Area (cm2), Drought 1
Average Grain Area (cm2), Low N  2
Average Grain Area (cm2), Normal 3
FW - Head/Plant (gr) (based on plot), Drought 4
FW - Head/Plant (gr.) (based on plot), Low N 5
FW - Head/Plant (gr.) (based on plot), Normal 6
FW - Head/Plant (gr.) (based on 5 plants), Low N 7
FW - Head/Plant (gr.) (based on 5 plants), Normal 8
FW Heads/(FW Heads + FW Plants)(all plot), Drought 9
FW Heads/(FW Heads + FW Plants)(all plot), Low N 10
FW Heads/(FW Heads + FW Plants) (all plot), Normal 11
FW/Plant (gr) (based on plot), Drought 12
FW/Plant (gr.) (based on plot), Low N 13
FW/Plant (gr.) (based on plot), Normal 14
Final Plant Height (cm), Drought 15
Final Plant Height (cm), Low N   16
Final Plant Height (cm), Normal  17
Head Average Area (cm2), Drought 18
Head Average Area (cm2), Low N   19
Head Average Area (cm2), Normal  20
Head Average Length (cm), Drought 21
Head Average Length (cm), Low N  22
Head Average Length (cm), Normal 23
Head Average Perimeter (cm), Drought 24
Head Average Perimeter (cm), Low N 25
Head Average Perimeter (cm), Normal 26
Head Average Width (cm), Drought 27
Head Average Width (cm), Low N   28
Head Average Width (cm), Normal  29
Leaf SPAD 64 DPS (Days Post Sowing), Drought 30
Leaf SPAD 64 DPS (Days Post Sowing), Low N 31
Leaf SPAD 64 DPS (Days Post Sowing), Normal 32
Lower Ratio Average Grain Area (value), Low N 33
Lower Ratio Average Grain Area (value), Normal 34
Lower Ratio Average Grain Length (value), Low N 35
Lower Ratio Average Grain Length (value), Normal 36
Lower Ratio Average Grain Perimeter (value), Low N 37
Lower Ratio Average Grain Perimeter, (value) Normal 38
Lower Ratio Average Grain Width (value), Low N 39
Lower Ratio Average Grain Width (value), Normal 40
Total grain weight/Head (based on plot) (gr.), Low N 41
Total grain weight/Head (gr.) (based on 5 heads), Low N 42
Total grain weight/Head (gr.) (based on 5 heads), Normal 43
Total grain weight/Head (gr.) (based on plot), Normal 44
Total grain weight/Head (gr.) (based on plot), Drought 45
Upper Ratio Average Grain Area, Drought (value) 46
Upper Ratio Average Grain Area (value), Low N 47
Upper Ratio Average Grain Area (value), Normal 48
[Grain Yield + plant biomass/SPAD 64 DPS] (gr.), Normal 49
[Grain Yield + plant biomass/SPAD 64 DPS] (gr.), Low N 50
[Grain yield/SPAD 64 DPS] (gr.), Low N 51
[Grain yield/SPAD 64 DPS] (gr.), Normal 52
[Plant biomass (FW)/SPAD 64 DPS] (gr) Drought 53
[Plant biomass (FW)/SPAD 64 DPS] (gr.), Low N 54
[Plant biomass (FW)/SPAD 64 DPS] (gr.), Normal 55

Table 35. Provided are the Sorghum correlated parameters (vectors). “gr.”=grams; “SPAD”=chlorophyll levels; “FW”=Plant Fresh weight; “normal”=standard growth conditions.

TABLE 36
Measured parameters in Sorghum accessions
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9
1	0.10	0.11	0.11	0.09	0.09	0.11
2	0.11	0.11	0.14	0.12	0.14	0.13	0.12	0.12	0.12
3	0.105	0.112	0.131	0.129	0.139	0.141	0.110	0.113	0.102
4	154.90	122.02	130.51	241.11	69.03	186.41	62.11	39.02	58.94
5	214.78	205.05	73.49	122.96	153.07	93.23	134.11	77.43	129.63
6	175.15	223.49	56.40	111.62	67.34	66.90	126.18	107.74	123.86
7	388.00	428.67	297.67	280.00	208.33	303.67	436.00	376.33	474.67
8	406.50	518.00	148.00	423.00	92.00	101.33	423.50	386.50	409.50
9	0.42	0.47	0.42	0.37	0.23	0.31	0.41	0.44	0.40
10	0.51	0.51	0.17	0.39	0.21	0.19	0.48	0.37	0.42
11	0.51	0.51	0.12	0.26	0.12	0.18	0.46	0.43	0.42
12	207.99	138.02	255.41	402.22	233.55	391.75	89.31	50.61	87.02
13	204.78	199.64	340.51	240.60	537.78	359.40	149.20	129.06	178.71
14	162.56	212.59	334.83	313.46	462.28	318.26	151.13	137.60	167.98
15	89.40	75.73	92.10	94.30	150.80	110.73	99.20	84.00	99.00
16	104.00	80.93	204.73	125.40	225.40	208.07	121.40	100.27	121.13
17	95.25	79.20	197.85	234.20	189.40	194.67	117.25	92.80	112.65
18	83.14	107.79	88.68	135.91	90.76	123.95	86.06	85.20	113.10
19	96.24	214.72	98.59	182.83	119.64	110.19	172.36	84.81	156.25
20	120.14	167.60	85.14	157.26	104.00	102.48	168.54	109.32	135.13
21	21.63	21.94	21.57	22.01	20.99	28.60	21.35	20.81	24.68
22	23.22	25.58	20.93	28.43	24.32	22.63	32.11	20.38	26.69
23	25.58	26.84	21.02	26.84	23.14	21.82	31.33	23.18	25.70
24	52.78	64.49	56.59	64.37	53.21	71.66	55.61	52.96	69.83
25	56.32	79.20	53.25	76.21	67.27	59.49	79.28	51.52	69.88
26	61.22	67.90	56.26	65.38	67.46	67.46	74.35	56.16	61.64
27	4.83	6.31	5.16	7.78	5.28	5.49	5.04	5.07	5.77
28	5.26	10.41	5.93	8.25	6.19	6.12	6.80	5.25	7.52
29	5.97	7.92	4.87	7.43	5.58	5.88	6.78	5.99	6.62
30	40.58	40.88	45.01	42.30	45.24	40.56	44.80	45.07	40.65
31	38.33	38.98	42.33	40.90	43.15	39.85	42.68	43.31	39.01
32	43.01	.	43.26	44.74	45.76	41.61	45.21	45.14	43.03
33	0.82	0.77	0.81	0.79	0.78	0.80	0.83	0.79	0.81
34	0.825	0.740	0.778	0.802	0.697	0.699	0.827	0.805	0.841
35	0.91	0.90	0.92	0.90	0.91	0.93	0.92	0.89	0.90
36	0.914	0.884	0.921	0.908	0.890	0.877	0.913	0.903	0.920
37	0.90	0.88	0.92	0.90	0.92	0.92	0.92	0.89	0.90
38	0.91	0.87	0.91	0.95	0.90	0.91	0.91	0.91	0.92
39	0.90	0.85	0.89	0.88	0.86	0.87	0.91	0.89	0.90
40	0.91	0.83	0.85	0.87	0.79	0.80	0.90	0.89	0.91
41	25.95	30.57	19.37	35.62	25.18	22.18	49.96	27.48	51.12
42	50.27	50.93	36.13	73.10	37.87	36.40	71.67	35.00	76.73
43	47.40	46.30	28.37	70.40	32.15	49.23	63.45	44.45	56.65
44	31.12	26.35	18.72	38.38	26.67	28.84	47.67	31.00	39.99
45	22.11	16.77	9.19	104.44	3.24	22.00	9.97	18.58	29.27
46	1.31	1.19	1.29	1.46	1.21	1.21
47	1.18	1.31	1.11	1.21	1.19	1.18	1.16	1.23	1.17
48	1.22	1.30	1.13	1.14	1.16	1.15	1.19	1.23	1.25
49	4.50	8.17	7.87	10.68	8.34	4.40	3.74	4.83	3.67
50	6.02	5.91	8.50	6.75	13.05	9.58	4.67	3.61	5.89
51	0.68	0.78	0.46	0.87	0.58	0.56	1.17	0.63	1.31
52	3.78	7.74	7.01	10.10	7.65	3.34	3.05	3.90	2.83
53	5.13	3.38	5.67	9.51	5.16	9.66	1.99	1.12	2.14
54	5.34	5.12	8.05	5.88	12.46	9.02	3.50	2.98	4.58
55	0.72	0.43	0.86	0.58	0.69	1.05	0.69	0.93	0.84

Table 36: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (ecotype) under normal, low nitrogen and drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 37
Additional measured parameters in Sorghum accessions
Ecotype/
Treatment	Line-10	Line-11	Line-12	Line-13	Line-14	Line-15	Line-16	Line-17
2	0.13	0.13	0.12	0.12	0.11	0.11	0.12	0.11
3	0.118	0.121	0.111	0.117	0.108	0.105	0.110	0.105
4	76.37	33.47	42.20	41.53	131.67	60.84	44.33	185.44
5	99.83	76.95	84.25	92.24	138.83	113.32	95.50	129.49
6	102.75	82.33	77.59	91.17	150.44	109.10	107.58	130.88
7	437.67	383.00	375.00	425.00	434.00	408.67	378.50	432.00
8	328.95	391.00	435.75	429.50	441.00	415.75	429.50	428.50
9	0.44	0.47	0.47	0.48	0.35	0.35	0.23	0.33
10	0.44	0.43	0.39	0.44	0.44	0.44	0.43	0.42
11	0.44	0.46	0.45	0.45	0.51	0.46	0.44	0.39
12	120.43	37.21	48.18	44.20	231.60	116.01	123.08	342.50
13	124.27	101.33	132.12	117.90	176.99	143.67	126.98	180.45
14	128.97	97.62	99.32	112.24	157.42	130.55	135.66	209.21
15	92.20	81.93	98.80	86.47	99.60	83.00	83.53	92.30
16	94.53	110.00	115.07	104.73	173.67	115.60	138.80	144.40
17	97.50	98.00	100.00	105.60	151.15	117.10	124.45	126.50
18	100.79	80.41	126.89	86.41	92.29	77.89	76.93
19	136.71	137.70	96.54	158.19	163.95	138.39	135.46	165.64
20	169.03	156.10	112.14	154.74	171.70	168.51	162.51	170.46
21	24.28	21.95	24.98	19.49	20.42	16.81	18.88
22	26.31	25.43	23.11	27.87	28.88	27.64	25.52	30.33
23	28.82	28.13	22.97	28.09	30.00	30.54	27.17	29.26
24	65.14	55.27	69.06	53.32	56.29	49.12	51.88
25	66.17	67.37	57.90	70.61	73.76	66.87	65.40	75.97
26	71.40	68.56	56.44	67.79	71.54	78.94	67.03	74.11
27	5.37	4.66	6.35	5.58	5.76	5.86	5.10
28	6.59	6.85	5.32	7.25	7.19	6.27	6.57	6.82
29	7.42	6.98	6.19	7.02	7.18	7.00	7.39	7.35
30	45.43	42.58	44.18	44.60	42.41	43.25	40.30	40.75
31	42.71	40.08	43.98	45.44	44.75	42.58	43.81	46.73
32	45.59	44.83	45.33	46.54	43.99	45.09	45.14	43.13
33	0.77	0.74	0.80	0.79	0.82	0.80	0.81	0.81
34	0.788	0.765	0.803	0.806	0.821	0.814	0.818	0.817
35	0.91	0.89	0.90	0.89	0.91	0.89	0.89	0.90
36	0.923	0.893	0.913	0.907	0.911	0.904	0.903	0.913
37	0.91	0.89	0.90	0.90	0.91	0.89	0.90	0.90
38	0.93	0.91	0.92	0.90	0.91	0.90	0.91	0.91
39	0.86	0.84	0.90	0.89	0.91	0.90	0.90	0.90
40	0.85	0.86	0.88	0.90	0.90	0.91	0.90	0.90
41	36.84	29.45	26.70	29.42	51.12	37.04	39.85	41.78
42	57.58	42.93	36.47	68.60	71.80	49.27	43.87	52.07
43	60.00	45.45	58.19	70.60	70.10	53.95	59.87	52.65
44	38.36	32.10	32.69	32.79	51.53	35.71	38.31	42.44
45	10.45	14.77	12.86	18.24	11.60	18.65	16.36
46
47	1.22	1.24	1.19	1.23	1.16	1.34	1.21	1.21
48	1.24	1.32	1.22	1.18	1.18	1.22	1.25	1.22
49	2.89	2.91	3.12	4.75	3.69	3.85	5.84
50	3.77	3.26	3.61	3.24	5.10	4.25	3.81	4.76
51	0.86	0.73	0.61	0.65	1.14	0.87	0.91	0.89
52	2.18	2.19	2.41	3.58	2.90	3.01	4.85
53	2.65	0.87	1.09	0.99	5.46	2.68	3.05	8.40
54	2.91	2.53	3.00	2.60	3.96	3.38	2.90	3.86
55	0.72	0.72	0.70	1.17	0.79	0.85	0.98

Table 37: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (ecotype) under normal, low nitrogen and drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 38
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under low nitrogen, normal or
drought stress conditions across Sorghum accessions
				Corr.
Gene			Exp.	Set	Gene			Exp.	Corr.
Name	R	P value	set	ID	Name	R	P value	set	Set ID
LBY14	0.72	1.91E−02	6	17	LBY14	0.80	5.97E−03	6	44
LBY14	0.74	1.41E−02	2	47	LBY14	0.83	2.89E−03	4	53
LBY14	0.73	1.74E−02	4	4	LBY14	0.83	2.86E−03	4	12
LBY14	0.79	6.98E−03	5	5	LBY14	0.83	3.07E−03	5	50
LBY14	0.79	6.21E−03	5	54	LBY14	0.89	6.00E−04	5	13
LBY148	0.71	2.02E−02	6	52	LBY148	0.70	2.30E−02	6	49
LBY148	0.73	1.58E−02	6	3	LBY148	0.77	9.54E−03	2	47
LBY148	0.73	1.70E−02	5	2	LBY149	0.72	2.82E−02	4	18
LBY149	0.72	2.83E−02	4	24	LBY149	0.73	2.69E−02	4	21
LBY149	0.78	7.48E−03	5	5	LBY149	0.71	2.10E−02	5	50
LBY149	0.77	9.23E−03	5	10	LBY149	0.70	2.35E−02	5	13
LBY150	0.80	5.82E−03	5	2	LBY150	0.71	3.06E−02	3	55
LBY150	0.75	1.32E−02	1	53	LBY150	0.74	1.40E−02	1	12
LBY151	0.73	1.61E−02	8	5	LBY151	0.84	2.25E−03	8	50
LBY151	0.77	9.57E−03	8	54	LBY151	0.73	1.60E−02	8	35
LBY151	0.81	4.63E−03	8	13	LBY151	0.95	1.08E−04	3	52
LBY151	0.82	3.54E−03	3	6	LBY151	0.92	3.92E−04	3	49
LBY151	0.84	2.50E−03	3	8	LBY152	0.81	4.52E−03	2	16
LBY152	0.78	7.77E−03	8	31	LBY152	0.81	4.63E−03	3	17
LBY152	0.78	7.80E−03	3	44	LBY153	0.84	2.15E−03	9	17
LBY153	0.71	2.03E−02	9	40	LBY153	0.74	1.48E−02	9	38
LBY153	0.84	2.36E−03	9	44	LBY153	0.74	1.34E−02	9	34
LBY153	0.83	2.75E−03	4	53	LBY153	0.72	1.83E−02	4	4
LBY153	0.83	2.73E−03	4	12	LBY153	0.74	1.45E−02	7	15
LBY154	0.79	6.58E−03	6	17	LBY154	0.71	2.11E−02	6	23
LBY154	0.79	6.33E−03	6	44	LBY154	0.80	5.44E−03	2	16
LBY154	0.74	2.28E−02	4	18	LBY154	0.75	2.10E−02	4	27
LBY154	0.73	1.59E−02	4	53	LBY154	0.72	2.84E−02	4	24
LBY154	0.74	1.39E−02	4	12	LBY154	0.72	1.86E−02	5	50
LBY154	0.72	1.92E−02	5	13	LBY155	0.75	1.31E−02	6	3
LBY156	0.89	4.92E−04	6	52	LBY156	0.70	2.33E−02	6	14
LBY156	0.90	4.08E−04	6	49	LBY156	0.80	5.60E−03	2	31
LBY156	0.88	1.63E−03	7	18	LBY156	0.72	2.77E−02	7	27
LBY156	0.80	9.08E−03	7	24	LBY156	0.77	1.61E−02	7	21
LBY157	0.72	1.81E−02	6	6	LBY157	0.76	1.13E−02	2	47
LBY158	0.87	1.09E−03	4	53	LBY158	0.87	9.17E−04	4	4
LBY158	0.87	1.01E−03	4	12	LBY159	0.74	1.53E−02	7	9
LBY159	0.76	1.65E−02	1	18	LBY159	0.74	1.53E−02	1	15
LBY160	0.79	6.72E−03	6	48	LBY160	0.85	1.70E−03	6	3
LBY160	0.72	1.78E−02	5	2	LBY161	0.92	1.65E−04	4	53
LBY161	0.84	2.25E−03	4	4	LBY161	0.92	1.73E−04	4	12
LBY161	0.91	2.66E−04	8	35	LBY161	0.70	2.31E−02	8	42
LBY161	0.71	2.22E−02	8	37	LBY161	0.86	1.51E−03	5	5
LBY161	0.89	5.33E−04	5	50	LBY161	0.88	7.10E−04	5	54
LBY161	0.91	2.41E−04	5	13	LBY161	0.76	1.03E−02	1	53
LBY161	0.81	4.72E−03	1	4	LBY161	0.77	8.76E−03	1	12
LBY162	0.71	2.06E−02	6	3	LBY162	0.73	1.73E−02	2	31
LBY162	0.77	9.20E−03	8	37	LBY162	0.91	2.88E−04	3	32
LBY162	0.72	1.85E−02	3	40	LBY162	0.77	1.52E−02	3	55
LBY162	0.80	5.47E−03	3	38	LBY162	0.73	1.69E−02	3	36
LBY163	0.76	1.79E−02	3	52	LBY163	0.74	2.41E−02	3	49
LBY163	0.78	8.21E−03	3	8	LBY164	0.89	6.23E−04	4	53
LBY164	0.83	3.15E−03	4	4	LBY164	0.90	4.03E−04	4	12
LBY164	0.76	1.11E−02	8	47	LBY164	0.73	1.76E−02	8	28
LBY165	0.81	4.65E−03	6	3	LBY165	0.76	1.08E−02	5	2
LBY165	0.88	1.74E−03	3	52	LBY165	0.88	1.57E−03	3	49
LBY166	0.75	1.31E−02	2	41	LBY166	0.78	7.83E−03	2	42
LBY166	0.72	1.96E−02	2	51	LBY166	0.74	1.40E−02	2	16
LBY166	0.71	2.16E−02	8	16	LBY166	0.80	9.36E−03	3	52
LBY166	0.85	2.03E−03	3	6	LBY166	0.73	1.67E−02	3	14
LBY166	0.78	1.37E−02	3	49	LBY166	0.78	7.40E−03	3	8
LBY167	0.77	8.71E−03	6	3	LBY167	0.72	1.89E−02	9	17
LBY167	0.70	3.53E−02	4	27	LBY167	0.78	1.24E−02	3	52
LBY167	0.72	2.86E−02	3	49	LBY167	0.87	1.21E−03	3	8
LBY168	0.84	2.56E−03	6	6	LBY168	0.81	4.40E−03	6	14
LBY168	0.76	9.94E−03	2	7	LBY168	0.84	2.16E−03	2	41
LBY168	0.84	2.20E−03	2	22	LBY168	0.83	3.03E−03	2	51
LBY168	0.77	1.50E−02	7	21	LBY170	0.77	8.79E−03	6	52
LBY170	0.73	1.58E−02	6	49	LBY170	0.74	1.47E−02	6	8
LBY171	0.70	2.39E−02	6	11	LBY171	0.77	8.75E−03	2	47
LBY171	0.90	4.10E−04	4	53	LBY171	0.84	2.20E−03	4	4
LBY171	0.89	5.28E−04	4	12	LBY171	0.84	2.61E−03	5	5
LBY171	0.82	3.36E−03	5	50	LBY171	0.82	4.06E−03	5	54
LBY171	0.84	2.13E−03	5	13	LBY173	0.77	9.12E−03	2	41
LBY173	0.72	2.01E−02	2	51	LBY173	0.78	7.72E−03	2	37
LBY173	0.76	1.05E−02	2	16	LBY174	0.74	1.46E−02	6	17
LBY174	0.74	1.36E−02	6	11	LBY174	0.75	1.22E−02	6	44
LBY174	0.87	1.06E−03	2	41	LBY174	0.70	2.40E−02	2	35
LBY174	0.71	2.12E−02	2	42	LBY174	0.86	1.36E−03	2	51
LBY174	0.80	5.02E−03	2	37	LBY174	0.75	1.30E−02	2	16
LBY174	0.87	9.84E−04	5	5	LBY174	0.87	9.19E−04	5	50
LBY174	0.81	4.20E−03	5	54	LBY174	0.82	3.95E−03	5	10
LBY174	0.80	5.46E−03	5	35	LBY174	0.84	2.36E−03	5	13
LBY174	0.90	8.09E−04	3	52	LBY174	0.72	2.00E−02	3	6
LBY174	0.88	1.78E−03	3	49	LBY174	0.80	5.36E−03	3	8
LBY175	0.73	2.44E−02	4	18	LBY175	0.72	2.74E−02	4	21
LBY176	0.70	3.46E−02	3	52	LBY176	0.89	4.94E−04	3	6
LBY177	0.87	1.07E−03	6	17	LBY177	0.73	1.59E−02	6	40
LBY177	0.86	1.39E−03	6	44	LBY177	0.71	2.07E−02	6	43
LBY177	0.71	2.16E−02	6	36	LBY177	0.78	7.48E−03	6	34
LBY177	0.70	2.39E−02	8	2	LBY177	0.79	6.60E−03	5	33
LBY177	0.74	1.49E−02	5	39	LBY178	0.76	1.09E−02	6	40
LBY178	0.75	1.22E−02	6	55	LBY178	0.72	1.98E−02	6	43
LBY178	0.81	4.70E−03	9	14	LBY178	0.77	9.03E−03	2	33
LBY178	0.91	2.45E−04	2	41	LBY178	0.73	1.68E−02	2	39
LBY178	0.70	2.28E−02	2	35	LBY178	0.87	9.72E−04	9	51
LBY178	0.79	7.09E−03	2	37	LBY178	0.91	2.35E−04	2	16
LBY178	0.83	2.91E−03	4	53	LBY178	0.73	1.72E−02	4	4
LBY178	0.83	2.88E−03	4	12	LBY178	0.72	1.87E−02	5	31
LBY178	0.76	9.95E−03	5	16	LBY178	0.86	3.24E−03	3	52
LBY178	0.81	4.72E−03	3	6	LBY178	0.84	4.57E−03	3	49
LBY178	0.73	1.71E−02	3	8	LBY179	0.76	1.08E−02	6	17
LBY179	0.70	2.34E−02	6	44	LBY179	0.92	1.95E−04	4	53
LBY179	0.83	2.91E−03	4	4	LBY179	0.91	2.08E−04	4	12
LBY179	0.70	2.32E−02	5	13	LBY180	0.73	1.68E−02	6	48
LBY180	0.75	1.17E−02	8	16	LBY181	0.77	8.50E−03	6	40
LBY181	0.73	1.60E−02	6	34	LBY181	0.76	1.78E−02	9	55
LBY181	0.74	2.38E−02	7	45	LBY182	0.72	1.97E−02	2	33
LBY182	0.72	1.92E−02	2	50	LBY182	0.90	4.10E−04	2	35
LBY182	0.77	9.14E−03	5	5	LBY182	0.80	5.92E−03	5	50
LBY182	0.79	6.98E−03	5	54	LBY182	0.74	1.41E−02	5	13
LBY182	0.79	6.72E−03	3	11	LBY182	0.94	5.85E−05	3	6
LBY183	0.71	2.12E−02	6	11	LBY183	0.74	1.51E−02	9	11
LBY183	0.76	1.13E−02	8	10	LBY183	0.73	1.62E−02	5	50
LBY183	0.73	1.74E−02	5	10	LBY183	0.72	1.90E−02	3	11
LBY186	0.80	5.01E−03	9	17	LBY186	0.84	2.54E−03	9	44
LBY186	0.77	9.83E−03	3	44	LBY188	0.81	4.23E−03	5	2
LBY189	0.75	1.28E−02	9	16	LBY189	0.74	1.45E−02	3	6
LBY191	0.74	1.39E−02	1	30	LBY192	0.74	1.35E−02	8	2
LBY192	0.78	7.83E−03	5	5	LBY192	0.71	2.20E−02	5	50
LBY192	0.74	1.42E−02	5	54	LBY192	0.71	2.06E−02	5	13
LGN3	0.82	3.99E−03	6	17	LGN3	0.78	7.76E−03	6	44
LGN3	0.84	4.41E−03	9	52	LGN3	0.83	5.83E−03	9	49
LGN3	0.79	7.06E−03	9	8	LGN3	0.91	2.59E−04	4	53
LGN3	0.84	2.38E−03	4	4	LGN3	0.92	1.64E−04	4	12
LGN3	0.74	1.35E−02	8	47	LGN4	0.81	4.25E−03	6	17
LGN4	0.77	9.90E−03	6	44	LGN4	0.70	3.52E−02	9	52
LGN4	0.71	3.11E−02	9	49	LGN4	0.80	5.52E−03	4	53
LGN4	0.74	1.35E−02	4	4	LGN4	0.82	3.99E−03	4	12
LGN5	0.70	2.37E−02	6	55	LGN5	0.86	1.27E−03	2	41
LGN5	0.76	1.05E−02	2	35	LGN5	0.87	9.62E−04	2	51
LGN5	0.85	1.75E−03	2	37	LGN5	0.72	1.78E−02	2	16
LGN5	0.79	6.72E−03	5	2	LGN5	0.73	1.56E−02	3	17
LGN5	0.73	1.58E−02	7	4	LGN5	0.78	1.26E−02	1	45
LGN54	0.70	2.31E−02	9	14	LGN54	0.81	4.13E−03	9	8
LGN57	0.85	1.73E−03	9	17	LGN57	0.79	6.65E−03	9	44
LGN57	0.75	1.23E−02	9	41	LGN57	0.80	5.40E−03	2	16
LGN57	0.83	3.06E−03	8	33	LGN57	0.86	1.38E−03	8	41
LGN57	0.71	2.15E−02	8	39	LGN57	0.82	3.75E−03	8	35
LGN57	0.84	2.09E−03	8	51	LGN57	0.86	1.42E−03	8	37
LGN57	0.78	8.45E−03	8	16	LGN57	0.74	2.26E−02	3	55
LGN57	0.81	4.59E−03	3	43	LGN6	0.78	7.30E−03	6	17
LGN6	0.84	2.54E−03	6	44	LGN6	0.70	2.40E−02	5	50
LGN6	0.70	2.38E−02	5	13	LGN6	0.85	3.72E−03	3	52
LGN6	0.88	1.83E−03	3	49	LGN6	0.71	2.08E−02	7	30
LGN7	0.75	1.33E−02	6	17	LGN7	0.70	2.40E−02	6	44
LGN7	0.70	2.40E−02	6	36	LGN7	0.76	1.07E−02	4	53
LGN7	0.76	1.04E−02	4	12	LGN7	0.71	2.23E−02	8	47
LGN7	0.76	1.14E−02	5	41	LGN7	0.75	1.25E−02	5	22
LGN7	0.71	2.15E−02	5	51	LGN7	0.70	3.57E−02	3	52
LGN7	0.88	7.09E−04	1	53	LGN7	0.85	1.97E−03	1	4
LGN7	0.89	5.78E−04	1	12

Table 38. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 35. “Exp. Set”—Expression set specified in Table 34. “R”=Pearson correlation coefficient; “P”=p value.

II. Correlation of Sorghum Varieties Across Ecotype Grown Under Salinity Stress, Cold Stress, Low Nitrogen and Normal Conditions

Sorghum vigor related parameters under 100 mM NaCl and low temperature (10±2° C.)—Ten Sorghum varieties were grown in 3 repetitive plots, each containing 17 plants, at a net house under semi-hydroponics conditions. Briefly, the growing protocol was as follows: Sorghum seeds were sown in trays filled with a mix of vermiculite and peat in a 1:1 ratio. Following germination, the trays were transferred to the high salinity solution (100 mM NaCl in addition to the Full Hogland solution at 28±2° C.), low temperature (10±2° C. in the presence of Full Hogland solution), low nitrogen (1.2 mM Nitrogen at 28±2° C.) or at Normal growth solution [Full Hogland solution at 28±2° C.].

Full Hogland solution consists of: KNO₃—0.808 grams/liter, MgSO₄—0.12 grams/liter, KH₂PO₄—0.172 grams/liter and 0.01% (volume/volume) of ‘Super coratin’ micro elements (Iron-EDDHA [ethylenediamine-N,N′-bis(2-hydroxyphenylacetic acid)]—40.5 grams/liter; Mn—20.2 grams/liter: Zn 10.1 grams/liter; Co 1.5 grams/liter; and Mo 1.1 grams/liter), solution's pH should be 6.5-6.8].

All 10 selected varieties were sampled per each treatment. Two tissues [meristems and roots] growing at 100 mM NaCl, low temperature (10±2° C.), low nitrogen (1.2 mM Nitrogen) or under Normal conditions (full Hogland at a temperature between 28±2° C.) were sampled and RNA was extracted as described hereinabove under “GENERAL EXPERIMENTAL AND BIOINFORMATICS METHODS”.

TABLE 39
Sorghum transcriptome expression sets
                                 Set
Expression Set                   ID
root at vegetative stage (V4-V5) under cold conditions 1
root vegetative stage (V4-V5) under normal conditions 2
root vegetative stage (V4-V5) under low nitrogen conditions 3
root vegetative stage (V4-V5) under salinity conditions 4
vegetative meristem at vegetative stage (V4-V5) under 5
cold conditions
vegetative meristem at vegetative stage (V4-V5) under 6
low nitrogen conditions
vegetative meristem at vegetative stage (V4-V5) under 7
salinity conditions
vegetative meristem at vegetative stage (V4-V5) under 8
normal conditions

Table 39: Provided are the Sorghum transcriptome expression sets. Cold conditions=10±2° C.; NaCl=100 mM NaCl; low nitrogen=1.2 mM Nitrogen; Normal conditions=16 mM Nitrogen.

Sorghum Biomass, Vigor, Nitrogen Use Efficiency and Growth-Related Components

Root DW (dry weight)—At the end of the experiment, the root material was collected, measured and divided by the number of plants.

Shoot DW—At the end of the experiment, the shoot material (without roots) was collected, measured and divided by the number of plants.

Total biomass—total biomass including roots and shoots.

Plant leaf number—Plants were characterized for leaf number at 3 time points during the growing period. In each measure, plants were measured for their leaf number by counting all the leaves of 3 selected plants per plot.

Shoot/root Ratio—The shoot/root Ratio was calculated using Formula XXX above.

Percent of reduction of root biomass compared to normal—the difference (reduction in percent) between root biomass under normal and under low nitrogen conditions.

Percent of reduction of shoot biomass compared to normal—the difference (reduction in percent) between shoot biomass under normal and under low nitrogen conditions.

Percent of reduction of total biomass compared to normal—the difference (reduction in percent) between total biomass (shoot and root) under normal and under low nitrogen conditions

Plant height—Plants were characterized for height at 3 time points during the growing period. In each measure, plants were measured for their height using a measuring tape. Height was measured from ground level to top of the longest leaf

Relative Growth Rate of leaf number was calculated using Formula VIII above.

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 64 days post sowing. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Root Biomass [DW-gr.]/SPAD—root biomass divided by SPAD results.

Shoot Biomass [DW-gr.]/SPAD—shoot biomass divided by SPAD results.

Total Biomass-Root+Shoot [DW-gr.]/SPAD—total biomass divided by SPAD results.

Plant nitrogen level (calculated as SPAD/leaf biomass)—The chlorophyll content of leaves is a good indicator of the nitrogen plant status since the degree of leaf greenness is highly correlated to this parameter.

Experimental Results

10 different Sorghum varieties were grown and characterized for the following parameters: “Leaf number Normal”=leaf number per plant under normal conditions (average of five plants); “Plant Height Normal”=plant height under normal conditions (average of five plants); “Root DW 100 mM NaCl”—root dry weight per plant under salinity conditions (average of five plants): The average for each of the measured parameters was calculated using the JMP software and values are summarized in Table 41 below. Subsequent correlation analysis between the various transcriptome sets and the average parameters were conducted (Table 42). Results were then integrated to the database.

TABLE 40
Sorghum correlated parameters (vectors)
                                 Correlation
Correlated parameter with        ID
DW Root/Plant (gr./number) at 100 mM NaCl conditions 1
DW Root/Plant (gr./number) at Cold conditions 2
DW Root/Plant (gr./number) at Low Nitrogen conditions 3
DW Root/Plant (gr./number) at Normal conditions 4
DW Shoot/Plant (gr./number) at Low Nitrogen conditions 5
DW Shoot/Plant (gr./number) at 100 mM NaCl conditions 6
DW Shoot/Plant (gr./number) at Cold conditions 7
DW Shoot/Plant (gr./number) at Normal conditions 8
Leaf number (at time point 1) at 100 mM NaCl conditions 9
Leaf number (at time point 1) at Cold conditions 10
Leaf number (at time point 1) at Low Nitrogen conditions 11
Leaf number (at time point 1) at Normal conditions 12
Leaf number (at time point 2) at 100 mM NaCl conditions 13
Leaf number (at time point 2) at Cold conditions 14
Leaf number (at time point 2) at Low Nitrogen conditions 15
Leaf number (at time point 2) at Normal conditions 16
Leaf number (at time point 3) at 100 mM NaCl conditions 17
Leaf number (at time point 3) at Cold conditions 18
Leaf number (at time point 3) at Low Nitrogen conditions 19
Leaf number (at time point 3) at Normal conditions 20
total biomass DW (gr.) at Low N conditions 21
Shoot/Root (ratio) at Low N conditions 22
roots DW (gr.) at Low N conditions 23
shoots DW (gr.) at Low N conditions 24
percent root biomass at Low N compared to normal 25
conditions
percent shoot biomass at Low N compared to normal 26
conditions
percent total biomass reduction at Low N compared 27
to normal conditions
N level/Leaf (SPAD/gr.) at Low Nitrogen conditions 28
N level/Leaf (SPAD/gr.) at 100 mM NaCl conditions 29
N level/Leaf (SPAD/gr.) at Cold conditions 30
N level/Leaf (SPAD/gr.) at Normal conditions 31
Normal, Shoot/Root (ratio) at normal conditions 32
Roots DW (gr.) at normal conditions 33
Shoots DW (gr.) at normal conditions 34
Total biomass (gr. at normal conditions 35
Plant Height (at time point 1) (cm) at 100 mM 36
NaCl conditions
Plant Height (at time point 1) (cm) at Cold 37
conditions
Plant Height (at time point 1), (cm) at Low 38
Nitrogen conditions
Plant Height (at time point 1), (cm) at normal 39
conditions
Plant Height (at time point 2), (cm) at Cold 40
conditions
Plant Height (at time point 2), (cm) at Low 41
Nitrogen conditions
Plant Height (at time point 2), (cm) at normal 42
conditions
Plant Height (at time point 2), (cm) at 100 mM 43
NaCl conditions
Plant Height (at time point 3), (cm) at 100 mM 44
NaCl conditions
Plant Height (at time point 3), (cm) at Low 45
Nitrogen conditions
RGR Leaf Num at Normal conditions 46
Root Biomass (DW- gr.)/SPAD at 100 mM NaCl 47
conditions
Root Biomass (DW, gr.)/SPAD at Cold conditions 48
Root Biomass (DW, gr.)/SPAD at Low Nitrogen 49
conditions
Root Biomass [DW, gr.]/SPAD at Normal 50
conditions
SPAD, at Cold conditions         51
SPAD (number) at Low Nitrogen conditions 52
SPAD (number) at Normal conditions 53
SPAD (number) at 100 mM NaCl conditions 54
Shoot Biomass (DW, gr.)/SPAD at 100 mM NaCl 55
conditions
Shoot Biomass (DW, gr.)/SPAD at Cold conditions 56
Shoot Biomass (DW, gr.)/SPAD at Low Nitrogen 57
conditions
Shoot Biomass (DW, gr.)/SPAD at Normal conditions 58
Total Biomass (Root + Shoot; DW, gr.)/SPAD 59
at 100 mM NaCl conditions
Total Biomass (Root + Shoot; DW, gr.)/SPAD 60
at Cold conditions
Total Biomass (Root + Shoot; DW, gr.)/SPAD 61
at Low Nitrogen conditions
Total Biomass (Root + Shoot; DW, gr.)/SPAD 62
at Normal conditions

Table 40: Provided are the Sorghum correlated parameters. Cold conditions=10±2° C.; NaCl=100 mM NaCl; low nitrogen=1.2 mM Nitrogen; Normal conditions=16 mM Nitrogen.

TABLE 41
Sorghum accessions, measured parameters
Ecotype/										Line-
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9	10
4	0.05	0.13	0.17	0.10	0.11	0.12	0.14	0.12	0.10	0.11
8	0.10	0.24	0.31	0.16	0.19	0.19	0.24	0.24	0.19	0.24
12	3.00	3.07	3.80	3.20	3.23	3.23	3.13	3.43	3.00	3.00
16	4.17	4.50	4.80	4.60	4.53	4.97	4.60	4.93	4.50	4.57
20	5.33	5.87	6.20	5.80	5.80	5.73	5.73	6.00	5.60	6.07
39	7.47	9.30	12.87	8.57	8.93	8.53	10.67	10.27	7.87	8.77
42	14.97	18.23	22.10	17.60	18.07	18.53	22.83	22.03	20.03	21.80
46	0.16	0.19	0.16	0.17	0.17	0.17	0.17	0.17	0.17	0.20
53	26.70	29.33	29.86	29.09	24.98	24.62	30.79	25.50	32.89	33.54
3	0.04	0.11	0.20	0.10	0.08	0.09	0.13	0.09	0.09	0.09
5	0.08	0.19	0.33	0.16	0.16	0.16	0.26	0.20	0.13	0.18
11	3.00	3.13	3.87	3.53	3.20	3.13	3.13	3.30	3.07	3.07
15	4.00	4.58	4.97	4.73	4.60	4.70	4.97	4.87	4.67	4.57
19	3.90	4.27	4.70	4.23	4.30	4.57	4.63	4.67	3.97	4.10
38	6.73	9.77	12.70	8.67	9.77	9.23	10.27	10.10	7.93	8.23
41	13.30	20.63	23.70	18.03	19.33	19.20	21.87	22.13	18.20	21.00
45	22.23	31.07	34.67	30.03	30.83	29.87	30.87	32.40	29.37	30.70
52	26.88	28.02	29.64	31.52	29.61	26.82	28.48	28.21	30.48	27.63
1	0.05	0.10	0.12	0.07	0.08	0.08	0.14	0.10	0.16	0.14
6	0.09	0.19	0.20	0.14	0.13	0.13	0.15	0.19	0.10	0.12
9	3.00	3.13	3.40	3.07	3.33	3.07	3.07	3.27	3.00	3.07
13	4.00	4.37	4.87	4.60	4.50	4.53	4.50	4.77	4.32	4.20
17	4.00	4.13	4.57	4.43	4.07	4.33	4.13	4.50	3.78	4.20
36	7.90	9.50	10.93	7.93	9.70	8.53	8.90	10.37	7.00	7.83
43	14.20	16.27	20.37	13.33	15.90	16.53	15.47	18.93	13.68	15.77
44	21.80	23.17	30.37	22.83	23.70	23.30	22.47	26.83	20.28	23.57
54	32.73	35.14	27.97	30.93	34.53	29.99	32.09	31.86	32.51	34.32
2	0.07	0.11	0.16	0.09	0.08	0.11	0.14	0.13	0.11	0.14
7	0.08	0.15	0.19	0.11	0.13	0.16	0.15	0.15	0.11	0.14
10	3.00	3.00	3.50	3.17	3.40	3.20	3.13	3.07	3.07	3.00
14	3.90	4.13	4.63	4.17	4.27	4.23	4.20	4.30	4.17	4.00
18	4.73	5.33	5.43	5.50	5.33	5.07	4.50	5.40	5.37	5.18
37	6.50	8.77	10.40	6.80	9.03	9.00	7.97	9.17	6.50	7.23
40	11.17	15.87	18.43	12.20	16.03	14.63	14.60	17.27	13.43	13.91
51	28.62	30.31	27.04	32.28	28.28	29.89	32.47	28.63	31.71	29.56
30	6.05	5.68	4.98	5.87	5.30	5.90	7.21	5.30	5.91	5.70
48	0.002	0.004	0.006	0.003	0.003	0.004	0.004	0.004	0.003	0.005
56	0.003	0.005	0.007	0.003	0.005	0.006	0.005	0.005	0.004	0.005
60	0.005	0.009	0.013	0.006	0.008	0.009	0.009	0.010	0.007	0.009
21	27.53	64.12	115.23	58.02	52.22	35.10	84.57	63.73	47.03	60.00
22	1.87	1.71	1.73	1.57	2.10	1.81	2.06	2.10	1.50	2.00
23	9.65	23.54	43.88	22.58	16.89	12.44	28.19	20.53	18.76	20.09
24	17.88	40.59	71.35	35.44	35.33	22.66	56.38	43.20	28.27	39.91
25	84.53	80.95	117.00	100.52	72.54	71.78	93.47	76.05	86.82	80.51
26	81.57	79.16	104.75	103.50	83.71	83.22	107.69	81.39	70.30	75.86
27	82.58	79.81	109.10	102.32	79.74	78.77	102.49	79.59	76.07	77.36
28	6.89	6.57	6.31	7.45	6.89	5.87	6.15	6.05	7.68	6.74
49	0.002	0.004	0.007	0.003	0.003	0.003	0.005	0.003	0.003	0.003
57	0.003	0.007	0.011	0.005	0.005	0.006	0.009	0.007	0.004	0.007
61	0.005	0.011	0.018	0.008	0.008	0.009	0.014	0.010	0.007	0.010
29	8.18	8.50	6.12	6.98	8.49	6.92	7.76	7.08	8.60	8.17
47	0.002	0.003	0.004	0.002	0.002	0.003	0.004	0.003	0.005	0.004
55	0.003	6.005	0.007	0.004	0.004	0.004	0.005	0.006	0.003	0.004
59	0.004	0.008	0.012	0.007	0.006	0.007	0.009	0.009	0.008	0.008
31	5.01	5.00	4.82	5.02	4.31	4.29	5.37	4.25	5.87	5.53
32	1.98	1.94	1.90	1.59	1.81	1.58	1.76	1.99	1.89	2.20
33	0.86	2.19	2.83	1.69	1.76	1.96	2.27	2.04	1.09	1.88
34	1.65	3.87	5.14	2.58	3.18	3.08	3.95	4.00	2.02	3.97
35	2.51	6.06	7.96	4.28	4.94	5.04	6.22	6.04	3.11	5.85
50	0.002	0.005	0.006	0.004	0.004	0.005	0.005	0.005	0.003	0.003
58	0.004	0.008	0.010	0.005	0.008	0.008	0.008	0.010	0.006	0.007
62	0.006	0.013	0.016	0.009	0.012	0.012	0.012	0.014	0.009	0.011

Table 41: Provided are the measured parameters under 100 mM NaCl, low nitrogen (1.2 mM), low temperature (8-10° C.) and normal conditions of Sorghum accessions (Seed ID) according to the Correlation ID numbers (described in Table 40 above).

TABLE 42
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under low nitrogen, normal,
cold or salinity stress conditions across Sorghum accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY14	0.75	1.28E−02	1	30	LBY148	0.73	2.60E−02	5	10
LBY148	0.76	1.80E−02	5	14	LBY148	0.84	4.97E−03	8	12
LBY149	0.77	4.09E−02	3	38	LBY149	0.72	2.97E−02	6	49
LBY149	0.73	2.52E−02	6	3	LBY149	0.71	3.34E−02	6	5
LBY149	0.84	4.83E−03	6	11	LBY149	0.73	2.52E−02	6	23
LBY149	0.71	3.34E−02	6	24	LBY149	0.72	2.73E−02	6	21
LBY149	0.71	3.25E−02	6	38	LBY149	0.85	4.13E−03	2	46
LBY150	0.79	1.06E−02	7	29	LBY150	0.73	2.65E−02	7	54
LBY151	0.78	1.36E−02	8	39	LBY151	0.75	2.01E−02	8	33
LBY151	0.73	2.61E−02	8	50	LBY151	0.73	2.50E−02	8	4
LBY152	0.72	2.94E−02	6	28	LBY153	0.75	1.98E−02	7	29
LBY153	0.71	3.29E−02	7	54	LBY153	0.84	4.94E−03	2	46
LBY154	0.86	1.27E−02	3	38	LBY156	0.79	1.11E−02	5	48
LBY156	0.73	2.54E−02	5	10	LBY156	0.76	1.67E−02	5	56
LBY156	0.80	9.81E−03	5	60	LBY156	0.83	5.18E−03	5	14
LBY157	0.73	2.49E−02	2	12	LBY157	0.71	3.36E−02	2	39
LBY158	0.71	3.31E−02	6	3	LBY158	0.74	2.39E−02	6	45
LBY158	0.81	8.44E−03	6	11	LBY158	0.71	3.31E−02	6	23
LBY158	0.72	2.92E−02	6	38	LBY159	0.70	7.77E−02	3	25
LBY161	0.75	5.23E−02	3	49	LBY161	0.70	7.78E−02	3	3
LBY161	0.78	3.98E−02	3	5	LBY161	0.78	3.68E−02	3	61
LBY161	0.71	7.58E−02	3	38	LBY161	0.81	2.71E−02	3	19
LBY161	0.77	4.27E−02	3	57	LBY161	0.75	1.99E−02	7	29
LBY161	0.72	2.75E−02	7	54	LBY162	0.74	5.48E−02	3	15
LBY162	0.83	2.06E−02	3	28	LBY162	0.75	1.88E−02	5	51
LBY162	0.82	7.09E−03	5	30	LBY163	0.70	7.97E−02	3	38
LBY164	0.70	3.43E−02	7	29	LBY165	0.75	5.44E−02	3	27
LBY165	0.88	9.23E−03	3	26	LBY167	0.88	1.71E−03	8	12
LBY167	0.77	1.52E−02	8	35	LBY167	0.75	1.99E−02	8	34
LBY167	0.93	2.25E−04	8	39	LBY167	0.85	4.11E−03	8	58
LBY167	0.87	2.58E−03	8	62	LBY167	0.79	1.16E−02	8	33
LBY167	0.88	1.77E−03	8	50	LBY167	0.74	2.16E−02	8	8
LBY167	0.79	1.10E−02	8	4	LBY167	0.84	4.41E−03	7	44
LBY167	0.75	1.96E−02	7	9	LBY167	0.87	2.51E−03	2	12
LBY167	0.74	2.13E−02	2	16	LBY167	0.72	1.85E−02	1	51
LBY170	0.70	3.46E−02	5	7	LBY170	0.74	2.30E−02	5	56
LBY170	0.73	2.59E−02	5	60	LBY170	0.71	3.18E−02	5	37
LBY170	0.83	5.43E−03	5	40	LBY170	0.77	1.42E−02	7	6
LBY171	0.76	4.55E−02	3	27	LBY171	0.70	7.89E−02	3	11
LBY171	0.87	1.14E−02	3	26	LBY171	0.87	2.21E−03	5	7
LBY171	0.77	1.50E−02	5	48	LBY171	0.71	3.07E−02	5	2
LBY171	0.88	1.55E−03	5	56	LBY171	0.85	3.34E−03	5	60
LBY171	0.87	2.51E−03	5	37	LBY171	0.86	2.70E−03	5	40
LBY171	0.86	3.26E−03	5	14	LBY171	0.79	1.08E−02	6	49
LBY171	0.81	7.89E−03	6	3	LBY171	0.71	3.04E−02	6	25
LBY171	0.71	3.13E−02	6	5	LBY171	0.81	7.89E−03	6	23
LBY171	0.73	2.69E−02	6	61	LBY171	0.71	3.13E−02	6	24
LBY171	0.76	1.78E−02	6	21	LBY173	0.79	3.32E−02	3	23
LBY173	0.85	1.57E−02	3	52	LBY173	0.73	6.06E−02	3	24
LBY173	0.77	4.11E−02	3	21	LBY173	0.77	1.49E−02	7	59
LBY173	0.71	3.25E−02	7	6	LBY174	0.75	5.31E−02	3	28
LBY174	0.77	1.61E−02	5	7	LBY174	0.72	3.02E−02	5	56
LBY174	0.74	2.24E−02	5	40	LBY174	0.70	3.49E−02	8	31
LBY175	0.75	5.08E−02	3	61	LBY175	0.76	4.76E−02	3	57
LBY176	0.73	6.46E−02	3	23	LBY176	0.75	5.20E−02	3	52
LBY176	0.71	7.49E−02	3	24	LBY176	0.73	6.40E−02	3	21
LBY176	0.79	6.66E−03	1	48	LBY176	0.71	2.27E−02	1	2
LBY176	0.76	1.10E−02	1	60	LBY178	0.81	2.73E−02	3	49
LBY178	0.72	6.56E−02	3	3	LBY178	0.72	6.64E−02	3	61
LBY178	0.71	7.39E−02	3	41	LBY179	0.75	2.09E−02	5	7
LBY179	0.76	1.84E−02	5	56	LBY179	0.81	8.31E−03	5	37
LBY179	0.82	6.58E−03	5	40	LBY179	0.85	3.36E−03	5	14
LBY179	0.81	8.29E−03	6	27	LBY179	0.73	2.53E−02	6	25
LBY179	0.77	1.46E−02	6	26	LBY180	0.71	7.16E−02	3	27
LBY180	0.92	3.53E−03	3	25	LBY180	0.70	3.47E−02	8	33
LBY180	0.71	3.26E−02	7	9	LBY180	0.70	3.42E−02	7	13
LBY183	0.75	5.38E−02	3	52	LBY183	0.75	5.21E−02	3	28
LBY183	0.74	2.38E−02	5	7	LBY183	0.90	8.91E−04	5	10
LBY183	0.78	1.26E−02	5	56	LBY183	0.88	1.93E−03	5	37
LBY183	0.79	1.20E−02	5	40	LBY183	0.88	1.74E−03	5	14
LBY184	0.72	6.62E−02	3	61	LBY184	0.71	7.31E−02	3	57
LBY184	0.75	1.93E−02	2	46	LBY185	0.75	5.39E−02	3	15
LBY185	0.79	3.26E−02	3	52	LBY185	0.74	2.33E−02	6	3
LBY185	0.70	3.52E−02	6	15	LBY185	0.71	3.18E−02	6	45
LBY185	0.71	3.36E−02	6	11	LBY185	0.74	2.33E−02	6	23
LBY185	0.71	3.16E−02	6	21	LBY185	0.79	1.12E−02	7	59
LBY186	0.81	4.89E−03	1	48	LBY186	0.77	9.92E−03	1	2
LBY187	0.72	6.75E−02	3	22	LBY188	0.89	1.18E−03	5	10
LBY188	0.71	3.26E−02	5	14	LBY190	0.73	6.10E−02	3	49
LBY190	0.73	6.40E−02	3	3	LBY191	0.80	9.80E−03	5	51
LGN3	0.72	6.78E−02	3	22	LGN3	0.76	1.78E−02	5	56
LGN3	0.82	6.98E−03	5	37	LGN3	0.79	1.07E−02	5	40
LGN3	0.81	8.13E−03	5	14	LGN4	0.82	2.25E−02	3	15
LGN4	0.76	4.83E−02	3	45	LGN4	0.85	3.98E−03	5	7
LGN4	0.74	2.17E−02	5	48	LGN4	0.71	3.24E−02	5	10
LGN4	0.85	3.86E−03	5	56	LGN4	0.82	6.63E−03	5	60
LGN4	0.80	8.96E−03	5	37	LGN4	0.80	9.21E−03	5	40
LGN4	0.95	6.09E−05	5	14	LGN4	0.82	6.74E−03	6	49
LGN4	0.83	5.67E−03	6	3	LGN4	0.78	1.30E−02	6	25
LGN4	0.72	2.73E−02	6	5	LGN4	0.83	5.67E−03	6	23
LGN4	0.75	1.93E−02	6	61	LGN4	0.72	2.73E−02	6	24
LGN4	0.77	1.45E−02	6	21	LGN5	0.87	1.06E−02	3	22
LGN5	0.78	1.39E−02	8	12	LGN5	0.73	2.70E−02	6	22
LGN57	0.83	2.18E−02	3	25	LGN57	0.70	3.46E−02	5	51
LGN57	0.72	2.96E−02	5	30	LGN57	0.79	1.15E−02	2	31
LGN6	0.76	1.85E−02	7	1	LGN6	0.70	3.54E−02	7	47
LGN7	0.74	5.77E−02	3	11	LGN7	0.71	7.22E−02	3	24
LGN7	0.71	3.06E−02	5	37	LGN7	0.71	3.07E−02	6	38
LGN7	0.77	1.48E−02	6	19

Table 42. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 40. “Exp. Set”—Expression set specified in Table 39. “R”=Pearson correlation coefficient; “P”=p value.

Example 7

Production of Sorghum Transcriptome and High Throughput Correlation Analysis Using 60K Sorghum Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a sorghum oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60,000 sorghum genes and transcripts. In order to define correlations between the levels of RNA expression with vigor related parameters, various plant characteristics of 10 different sorghum hybrids were analyzed. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Correlation of Sorghum varieties across ecotypes grown in growth chambers under temperature of 30° C. or 14° C. at low light (100 μE) or high light (250 μE) conditions.

Analyzed Sorghum tissues—All 10 selected Sorghum hybrids were sampled per each condition. Leaf tissue growing under 30° C. and low light (100 μE m⁻² sec⁻¹), 14° C. and low light (100 μE m⁻² sec⁻¹), 30° C. and high light (250 μE m⁻² sec⁻¹), 14° C. and high light (250 μE m⁻² sec⁻¹) were sampled at vegetative stage of four-five leaves and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 43 below.

TABLE 43
Sorghum transcriptome expression sets in field experiments
Description                      Expression set
Sorghum/leaf, under 14 Celsius degrees and high 1
light (light on)
Sorghum/leaf, under 14 Celsius degrees and low 2
light (light on)
Sorghum/leaf, under 30 Celsius degrees and high 3
light (light on)
Sorghum/leaf, under 30 Celsius degrees and low 4
light (light on)

Table 43: Provided are the sorghum transcriptome expression sets.

The following parameters were collected by sampling 8-10 plants per plot or by measuring the parameter across all the plants within the plot (Table 44 below).

Relative Growth Rate of vegetative dry weight was performed using Formula VII.

Leaves number—Plants were characterized for leaf number during growing period. In each measure, plants were measured for their leaf number by counting all the leaves of selected plants per plot.

Shoot FW—shoot fresh weight (FW) per plant, measurement of all vegetative tissue above ground.

Shoot DW—shoot dry weight (DW) per plant, measurement of all vegetative tissue above ground after drying at 70° C. in oven for 48 hours.

The average for each of the measured parameters was calculated and values are summarized in Tables 45-48 below. Subsequent correlation analysis was performed (Table 49). Results were then integrated to the database.

TABLE 44
Sorghum correlated parameters (vectors)
                              Correlation
Correlated parameter with     ID
Leaves number                 1
Leaves temperature [° C.]     2
RGR (relative growth rate)    3
Shoot DW (dry weight) (gr.)   4
Shoot FW (fresh weight) (gr.) 5

Table 44. Provided are the Sorghum correlated parameters (vectors).

TABLE 45
Measured parameters in Sorghum accessions under 14° C. and low light (100 μE m−2 sec−1)
Ecotype/										Line-
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9	10
1	3.00	3.00	2.75	2.75	2.63	3.00	3.50	2.75	2.43	2.00
3	0.032	−0.014	−0.022	0.024	−0.037	−0.045	0.083	NA	−0.050	−0.073
4	0.041	0.013	0.013	0.009	0.011	0.011	0.031	0.009	0.009	0.009
5	0.55	0.30	0.33	0.28	0.36	0.36	0.58	0.22	0.18	0.30

Table 45: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under 14° C. and low light (100 μE m⁻² sec⁻¹).

TABLE 46
Measured parameters in Sorghum accessions under 30° C. and low light (100 μE m−2 sec−1)
Ecotype/										Line-
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9	10
1	5.27	5.00	4.75	4.00	4.00	4.00	5.25	4.50	3.75	4.00
2	28.140	29.813	24.213	23.138	19.900	21.350	23.360	29.922	21.525	24.440
3	0.099	0.098	0.090	0.122	0.108	0.084	0.113	0.121	0.042	0.039
4	0.114	0.079	0.071	0.056	0.093	0.077	0.040	0.055	0.036	0.050
5	1.35	1.05	0.88	0.95	1.29	1.13	0.71	0.79	0.67	0.82

Table 46: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under 30° C. and low light (100 μE m⁻² sec⁻¹).

TABLE 47
Measured parameters in Sorghum accessions under 30° C. and high light (250 μE m−2 sec−1)
Ecotype/										Line-
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9	10
1	4.00	3.70	3.50	3.33	4.00	4.00	3.60	3.40	3.30	3.40
3	0.098	0.096	0.087	0.070	0.094	0.118	0.097	0.099	0.106	0.121
4	0.076	0.050	0.047	0.036	0.065	0.085	0.049	0.042	0.042	0.062
5	0.77	0.52	0.49	0.38	0.71	0.86	0.49	0.45	0.44	0.67

Table 47: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under 30° C. and high light (250 μE m⁻² sec⁻¹).

TABLE 48
Measured parameters in Sorghum accessions under 14° C. and high light (250 μE m−2 sec−1)
Ecotype/										Line-
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8	Line-9	10
3	0.053	0.052	0.034	0.040	0.056	0.061	0.049	0.056	0.068	0.063
4	0.037	0.026	0.021	0.023	0.037	0.036	0.022	0.022	0.023	0.027
5	0.37	0.25	0.22	0.25	0.43	0.37	0.24	0.23	0.24	0.27

Table 48: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed 2D) under 14° C. and high light (250 μE m⁻² sec⁻¹).

TABLE 49
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under combinations of
temperature and light conditions treatments (14° C. or 30° C.; high light (250 μE m−2 sec−1) or
low light (100 μE m−2 sec−1) across Sorghum accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY148	0.70	3.50E−02	2	3	LBY150	0.87	2.55E−02	3	5
LBY150	0.90	1.32E−02	3	4	LBY150	0.77	7.42E−02	3	1
LBY151	0.78	6.98E−02	3	3	LBY152	0.88	7.21E−04	4	2
LBY157	0.73	1.66E−02	1	5	LBY157	0.71	2.03E−02	1	4
LBY158	0.72	1.84E−02	4	4	LBY158	0.72	1.94E−02	2	5
LBY158	0.80	1.04E−02	2	3	LBY158	0.77	7.20E−02	3	5
LBY158	0.83	4.25E−02	3	4	LBY159	0.77	8.88E−03	4	2
LBY162	0.86	1.37E−03	2	5	LBY162	0.79	1.17E−02	2	3
LBY162	0.86	1.25E−03	2	4	LBY164	0.77	9.28E−03	2	5
LBY165	0.84	3.76E−02	3	3	LBY168	0.74	1.34E−02	1	5
LBY168	0.70	2.40E−02	1	4	LBY168	0.73	1.68E−02	4	1
LBY170	0.72	1.77E−02	2	5	LBY170	0.91	6.12E−04	2	3
LBY171	0.75	1.32E−02	4	3	LBY173	0.75	1.17E−02	4	2
LBY173	0.72	1.07E−01	3	4	LBY174	0.74	9.02E−02	3	3
LBY175	0.75	8.56E−02	3	5	LBY175	0.81	5.27E−02	3	4
LBY177	0.77	1.60E−02	2	3	LBY177	0.88	2.20E−02	3	5
LBY177	0.90	1.47E−02	3	4	LBY177	0.75	8.33E−02	3	1
LBY178	0.76	1.07E−02	2	5	LBY178	0.79	6.08E−02	3	5
LBY178	0.81	5.07E−02	3	4	LBY178	0.81	5.15E−02	3	1
LBY180	0.72	2.82E−02	2	3	LBY180	0.74	9.20E−02	3	5
LBY180	0.79	6.04E−02	3	4	LBY183	0.74	2.19E−02	2	3
LBY187	0.71	1.15E−01	3	3	LBY187	0.71	1.16E−01	3	4
LBY190	0.71	2.27E−02	4	2	LBY192	0.75	1.33E−02	2	5
LBY192	0.81	4.58E−03	2	4	LGN5	0.85	4.01E−03	2	3
LGN5	0.79	6.00E−02	3	3	LGN54	0.93	7.13E−03	3	3
LGN7	0.93	6.90E−03	3	5	LGN7	0.96	2.94E−03	3	4
LGN7	0.93	7.34E−03	3	1

Table 49. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 44. “Exp. Set”—Expression set specified in Table 43. “R”=Pearson correlation coefficient; “P”=p value.

Example 8

Production of Sorghum Transcriptome and High Throughput Correlation Analysis with Yield and Drought Related Parameters Measured in Fields Using 65K Sorguhm Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a sorghum oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 65,000 sorghum genes and transcripts. In order to define correlations between the levels of RNA expression with ABST, drought and yield components or vigor related parameters, various plant characteristics of 12 different sorghum hybrids were analyzed. Among them, 8 hybrids encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

12 Sorghum varieties were grown in 6 repetitive plots, in field. Briefly, the growing protocol was as follows:

1. Regular growth conditions: sorghum plants were grown in the field using commercial fertilization and irrigation protocols, which include 452 m³ water per dunam (1000 square meters) per entire growth period and fertilization of 14 units nitrogen per dunam per entire growth period (normal conditions). The nitrogen can be obtained using URAN® 21% (Nitrogen Fertilizer Solution; PCS Sales. Northbrook, Ill. USA).

2. Drought conditions: sorghum seeds were sown in soil and grown under normal condition until flowering stage (59 days from sowing), drought treatment was imposed by irrigating plants with 50% water relative to the normal treatment from this stage [309 m³ water per dunam (1000 square meters) per the entire growth period)], with normal fertilization (i.e., 14 units nitrogen per dunam).

Analyzed Sorghum tissues—All 12 selected Sorghum hybrids were sampled per each treatment. Tissues [Flag leaf, upper stem, lower stem, flower, grain] representing different plant characteristics, from plants growing under normal conditions and drought stress conditions were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 50 below.

TABLE 50
Sorghum transcriptome expression sets in
field experiment under normal conditions
                                 Set
Expression Set                   ID
Basal head at grain filling stage under normal conditions 1
Distal head at grain filling stage under normal conditions 2
Flag leaf at flowering stage under normal conditions 3
Flag leaf at grain filling stage under normal conditions 4
Up stem at flowering stage under normal conditions 5
Up stem at grain filling stage under normal conditions 6

Table 50: Provided are the sorghum transcriptome expression sets. Flag leaf=the leaf below the flower.

TABLE 51
Sorghum transcriptome expression sets in
field experiment under drought conditions
                                 Set
Expression Set                   ID
Basal head at grain filling stage under drought conditions 1
Distal head at grain filling stage under drought conditions 2
Flag leaf at flowering stage under drought conditions 3
Flag leaf at grain filling stage under drought conditions 4
Up stem at flowering stage under drought conditions 5
Up stem at grain filling stage under drought conditions 6

Table 51: Provided are the sorghum transcriptome expression sets under drought conditions. Flag leaf=the leaf below the flower.

Sorghum yield components and vigor related parameters assessment—Plants were phenotyped as shown in Tables 53-56 below. Some of the following parameters were collected using digital imaging system:

Grains yield per plant (gr)—At the end of the growing period heads were collected (harvest stage). Selected heads were separately threshed and grains were weighted. The average grain weight per plant was calculated by dividing the total grain weight by the number of selected plants.

Heads weight per plant (RP) (kg)—At the end of the growing period heads of selected plants were collected (harvest stage) from the rest of the plants in the plot.

Heads were weighted after oven dry (dry weight), and average head weight per plant was calculated.

Grains num (SP) (num)—was calculated by dividing seed yield from selected plants by a single seed weight.

1000 grain (seed) weight (gr)—was calculated based on Formula XIV.

Grain area (cm²)—At the end of the growing period the grains were separated from the Plant ‘Head’. A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Grain Circularity—The circularity of the grains was calculated based on Formula XIX.

Main Head Area (cm²)—At the end of the growing period selected “Main Heads” were photographed and images were processed using the below described image processing system. The “Main Head” area was measured from those images and was divided by the number of “Main Heads”.

Main Head length (cm)—At the end of the growing period selected “Main Heads” were photographed and images were processed using the below described image processing system. The “Main Head” length (longest axis) was measured from those images and was divided by the number of “Main Heads”.

Main Head Width (cm)—At the end of the growing period selected “Main Heads” were photographed and images were processed using the below described image processing system. The “Main Head” width (longest axis) was measured from those images and was divided by the number of “Main Heads”.

An image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37. Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Additional parameters were collected either by sampling selected plants in a plot or by measuring the parameter across all the plants within the plot.

All Heads Area (cm²)—At the end of the growing period (harvest) selected plants main and secondary heads were photographed and images were processed using the above described image processing system. All heads area was measured from those images and was divided by the number of plants.

All Heads length (cm)—At the end of the growing period (harvest) selected plants main and secondary heads were photographed and images were processed using the above described image processing system. All heads length (longest axis) was measured from those images and was divided by the number of plants.

All Heads Width (cm)—At the end of the growing period main and secondary heads were photographed and images were processed using the above described image processing system. All heads width (longest axis) was measured from those images and was divided by the number of plants.

Head weight per plant (RP)/water until maturity (gr./lit)—At the end of the growing period heads were collected (harvest stage) from the rest of the plants in the plot. Heads were weighted after oven dry (dry weight), and average head weight per plant was calculated. Head weight per plant was then divided by the average water volume used for irrigation until maturity.

Harvest index (SP)—was calculated based on Formula XVI above.

Heads index (RP)—was calculated based on Formula XXXXVI above.

Head dry weight (GF) (gr.)—selected heads per plot were collected at the grain filling stage (R2-R3) and weighted after oven dry (dry weight).

Heads per plant (RP) (num)—At the end of the growing period total number of rest of plot heads were counted and divided by the total number of rest of plot plants.

Leaves temperature 2 (C)—leaf temperature was measured using Fluke IR thermometer 568 device. Measurements were done on opened leaves at grain filling stage.

Leaves temperature 6 (° C.)—leaf temperature was measured using Fluke IR thermometer 568 device. Measurements were done on opened leaves at late grain filling stage.

Stomatal conductance (F) (mmol m⁻² s⁻¹)—plants were evaluated for their stomata conductance using SC-1 Leaf Porometer (Decagon devices) at flowering (F) stage. Stomata conductance readings were done on fully developed leaf, for 2 leaves and 2 plants per plot.

Stomatal conductance (GF) (mmol m⁻² s⁻¹)—plants were evaluated for their stomata conductance using SC-1 Leaf Porometer (Decagon devices) at grain filling (GF) stage. Stomata conductance readings were done on fully developed leaf, for 2 leaves and 2 plants per plot.

Relative water content 2 (RWC, %)—was calculated based on Formula I at grain filling.

Specific leaf area (SLA) (GF)—was calculated based on Formula XXXVII above.

Waxy leaf blade—was defined by view of leaf blades % of Normal and % of grayish (powdered coating/frosted appearance). Plants were scored for their waxiness according to the scale 0=normal, 1=intermediate, 2=grayish.

SPAD 2 (SPAD unit)—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at flowering. SPAD meter readings were done on fully developed leaf. Three measurements per leaf were taken per plant.

SPAD 3 (SPAD unit)—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at grain filling. SPAD meter readings were done on fully developed leaf. Three measurements per leaf were taken per plant.

% yellow leaves number (F) (percentage)—At flowering stage, leaves of selected plants were collected. Yellow and green leaves were separately counted. Percent of yellow leaves at flowering was calculated for each plant by dividing yellow leaves number per plant by the overall number of leaves per plant and multiplying by 100.

% yellow leaves number (H) (percentage)—At harvest stage, leaves of selected plants were collected. Yellow and green leaves were separately counted. Percent of yellow leaves at flowering was calculated for each plant by dividing yellow leaves number per plant by the overall number of leaves per plant and multiplying by 100.

% Canopy coverage (GF)—was calculated based on Formula XXXII above.

LAI LP-80 (GF)—Leaf area index values were determined using an AccuPAR Centrometer Model LP-80 and measurements were performed at grain filling stage with three measurements per plot.

Leaves area per plant (GF) (cm²)—total leaf area of selected plants in a plot. This parameter was measured using a Leaf area-meter at the grain filling period (GF).

Plant height (H) (cm)—Plants were characterized for height at harvest. Plants were measured for their height using a measuring tape. Height was measured from ground level to top of the longest leaf.

Relative growth rate of Plant height (cm/day)—was calculated based on Formula III above.

Number days to Heading (num)—Calculated as the number of days from sowing till 50% of the plot arrives to heading.

Number days to Maturity (num)—Calculated as the number of days from sowing till 50% of the plot arrives to seed maturation.

Vegetative DWper plant (gr.)—At the end of the growing period all vegetative material (excluding roots) from plots were collected and weighted after oven dry (dry weight). The biomass per plant was calculated by dividing total biomass by the number of plants.

Lower Stem dry density (F) (gr/cm³)—measured at flowering. Lower internodes from selected plants per plot were separated from the plants and weighted (dry weight). To obtain stem density, internode dry weight was divided by the internode volume.

Lower Stem dry density (H) (gr/cm³)—measured at harvest. Lower internodes from selected plants per plot were separated from the plant and weighted (dry weight).

To obtain stem density, internode dry weight was divided by the internode volume.

Lower Stem fresh density (F) (gr/cm³)—measured at flowering. Lower internodes from selected plants per plot were separated from the plants and weighted (fresh weight). To obtain stem density, internodes fresh weight was divided by the stem volume.

Lower Stem fresh density (H) (gr/cm^j)—measured at harvest. Lower internodes from selected plants per plot were separated from the plants and weighted (fresh weight). To obtain stem density, internodes fresh weight was divided by the stem volume.

Lower Stem length (F) (cm)—Lower internodes from selected plants per plot were separated from the plants at flowering (F). Internodes were measured for their length using a ruler.

Lower Stem length (H) (cm)—Lower internodes from selected plants per plot were separated from the plant at harvest (H). Internodes were measured for their length using a ruler.

Lower Stem width (F) (cm)—Lower internodes from selected plants per plot were separated from the plant at flowering (F). Internodes were measured for their width using a caliber.

Lower Stem width (GF) (cm)—Lower internodes from selected plants per plot were separated from the plant at grain filling (GF). Internodes were measured for their width using a caliber.

Lower Stem width (H) (cm)—Lower internodes from selected plants per plot were separated from the plant at harvest (H). Internodes were measured for their width using a caliber.

Upper Stem dry density (F) (gr/cm³)—measured at flowering (F). Upper internodes from selected plants per plot were separated from the plant and weighted (dry weight). To obtain stem density, stem dry weight was divided by the stem volume.

Upper Stem dry density (H) (gr/cm³)—measured at harvest (H). Upper stems from selected plants per plot were separated from the plant and weighted (dry weight). To obtain stem density, stem dry weight was divided by the stem volume.

Upper Stem fresh density (F) (gr/cm³)—measured at flowering (F). Upper stems from selected plants per plot were separated from the plant and weighted (fresh weight). To obtain stem density, stem fresh weight was divided by the stem volume.

Upper Stem fresh density (H) (gr/cm³)—measured at harvest (H). Upper stems from selected plants per plot were separated from the plant and weighted (fresh weight). To obtain stem density, stem fresh weight was divided by the stem volume.

Upper Stem length (F) (cm)—Upper stems from selected plants per plot were separated from the plant at flowering (F). Stems were measured for their length using a ruler.

Upper Stem length (H) (cm)—Upper stems from selected plants per plot were separated from the plant at harvest (H). Stems were measured for their length using a ruler.

Upper Stem width (F) (cm)—Upper stems from selected plants per plot were separated from the plant at flowering (F). Stems were measured for their width using a caliber.

Upper Stem width (H) (cm)—Upper stems from selected plants per plot were separated from the plant at harvest (H). Stems were measured for their width using a caliber.

Upper Stem volume (H)—was calculated based on Formula L above. Data parameters collected are summarized in Table 52, herein below.

TABLE 52
Sorghum correlated parameters under normal and drought growth
conditions (vectors)
Correlated parameter with        Correlation ID
% Canopy coverage (GF) [%]       1
% yellow leaves number (F) [%]   2
% yellow leaves number (H) [%]   3
1000 grain weight [gr.]          4
All Heads Area [cm2]             5
All Heads Width [cm]             6
All Heads length [cm]            7
Grain Circularity [cm2/cm2]      8
Grain area [cm2]                 9
Grains num (SP) [num]            10
Grains yield per plant [gr.]     11
Harvest index (SP)               12
Head DW (GF) [gr.]               13
Head weight per plant (RP)/water until maturity [gr./lit] 14
Heads index (RP)                 15
Heads per plant (RP) [num]       16
Heads weight per plant (RP) [kg] 17
LAI LP-80 (GF)                   18
Leaves area per plant (GF) [cm2] 19
Leaves temperature_2 [° C.]      20
Leaves temperature_6 [° C.]      21
Lower Stem dry density (F) [gr./cm3] 22
Lower Stem dry density (H) gr./cm3] 23
Lower Stem fresh density (F) [gr./cm3] 24
Lower Stem fresh density (H) [gr./cm3] 25
Lower Stem length (F) [cm]       26
Lower Stem length (H) [cm]       27
Lower Stem width (F) [cm]        28
Lower Stem width (GF) [cm]       29
Lower Stem width (H) [cm]        30
Main Head Area [cm2]             31
Main Head Width [cm]             32
Main Head length [cm]            33
Num days to Heading [num]        34
Num days to Maturity [num]       35
Plant height (H) [cm]            36
Plant height growth [cm/day]     37
RWC 2 [%]                        38
SPAD 2 [SPAD unit]               39
SPAD 3 [SPAD unit]               40
Specific leaf area (GF) [cm2/gr] 41
Stomatal conductance (F) [mmol m−2 s−1] 42
Stomatal conductance (GF) [mmol m−2 s−1] 43
Upper Stem dry density (F) [gr/cm3] 44
Upper Stem dry density (H) [gr/cm3] 45
Upper Stem fresh density (F) [gr/cm3] 46
Upper Stem fresh density (H) [gr/cm3] 47
Upper Stem length (F) [cm]       48
Upper Stem length (H) [cm]       49
Upper Stem volume (H) [cm3]      50
Upper Stem width (F) [cm]        51
Upper Stem width (H) [cm]        52
Vegetative DW per plant [gr]     53
Waxy leaf blade [scoring 0-2]    54

Table 52. Provided are the Sorghum correlated parameters (vectors). “gr.”=grams; “kg”=kilograms”; “RP”=Rest of plot; “SP”=Selected plants; “num”=Number; “lit”=Liter; “SPAD”=chlorophyll levels; “FW”=Plant Fresh weight; “DW”=Plant Dry weight; “GF”=Grain filling growth stage; “F”=Flowering stage; “H”=Harvest stage; “cm”=Centimeter; “mmol”=millimole.

Experimental Results

Twelve different sorghum hybrids were grown and characterized for different parameters (Table 52). The average for each of the measured parameter was calculated using the JMP software (Tables 53-56) and a subsequent correlation analysis was performed (Tables 57-58). Results were then integrated to the database.

TABLE 53
Measured parameters in Sorghum accessions under normal conditions
	Line
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1	94.985	69.219	97.525	83.591	92.773	84.341
2	0.611	0.853	0.548	0.314	0.713	0.573
3	0.406	0.111	0.370	0.126	0.485	0.149
4	27.623	22.819	14.876	18.467	28.471	27.138
5	114.483	79.685	77.873	79.688	218.954	100.146
6	5.536	4.925	6.197	4.558	9.988	6.545
7	27.738	21.360	17.811	23.739	32.185	19.449
8	0.8722	0.8653	0.8714	0.8821	0.8682	0.8856
9	0.154	0.119	0.098	0.122	0.154	0.149
10	12730.1	6281.9	4599.5	15182.6	12628.1	17505.0
11	43.867	18.013	8.536	33.168	44.326	60.190
12	0.218	0.185	0.054	0.253	0.261	0.375
13	29.307	12.924	27.947	41.320	38.867	15.243
14	0.248	0.163	0.136	0.197	0.178	0.285
15	0.343	0.402	0.241	0.338	0.361	0.532
16	NA	1.420	1.742	1.296	0.974	1.727
17	0.0569	0.0374	0.0312	0.0452	0.0409	0.0655
18	6.272	NA	6.111	5.422	5.432	NA
19	2825.8	1911.2	2030.0	2866.8	1554.7	2342.6
20	32.4397	32.1479	33.1993	32.3472	32.4000	31.0687
21	33.3486	33.9333	33.2315	33.3292	33.6167	33.8037
22	1.572	1.371	2.811	2.171	2.349	1.404
23	1.832	2.027	3.476	2.527	3.048	1.801
24	10.4667	10.6380	8.5509	10.8515	11.3170	10.0379
25	9.791	10.382	10.521	10.490	11.283	7.286
26	7.787	3.500	14.900	3.413	11.121	8.158
27	7.992	4.830	12.873	3.117	10.760	8.302
28	19.489	16.718	14.703	17.942	14.826	15.979
29	20.041	20.885	14.661	18.797	15.291	15.874
30	19.124	15.508	14.368	20.277	15.150	15.143
31	114.483	80.837	77.873	79.688	218.954	112.095
32	5.536	4.988	6.197	4.558	9.988	7.191
33	27.738	21.610	17.811	23.739	32.185	20.663
34	89.400	65.667	88.167	74.000	84.000	71.500
35	126	107	115	107	107	92
36	182.125	104.563	143.792	99.010	173.550	170.063
37	2.865	1.852	2.551	1.653	3.124	2.733
38	72.075	91.721	79.533	86.664	74.009	90.557
39	47.804	49.275	44.667	49.080	41.689	47.181
40	47.650	35.422	45.782	42.122	41.449	33.393
41	80.187	170.318	54.259	76.900	51.450	163.058
42	670.381	1017.614	584.437	640.600	349.994	553.500
43	382.950	809.436	468.742	486.858	421.500	633.092
44	NA	1.238	NA	NA	2.109	1.230
45	2.047	1.767	2.363	1.834	1.730	1.859
46	NA	9.790	NA	NA	10.444	9.383
47	6.605	8.924	6.425	8.250	7.243	4.635
48	NA	42.625	NA	NA	NA	9.208
49	38.783	45.049	24.530	52.492	38.385	34.019
50	2352.483	2169.089	968.809	2452.559	1997.708	2767.520
51	8.226	8.978	7.113	7.125	6.815	10.421
52	8.742	7.459	6.985	7.677	7.833	10.072
53	0.1255	0.0503	0.1223	0.0760	0.0966	0.0619
54	NA	2.000	NA	NA	NA	1.063

Table 53: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Line) under normal conditions. Growth conditions are specified in the experimental procedure section. “NA”=not available.

TABLE 54
Measured parameters in additional Sorghum accessions under normal growth conditions
	Line
Corr. ID	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1	80.617	75.681	80.171	79.658	65.915	89.644
2	0.584	0.544	0.208	0.484	0.351	0.574
3	0.076	0.022	0.018	0.129	0.096	0.424
4	18.470	18.457	23.479	25.937	24.294	20.366
5	85.403	138.989	70.043	78.551	152.012	145.250
6	5.453	6.371	4.479	4.573	7.408	6.316
7	21.298	30.863	19.174	21.016	27.845	29.966
8	0.8879	0.8842	0.8895	0.8974	0.8873	0.8982
9	0.117	0.121	0.122	0.129	0.123	0.125
10	13887.9	21509.8	13138.7	16910.0	18205.2	24801.2
11	32.051	49.629	38.998	54.808	55.265	64.740
12	0.309	0.409	0.343	0.360	0.314	0.318
13	10.235	27.607	31.563	25.847	21.326	74.493
14	0.249	0.271	0.284	0.315	0.216	0.325
15	0.477	0.554	0.538	0.502	0.471	0.478
16	1.372	1.081	2.200	1.523	1.168	1.015
17	0.0571	0.0621	0.0652	0.0724	0.0495	0.0746
18	NA	NA	NA	NA	NA	5.790
19	2008.9	2212.0	1495.5	1997.8	2692.1	2647.7
20	32.8562	33.0333	31.5844	32.4083	32.7021	32.7500
21	33.5694	33.8926	32.2764	32.9255	32.3765	33.3296
22	1.975	2.049	2.293	1.871	1.708	2.138
23	2.933	2.471	2.557	2.476	2.744	1.640
24	10.7072	10.8184	10.8381	10.8360	10.7013	10.5546
25	10.089	10.853	11.003	11.199	7.357	8.622
26	2.833	3.217	4.017	4.882	2.818	8.786
27	2.973	3.719	5.903	5.069	3.783	9.979
28	17.752	18.677	13.543	14.999	14.675	16.371
29	21.451	21.037	19.488	16.473	19.939	19.413
30	17.382	16.334	13.313	14.982	16.360	18.739
31	85.403	138.989	98.915	114.696	154.742	147.871
32	5.453	6.371	5.897	6.274	7.497	6.404
33	21.298	30.863	22.503	24.722	28.256	30.450
34	67.667	63.667	56.000	59.000	56.000	75.333
35	107	92	107	107	107	107
36	54.938	94.771	101.604	112.979	88.326	163.792
37	0.881	1.566	1.733	1.911	1.593	2.865
38	88.841	90.211	90.765	88.475	86.674	82.031
39	52.089	53.727	52.567	53.862	51.777	44.129
40	50.174	41.898	46.828	46.796	48.597	40.065
41	194.138	213.658	212.049	214.648	157.440	67.729
42	473.775	796.950	879.000	810.325	889.012	607.200
43	485.718	886.017	730.573	886.550	784.958	384.530
44	1.261	1.501	1.938	1.924	1.956	NA
45	1.756	1.747	1.788	1.663	1.868	1.674
46	10.215	9.687	9.981	10.737	10.326	NA
47	7.234	7.311	7.923	7.055	5.396	4.820
48	26.583	60.364	53.600	55.000	44.583	NA
49	28.808	59.663	51.983	54.794	45.548	48.496
50	1607.665	3510.662	2907.809	3639.453	3045.637	3301.794
51	9.430	9.537	8.043	8.853	7.913	8.071
52	8.417	8.607	8.513	9.187	9.136	9.311
53	0.0446	0.0446	0.0461	0.0626	0.0861	0.0991
54	1.125	1.438	1.000	1.750	1.000	NA

Table 54: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under normal conditions. Growth conditions are specified in the experimental procedure section. “NA”=not available.

TABLE 55
Measured parameters in Sorghum accessions under drought growth conditions
	Line
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1	86.887	61.338	75.023	77.781	75.524	80.375
2	0.371	0.728	0.407	0.695	0.425	0.878
3	0.286	0.424	0.256	0.478	0.366	0.394
4	24.160	19.803	14.209	14.639	25.540	20.829
5	72.386	93.839	30.770	55.311	131.242	76.546
6	4.272	5.395	3.511	3.722	6.999	5.270
7	22.325	24.388	12.159	19.926	27.603	18.164
8	0.8734	0.8718	0.8626	0.8754	0.8708	0.8866
9	0.1422	0.1143	0.0946	0.1115	0.1442	0.1309
10	6968	5452	3960	9839	6482	12403
11	23.833	13.673	6.991	18.234	20.717	34.426
12	0.135	0.158	0.065	0.187	0.255	0.291
13	NA	12.103	24.831	37.040	23.293	11.722
14	0.110	0.094	0.030	0.094	0.056	0.116
15	0.157	0.359	0.071	0.244	0.056	0.511
16	NA	2.017	1.000	1.041	NA	1.058
17	0.0227	0.0194	0.0063	0.0195	0.0115	0.0239
18	3.582	NA	2.642	3.428	2.805	NA
19	3308.1	1206.0	2464.6	1142.9	2116.3	1550.0
20	36.085	35.833	35.464	36.576	35.868	33.764
21	35.847	36.030	36.526	38.399	35.915	36.452
22	1.758	1.458	2.267	2.784	2.393	1.276
23	1.958	1.605	2.271	2.494	3.555	1.253
24	9.617	10.459	7.487	10.787	10.250	9.660
25	9.676	8.315	7.384	10.106	10.721	5.513
26	7.787	4.027	16.460	3.287	10.829	10.818
27	7.064	4.509	16.228	3.305	9.885	10.500
28	19.206	16.627	14.929	18.353	15.795	13.963
29	18.979	18.365	16.017	19.125	15.487	14.340
30	20.086	16.099	14.439	18.471	15.469	14.061
31	72.386	96.616	32.820	55.311	131.242	85.867
32	4.272	5.526	3.696	3.722	6.999	5.806
33	22.325	24.787	12.396	19.926	27.603	19.408
34	91.500	66.333	88.000	74.667	90.000	71.000
35	115.0	92.0	115.0	107.0	107.0	107.0
36	104.646	83.240	113.031	69.036	104.200	133.542
37	1.586	1.556	1.831	1.279	1.798	2.024
38	65.594	78.509	83.840	54.860	69.741	74.513
39	45.787	46.967	38.775	38.188	35.907	43.352
40	43.458	26.980	36.000	34.140	27.291	25.840
41	75.917	143.323	62.928	44.434	61.434	106.055
42	30.407	774.842	61.788	68.263	31.208	330.458
43	135.117	561.183	94.442	276.217	64.117	217.192
44	NA	1.436	NA	NA	NA	1.376
45	2.328	1.432	2.169	1.923	1.848	1.660
46	0.860	9.887	NA	NA	NA	8.097
47	9.451	5.717	7.258	8.602	6.533	3.604
48	25.000	40.000	NA	NA	NA	15.909
49	26.609	39.567	15.492	31.055	31.100	20.723
50	1288.2	2524.3	468.4	1128.6	1370.3	1724.9
51	10.083	9.422	6.421	6.773	7.809	9.702
52	7.788	8.919	5.873	6.628	7.453	10.203
53	0.0820	0.0392	0.0857	0.0623	0.0172	0.0475
54	NA	2.000	NA	NA	NA	1.000

Table 55: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 56
Measured parameters in additional Sorghum accessions under drought growth conditions
	Line
Corr. ID	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1	64.246	70.802	64.110	75.677	72.095	87.168
2	0.678	0.807	0.788	0.731	0.741	0.831
3	0.326	0.329	0.364	0.377	0.469	0.625
4	15.432	13.299	17.877	20.239	18.706	17.951
5	67.460	112.580	82.793	100.459	122.877	86.267
6	4.570	4.959	4.994	5.560	7.292	4.721
7	19.614	30.763	20.985	23.992	24.820	24.418
8	0.8898	0.8835	0.8952	0.8974	0.8989	0.8889
9	0.1094	0.1019	0.1067	0.1162	0.1112	0.1205
10	9980	17494	14526	15729	10949	13808
11	19.098	29.216	31.744	40.213	25.228	29.520
12	0.235	0.325	0.335	0.342	0.222	0.223
13	9.324	19.286	33.147	27.315	24.680	50.380
14	0.127	0.171	0.203	0.244	0.160	0.151
15	0.445	0.480	0.544	0.524	0.462	0.348
16	1.139	1.002	1.181	1.113	1.294	0.851
17	0.0262	0.0353	0.0420	0.0503	0.0330	0.0312
18	NA	NA	NA	NA	NA	3.941
19	1476.2	1773.1	1052.7	1408.5	417.2	1247.1
20	37.469	41.242	36.471	36.994	36.767	35.942
21	36.248	36.507	35.011	36.304	35.798	36.509
22	1.748	1.691	2.375	1.615	1.516	2.031
23	2.381	1.705	1.660	1.641	2.362	1.598
24	10.872	10.357	11.277	10.702	10.715	9.678
25	7.507	7.544	8.754	8.340	4.525	7.762
26	2.818	4.038	4.750	4.725	3.292	7.664
27	3.115	4.123	4.313	5.742	3.530	5.896
28	17.195	14.904	13.322	14.525	13.772	17.270
29	17.228	20.037	15.979	16.879	16.951	19.561
30	17.001	16.372	13.722	14.666	14.041	19.479
31	68.685	114.581	94.240	104.215	125.804	87.375
32	4.624	5.019	5.571	5.702	7.385	4.774
33	19.901	31.121	22.157	24.362	25.333	24.757
34	68.333	63.000	56.000	59.667	56.000	76.667
35	92.0	92.0	92.0	92.0	92.0	107.0
36	47.823	80.917	93.427	104.146	75.804	105.625
37	0.924	1.441	1.598	1.869	1.328	1.895
38	71.703	66.866	68.615	68.248	70.701	76.334
39	47.579	44.665	51.921	48.835	40.021	37.598
40	42.919	30.929	43.686	37.805	38.415	32.486
41	128.668	132.895	138.516	133.257	78.293	47.343
42	387.650	582.067	985.592	834.958	753.417	54.162
43	81.209	129.775	241.650	322.917	257.033	127.167
44	1.471	1.806	2.118	1.792	2.073	NA
45	1.550	1.654	1.621	1.634	1.712	1.759
46	10.693	10.122	10.486	10.012	10.557	NA
47	4.609	5.182	5.392	5.399	2.975	5.529
48	25.773	50.091	46.845	46.875	44.250	NA
49	24.072	48.602	48.781	48.731	38.213	26.050
50	1507.8	2865.3	2857.9	2956.0	1964.3	1288.5
51	9.066	7.925	8.170	8.543	7.672	7.365
52	8.878	8.605	8.586	8.727	8.126	7.850
53	0.0378	0.0328	0.0326	0.0435	0.0613	0.0761
54	1.250	1.688	1.125	1.750	1.375	NA

Table 56: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Seed ID) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 57
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions across
Sorghum accessions
				Corr.
Gene			Exp.	Set	Gene			Exp.	Corr.
Name	R	P value	set	ID	Name	R	P value	set	Set ID
LBY14	0.79	3.45E−02	2	51	LBY14	0.72	1.09E−01	2	16
LBY14	0.72	1.21E−02	5	17	LBY14	0.72	1.21E−02	5	14
LBY14	0.79	7.04E−03	4	52	LBY14	0.81	2.75E−03	3	51
LBY14	0.73	1.00E−02	3	38	LBY14	0.84	1.73E−02	1	45
LBY148	0.73	6.17E−02	2	9	LBY148	0.84	1.81E−02	2	45
LBY148	0.70	1.18E−01	5	54	LBY148	0.74	9.43E−03	5	42
LBY148	0.77	9.16E−03	6	45	LBY148	0.83	2.82E−03	4	4
LBY148	0.77	9.25E−03	4	32	LBY148	0.80	5.26E−03	4	9
LBY148	0.72	1.23E−02	3	2	LBY148	0.73	6.24E−02	1	4
LBY148	0.84	1.89E−02	1	9	LBY148	0.84	1.94E−02	1	45
LBY148	0.73	6.03E−02	1	34	LBY149	0.83	2.09E−02	2	15
LBY149	0.80	3.08E−02	2	51	LBY149	0.83	2.09E−02	2	12
LBY149	0.84	1.70E−02	2	38	LBY149	0.79	3.43E−02	2	43
LBY149	0.90	5.93E−03	2	41	LBY149	0.81	2.58E−02	2	39
LBY149	0.84	2.23E−03	6	6	LBY149	0.75	1.26E−02	6	31
LBY149	0.72	1.94E−02	6	39	LBY149	0.77	8.48E−03	6	32
LBY149	0.82	4.60E−02	6	54	LBY149	0.78	8.19E−03	6	5
LBY149	0.71	2.06E−02	4	12	LBY149	0.80	5.32E−03	4	32
LBY149	0.81	2.70E−02	1	43	LBY149	0.79	6.40E−02	1	16
LBY149	0.91	4.03E−03	1	41	LBY149	0.96	6.80E−04	1	39
LBY150	0.76	4.76E−02	2	4	LBY150	0.73	1.76E−02	4	51
LBY150	0.75	5.00E−02	1	22	LBY150	0.83	2.00E−02	1	49
LBY151	0.71	2.22E−02	6	6	LBY151	0.93	6.40E−03	4	54
LBY151	0.75	7.89E−03	3	43	LBY151	0.81	5.10E−02	3	48
LBY151	0.77	5.55E−03	3	49	LBY151	0.78	3.97E−02	1	6
LBY151	0.92	3.41E−03	1	37	LBY151	0.81	2.84E−02	1	7
LBY151	0.78	4.06E−02	1	27	LBY151	0.71	7.40E−02	1	31
LBY151	0.70	7.73E−02	1	33	LBY151	0.90	5.80E−03	1	3
LBY151	0.86	1.20E−02	1	53	LBY151	0.86	1.40E−02	1	9
LBY151	0.87	1.02E−02	1	26	LBY151	0.78	3.82E−02	1	1
LBY151	0.81	2.58E−02	1	5	LBY151	0.97	3.58E−04	1	34
LBY151	0.90	6.47E−03	1	36	LBY152	0.71	7.12E−02	2	10
LBY152	0.75	5.14E−02	2	52	LBY152	0.72	6.67E−02	2	11
LBY152	0.73	1.75E−02	5	16	LBY152	0.84	1.11E−03	5	42
LBY152	0.73	1.63E−02	4	43	LBY152	0.71	1.16E−01	4	54
LBY152	0.78	6.47E−02	4	48	LBY152	0.74	1.48E−02	4	49
LBY152	0.82	1.99E−03	3	38	LBY152	0.74	9.12E−03	3	43
LBY152	0.73	9.73E−02	3	48	LBY52	0.74	9.25E−03	3	49
LBY152	0.75	8.01E−03	3	42	LBY152	0.81	2.81E−02	1	28
LBY152	0.77	4.11E−02	1	51	LBY152	0.72	6.85E−02	1	45
LBY152	0.83	2.14E−02	1	19	LBY153	0.79	3.46E−02	2	20
LBY153	0.75	5.15E−02	2	13	LBY153	0.81	2.60E−03	5	51
LBY153	0.72	1.18E−02	5	41	LBY153	0.71	2.13E−02	6	45
LBY153	0.74	9.69E−03	3	19	LBY153	0.74	9.41E−03	3	30
LBY153	0.71	7.40E−02	1	29	LBY153	0.77	4.27E−02	1	40
LBY153	0.73	6.24E−02	1	49	LBY153	0.80	2.97E−02	1	35
LBY154	0.80	3.07E−02	2	53	LBY154	0.70	7.95E−02	2	9
LBY154	0.92	3.33E−03	2	45	LBY154	0.75	5.21E−02	2	1
LBY154	0.83	2.20E−02	2	34	LBY154	0.84	1.71E−02	2	35
LBY154	0.70	1.57E−02	5	7	LBY154	0.82	4.44E−02	6	54
LBY154	0.77	4.28E−02	1	4	LBY154	0.76	4.63E−02	1	53
LBY154	0.84	1.72E−02	1	9	LBY154	0.81	2.65E−02	1	45
LBY154	0.75	5.01E−02	1	1	LBY154	0.72	6.64E−02	1	34
LBY155	0.78	3.65E−02	2	4	LBY155	0.81	2.60E−02	2	37
LBY155	0.78	3.78E−02	2	53	LBY155	0.73	6.21E−02	2	9
LBY155	0.82	2.44E−02	2	36	LBY155	0.82	3.75E−03	6	51
LBY155	0.74	1.52E−02	6	41	LBY155	0.73	1.72E−02	4	51
LBY155	0.74	1.36E−02	4	43	LBY155	0.77	9.82E−03	4	41
LBY155	0.72	6.56E−02	1	51	LBY156	0.72	6.80E−02	2	9
LBY156	0.75	5.15E−02	2	45	LBY156	0.72	2.75E−02	6	16
LBY156	0.76	6.94E−03	3	8	LBY156	0.72	1.21E−02	3	10
LBY156	0.73	1.06E−02	3	15	LBY156	0.77	5.78E−03	3	51
LBY156	0.74	8.75E−03	3	52	LBY156	0.82	2.24E−03	3	12
LBY156	0.82	1.85E−03	3	50	LBY156	0.81	2.65E−03	3	17
LBY156	0.81	2.65E−03	3	14	LBY156	0.77	5.73E−03	3	11
LBY156	0.77	4.30E−02	1	9	LBY157	0.79	3.57E−02	2	51
LBY157	0.83	1.51E−03	5	25	LBY157	0.74	9.31E−02	5	54
LBY157	0.95	3.83E−03	5	48	LBY157	0.73	1.66E−02	4	39
LBY157	0.74	9.24E−02	3	54	LBY157	0.75	5.32E−02	1	28
LBY157	0.84	1.72E−02	1	45	LBY157	0.77	4.25E−02	1	35
LBY158	0.79	3.57E−02	2	37	LBY158	0.73	6.12E−02	2	27
LBY158	0.76	4.82E−02	2	3	LBY158	0.87	1.01E−02	2	53
LBY158	0.77	4.26E−02	2	9	LBY158	0.73	6.48E−02	2	26
LBY158	0.79	3.30E−02	2	45	LBY158	0.91	5.07E−03	2	1
LBY158	0.91	4.37E−03	2	34	LBY158	0.85	1.63E−02	2	36
LBY158	0.76	7.10E−03	5	26	LBY158	0.84	1.34E−03	5	45
LBY158	0.74	1.38E−02	6	35	LBY158	0.75	1.17E−02	4	28
LBY158	0.82	3.80E−03	4	45	LBY158	0.70	2.29E−02	4	35
LBY158	0.73	6.29E−02	1	37	LBY158	0.73	6.10E−02	1	7
LBY158	0.80	3.08E−02	1	3	LBY158	0.85	1.43E−02	1	53
LBY158	0.84	1.87E−02	1	9	LBY158	0.78	3.96E−02	1	1
LBY158	0.89	7.84E−03	1	34	LBY158	0.74	5.48E−02	1	36
LBY159	0.78	6.79E−02	5	54	LBY159	0.79	6.84E−03	4	29
LBY159	0.92	2.86E−03	1	28	LBY159	0.79	3.41E−02	1	45
LBY159	0.76	4.70E−02	1	35	LBY160	0.88	1.98E−02	5	48
LBY160	0.91	2.08E−04	4	8	LBY160	0.81	4.58E−03	4	15
LBY160	0.85	1.72E−03	4	12	LBY160	0.81	4.41E−03	4	17
LBY160	0.81	4.41E−03	4	14	LBY160	0.73	1.08E−02	3	8
LBY160	0.73	1.14E−02	3	51	LBY160	0.72	1.33E−02	3	52
LBY160	0.73	6.32E−02	1	51	LBY160	0.82	2.42E−02	1	21
LBY161	0.72	6.60E−02	2	8	LBY161	0.84	1.81E−02	2	10
LBY161	0.81	2.58E−02	2	50	LBY161	0.81	2.63E−02	2	17
LBY161	0.81	2.63E−02	2	14	LBY161	0.74	5.93E−02	2	11
LBY161	0.73	6.38E−02	2	13	LBY161	0.71	7.60E−02	2	49
LBY161	0.89	7.83E−03	2	19	LBY161	0.71	7.38E−02	2	42
LBY161	0.79	3.80E−03	5	50	LBY161	0.79	6.38E−02	5	48
LBY161	0.85	1.00E−03	5	49	LBY161	0.74	1.50E−02	6	50
LBY161	0.78	5.06E−03	3	10	LBY161	0.81	2.39E−03	3	50
LBY161	0.79	3.97E−03	3	17	LBY161	0.79	3.97E−03	3	14
LBY161	0.75	8.35E−03	3	11	LBY161	0.79	3.62E−02	1	8
LBY161	0.74	5.73E−02	1	10	LBY161	0.82	2.41E−02	1	17
LBY161	0.82	2.41E−02	1	14	LBY161	0.85	1.46E−02	1	19
LBY162	0.85	1.56E−02	2	21	LBY162	0.82	2.49E−02	2	9
LBY162	0.90	6.36E−03	2	45	LBY162	0.76	6.16E−03	5	25
LBY162	0.70	7.76E−02	5	44	LBY162	0.88	2.14E−02	5	54
LBY162	0.91	1.21E−02	5	48	LBY162	0.72	1.27E−02	5	49
LBY162	0.73	1.03E−02	5	42	LBY162	0.88	7.46E−04	6	6
LBY162	0.83	2.81E−03	6	31	LBY162	0.88	8.20E−04	6	32
LBY162	0.82	3.57E−03	6	5	LBY162	0.83	5.69E−03	4	16
LBY162	0.74	1.40E−02	4	39	LBY162	0.78	6.64E−02	4	54
LBY162	0.80	5.39E−02	4	48	LBY162	0.73	1.62E−02	4	42
LBY162	0.77	5.57E−03	3	38	LBY162	0.75	7.29E−03	3	41
LBY162	0.70	1.55E−02	3	39	LBY162	0.72	1.32E−02	3	45
LBY162	0.78	4.29E−03	3	42	LBY162	0.71	7.61E−02	1	4
LBY162	0.72	6.91E−02	1	28	LBY162	0.78	3.67E−02	1	53
LBY162	0.90	6.08E−03	1	9	LBY162	0.81	2.75E−02	1	45
LBY162	0.81	2.60E−02	1	34	LBY162	0.86	1.27E−02	1	35
LBY162	0.81	2.76E−02	1	36	LBY163	0.73	6.25E−02	2	8
LBY163	0.80	3.06E−02	2	10	LBY163	0.88	8.62E−03	2	22
LBY163	0.84	1.85E−02	5	44	LBY163	0.96	2.33E−03	5	48
LBY163	0.76	8.10E−02	6	54	LBY163	0.77	5.58E−03	3	50
LBY163	0.94	5.88E−03	3	48	LBY163	0.86	7.81E−04	3	49
LBY163	0.74	5.82E−02	1	4	LBY163	0.75	5.36E−02	1	6
LBY163	0.81	2.67E−02	1	37	LBY163	0.73	6.38E−02	1	27
LBY163	0.72	7.01E−02	1	31	LBY163	0.76	4.92E−02	1	3
LBY163	0.76	4.88E−02	1	53	LBY163	0.92	3.71E−03	1	9
LBY163	0.81	2.56E−02	1	26	LBY163	0.86	1.32E−02	1	1
LBY163	0.75	5.01E−02	1	5	LBY163	0.84	1.67E−02	1	34
LBY163	0.81	2.68E−02	1	36	LBY164	0.79	3.34E−02	2	10
LBY164	0.93	2.48E−03	2	13	LBY164	0.78	7.35E−03	4	47
LBY164	0.72	1.08E−01	4	54	LBY164	0.76	8.26E−02	4	48
LBY164	0.73	1.63E−02	4	49	LBY164	0.90	3.42E−04	4	42
LBY164	0.79	4.01E−03	3	45	LBY164	0.85	1.67E−02	1	13
LBY165	0.83	2.14E−02	2	37	LBY165	0.90	5.61E−03	2	27
LBY165	0.79	3.28E−02	2	31	LBY165	0.72	6.87E−02	2	33
LBY165	0.94	1.75E−03	2	3	LBY165	0.78	3.89E−02	2	53
LBY165	0.87	1.06E−02	2	26	LBY165	0.81	2.58E−02	2	13
LBY165	0.79	3.57E−02	2	1	LBY165	0.78	3.66E−02	2	5
LBY165	0.74	5.53E−02	2	36	LBY165	0.70	1.63E−02	5	50
LBY165	0.80	5.60E−02	5	48	LBY165	0.82	2.03E−03	5	49
LBY165	0.74	9.17E−02	6	54	LBY165	0.79	6.38E−03	4	15
LBY165	0.70	2.35E−02	4	52	LBY165	0.71	2.12E−02	4	12
LBY165	0.85	1.78E−03	4	43	LBY165	0.90	1.57E−02	4	54
LBY165	0.84	2.31E−03	4	42	LBY165	0.86	5.95E−04	3	15
LBY165	0.74	8.72E−03	3	12	LBY165	0.76	7.01E−03	3	50
LBY165	0.77	6.06E−03	3	17	LBY165	0.77	6.06E−03	3	14
LBY165	0.77	4.35E−02	1	21	LBY165	0.73	6.18E−02	1	2
LBY166	0.72	6.53E−02	2	25	LBY166	0.76	4.53E−02	2	47
LBY166	0.80	3.26E−02	2	20	LBY166	0.73	1.10E−02	3	10
LBY166	0.81	2.29E−03	3	13	LBY166	0.79	3.41E−02	1	22
LBY166	0.78	3.69E−02	1	49	LBY167	0.78	3.86E−02	2	53
LBY167	0.76	4.67E−02	2	1	LBY167	0.71	7.30E−02	2	36
LBY167	0.87	1.15E−03	6	45	LBY167	0.84	2.45E−03	4	45
LBY167	0.78	5.01E−03	3	27	LBY167	0.85	9.04E−04	3	26
LBY167	0.75	8.05E−03	3	45	LBY167	0.71	7.21E−02	1	20
LBY167	0.72	6.98E−02	1	53	LBY167	0.75	5.32E−02	1	40
LBY167	0.92	3.22E−03	1	35	LBY168	0.77	4.48E−02	2	25
LBY168	0.86	1.25E−02	2	15	LBY168	0.84	1.77E−02	2	51
LBY168	0.84	1.81E−02	2	12	LBY168	0.89	7.57E−03	2	38
LBY168	0.82	2.43E−02	2	43	LBY168	0.91	4.63E−03	2	41
LBY168	0.85	1.43E−02	2	39	LBY168	0.91	4.06E−03	2	49
LBY168	0.91	1.24E−02	5	48	LBY168	0.72	1.17E−02	5	45
LBY168	0.80	5.29E−03	6	8	LBY168	0.74	1.53E−02	6	10
LBY168	0.95	1.17E−03	6	46	LBY168	0.71	2.11E−02	6	50
LBY168	0.71	2.12E−02	6	17	LBY168	0.83	5.83E−03	6	16
LBY168	0.71	2.12E−02	6	14	LBY168	0.71	2.21E−02	4	15
LBY168	0.75	1.20E−02	4	43	LBY168	0.71	2.12E−02	4	41
LBY168	0.82	4.70E−02	4	54	LBY168	0.73	1.76E−02	4	9
LBY168	0.74	9.26E−02	4	48	LBY168	0.91	2.82E−04	4	42
LBY168	0.74	5.69E−02	1	52	LBY168	0.81	2.62E−02	1	22
LBY168	0.70	7.84E−02	1	17	LBY168	0.70	7.84E−02	1	14
LBY168	0.74	5.60E−02	1	11	LBY168	0.74	5.97E−02	1	40
LBY168	0.87	1.14E−02	1	13	LBY170	0.83	4.31E−02	2	16
LBY170	0.89	6.78E−03	2	45	LBY170	0.89	1.80E−02	5	48
LBY170	0.73	6.33E−02	1	45	LBY171	0.71	7.55E−02	2	53
LBY171	0.73	6.33E−02	2	9	LBY171	0.74	5.54E−02	2	45
LBY171	0.79	3.33E−02	2	19	LBY171	0.83	2.17E−02	2	34
LBY171	0.85	3.15E−02	5	54	LBY171	0.91	1.20E−02	6	48
LBY171	0.83	3.20E−03	6	45	LBY171	0.80	5.68E−03	4	6
LBY171	0.70	2.33E−02	4	27	LBY171	0.79	6.29E−03	4	31
LBY171	0.79	7.12E−03	4	32	LBY171	0.86	1.27E−03	4	3
LBY171	0.79	6.66E−03	4	53	LBY171	0.82	3.97E−03	4	26
LBY171	0.79	6.41E−03	4	1	LBY171	0.79	6.37E−03	4	34
LBY171	0.78	8.24E−03	4	5	LBY171	0.77	5.58E−03	3	3
LBY171	0.83	1.63E−03	3	53	LBY171	0.78	4.48E−03	3	26
LBY171	0.92	4.61E−05	3	1	LBY171	0.89	2.19E−04	3	34
LBY171	0.79	3.28E−02	1	28	LBY171	0.89	7.21E−03	1	53
LBY171	0.78	4.03E−02	1	45	LBY171	0.70	7.71E−02	1	1
LBY171	0.82	2.47E−02	1	34	LBY171	0.84	1.91E−02	1	35
LBY171	0.74	5.82E−02	1	30	LBY173	0.79	3.50E−02	2	10
LBY173	0.73	6.26E−02	2	37	LBY173	0.74	5.71E−02	2	3
LBY173	0.89	7.12E−03	2	53	LBY173	0.73	6.41E−02	2	13
LBY173	0.74	5.50E−02	2	45	LBY173	0.87	1.13E−02	2	1
LBY173	0.78	3.66E−02	2	19	LBY173	0.91	4.39E−03	2	34
LBY173	0.79	3.44E−02	2	36	LBY173	0.74	9.45E−03	5	3
LBY173	0.75	8.59E−02	5	54	LBY173	0.81	2.69E−03	5	13
LBY173	0.73	6.22E−02	6	46	LBY173	0.75	5.23E−02	6	44
LBY173	0.92	1.28E−04	6	13	LBY173	0.70	2.39E−02	6	19
LBY173	0.80	5.24E−03	4	10	LBY173	0.92	9.67E−03	4	54
LBY173	0.73	1.66E−02	4	11	LBY173	0.74	8.96E−03	3	27
LBY173	0.91	4.82E−03	3	44	LBY173	0.82	2.11E−03	3	26
LBY173	0.84	1.11E−03	3	45	LBY173	0.70	7.88E−02	1	10
LBY173	0.83	2.05E−02	1	53	LBY173	0.86	1.38E−02	1	13
LBY173	0.90	6.35E−03	1	1	LBY173	0.72	6.53E−02	1	34
LBY174	0.84	1.77E−02	9	9	LBY174	0.85	1.58E−02	5	44
LBY174	0.79	4.08E−03	5	13	LBY174	0.93	7.24E−03	5	48
LBY175	0.78	3.77E−02	2	25	LBY175	0.72	6.76E−02	2	47
LBY175	0.71	7.52E−02	1	25	LBY175	0.87	1.06E−02	1	47
LBY176	0.79	3.49E−02	2	8	LBY176	0.72	6.70E−02	2	17
LBY176	0.72	6.70E−02	2	14	LBY176	0.88	3.39E−04	5	3
LBY176	0.82	1.93E−03	5	53	LBY176	0.75	8.41E−03	5	1
LBY176	0.82	2.16E−03	5	34	LBY176	0.83	2.72E−03	6	53
LBY176	0.72	2.01E−02	6	35	LBY176	0.72	1.98E−02	4	43
LBY176	0.73	1.12E−02	3	23	LBY176	0.73	1.03E−02	3	27
LBY176	0.83	1.50E−03	3	26	LBY176	0.80	2.85E−03	3	45
LBY176	0.90	5.27E−03	1	49	LBY177	0.98	1.73E−04	2	10
LBY177	0.72	6.61E−02	2	17	LBY177	0.72	6.61E−02	2	14
LBY177	0.76	4.59E−02	2	11	LBY177	0.76	4.95E−02	2	13
LBY177	0.90	8.34E−04	6	16	LBY177	0.82	3.97E−03	6	41
LBY177	0.73	1.58E−02	6	39	LBY177	0.75	1.19E−02	6	45
LBY177	0.81	8.80E−03	4	16	LBY177	0.72	1.33E−02	3	8
LBY177	0.87	4.54E−04	3	15	LBY177	0.76	7.12E−03	3	12
LBY177	0.84	1.25E−03	3	38	LBY177	0.79	3.59E−03	3	50
LBY177	0.71	1.50E−02	3	43	LBY177	0.72	1.26E−02	3	17
LBY177	0.74	8.65E−03	3	41	LBY177	0.72	1.26E−02	3	14
LBY177	0.74	9.72E−03	3	42	LBY177	0.71	7.67E−02	1	28
LBY177	0.84	1.90E−02	1	37	LBY177	0.85	1.58E−02	1	27
LBY177	0.77	4.41E−02	1	53	LBY177	0.74	5.68E−02	1	9
LBY177	0.84	1.90E−02	1	26	LBY177	0.82	2.26E−02	1	45
LBY177	0.76	4.76E−02	1	1	LBY177	0.75	5.28E−02	1	19
LBY177	0.73	6.50E−02	1	34	LBY177	0.83	2.02E−02	1	36
LBY178	0.73	6.28E−02	2	10	LBY178	0.70	7.91E−02	2	28
LBY178	0.70	7.91E−02	2	52	LBY178	0.72	7.09E−02	2	50
LBY178	0.80	5.34E−02	2	16	LBY178	0.87	1.16E−02	2	45
LBY178	0.90	5.62E−03	2	49	LBY178	0.74	5.58E−02	2	19
LBY178	0.80	3.24E−02	2	34	LBY178	0.73	1.69E−02	6	8
LBY178	0.78	8.29E−03	6	6	LBY178	0.72	1.04E−01	6	48
LBY178	0.71	2.11E−02	4	15	LBY178	0.75	8.70E−02	4	48
LBY178	0.71	2.06E−02	4	19	LBY178	0.80	2.90E−03	3	8
LBY178	0.71	1.53E−02	3	21	LBY178	0.70	7.76E−02	1	8
LBY178	0.81	2.62E−02	1	51	LBY178	0.82	2.54E−02	1	49
LBY179	0.81	2.78E−02	2	9	LBY179	0.81	2.61E−02	2	45
LBY179	0.71	1.49E−02	5	25	LBY179	0.95	3.86E−03	5	48
LBY179	0.82	4.62E−02	6	54	LBY179	0.83	3.18E−03	4	3
LBY179	0.79	6.71E−03	4	53	LBY179	0.78	8.15E−03	4	1
LBY179	0.91	2.64E−04	4	34	LBY179	0.78	4.00E−02	1	45
LBY180	0.80	3.07E−02	2	3	LBY180	0.94	1.47E−03	2	53
LBY180	0.86	1.31E−02	2	1	LBY180	0.83	2.20E−02	2	34
LBY180	0.80	3.14E−02	2	35	LBY180	0.79	3.29E−02	2	30
LBY180	0.79	4.15E−03	5	22	LBY180	0.89	7.77E−03	5	44
LBY180	0.82	4.70E−02	5	48	LBY180	0.71	2.20E−02	6	23
LBY180	0.71	2.18E−02	4	53	LBY180	0.77	9.94E−03	4	13
LBY180	0.76	7.82E−02	4	48	LBY180	0.71	2.19E−02	4	19
LBY180	0.81	2.73E−02	1	28	LBY180	0.71	7.32E−02	1	3
LBY180	0.92	3.78E−03	1	53	LBY180	0.76	4.97E−02	1	1
LBY180	0.81	2.64E−02	1	19	LBY180	0.78	3.98E−02	1	34
LBY180	0.76	4.67E−02	1	35	LBY180	0.72	7.06E−02	1	36
LBY180	0.92	3.03E−03	1	30	LBY181	0.85	1.46E−02	2	8
LBY181	0.70	7.92E−02	2	10	LBY181	0.81	2.75E−02	2	17
LBY181	0.81	2.75E−02	2	14	LBY181	0.74	5.88E−02	2	13
LBY181	0.73	1.09E−02	5	25	LBY181	0.78	4.03E−02	5	46
LBY181	0.71	2.12E−02	6	51	LBY181	0.75	1.28E−02	3	16
LBY181	0.75	5.00E−02	1	29	LBY181	0.86	1.40E−02	1	40
LBY181	0.75	5.04E−02	1	35	LBY182	0.86	1.26E−02	2	28
LBY182	0.76	4.55E−02	2	45	LBY182	0.72	1.33E−02	5	20
LBY182	0.70	1.62E−02	5	53	LBY182	0.88	2.23E−02	5	48
LBY182	0.72	1.28E−02	5	45	LBY182	0.70	2.37E−02	6	37
LBY182	0.78	8.00E−03	6	3	LBY182	0.83	3.18E−03	6	53
LBY182	0.72	1.92E−02	6	11	LBY182	0.72	1.78E−02	6	26
LBY182	0.73	1.69E−02	6	1	LBY182	0.72	1.91E−02	6	36
LBY182	0.78	7.96E−03	4	53	LBY182	0.85	1.71E−03	4	9
LBY182	0.76	1.03E−02	4	45	LBY182	0.78	8.14E−03	4	1
LBY182	0.81	4.83E−03	4	34	LBY182	0.86	6.46E−04	3	45
LBY182	0.75	5.34E−02	1	47	LBY182	0.77	4.49E−02	1	20
LBY182	0.93	2.43E−03	1	35	LBY183	0.78	3.72E−02	2	6
LBY183	0.71	7.13E−02	2	27	LBY183	0.78	3.82E−02	2	31
LBY183	0.75	5.05E−02	2	32	LBY183	0.78	3.80E−02	2	5
LBY183	0.72	1.24E−02	5	22	LBY183	0.85	1.49E−02	5	44
LBY183	0.71	1.43E−02	5	26	LBY183	0.92	9.13E−03	5	48
LBY183	0.76	1.11E−02	4	13	LBY183	0.75	8.28E−02	4	48
LBY183	0.74	1.42E−02	4	30	LBY183	0.83	2.09E−02	1	4
LBY183	0.77	4.31E−02	1	6	LBY183	0.71	7.51E−02	1	37
LBY183	0.84	1.78E−02	1	27	LBY183	0.72	7.04E−02	1	32
LBY183	0.85	1.57E−02	1	9	LBY183	0.77	4.20E−02	1	26
LBY183	0.83	2.07E−02	1	45	LBY184	0.85	3.19E−02	2	16
LBY184	0.76	1.71E−02	6	16	LBY184	0.80	5.58E−03	4	19
LBY185	0.79	3.32E−02	2	45	LBY185	0.88	8.93E−04	5	16
LBY185	0.78	7.22E−03	6	50	LBY185	0.80	3.14E−03	3	42
LBY185	0.77	4.49E−02	1	4	LBY185	0.79	3.39E−02	1	9
LBY185	0.87	1.15E−02	1	45	LBY186	0.74	5.54E−02	2	45
LBY186	0.77	9.01E−03	6	38	LBY186	0.89	6.42E−04	6	6
LBY186	0.84	2.59E−03	6	31	LBY186	0.84	2.41E−03	6	32
LBY186	0.85	2.04E−03	6	5	LBY186	0.91	2.30E−04	4	15
LBY186	0.84	2.54E−03	4	12	LBY186	0.79	6.24E−03	4	38
LBY186	0.78	3.89E−02	4	44	LBY186	0.77	8.70E−03	4	43
LBY186	0.83	2.69E−03	4	41	LBY186	0.87	1.13E−03	4	39
LBY186	0.87	2.30E−02	4	48	LBY186	0.79	3.58E−03	3	15
LBY186	0.73	1.05E−02	3	12	LBY186	0.82	1.98E−03	3	43
LBY186	0.75	8.13E−03	3	41	LBY186	0.75	8.79E−02	3	48
LBY187	0.84	1.84E−02	2	8	LBY187	0.73	6.23E−02	2	10
LBY187	0.72	6.53E−02	2	50	LBY187	0.72	6.73E−02	2	17
LBY187	0.72	6.73E−02	2	14	LBY187	0.70	7.78E−02	2	49
LBY187	0.89	6.64E−04	6	45	LBY187	0.74	1.52E−02	6	34
LBY187	0.72	1.23E−02	3	10	LBY187	0.71	1.37E−02	3	15
LBY187	0.76	6.71E−03	3	12	LBY187	0.75	8.19E−03	3	50
LBY187	0.78	3.90E−02	1	22	LBY187	0.72	6.71E−02	1	49
LBY188	0.77	4.42E−02	2	8	LBY188	0.71	7.67E−02	2	39
LBY188	0.74	9.31E−02	5	54	LBY188	0.78	8.05E−03	6	8
LBY188	0.81	4.46E−03	4	19	LBY188	0.71	7.37E−02	1	8
LBY188	0.71	7.13E−02	1	49	LBY189	0.80	3.08E−02	2	8
LBY189	0.74	1.37E−02	6	53	LBY189	0.70	7.81E−02	3	46
LBY189	0.71	7.23E−02	3	44	LBY189	0.74	8.99E−03	3	13
LBY189	0.83	2.06E−02	1	10	LBY189	0.72	6.91E−02	1	22
LBY189	0.87	1.16E−02	1	13	LBY189	0.73	6.03E−02	1	30
LBY190	0.72	7.04E−02	2	27	LBY190	0.75	5.10E−02	2	3
LBY190	0.92	3.14E−03	2	13	LBY190	0.76	8.00E−02	5	54
LBY190	0.78	7.15E−03	4	28	LBY190	0.84	2.55E−03	4	45
LBY190	0.91	1.10E−04	3	6	LBY190	0.74	9.33E−03	3	31
LBY190	0.90	1.88E−04	3	32	LBY190	0.75	7.88E−03	3	5
LBY191	0.79	3.64E−02	2	52	LBY191	0.75	5.26E−02	5	44
LBY191	0.82	4.57E−02	5	48	LBY191	0.76	1.05E−02	4	8
LBY191	0.71	2.10E−02	4	15	LBY191	0.83	2.70E−03	4	52
LBY191	0.82	4.02E−03	4	17	LBY191	0.82	4.02E−03	4	14
LBY191	0.74	1.45E−02	4	11	LBY191	0.84	1.32E−03	3	52
LBY191	0.70	1.64E−02	3	17	LBY191	0.70	1.64E−02	3	14
LBY191	0.79	3.51E−02	1	51	LBY192	0.70	7.84E−02	2	10
LBY192	0.92	3.39E−03	2	13	LBY192	0.74	1.46E−02	5	16
LBY192	0.88	2.24E−02	5	48	LBY192	0.73	1.56E−02	6	45
LBY192	0.82	3.39E−03	4	8	LBY192	0.73	1.71E−02	4	6
LBY192	0.74	1.52E−02	4	37	LBY192	0.84	2.11E−03	4	27
LBY192	0.80	5.58E−03	4	17	LBY192	0.71	2.15E−02	4	31
LBY192	0.80	5.58E−03	4	14	LBY192	0.84	2.15E−03	4	32
LBY192	0.71	2.07E−02	4	11	LBY192	0.82	3.34E−03	4	26
LBY192	0.76	4.59E−02	1	10	LBY192	0.86	1.20E−02	1	38
LBY192	0.89	7.81E−03	1	37	LBY192	0.88	9.35E−03	1	27
LBY192	0.70	7.91E−02	1	3	LBY192	0.79	3.63E−02	1	11
LBY192	0.86	1.27E−02	1	26	LBY192	0.86	1.38E−02	1	36
LGN3	0.85	1.46E−02	2	51	LGN3	0.71	7.59E−02	2	52
LGN3	0.77	4.49E−02	2	45	LGN3	0.80	2.94E−02	5	46
LGN3	0.79	3.59E−02	5	44	LGN3	0.79	3.65E−03	5	40
LGN3	0.73	1.62E−02	6	51	LGN3	0.73	1.57E−02	4	45
LGN3	0.74	8.56E−03	3	43	LGN3	0.73	1.01E−02	3	41
LGN3	0.72	1.33E−02	3	39	LGN3	0.71	7.45E−02	1	4
LGN3	0.74	5.94E−02	1	28	LGN3	0.92	3.11E−03	1	45
LGN3	0.74	5.53E−02	1	35	LGN5	0.93	2.78E−03	2	10
LGN5	0.77	4.43E−02	2	50	LGN5	0.71	7.23E−02	2	43
LGN5	0.70	7.72E−02	2	11	LGN5	0.77	4.41E−02	2	13
LGN5	0.73	6.33E−02	2	49	LGN5	0.72	6.68E−02	2	42
LGN5	0.70	1.59E−02	5	53	LGN5	0.79	3.68E−03	5	35
LGN5	0.83	5.88E−03	6	16	LGN5	0.82	3.90E−03	6	45
LGN5	0.70	2.32E−02	6	35	LGN5	0.81	4.78E−03	4	43
LGN5	0.76	1.08E−02	4	41	LGN5	0.78	8.41E−03	4	39
LGN5	0.94	5.85E−03	4	48	LGN5	0.79	6.58E−03	4	42
LGN5	0.93	2.31E−03	3	44	LGN5	0.72	1.06E−01	3	48
LGN5	0.76	4.70E−02	1	17	LGN5	0.76	4.70E−02	1	14
LGN5	0.85	1.65E−02	1	45	LGN54	0.71	7.25E−02	2	45
LGN54	0.89	7.01E−03	5	44	LGN54	0.90	1.48E−02	5	48
LGN54	0.72	1.97E−02	6	6	LGN54	0.70	2.35E−02	6	7
LGN54	0.74	1.46E−02	6	31	LGN54	0.81	4.71E−03	6	3
LGN54	0.78	7.66E−03	6	1	LGN54	0.78	7.88E−03	6	5
LGN54	0.74	1.54E−02	4	22	LGN54	0.77	4.38E−02	3	46
LGN54	0.76	4.60E−02	1	28	LGN54	0.75	5.05E−02	1	9
LGN54	0.94	1.97E−03	1	45	LGN57	0.76	4.91E−02	2	27
LGN57	0.91	4.02E−03	2	13	LGN57	0.81	2.57E−03	5	43
LGN57	0.77	7.17E−02	5	54	LGN57	0.86	6.84E−04	5	42
LGN57	0.71	2.10E−02	6	23	LGN57	0.80	3.07E−02	6	46
LGN57	0.96	5.21E−04	6	44	LGN57	0.74	1.53E−02	6	31
LGN57	0.73	1.61E−02	6	32	LGN57	0.71	2.23E−02	6	5
LGN57	0.77	8.75E−03	6	24	LGN57	0.74	1.44E−02	4	47
LGN57	0.82	3.66E−03	4	42	LGN57	0.71	1.38E−02	3	10
LGN57	0.72	6.92E−02	3	44	LGN57	0.79	3.43E−02	1	10
LGN57	0.70	7.71E−02	1	37	LGN57	0.89	6.48E−03	1	7
LGN57	0.85	1.66E−02	1	27	LGN57	0.74	5.98E−02	1	31
LGN57	0.88	8.19E−03	1	33	LGN57	0.84	1.87E−02	1	3
LGN57	0.73	6.36E−02	1	26	LGN57	0.90	6.07E−03	1	13
LGN57	0.80	3.20E−02	1	5	LGN6	0.73	6.12E−02	2	21
LGN6	0.85	1.56E−02	5	44	LGN6	0.77	7.16E−02	5	48
LGN6	0.81	4.23E−03	6	43	LGN6	0.87	1.18E−03	6	41
LGN6	0.85	1.80E−03	6	39	LGN7	0.81	2.74E−02	2	8
LGN7	0.85	1.62E−02	2	10	LGN7	0.90	6.27E−03	2	43
LGN7	0.72	7.05E−02	2	17	LGN7	0.79	3.27E−02	2	41
LGN7	0.72	7.05E−02	2	14	LGN7	0.83	2.21E−02	2	39
LGN7	0.79	3.46E−02	2	49	LGN7	0.75	5.45E−02	2	42
LGN7	0.77	4.32E−02	5	46	LGN7	0.77	5.71E−03	5	22
LGN7	0.80	3.06E−02	5	44	LGN7	0.76	7.11E−03	5	13
LGN7	0.74	1.43E−02	6	23	LGN7	0.74	5.48E−02	6	44
LGN7	0.86	2.80E−02	6	48	LGN7	0.81	4.33E−03	6	24
LGN7	0.79	3.43E−02	4	44	LGN7	0.73	1.73E−02	4	13
LGN7	0.83	2.03E−02	1	8	LGN7	0.72	6.67E−02	1	10
LGN7	0.76	4.84E−02	1	15	LGN7	0.79	3.54E−02	1	12
LGN7	0.81	2.65E−02	1	38	LGN7	0.71	7.46E−02	1	22
LGN7	0.73	6.20E−02	1	50	LGN7	0.79	3.61E−02	1	43
LGN7	0.79	3.40E−02	1	17	LGN7	0.87	2.55E−02	1	16
LGN7	0.88	8.71E−03	1	41	LGN7	0.79	3.40E−02	1	14
LGN7	0.79	3.44E−02	1	39	LGN7	0.71	7.11E−02	1	11
LGN7	0.72	7.08E−02	1	49

Table 57. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 52. “Exp. Set”—Expression set specified in Table 50. “R”=Pearson correlation coefficient; “P”=p value

TABLE 58
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under drought conditions across
Sorghum accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY14	0.71	1.52E−02	3	51	LBY14	0.79	3.46E−03	3	39
LBY148	0.74	2.31E−02	6	51	LBY148	0.70	1.59E−02	5	52
LBY148	0.79	3.60E−03	3	15	LBY148	0.85	9.14E−04	3	52
LBY148	0.74	5.49E−02	3	46	LBY148	0.90	1.75E−04	3	41
LBY148	0.79	3.64E−03	3	39	LBY148	0.83	1.64E−03	3	42
LBY149	0.86	5.63E−03	1	52	LBY149	0.70	5.27E−02	1	2
LBY149	0.70	7.96E−02	5	46	LBY149	0.75	7.97E−03	5	7
LBY149	0.73	1.00E−02	5	31	LBY149	0.76	6.35E−03	5	33
LBY149	0.72	1.04E−01	5	54	LBY149	0.80	3.07E−02	5	48
LBY149	0.74	9.12E−03	5	5	LBY149	0.70	1.62E−02	5	2
LBY149	0.90	1.57E−02	4	44	LBY149	0.89	6.65E−03	4	48
LBY149	0.71	1.52E−02	4	49	LBY149	0.83	1.63E−03	3	4
LBY149	0.77	5.98E−03	3	6	LBY149	0.74	8.55E−03	3	32
LBY149	0.75	8.22E−03	3	9	LBY149	0.71	1.39E−02	3	5
LBY150	0.93	7.82E−04	1	7	LBY150	0.78	2.38E−02	1	20
LBY150	0.92	1.25E−03	1	33	LBY150	0.72	1.04E−01	1	54
LBY150	0.83	2.08E−02	1	48	LBY150	0.77	2.63E−02	1	5
LBY150	0.79	2.09E−02	1	24	LBY150	0.83	5.40E−03	6	47
LBY150	0.84	3.86E−02	6	44	LBY150	0.82	6.19E−03	6	45
LBY150	0.85	4.09E−03	6	19	LBY150	0.76	6.94E−03	4	27
LBY150	0.79	3.79E−03	4	26	LBY150	0.72	1.33E−02	4	19
LBY150	0.75	7.61E−03	4	34	LBY150	0.77	5.56E−03	4	35
LBY150	0.86	7.81E−04	3	47	LBY150	0.72	1.16E−02	3	53
LBY150	0.95	6.42E−06	3	45	LBY150	0.74	9.71E−03	3	1
LBY150	0.71	1.39E−02	3	19	LBY150	0.89	2.72E−04	3	34
LBY150	0.90	1.79E−04	3	35	LBY150	0.70	5.30E−02	2	21
LBY151	0.79	1.06E−02	6	50	LBY151	0.72	2.86E−02	6	17
LBY151	0.73	2.50E−02	6	31	LBY151	0.72	2.86E−02	6	14
LBY151	0.72	6.74E−02	6	48	LBY151	0.82	6.38E−03	6	49
LBY151	0.76	1.77E−02	6	5	LBY151	0.77	5.18E−03	3	50
LBY151	0.72	4.23E−02	2	4	LBY151	0.77	2.52E−02	2	23
LBY151	0.78	2.13E−02	2	6	LBY151	0.77	2.46E−02	2	32
LBY152	0.80	1.81E−02	1	52	LBY152	0.78	4.74E−03	5	6
LBY152	0.78	4.49E−03	5	32	LBY152	0.79	4.08E−03	4	21
LBY152	0.71	1.53E−02	3	21	LBY152	0.70	1.20E−01	3	54
LBY153	0.86	6.38E−03	1	7	LBY153	0.75	8.41E−02	1	44
LBY153	0.80	1.66E−02	1	20	LBY153	0.86	5.86E−03	1	33
LBY153	0.70	1.20E−01	1	54	LBY153	0.92	3.37E−03	1	48
LBY153	0.85	7.37E−03	1	49	LBY153	0.71	3.35E−02	6	22
LBY153	0.76	1.65E−02	6	27	LBY153	0.91	7.69E−04	6	53
LBY153	0.80	9.94E−03	6	26	LBY153	0.81	8.80E−03	6	45
LBY153	0.77	1.44E−02	6	34	LBY153	0.80	1.02E−02	6	35
LBY153	0.77	5.75E−03	4	53	LBY153	0.80	3.38E−03	3	21
LBY153	0.70	1.65E−02	3	53	LBY153	0.74	9.35E−02	3	54
LBY154	0.70	5.19E−02	1	45	LBY154	0.76	2.87E−02	1	19
LBY154	0.72	6.79E−02	6	46	LBY154	0.75	2.09E−02	6	6
LBY154	0.86	2.74E−03	6	50	LBY154	0.80	9.86E−03	6	43
LBY154	0.71	3.36E−02	6	31	LBY154	0.76	3.02E−02	6	16
LBY154	0.83	6.19E−03	6	41	LBY154	0.89	1.83E−02	6	54
LBY154	0.75	5.08E−02	6	48	LBY154	0.81	8.74E−03	6	49
LBY154	0.89	1.34E−03	6	42	LBY154	0.77	5.15E−03	5	43
LBY154	0.88	1.78E−03	5	16	LBY154	0.71	1.13E−01	4	44
LBY154	0.71	1.47E−02	4	20	LBY154	0.70	1.59E−02	3	21
LBY154	0.74	9.32E−02	3	54	LBY154	0.79	3.47E−02	3	48
LBY154	0.72	4.46E−02	2	4	LBY154	0.71	4.64E−02	2	47
LBY154	0.87	2.44E−02	2	16	LBY154	0.75	3.04E−02	2	9
LBY154	0.82	1.34E−02	2	19	LBY155	0.72	4.33E−02	1	51
LBY155	0.71	4.71E−02	1	27	LBY155	0.70	5.09E−02	1	26
LBY155	0.72	4.61E−02	1	35	LBY155	0.73	1.01E−02	5	38
LBY155	0.76	6.13E−03	4	52	LBY155	0.80	3.32E−03	3	19
LBY155	0.86	6.10E−03	2	4	LBY155	0.75	3.27E−02	2	6
LBY155	0.81	1.45E−02	2	32	LBY155	0.85	8.02E−03	2	9
LBY156	0.71	4.81E−02	1	52	LBY156	0.78	6.65E−02	4	44
LBY156	0.73	1.07E−02	4	2	LBY156	0.83	1.52E−03	3	15
LBY156	0.88	3.52E−04	3	52	LBY156	0.76	6.98E−03	3	41
LBY156	0.71	1.53E−02	3	2	LBY157	0.75	3.22E−02	1	29
LBY157	0.80	1.65E−02	1	20	LBY157	0.78	1.40E−02	6	50
LBY157	0.86	2.84E−02	6	44	LBY157	0.71	3.25E−02	6	17
LBY157	0.71	3.13E−02	6	41	LBY157	0.71	3.25E−02	6	14
LBY157	0.92	4.22E−04	6	39	LBY157	0.76	1.66E−02	6	49
LBY157	0.84	4.78E−03	6	42	LBY157	0.74	2.14E−02	6	24
LBY157	0.79	3.75E−03	4	50	LBY157	0.93	6.34E−03	4	44
LBY157	0.70	1.64E−02	4	41	LBY157	0.89	7.85E−03	4	48
LBY157	0.77	6.06E−03	4	49	LBY157	0.78	5.00E−03	4	42
LBY157	0.75	7.51E−03	3	15	LBY157	0.70	7.92E−02	3	46
LBY157	0.80	3.36E−03	3	41	LBY157	0.78	4.69E−03	3	39
LBY157	0.85	9.19E−04	3	42	LBY157	0.74	3.67E−02	2	51
LBY157	0.96	2.56E−03	2	16	LBY157	0.75	3.28E−02	2	40
LBY158	0.77	2.63E−02	1	28	LBY158	0.78	2.12E−02	1	9
LBY158	0.84	9.79E−03	1	45	LBY158	0.89	3.13E−03	1	19
LBY158	0.93	8.62E−04	1	34	LBY158	0.79	1.85E−02	1	35
LBY158	0.76	2.93E−02	1	30	LBY158	0.81	7.60E−03	6	47
LBY158	0.78	1.23E−02	6	45	LBY158	0.88	1.77E−03	6	19
LBY158	0.96	2.70E−03	5	54	LBY158	0.78	4.82E−03	5	45
LBY158	0.95	6.52E−06	5	19	LBY158	0.75	8.13E−03	5	34
LBY158	0.74	9.14E−02	4	44	LBY158	0.76	6.79E−03	3	47
LBY158	0.75	8.15E−03	3	45	LBY158	0.75	7.84E−03	3	19
LBY158	0.70	5.14E−02	2	53	LBY158	0.77	4.22E−02	2	13
LBY158	0.91	1.66E−03	2	1	LBY159	0.72	4.28E−02	1	28
LBY159	0.74	3.65E−02	1	9	LBY159	0.83	1.00E−02	1	34
LBY159	0.75	2.07E−02	6	6	LBY159	0.70	3.41E−02	6	43
LBY159	0.71	3.08E−02	6	32	LBY159	0.79	1.07E−02	5	16
LBY159	0.80	5.50E−02	3	54	LBY159	0.71	2.27E−02	3	13
LBY159	0.88	3.91E−03	2	23	LBY160	0.86	3.19E−03	6	15
LBY160	0.76	1.81E−02	6	52	LBY160	0.78	1.41E−02	6	12
LBY160	0.91	4.47E−03	6	46	LBY160	0.73	2.60E−02	6	6
LBY160	0.88	1.54E−03	6	50	LBY160	0.76	7.73E−02	6	44
LBY160	0.79	1.21E−02	6	31	LBY160	0.86	3.16E−03	6	41
LBY160	0.73	2.41E−02	6	32	LBY160	0.75	5.26E−02	6	48
LBY160	0.81	7.85E−03	6	49	LBY160	0.74	2.13E−02	6	5
LBY160	0.86	3.01E−03	6	42	LBY160	0.71	3.12E−02	6	2
LBY160	0.89	1.15E−03	6	24	LBY160	0.82	1.90E−03	4	10
LBY160	0.75	8.22E−03	4	12	LBY160	0.72	1.29E−02	3	22
LBY160	0.76	6.75E−03	3	21	LBY161	0.80	1.67E−02	1	10
LBY161	0.81	4.97E−02	1	44	LBY161	0.75	3.29E−02	1	1
LBY161	0.80	9.86E−03	6	1	LBY161	0.78	4.29E−03	4	10
LBY161	0.82	2.08E−03	3	10	LBY161	0.73	1.00E−02	3	17
LBY161	0.73	1.00E−02	3	14	LBY161	0.71	1.40E−02	3	11
LBY161	0.86	5.58E−03	2	10	LBY161	0.77	2.60E−02	2	51
LBY161	0.73	4.15E−02	2	12	LBY161	0.71	4.85E−02	2	7
LBY161	0.71	4.73E−02	2	50	LBY161	0.78	2.20E−02	2	17
LBY161	0.78	2.20E−02	2	14	LBY161	0.74	3.69E−02	2	33
LBY161	0.87	4.65E−03	2	11	LBY162	0.78	2.33E−02	1	7
LBY162	0.76	2.83E−02	1	27	LBY162	0.77	2.46E−02	1	33
LBY162	0.83	4.12E−02	1	54	LBY162	0.71	4.83E−02	1	26
LBY162	0.74	5.97E−02	1	48	LBY162	0.77	2.55E−02	1	35
LBY162	0.83	1.72E−03	5	38	LBY162	0.75	8.05E−03	4	38
LBY162	0.75	7.85E−03	3	15	LBY162	0.74	9.60E−03	3	52
LBY162	0.84	1.81E−02	3	46	LBY162	0.86	7.16E−04	3	41
LBY163	0.78	3.70E−02	1	48	LBY163	0.75	2.12E−02	6	15
LBY163	0.91	5.00E−03	6	46	LBY163	0.71	3.13E−02	6	6
LBY163	0.84	4.85E−03	6	50	LBY163	0.71	4.79E−02	6	16
LBY163	0.85	3.56E−03	6	41	LBY163	0.71	1.13E−01	6	54
LBY163	0.72	6.67E−02	6	48	LBY163	0.77	1.45E−02	6	49
LBY163	0.91	6.26E−04	6	42	LBY163	0.70	3.52E−02	6	24
LBY163	0.73	1.01E−02	5	40	LBY163	0.74	9.03E−02	4	54
LBY163	0.84	1.70E−02	4	48	LBY163	0.85	8.21E−04	3	3
LBY163	0.88	8.95E−04	3	13	LBY163	0.83	1.12E−02	2	7
LBY163	0.91	1.55E−03	2	20	LBY163	0.81	1.46E−02	2	33
LBY163	0.82	1.33E−02	2	49	LBY164	0.79	2.02E−02	1	50
LBY164	0.80	5.36E−02	1	44	LBY164	0.81	2.84E−02	1	13
LBY164	0.87	1.07E−02	1	48	LBY164	0.88	4.30E−03	1	49
LBY164	0.80	1.60E−02	1	42	LBY164	0.74	3.44E−02	1	24
LBY164	0.79	1.07E−02	6	20	LBY164	0.71	3.32E−02	6	49
LBY164	0.85	8.49E−04	5	20	LBY164	0.73	1.05E−02	4	21
LBY164	0.71	1.38E−02	3	25	LBY164	0.72	1.17E−02	3	23
LBY164	0.75	7.75E−03	3	47	LBY164	0.74	9.12E−03	3	22
LBY164	0.73	1.12E−02	3	45	LBY164	0.84	8.80E−03	2	3
LBY164	0.93	2.70E−03	2	13	LBY165	0.78	1.28E−02	6	41
LBY165	0.72	2.97E−02	6	39	LBY165	0.75	2.04E−02	6	42
LBY165	0.82	6.80E−03	6	24	LBY165	0.74	8.66E−03	5	43
LBY165	0.79	3.82E−03	4	21	LBY165	0.73	1.11E−02	3	25
LBY165	0.80	3.33E−03	3	23	LBY165	0.78	2.34E−02	2	4
LBY165	0.77	2.46E−02	2	9	LBY166	0.76	2.71E−02	1	50
LBY166	0.91	1.27E−02	1	44	LBY166	0.91	4.69E−03	1	13
LBY166	0.98	1.43E−04	1	48	LBY166	0.93	7.15E−04	1	49
LBY166	0.72	1.98E−02	4	13	LBY166	0.74	8.67E−03	4	1
LBY166	0.71	1.50E−02	4	30	LBY166	0.79	3.99E−03	3	3
LBY166	0.78	7.39E−03	3	13	LBY166	0.74	3.56E−02	2	10
LBY166	0.74	3.39E−02	2	17	LBY166	0.72	4.46E−02	2	41
LBY166	0.74	3.39E−02	2	14	LBY166	0.88	3.74E−03	2	20
LBY166	0.74	3.62E−02	2	42	LBY167	0.76	1.76E−02	6	28
LBY167	0.81	7.70E−03	6	9	LBY167	0.75	2.09E−02	6	1
LBY167	0.85	3.55E−03	6	30	LBY167	0.76	6.88E−03	4	23
LBY167	0.78	4.35E−03	3	9	LBY167	0.81	2.53E−03	3	1
LBY167	0.79	3.94E−03	3	34	LBY167	0.72	1.29E−02	3	35
LBY167	0.94	5.26E−04	2	51	LBY167	0.90	2.25E−03	2	52
LBY167	0.70	5.23E−02	2	11	LBY168	0.80	1.75E−02	1	10
LBY168	0.77	2.66E−02	1	50	LBY168	0.96	2.74E−03	1	44
LBY168	0.74	3.49E−02	1	43	LBY168	0.79	2.08E−02	1	17
LBY168	0.79	2.08E−02	1	14	LBY168	0.75	5.19E−02	1	13
LBY168	0.74	5.62E−02	1	48	LBY168	0.78	2.17E−02	1	49
LBY168	0.81	1.37E−02	1	42	LBY168	0.75	3.11E−02	1	24
LBY168	0.77	1.58E−02	6	38	LBY168	0.71	3.30E−02	6	7
LBY168	0.84	4.64E−03	6	20	LBY168	0.72	2.89E−02	6	33
LBY168	0.90	8.49E−04	6	3	LBY168	0.79	1.20E−02	6	9
LBY168	0.72	2.99E−02	6	30	LBY168	0.73	1.13E−02	5	8
LBY168	0.78	4.38E−03	5	47	LBY168	0.74	9.46E−03	5	22
LBY168	0.91	1.10E−02	5	44	LBY168	0.81	2.70E−03	5	17
LBY168	0.81	2.70E−03	5	14	LBY168	0.74	8.90E−03	5	53
LBY168	0.85	9.11E−04	5	45	LBY168	0.71	1.34E−02	5	49
LBY168	0.86	7.91E−04	4	21	LBY168	0.79	3.80E−03	3	20
LBY168	0.74	3.67E−02	2	41	LBY168	0.72	4.24E−02	2	39
LBY168	0.80	1.65E−02	2	53	LBY170	0.81	5.27E−02	2	16
LBY170	0.79	1.96E−02	2	19	LBY171	0.74	2.27E−02	5	16
LBY171	0.85	3.40E−02	4	44	LBY171	0.74	9.57E−03	1	41
LBY171	0.75	8.36E−02	2	16	LBY171	0.79	2.08E−02	2	19
LBY173	0.70	5.32E−02	1	27	LBY173	0.79	2.04E−02	1	26
LBY173	0.72	2.81E−02	6	25	LBY173	0.70	3.45E−02	6	17
LBY173	0.70	3.45E−02	6	14	LBY173	0.73	2.49E−02	6	39
LBY173	0.81	8.66E−03	6	20	LBY173	0.73	2.62E−02	6	24
LBY173	0.81	2.64E−03	5	43	LBY173	0.71	3.09E−02	5	16
LBY173	0.85	3.23E−02	5	54	LBY173	0.79	3.26E−02	4	46
LBY173	0.76	6.57E−03	4	27	LBY173	0.74	9.24E−03	4	20
LBY173	0.71	1.48E−02	4	26	LBY173	0.82	2.09E−03	3	53
LBY173	0.85	3.03E−02	3	54	LBY173	0.79	4.04E−03	3	35
LBY173	0.81	1.51E−02	2	4	LBY173	0.88	4.23E−03	2	6
LBY173	0.83	1.00E−02	9	31	LBY173	0.89	2.78E−03	2	32
LBY173	0.83	9.92E−03	2	9	LBY173	0.71	4.80E−02	2	1
LBY173	0.81	1.59E−02	2	5	LBY173	0.78	2.20E−02	2	34
LBY173	0.72	4.30E−02	2	35	LBY174	0.78	1.36E−02	6	2
LBY174	0.74	2.28E−02	5	16	LBY174	0.72	1.25E−02	3	8
LBY174	0.72	1.29E−02	3	15	LBY174	0.71	1.51E−02	3	52
LBY174	0.73	1.09E−02	3	50	LBY174	0.73	1.12E−02	3	41
LBY174	0.74	9.56E−03	3	42	LBY174	0.76	7.16E−03	3	24
LBY175	0.95	4.42E−03	1	54	LBY175	0.77	4.23E−02	1	48
LBY175	0.72	4.37E−02	1	49	LBY175	0.76	2.87E−02	2	47
LBY175	0.74	3.75E−02	2	19	LBY176	0.78	1.41E−02	6	28
LBY176	0.78	1.40E−02	6	47	LBY176	0.74	2.29E−02	6	45
LBY176	0.80	9.86E−03	6	19	LBY176	0.76	1.80E−02	6	30
LBY176	0.72	1.17E−02	5	38	LBY176	0.77	5.31E−03	4	27
LBY176	0.79	3.71E−03	4	26	LBY176	0.77	6.07E−03	4	45
LBY176	0.72	1.23E−02	4	19	LBY176	0.86	7.70E−04	4	34
LBY176	0.79	4.03E−03	4	35	LBY176	0.88	3.94E−04	3	53
LBY176	0.71	2.02E−02	3	13	LBY176	0.88	3.40E−04	3	45
LBY176	0.75	7.40E−03	3	1	LBY176	0.80	3.01E−03	3	34
LBY176	0.86	6.68E−04	3	35	LBY176	0.74	3.52E−02	2	3
LBY176	0.84	1.93E−02	2	13	LBY177	0.76	7.95E−02	1	16
LBY177	0.76	2.84E−02	1	53	LBY177	0.78	2.13E−02	6	16
LBY177	0.73	2.50E−02	6	34	LBY177	0.75	2.03E−02	6	35
LBY177	0.76	6.48E−03	4	43	LBY177	0.75	2.03E−02	4	16
LBY177	0.79	6.23E−02	4	54	LBY177	0.71	1.36E−02	3	29
LBY177	0.71	1.15E−01	3	54	LBY177	0.71	1.36E−02	3	2
LBY177	0.84	9.30E−03	2	21	LBY178	0.71	4.93E−02	1	53
LBY178	0.97	1.45E−03	6	44	LBY178	0.71	7.45E−02	6	48
LBY178	0.75	1.99E−02	6	49	LBY178	0.71	1.45E−02	5	29
LBY178	0.86	7.32E−04	5	20	LBY178	0.77	6.02E−03	5	21
LBY178	0.71	1.47E−02	4	40	LBY178	0.77	5.39E−03	3	10
LBY178	0.72	1.31E−02	3	22	LBY178	0.72	1.16E−02	3	17
LBY178	0.72	1.16E−02	3	14	LBY178	0.73	1.04E−02	3	39
LBY178	0.93	7.82E−03	3	54	LBY178	0.74	3.62E−02	2	51
LBY178	0.71	1.12E−01	2	16	LBY178	0.78	2.28E−02	2	53
LBY179	0.76	2.74E−02	1	9	LBY179	0.71	4.72E−02	1	26
LBY179	0.88	4.38E−03	1	45	LBY179	0.86	5.68E−03	1	1
LBY179	0.87	4.58E−03	1	19	LBY179	0.78	2.23E−02	1	34
LBY179	0.93	9.05E−04	1	35	LBY179	0.93	7.16E−03	3	44
LBY179	0.72	1.32E−02	3	11	LBY180	0.73	3.81E−02	1	4
LBY180	0.71	5.04E−02	1	47	LBY180	0.89	3.21E−03	1	9
LBY180	0.91	1.98E−03	1	45	LBY180	0.81	1.56E−02	1	1
LBY180	0.90	2.61E−03	1	19	LBY180	0.92	1.07E−03	1	34
LBY180	0.97	4.05E−05	1	35	LBY180	0.89	1.44E−03	6	38
LBY180	0.71	3.31E−02	6	27	LBY180	0.71	1.38E−02	4	12
LBY180	0.73	1.05E−02	4	7	LBY180	0.74	9.68E−03	4	31
LBY180	0.71	1.44E−02	4	20	LBY180	0.74	9.69E−03	4	33
LBY180	0.82	2.35E−02	4	48	LBY180	0.77	5.53E−03	4	49
LBY180	0.74	8.82E−03	4	5	LBY180	0.71	1.45E−02	3	25
LBY180	0.80	3.30E−03	3	23	LBY180	0.71	1.39E−02	3	9
LBY180	0.75	3.22E−02	2	4	LBY180	0.76	2.98E−02	2	25
LBY180	0.75	3.33E−02	2	23	LBY180	0.74	3.66E−02	2	9
LBY180	0.84	8.94E−03	2	34	LBY181	0.71	4.92E−02	1	39
LBY181	0.96	1.36E−04	1	40	LBY181	0.83	1.65E−03	5	53
LBY181	0.73	1.14E−02	5	45	LBY181	0.72	1.25E−02	5	1
LBY181	0.71	1.47E−02	5	35	LBY181	0.71	1.39E−02	3	45
LBY181	0.83	1.64E−03	3	19	LBY181	0.79	3.65E−03	3	34
LBY181	0.85	7.30E−03	2	28	LBY181	0.86	6.00E−03	2	40
LBY181	0.74	3.62E−02	2	30	LBY182	0.95	3.69E−04	1	29
LBY182	0.85	7.75E−03	1	20	LBY182	0.86	2.69E−02	1	54
LBY182	0.85	3.96E−03	6	47	LBY182	0.76	1.87E−02	6	27
LBY182	0.89	1.78E−02	6	44	LBY182	0.79	1.17E−02	6	53
LBY182	0.74	2.14E−02	6	26	LBY182	0.92	5.34E−04	6	45
LBY182	0.84	4.27E−03	6	19	LBY182	0.76	1.81E−02	6	34
LBY182	0.74	2.16E−02	6	35	LBY182	0.79	3.95E−03	4	19
LBY182	0.74	9.19E−02	3	44	LBY183	0.78	2.33E−02	1	27
LBY183	0.78	2.21E−02	1	26	LBY183	0.82	6.89E−03	6	38
LBY183	0.79	1.04E−02	6	27	LBY183	0.82	7.05E−03	6	26
LBY183	0.73	6.06E−02	3	46	LBY183	0.80	3.43E−03	3	41
LBY183	0.82	1.25E−02	2	27	LBY183	0.86	6.42E−03	2	26
LBY183	0.78	2.19E−02	2	34	LBY183	0.71	4.92E−02	2	35
LBY184	0.87	5.19E−03	1	53	LBY184	0.72	1.25E−02	5	42
LBY184	0.80	3.29E−03	4	53	LBY184	0.83	1.56E−03	3	15
LBY184	0.86	1.41E−02	3	46	LBY184	0.85	9.88E−04	3	50
LBY184	0.92	5.33E−05	3	41	LBY184	0.79	4.00E−03	3	39
LBY184	0.73	6.43E−02	3	48	LBY184	0.90	1.80E−04	3	42
LBY185	0.72	4.42E−02	1	45	LBY185	0.79	1.86E−02	1	19
LBY185	0.75	3.12E−02	1	35	LBY185	0.77	4.10E−02	6	46
LBY185	0.76	1.86E−02	6	38	LBY185	0.70	1.56E−02	5	20
LBY185	0.78	4.72E−03	4	20	LBY186	0.79	1.98E−02	1	53
LBY186	0.83	9.91E−03	1	45	LBY186	0.83	1.12E−02	1	1
LBY186	0.78	2.38E−02	1	19	LBY186	0.88	4.41E−03	1	35
LBY186	0.72	2.76E−02	6	36	LBY186	0.77	1.49E−02	3	16
LBY186	0.73	4.02E−02	2	34	LBY186	0.77	2.69E−02	2	35
LBY187	0.74	3.55E−02	1	50	LBY187	0.70	7.74E−02	1	48
LBY187	0.74	3.64E−02	1	49	LBY187	0.76	2.81E−02	1	42
LBY187	0.72	2.76E−02	6	26	LBY187	0.75	1.92E−02	6	35
LBY187	0.72	1.20E−02	4	23	LBY187	0.72	1.28E−02	3	4
LBY187	0.72	1.30E−02	3	6	LBY187	0.73	1.15E−02	3	32
LBY188	0.88	3.94E−03	1	8	LBY188	0.73	4.02E−02	1	10
LBY188	0.80	5.36E−02	1	44	LBY188	0.87	4.68E−03	1	17
LBY188	0.87	4.68E−03	1	14	LBY188	0.72	4.43E−02	1	40
LBY188	0.73	6.05E−02	1	13	LBY188	0.86	5.58E−03	1	24
LBY188	0.71	3.33E−02	6	45	LBY188	0.76	1.75E−02	6	1
LBY188	0.72	2.77E−02	6	19	LBY188	0.80	5.69E−02	4	44
LBY188	0.83	2.13E−02	4	48	LBY188	0.74	9.54E−03	3	3
LBY188	0.77	8.80E−03	3	13	LBY188	0.79	4.11E−03	3	30
LBY188	0.75	3.34E−02	2	3	LBY188	0.77	4.33E−02	2	13
LBY189	0.74	2.17E−02	6	4	LBY189	0.83	5.86E−03	6	9
LBY189	0.75	8.77E−02	5	54	LBY189	0.77	5.62E−03	4	8
LBY189	0.78	8.05E−03	3	13	LBY189	0.71	4.78E−02	2	3
LBY189	0.85	1.56E−02	2	13	LBY190	0.71	5.07E−02	1	23
LBY190	0.96	1.10E−04	1	6	LBY190	0.83	1.15E−02	1	31
LBY190	0.89	3.09E−03	1	32	LBY190	0.84	9.33E−03	1	5
LBY190	0.75	1.97E−02	6	28	LBY190	0.82	7.39E−03	6	9
LBY190	0.75	2.02E−02	6	1	LBY190	0.80	9.52E−03	6	30
LBY190	0.72	1.23E−02	3	28	LBY190	0.79	3.98E−03	3	3
LBY190	0.81	4.78E−03	3	13	LBY190	0.78	4.59E−03	3	30
LBY190	0.87	4.70E−03	2	3	LBY190	0.98	5.75E−05	2	13
LBY191	0.75	3.13E−02	1	51	LBY191	0.82	1.34E−02	1	53
LBY191	0.72	4.31E−02	1	45	LBY191	0.79	1.87E−02	1	1
LBY191	0.84	8.80E−03	1	35	LBY191	0.82	6.53E−03	6	38
LBY191	0.74	8.59E−03	4	10	LBY191	0.78	4.93E−03	4	20
LBY191	0.82	2.10E−03	3	52	LBY191	0.74	3.41E−02	2	4
LBY191	0.77	2.65E−02	2	9	LBY192	0.73	4.05E−02	1	43
LBY192	0.73	1.00E−01	1	54	LBY192	0.90	1.07E−03	6	38
LBY192	0.80	9.14E−03	6	27	LBY192	0.82	7.34E−03	6	26
LBY192	0.71	1.13E−01	5	44	LBY192	0.76	6.75E−03	3	52
LBY192	0.82	1.99E−03	3	41	LBY192	0.74	8.87E−03	3	39
LBY192	0.74	3.75E−02	2	51	LGN3	0.88	3.72E−03	1	28
LGN3	0.73	4.03E−02	1	51	LGN3	0.86	6.27E−03	1	30
LGN3	0.76	1.64E−02	6	38	LGN3	0.88	1.52E−03	6	27
LGN3	0.82	6.21E−03	6	26	LGN3	0.72	1.30E−02	3	8
LGN3	0.75	8.03E−03	3	15	LGN3	0.71	1.50E−02	3	12
LGN3	0.76	7.20E−03	3	50	LGN3	0.89	1.72E−02	3	44
LGN3	0.73	1.09E−02	3	17	LGN3	0.80	3.06E−03	3	41
LGN3	0.73	1.09E−02	3	14	LGN3	0.82	1.88E−03	3	39
LGN3	0.85	8.72E−04	3	42	LGN3	0.77	2.55E−02	2	51
LGN4	0.71	4.97E−02	1	28	LGN4	0.71	1.50E−02	5	7
LGN4	0.70	1.56E−02	5	20	LGN4	0.70	1.62E−02	5	33
LGN4	0.70	1.62E−02	3	12	LGN4	0.77	5.28E−03	3	50
LGN4	0.99	1.78E−04	3	44	LGN4	0.75	7.88E−03	3	17
LGN4	0.75	7.88E−03	3	14	LGN4	0.79	3.56E−02	3	48
LGN4	0.81	2.41E−03	3	49	LGN4	0.76	6.50E−03	3	42
LGN4	0.85	7.50E−03	2	51	LGN5	0.71	1.43E−02	5	9
LGN5	0.76	6.50E−03	3	25	LGN5	0.73	1.14E−02	3	23
LGN5	0.79	4.19E−03	3	47	LGN5	0.74	9.07E−02	3	54
LGN5	0.73	1.11E−02	3	34	LGN5	0.76	2.98E−02	2	53
LGN5	0.75	5.24E−02	2	13	LGN54	0.80	1.78E−02	1	28
LGN54	0.76	2.84E−02	1	47	LGN54	0.85	7.90E−03	1	45
LGN54	0.87	5.22E−03	1	19	LGN54	0.73	3.90E−02	1	34
LGN54	0.86	6.68E−03	1	30	LGN54	0.85	9.63E−04	4	40
LGN54	0.77	5.29E−03	3	25	LGN54	0.84	1.26E−03	3	23
LGN54	0.77	2.62E−02	2	23	LGN57	0.92	1.15E−03	1	20
LGN57	0.76	4.97E−02	6	46	LGN57	0.74	2.31E−02	6	50
LGN57	0.74	2.25E−02	6	43	LGN57	0.92	1.16E−03	6	16
LGN57	0.86	2.78E−02	6	54	LGN57	0.72	6.69E−02	6	48
LGN57	0.72	3.02E−02	6	49	LGN57	0.83	5.69E−03	5	16
LGN57	0.71	1.53E−02	4	21	LGN57	0.78	4.74E−03	3	10
LGN57	0.73	1.06E−02	3	15	LGN57	0.82	2.25E−02	3	46
LGN57	0.73	1.16E−02	3	7	LGN57	0.74	9.12E−03	3	33
LGN57	0.71	1.36E−02	3	21	LGN57	0.93	2.55E−05	3	2
LGN57	0.76	2.80E−02	2	6	LGN57	0.77	2.55E−02	2	32
LGN57	0.74	3.57E−02	2	3	LGN6	0.82	4.74E−02	1	16
LGN6	0.75	8.38E−02	6	44	LGN6	0.83	1.16E−02	6	13
LGN6	0.79	4.21E−03	4	50	LGN6	0.79	6.37E−02	4	44
LGN6	0.85	9.65E−04	4	41	LGN6	0.84	1.36E−03	4	39
LGN6	0.73	6.14E−02	4	48	LGN6	0.73	1.03E−02	4	49
LGN6	0.89	2.77E−04	4	42	LGN6	0.76	6.16E−03	3	41
LGN6	0.78	4.71E−03	3	39	LGN6	0.84	1.32E−03	3	42
LGN7	0.80	1.72E−02	1	8	LGN7	0.94	5.46E−04	1	10
LGN7	0.83	1.16E−02	1	12	LGN7	0.76	2.78E−02	1	50
LGN7	0.87	2.36E−02	1	44	LGN7	0.84	8.42E−03	1	17
LGN7	0.84	8.42E−03	1	14	LGN7	0.73	3.82E−02	1	20
LGN7	0.75	5.39E−02	1	48	LGN7	0.76	2.92E−02	1	49
LGN7	0.79	3.47E−02	6	46	LGN7	0.78	6.89E−02	6	44
LGN7	0.73	2.60E−02	6	17	LGN7	0.73	2.60E−02	6	14
LGN7	0.72	2.84E−02	6	42	LGN7	0.74	9.91E−03	5	28
LGN7	0.72	1.29E−02	5	25	LGN7	0.75	8.48E−02	5	54
LGN7	0.72	1.97E−02	5	13	LGN7	0.73	1.11E−02	5	1
LGN7	0.88	3.35E−04	5	30	LGN7	0.74	9.26E−03	4	22
LGN7	0.71	1.40E−02	3	4	LGN7	0.72	1.29E−02	3	25
LGN7	0.72	1.23E−02	3	47

Table 58. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 52. “Exp. Set”—Expression set specified in Table 51. “R”=Pearson correlation coefficient; “P”=p value.

Example 9

Production of Sorghum Transcriptome and High Throughput Correlation Analysis with Yield, Drought and Lown Related Parameters Measured in Fields Using 65K Sorguhm Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a sorghum oligonucleotide micro-array, produced by Agilent Technologies [World Wide Web (dot) chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 65,000 sorghum genes and transcripts. In order to define correlations between the levels of RNA expression with ABST, drought, low N and yield components or vigor related parameters, various plant characteristics of 36 different sorghum inbreds and hybrids were analyzed under normal (regular) conditions, 35 sorghum lines were analyzed under drought conditions and 34 sorghum lines were analyzed under low N (nitrogen) conditions. All the lines were sent for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [World Wide Web (dot) davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

36 Sorghum varieties were grown in 5 repetitive plots, in field. Briefly, the growing protocol was as follows:

1. Regular growth conditions: sorghum plants were grown in the field using commercial fertilization and irrigation protocols, which include 549 m³ water per dunam (1000 square meters) per entire growth period and fertilization of 16 units of URAN® 21% (Nitrogen Fertilizer Solution; PCS Sales. Northbrook, Ill., USA) (normal growth conditions).

2. Drought conditions: sorghum seeds were sown in soil and grown under normal condition until vegetative stage (49 days from sowing), drought treatment was imposed by irrigating plants with approximately 60% of the water applied for the normal treatment [315 m³ water per dunam (1000 square meters) per entire growth period].

3. Low Nitrogen fertilization conditions: sorghum plants were sown in soil and irrigated with as the normal conditions (549 m³ water per dunam (1000 square meters) per entire growth period). No fertilization of nitrogen was applied, whereas other elements were fertilized as in the normal conditions.

Analyzed Sorghum tissues—All 36 Sorghum inbreds and hybrids were sample per each of the treatments. Tissues [Flag leaf and root] representing different plant characteristics, were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 59 below.

TABLE 59
Sorghum transcriptome expression sets in field experiment
Expression Set                   Set ID
Flag leaf at grain filling stage under normal conditions 1
Root at seedling stage under normal conditions 2
Flag leaf at grain filling stage under draught conditions 3
Flag leaf at grain filling stage Under low nitrogen conditions 4

Table 59: Provided are the sorghum transcriptome expression sets. Flag leaf=the leaf below the flower.

Sorghum yield components and vigor related parameters assessment—Plants were phenotyped as shown in Tables 60-61 below. Some of the following parameters were collected using digital imaging system:

Grains yield per dunam (kg)—At the end of the growing period all heads were collected (harvest). Heads were separately threshed and grains were weighted (grain yield). Grains yield per dunam was calculated by multiplying grain yield per m² by 1000 (dunam is 1000 m²).

Grains yield per plant (plot) (gr)—At the end of the growing period all heads were collected (harvest). Heads were separately threshed and grains were weighted (grain yield). The average grain weight per plant was calculated by dividing the grain yield by the number of plants per plot.

Grains yield per head (gr)—At the end of the growing period all heads were collected (harvest). Heads were separately threshed and grains were weighted (grain yield. Grains yield per head was calculated by dividing the grain yield by the number of heads.

Main head grains yield per plant (gr)—At the end of the growing period all plants were collected (harvest). Main heads were threshed and grains were weighted. Main head grains yield per plant was calculated by dividing the grain yield of the main heads by the number of plants.

Secondary heads grains yield per plant (gr)—At the end of the growing period all plants were collected (harvest). Secondary heads were threshed and grains were weighted. Secondary heads grain yield per plant was calculated by dividing the grain yield of the secondary heads by the number of plants.

Heads dry weight per dunam (kg)—At the end of the growing period heads of all plants were collected (harvest). Heads were weighted after oven dry (dry weight). Heads dry weight per dunam was calculated by multiplying grain yield per m² by 1000 (dunam is 1000 m²).

Average heads weight per plant at flowering (gr)—At flowering stage heads of 4 plants per plot were collected. Heads were weighted after oven dry (dry weight), and divided by the number of plants.

Leaf carbon isotope discrimination at harvest (%)—isotopic ratio of ¹³C to ¹²C in plant tissue was compared to the isotopic ratio of ¹³C to 12C in the atmosphere

Yield per dunam/water until maturity (kg/lit)—was calculated according to Formula XXXXII (above).

Vegetative dry weight per plant/water until maturity (gr/lit)—was calculated according to Formula XXXXIII above.

Total dry matter per plant at harvest/water until maturity (gr/lit)—was calculated according to Formula XXXXIV above.

Yield/SPAD at grain filling (kg/SPAD units) was calculated according to Formula XXXXVII above.

Grains number per dunam (num)—Grains yield per dunam divided by the average 1000 grain weight.

Grains per plant (num)—Grains yield per plant divided by the average 1000 grain weight.

Main head grains num per plant (num)—main head grain yield divided by the number of plants.

1000 grain weight (gr)—was calculated according to Formula XIV above.

Grain area (cm²)—At the end of the growing period the grains were separated from the head (harvest). A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Grain fill duration (num)—Duration of grain filling period was calculated by subtracting the number of days to flowering from the number of days to maturity.

Grain fill duration (GDD)—Duration of grain filling period according to the growing degree units (GDD) method. The accumulated GDD during the grain filling period was calculated by subtracting the Num days to Anthesis (GDD) from Num days to Maturity (GDD).

Yield per dunam filling rate (kg/day)—was calculated according to Formula XXXIX (using grain yield per dunam).

Yield per plant filling rate (gr/day)—was calculated according to Formula XXXIX (using grain yield per plant).

Head area (cm²)—At the end of the growing period (harvest) 6 plants main heads were photographed and images were processed using the below described image processing system. The head area was measured from those images and was divided by the number of plants.

Number days to flag leaf senescence (num)—the number of days from sowing till 50% of the plot arrives to Flag leaf senescence (above half of the leaves are yellow).

Number days to flag leaf senescence (GDD)—Number days to flag leaf senescence according to the growing degree units method. The accumulated GDD from sowing until flag leaf senescence.

% yellow leaves number at flowering (percentage)—At flowering stage, leaves of 4 plants per plot were collected. Yellow and green leaves were separately counted. Percent of yellow leaves at flowering was calculated for each plant by dividing yellow leaves number per plant by the overall number of leaves per plant and multiplying by 100.

% yellow leaves number at harvest (percentage)—At the end of the growing period (harvest) yellow and green leaves from 6 plants per plot were separately counted. Percent of the yellow leaves was calculated per each plant by dividing yellow leaves number per plant by the overall number of leaves per plant and multiplying by 100.

Leaf temperature at flowering (° celsius)—Leaf temperature was measured at flowering stage using Fluke IR thermometer 568 device. Measurements were done on 4 plants per plot on an open flag leaf.

Specific leaf area at flowering (cm²/gr)—was calculated according to Formula XXXVII above.

Flag leaf thickness at flowering (mm)—At the flowering stage, flag leaf thickness was measured for 4 plants per plot. Micrometer was used to measure the thickness of a flag leaf at an intermediate position between the border and the midrib.

Relative water content at flowering (percentage)—was calculated based on Formula I above.

Leaf water content at flowering (percentage)—was calculated based on Formula XXXXIX above.

Stem water content at flowering (percentage)—was calculated based on Formula XXXXVIII above.

Total heads per dunam at harvest (number)—At the end of the growing period the total number of heads per plot was counted (harvest). Total heads per dunam was calculated by multiplying heads number per m² by 1000 (dunam is 1000 m²).

Heads per plant (num)—At the end of the growing period total number of heads were counted and divided by the total number plants.

Tillering per plant (num)—Tillers of 6 plants per plot were counted at harvest stage and divided by the number of plants.

Harvest index (plot) (ratio)—The harvest index was calculated using Formula LVIII above.

Heads index (ratio)—Heads index was calculated using Formula XXXXVI above.

Total dry matter per plant at flowering (gr)—Total dry matter per plant was calculated at flowering. The vegetative portion above ground and all the heads dry weight of 4 plants per plot were summed and divided by the number of plants.

Total dry matter per plant (kg)—Total dry matter per plant at harvest was calculated by summing the average head dry weight and the average vegetative dry weight of 6 plants per plot.

Vegetative dry weight per plant at flowering (gr)—At the flowering stage, vegetative material (excluding roots) of 4 plants per plot were collected and weighted after (dry weight) oven dry. The biomass per plant was calculated by dividing total biomass by the number of plants.

Vegetative dry weight per plant (kg)—At the harvest stage, all vegetative material (excluding roots) were collected and weighted after (dry weight) oven dry.

Vegetative dry weight per plant was calculated by dividing the total biomass by the number of plants.

Plant height growth (cm/day)—The relative growth rate (RGR) of plant height was calculated based on Formula III above.

% Canopy coverage at flowering (percentage)—The % Canopy coverage at flowering was calculated based on Formula XXXII above.

PAR_LAI (Photosynthetic active radiance—Leaf area index)—Leaf area index values were determined using an AccuPAR Ceptometer Model LP-80 and measurements were performed at flowering stage with three measurements per plot.

Leaves area at flowering (cm²)—Green leaves area of 4 plants per plot was measured at flowering stage. Measurement was performed using a Leaf area-meter.

SPAD at vegetative stage (SPAD unit)—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at vegetative stage. SPAD meter readings were done on fully developed leaves of 4 plants per plot by performing three measurements per leaf per plant.

SPAD at flowering (SPAD unit)—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at flowering stage. SPAD meter readings were done on fully developed leaves of 4 plants per plot by performing three measurements per leaf per plant.

SPAD at grain filling (SPAD unit)—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at grain filling stage. SPAD meter readings were done on fully developed leaves of 4 plants per plot by performing three measurements per leaf per plant.

RUE (Radiation use efficiency)—(gr/% canopy coverage)—Total dry matter produced per intercepted PAR at flowering stage was calculated by dividing the average total dry matter per plant at flowering by the percent of canopy coverage.

Lower stem width at flowering (mm)—Lower stem width was measured at the flowering stage. Lower internodes from 4 plants per plot were separated from the plant and their diameter was measured using a caliber.

Upper stem width at flowering (mm)—Upper stem width was measured at flowering stage. Upper internodes from 4 plants per plot were separated from the plant and their diameter was measured using a caliber.

All stem volume at flowering (cm³)—was calculated based on Formula L above.

Number days to heading (num)—Number of days to heading was calculated as the number of days from sowing till 50% of the plot arrive heading.

Number days to heading (GDD)—Number days to heading according to the growing degree units method. The accumulated GDD from sowing until heading stage.

Number days to anthesis (num)—Number of days to flowering was calculated as the number of days from sowing till 50% of the plot arrive anthesis.

Number days to anthesis (GDD)—Number days to anthesis according to the growing degree units method. The accumulated GDD from sowing until anthesis stage.

Number days to maturity (GDD)—Number days to maturity according to the growing degree units method. The accumulated GDD from sowing until maturity stage.

N (Nitrogen) use efficiency (kg/kg)—was calculated based on Formula LI above.

Total NUtE—was calculated based on Formula LIII above.

Grain NUtE—was calculated based on Formula LV above.

NUpE (kg/kg)—was calculated based on Formula LII above.

N (Nitrogen) harvest index (Ratio)—was calculated based on Formula LVI above.

% N (Nitrogen) in shoot at flowering—% N content of dry matter in the shoot at flowering.

% N (Nitrogen) in head at flowering—% N content of dry matter in the head at flowering.

% N in (Nitrogen) shoot at harvest—% N content of dry matter in the shoot at harvest.

% N (Nitrogen) in grain at harvest—% N content of dry matter in the grain at harvest.

Data parameters collected are summarized in Tables 60-61 herein below.

TABLE 60
Sorghum correlated parameters under normal and low N conditions
(vectors)
Correlated parameter with        Correlation ID
% Canopy coverage (F) [%]        1
% yellow leaves number (F) [%]   2
% yellow leaves number (H) [%]   3
% N in grain (H) [%]             4
% N in head (F) [%]              5
% N in shoot (F) [%]             6
% N in shoot (H) [%]             7
1000 grain weight [gr.]          8
All stem volume (F) [cm3]        9
Average heads weight per plant (F) [gr.] 10
Flag Leaf thickness (F) [mm]     11
Grain N utilization efficiency [ratio] 12
Grain area [cm2]                 13
Grain fill duration [num]        14
Grain fill duration (GDD)        15
Grains yield per dunam [kg]      16
Grains yield per head (RP) [gr.] 17
Grains number per dunam [num]    18
Grains per plant (plot) [num]    19
Grains yield per plant (plot) [gr.] 20
Harvest index (plot) [ratio]     21
Head Area [cm2]                  22
Heads dry weight per dunam [kg]  23
Heads index (SP) [Ratio]         24
Heads per plant (RP) [num]       25
Leaf carbon isotope discrimination (H) (%) 26
Leaf temperature (F) [° C.]      27
Leaf water content (F) [%]       28
Leaves area (F) [cm2]            29
Lower Stem width (F) [mm]        30
Main head grains num per plant [num] 31
Main head grains yield per plant [gr] 32
N harvest index [ratio]          33
N use efficiency [ratio]         34
Number days to Anthesis [num]    35
Number days to Anthesis (GDD)    36
Number days to Flag leaf senescence [num] 37
Number days to Flag leaf senescence (GDD) 38
Number days to Heading (GDD)     39
Number days to Maturity (GDD)    40
NupE (H) [ratio]                 41
PAR_LAI (F) [μmol m−2 S−1]       42
Plant height growth [cm/day]     43
RUE [gr./% canopy coverage]      44
RWC (F) [%]                      45
SPAD (F) [SPAD unit]             46
SPAD (GF) [SPAD unit]            47
SPAD_(veg) [SPAD unit]           48
Secondary heads grains yield per plant [gr.] 49
Specific leaf area (F) [cm2/gr]  50
Stem water content (F) [%]       51
TDM (F)/water until flowering [gr./lit] 52
TDM (SP)/water until maturity [kg/lit] 53
Tillering per plant (SP) [number] 54
Total Heads per dunam (H) [number] 55
Total N utilization efficiency (H) [ratio] 56
Total dry matter per plant (F) [gr.] 57
Total dry matter per plant (SP) [kg] 58
Upper Stem width (F) [mm]        59
VDW (F)/water until flowering [gr./lit] 60
VDW (SP)/water until maturity [gr./lit] 61
Vegetative DW per plant (F) [gr.] 62
Vegetative DW per plant (RP) [kg] 63
Yield per dunam filling rate [kg/day] 64
Yield per dunam/water until maturity [kg/ml] 65
Yield per plant filling rate [gr./day] 66
Yield/SPAD (GF) [ratio]          67

Table 60. Provided are the Sorghum correlated parameters (vectors). “kg”=kilograms; “gr.”=grams; “RP”=Rest of plot; “SP”=Selected plants; “lit”=liter; “ml”—milliliter; “cm”=centimeter; “num”=number; “GDD”—Growing degree day; “SPAD”=chlorophyll levels; “FW”=Plant Fresh weight; “DW”=Plant Dry weight; “GF”=grain filling growth stage; “F”=flowering stage; “H”=harvest stage: “N”—Nitrogen; “NupE”—Nitrogen uptake efficiency; “VDW”=vegetative dry weight; “TDM”=Total dry matter. “RUE”=radiation use efficiency; “RWC” relative water content; “veg”=vegetative stage.

TABLE 61
Sorghum correlated parameters under drought conditions (vectors)
Correlated parameter with        Correlation ID
% Canopy coverage (F) [%]        1
% yellow leaves number (F) [%]   2
% yellow leaves number (H) [%]   3
1000 grain weight [gr.]          4
All stem volume (F) [cm3]        5
Average heads weight per plant (F) [gr.] 6
Flag Leaf thickness (F) [mm]     7
Grain area [cm2]                 8
Grain fill duration [number]     9
Grain fill duration (GDD)        10
Grains yield per dunam [kg]      11
Grains yield per head (RP) [gr.] 12
Grains number per dunam [number] 13
Grains per plant (plot) [number] 14
Grains yield per plant (plot) [gr.] 15
Harvest index (plot) [ratio]     16
Head Area [cm2]                  17
Heads dry weight per dunam [kg]  18
Heads index (SP) [ratio]         19
Heads per plant (RP) [number]    20
Leaf carbon isotope discrimination (H) (%) 21
Leaf temperature (F) [° C.]      22
Leaf water content (F) [%]       23
Leaves area (F) [cm2]            24
Lower Stem width (F) [mm]        25
Main head grains num per plant [num] 26
Main head grains yield per plant [gr.] 27
Number days to Anthesis [number] 28
Number days to Anthesis (GDD)    29
Number days to Flag leaf senescence [number] 30
Number days to Flag leaf senescence (GDD) 31
Number days to Heading (GDD)     32
Number days to Maturity (GDD)    33
PAR_LAI (F) [μmol m−2 S−1]       34
Plant height growth [cm/day]     35
RUE [gr./% canopy coverage]      36
RWC (F) [%]                      37
SPAD (F) [SPAD unit]             38
SPAD (GF) [SPAD unit]            39
SPAD_(veg) [SPAD unit]           40
Secondary heads grains yield per plant [gr.] 41
Specific leaf area (F) [cm2/gr.] 42
Stem water content (F) [%]       43
TDM (F)/water until flowering [gr./lit] 44
TDM (SP)/water until maturity [kg/lit] 45
Tillering per plant (SP) [number] 46
Total Heads per dunam (H) [number] 47
Total dry matter per plant (F) [gr.] 48
Total dry matter per plant (SP) [kg] 49
Upper Stem width (F) [mm]        50
VDW (F)/water until flowering [gr./lit] 51
VDW (SP)/water until maturity [gr./lit] 52
Vegetative DW per plant (F) [gr.] 53
Vegetative DW per plant (RP) [kg] 54
Yield per dunam filling rate [kg/day] 55
Yield per dunam/water until maturity [kg/ml] 56
Yield per plant filling rate [gr./day] 57
Yield/SPAD (GF) [ratio]          58

Table 61. Provided are the Sorghum correlated parameters (vectors). “kg”=kilograms; “gr.”=grams; “RP”=Rest of plot; “SP”=Selected plants; “lit”=liter; “ml”—milliliter; “cm”=centimeter; “num”=number; “GDD”—Growing degree day; “SPAD”=chlorophyll levels; “FW”=Plant Fresh weight; “DW”=Plant Dry weight; “GF”=grain filling growth stage; “F”=flowering stage; “H”=harvest stage; “N”—Nitrogen; “NupE”—Nitrogen uptake efficiency; “VDW”=vegetative dry weight; “TDM”=Total dry matter. “RUE”=radiation use efficiency; “RWC” relative water content; “veg”=vegetative stage.

Experimental Results

Thirty-six different sorghum inbreds and hybrids lines were grown and characterized for different parameters (Tables 60-61). The average for each of the measured parameter was calculated using the JMP software (Tables 62-76) and a subsequent correlation analysis was performed (Tables 77-79). Results were then integrated to the database.

TABLE 62
Measured parameters in Sorghum accessions under normal conditions
	L
Corr. ID	L-1	L-2	L-3	L-4	L-5	L-6	L-7
1	87.281	90.111	75.670	75.599	76.138	69.928	84.375
2	0.144	0.244	0.080	0.134	0.274	0.132	0.101
3	0.265	0.157	0.323	0.389	0.323	0.095	0.139
4	1.910	NA	1.621	2.086	NA	1.594	NA
5	2.315	NA	2.722	1.844	NA	1.970	NA
6	1.729	NA	1.414	1.303	NA	1.602	NA
7	1.080	NA	0.559	0.722	NA	1.112	NA
8	29.796	32.044	33.782	31.335	29.964	24.146	18.356
9	23261.2	19941.6	14878.4	31092.4	39294.6	13029.4	33015.4
10	17.005	17.720	9.727	10.183	37.679	11.140	11.271
11	0.179	0.144	0.144	0.164	0.127	0.186	0.138
12	18.510	NA	35.872	31.063	NA	30.945	NA
13	0.119	0.133	0.130	0.136	0.130	0.105	0.092
14	35.0	32.4	31.0	32.4	27.6	32.8	23.4
15	459.6	407.9	396.8	423.6	358.8	414.6	305.6
16	818.9	893.2	861.8	912.8	661.8	612.2	421.0
17	30.311	32.849	25.408	21.427	37.294	33.226	17.030
18	27117640	27702000	25021020	29202780	21264980	25132460	20308520
19	2766.2	3370.4	3162.2	4531.2	3464.5	3570.4	2267.5
20	77.2	103.5	100.8	130.3	100.3	72.4	43.5
21	0.225	0.271	0.281	0.335	0.271	0.306	0.126
22	134.403	96.685	112.799	101.680	106.065	84.074	105.631
23	1.046	1.062	0.956	1.010	0.797	0.768	0.747
24	0.345	0.399	0.393	0.453	0.384	0.536	0.344
25	1.125	1.306	1.712	2.280	1.144	1.151	1.287
26	−12.858	−13.200	−13.116	−12.834	−13.160	−13.047	−13.160
27	31.719	29.182	30.395	29.627	30.433	29.998	29.777
28	65.971	NA	74.090	71.840	63.293	77.500	70.016
29	16514.4	12058.4	12787.0	9932.2	11459.3	9116.4	9023.2
30	19.965	15.459	14.231	18.436	15.989	16.376	15.415
31	1322.3	1669.9	1615.1	1624.3	1784.3	1480.9	1008.7
32	38.221	53.811	55.644	51.041	53.356	35.979	19.751
33	0.354	NA	0.582	0.648	NA	0.493	NA
34	45.493	49.623	47.876	50.713	36.764	34.011	23.390
35	89.200	83.000	85.800	88.400	88.800	84.250	93.400
36	777.6	709.7	740.6	768.4	773.0	725.7	831.9
37	141.0	119.0	125.5	139.0	117.2	NA	126.8
38	1469.5	1165.8	1254.9	1441.2	1142.7	NA	1272.0
39	739.4	625.3	709.0	721.1	763.8	629.6	769.5
40	1237.2	1117.6	1137.4	1191.9	1131.7	1137.4	1137.4
41	1.913	NA	1.325	1.560	NA	1.101	NA
42	5.343	5.581	4.415	3.763	3.620	4.009	4.920
43	1.239	2.549	2.039	2.011	2.764	1.118	2.183
44	2.275	1.339	1.025	1.111	2.105	1.071	1.959
45	90.821	91.678	91.192	88.713	88.259	84.493	87.219
46	56.865	52.452	49.170	55.132	48.239	53.323	48.915
47	56.255	56.293	53.347	59.058	52.039	54.248	47.028
48	48.517	42.450	43.114	42.131	39.272	45.967	33.339
49	2.452	7.004	2.201	30.987	5.723	2.838	2.331
50	137.546	148.278	164.775	175.755	162.372	150.487	110.243
51	53.794	77.831	79.822	78.527	67.250	77.975	71.874
52	0.674	0.455	0.275	0.282	0.542	0.278	0.454
53	0.038	0.047	0.043	0.048	0.047	0.030	0.037
54	1.233	3.276	4.133	3.172	1.100	2.333	3.067
55	25950	25250	31350	37950	15918	16250	23200
56	91.317	NA	123.160	89.001	NA	93.670	NA
57	198.503	120.895	77.763	83.147	159.607	70.670	143.281
58	0.193	0.218	0.198	0.235	0.217	0.137	0.172
59	11.284	9.932	8.125	10.664	9.863	9.022	8.265
60	0.616	0.388	0.240	0.248	0.414	0.236	0.418
61	0.025	0.028	0.026	0.026	0.029	0.013	0.024
62	181.498	103.175	68.036	72.964	121.928	59.530	132.010
63	0.097	0.103	0.106	0.088	0.101	0.080	0.126
64	23.358	27.649	27.843	28.188	23.948	20.032	17.887
65	1.617	1.919	1.851	1.851	1.422	1.261	0.904
66	1.110	1.880	1.860	2.542	2.100	1.133	0.932
67	24.016	33.690	33.966	48.089	37.960	28.385	23.686

Table 62: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 63
Measured parameters in additional Sorghum accessions under normal conditions
	L
Corr. ID	L-8	L-9	L-10	L-11	L-12	L-13	L-14
1	NA	89.502	95.076	92.841	67.342	80.367	72.241
2	0.000	0.061	0.145	0.130	0.183	0.096	0.121
3	0.166	0.578	0.550	0.321	0.231	0.040	0.129
4	NA	1.796	NA	NA	NA	NA	NA
5	NA	1.369	NA	NA	NA	NA	NA
6	NA	1.795	NA	NA	NA	NA	NA
7	NA	1.151	NA	NA	NA	NA	NA
8	22.636	23.197	17.265	26.974	24.677	22.564	16.849
9	9480.2	21372.2	57928.1	42021.2	15340.9	10035.2	20685.1
10	6.766	11.973	22.375	35.695	8.805	10.347	23.983
11	NA	0.179	0.150	0.206	0.178	0.197	0.173
12	NA	26.691	NA	NA	NA	NA	NA
13	0.119	0.098	0.086	0.116	0.105	0.103	0.083
14	37.0	32.4	20.8	35.2	37.4	41.0	29.3
15	433.9	425.1	285.1	479.2	478.2	528.2	401.3
16	154.3	663.3	457.0	473.8	257.0	664.8	297.9
17	8.572	27.917	30.839	39.469	9.213	29.013	15.133
18	6938386	26620980	23566280	16059440	10047874	24969700	15586667
19	883.9	3870.3	3226.6	3209.9	1567.8	2899.6	3451.8
20	18.7	89.4	57.3	86.9	37.1	67.9	62.4
21	0.172	0.295	0.062	0.177	0.168	0.291	0.150
22	226.157	156.424	120.418	210.453	121.302	74.783	244.476
23	0.241	0.850	0.588	0.613	0.495	0.846	0.336
24	0.414	0.485	0.127	0.310	0.476	0.443	0.322
25	1.038	1.397	0.950	1.002	1.317	1.256	1.428
26	−13.473	−12.825	−12.990	−13.379	−12.587	−13.140	NA
27	NA	29.518	31.398	28.672	29.792	29.705	29.464
28	70.199	73.164	71.107	69.660	80.116	75.597	70.564
29	3520.4	12434.2	18050.2	16771.2	7915.8	8866.2	18167.7
30	9.303	20.503	21.948	22.635	17.902	13.734	24.669
31	450.1	1979.2	1582.7	1734.6	932.8	1362.5	2390.5
32	9.952	46.648	28.461	46.906	22.198	31.058	43.412
33	NA	0.479	NA	NA	NA	NA	NA
34	8.574	36.852	25.390	26.320	14.279	36.932	16.553
35	77.750	90.200	119.000	107.000	83.800	84.000	113.333
36	650.1	790.9	1167.9	1008.4	719.1	721.1	1091.8
37	112.6	148.8	149.3	152.2	148.7	121.3	152.0
38	1078.8	1581.4	1588.7	1630.5	1580.3	1198.4	1628.1
39	630.5	756.2	NA	945.3	621.2	663.5	945.3
40	1084.0	1216.0	1453.0	1487.6	1197.2	1122.6	1493.0
41	NA	1.527	NA	NA	NA	NA	NA
42	NA	6.036	7.090	3.898	2.935	4.595	2.359
43	2.839	0.820	1.486	1.199	1.106	1.199	0.616
44	NA	1.213	3.128	2.504	1.093	0.853	3.219
45	91.501	83.981	85.877	89.036	85.516	88.043	89.730
46	NA	57.607	53.649	59.822	50.902	54.497	58.942
47	60.127	59.927	50.535	58.642	51.887	52.722	57.114
48	48.864	45.617	39.567	43.694	45.175	42.747	36.967
49	0.107	4.372	0.215	NA	2.750	1.468	0.700
50	191.109	123.281	143.880	118.611	171.938	154.855	121.095
51	83.448	72.340	74.514	63.236	76.242	75.934	56.029
52	0.123	0.354	0.619	0.581	0.259	0.265	0.514
53	0.014	0.033	0.074	0.044	0.028	0.022	0.045
54	1.433	2.933	1.700	2.233	3.267	2.133	1.941
55	17500	22300	14750	11450	24700	21250	18694
56	NA	88.485	NA	NA	NA	NA	NA
57	26.001	108.460	292.856	232.745	72.540	68.447	233.233
58	0.060	0.170	0.415	0.248	0.132	0.107	0.252
59	7.777	9.952	7.341	11.882	9.938	9.195	9.462
60	0.092	0.316	0.589	0.492	0.228	0.224	0.461
61	0.008	0.017	0.064	0.031	0.015	0.012	0.031
62	19.236	96.488	278.538	197.050	63.735	58.100	209.250
63	0.033	0.074	0.474	0.178	0.058	0.078	0.126
64	3.968	20.500	21.872	13.193	6.880	19.827	10.751
65	0.321	1.311	0.811	0.841	0.515	1.386	0.529
66	0.279	1.579	1.391	1.358	0.669	0.855	1.507
67	7.545	35.974	32.965	29.782	20.168	26.248	42.091

Table 63: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 64
Measured parameters in additional Sorghum accessions under normal conditions
	L
Corr. ID	L-15	L-16	L-17	L-18	L-19	L-20	L-21
1	72.683	66.338	90.911	68.461	92.993	62.232	85.473
2	0.188	0.229	0.246	0.036	0.173	0.015	0.147
3	0.142	0.213	0.272	0.241	0.302	0.141	0.042
4	NA	NA	NA	NA	NA	NA	NA
5	NA	NA	NA	NA	NA	NA	NA
6	NA	NA	NA	NA	NA	NA	NA
7	NA	NA	NA	NA	NA	NA	NA
8	28.154	21.772	16.872	37.026	18.169	28.835	17.383
9	12649.4	15432.6	14500.7	26609.8	17621.5	13556.3	12018.1
10	9.566	14.145	7.660	24.738	24.100	13.475	16.594
11	0.169	0.195	0.144	0.209	0.162	0.204	0.189
12	NA	NA	NA	NA	NA	NA	NA
13	0.122	0.115	0.082	0.146	0.093	0.121	0.089
14	29.0	25.2	26.2	29.8	29.8	29.8	23.2
15	364.0	331.6	342.0	390.9	395.4	385.1	303.8
16	731.8	609.8	378.1	470.8	291.5	496.6	611.0
17	33.025	29.503	14.878	22.175	8.100	29.570	30.116
18	23737260	25534520	19319316	12802788	14629600	16643442	31788060
19	3187.1	3304.8	2184.2	2187.1	1951.8	2731.1	3818.6
20	88.0	72.9	39.1	76.0	37.0	75.9	67.5
21	0.324	0.322	0.187	0.179	0.110	0.351	0.264
22	82.036	106.139	129.335	86.311	83.329	114.026	90.007
23	0.860	0.762	0.646	0.602	0.619	0.523	0.717
24	0.472	0.519	0.302	0.326	0.278	0.508	0.350
25	1.092	0.995	1.238	1.530	2.057	1.029	1.125
26	−12.993	−12.733	−13.153	−13.293	−13.003	−13.193	−12.820
27	31.278	31.219	30.157	30.914	28.892	30.677	30.455
28	75.275	63.086	71.865	76.103	66.483	78.473	76.381
29	16019.6	20833.0	13190.4	16299.6	12096.8	11573.2	11655.8
30	16.079	20.902	16.868	22.274	16.304	19.221	19.066
31	1554.3	1950.9	993.2	848.9	686.6	1329.0	1808.6
32	43.158	43.208	17.962	31.778	12.954	37.849	32.471
33	NA	NA	NA	NA	NA	NA	NA
34	40.655	33.876	21.007	26.157	16.195	27.587	33.944
35	84.600	98.000	90.600	94.250	101.750	88.200	94.400
36	728.4	892.5	795.5	843.1	940.9	769.5	845.1
37	124.6	NA	NA	152.0	146.5	NA	137.0
38	1242.8	NA	NA	1628.1	1548.8	NA	1412.0
39	697.4	853.3	728.4	755.8	892.4	655.3	763.8
40	1092.4	1224.1	1137.4	1234.0	1336.3	1154.5	1148.8
41	NA	NA	NA	NA	NA	NA	NA
42	3.761	3.525	6.377	3.866	3.975	3.048	4.783
43	1.410	0.857	0.899	1.223	1.516	0.728	0.672
44	1.057	2.424	0.892	3.957	1.631	1.325	2.274
45	91.944	91.411	83.596	90.879	87.878	90.201	89.471
46	52.616	49.062	53.885	61.513	51.442	51.583	47.937
47	54.250	49.787	54.842	61.803	54.223	55.648	51.650
48	45.100	42.950	40.211	42.363	31.746	49.622	41.847
49	0.947	0.253	5.632	10.957	5.365	5.890	1.704
50	179.108	183.038	159.180	157.503	111.333	163.526	142.593
51	82.154	54.697	76.659	48.349	62.765	81.034	29.074
52	0.259	0.445	0.270	0.791	0.409	0.257	0.557
53	0.028	0.025	0.027	0.045	0.028	0.028	0.028
54	1.800	1.367	1.893	4.500	5.125	2.700	1.100
55	19607	18300	23150	22688	43348	14874	18626
56	NA	NA	NA	NA	NA	NA	NA
57	74.384	153.130	81.275	258.144	151.944	76.769	187.014
58	0.130	0.126	0.126	0.226	0.158	0.132	0.132
59	8.001	11.433	7.689	12.311	6.849	10.761	7.708
60	0.226	0.404	0.244	0.715	0.344	0.212	0.508
61	0.015	0.012	0.019	0.031	0.018	0.013	0.019
62	64.818	138.985	73.615	233.406	127.844	63.294	170.420
63	0.078	0.058	0.052	0.144	0.131	0.055	0.080
64	25.244	24.209	14.898	15.893	10.411	16.378	27.151
65	1.572	1.204	0.812	0.943	0.527	1.067	1.313
66	1.500	1.718	0.814	1.448	0.627	1.519	1.498
67	28.845	39.385	20.533	19.312	18.413	27.835	36.209

Table 64: Provided are the values of each of the parameters (as described above measured in Sorghum accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 65
Measured parameters in additional Sorghum accessions under normal conditions
L/
Corr. ID	L-22	L-23	L-24	L-25	L-26	L-27	L-28
1	76.025	92.104	88.446	62.175	54.728	94.411	57.550
2	0.043	0.125	0.245	0.128	0.114	0.327	0.077
3	0.059	0.413	0.788	0.188	0.152	0.635	0.139
4	NA	NA	1.542	1.604	NA	NA	NA
5	NA	NA	1.862	1.651	NA	NA	NA
6	NA	NA	0.795	1.293	NA	NA	NA
7	NA	NA	0.408	0.834	NA	NA	NA
8	21.378	27.975	27.046	28.951	20.937	29.442	22.508
9	8397.1	28819.2	52862.1	23299.4	8716.9	NA	18934.9
10	8.594	27.635	7.499	15.463	15.008	NA	20.314
11	NA	0.164	0.175	0.147	0.153	0.170	0.177
12	NA	NA	35.130	39.995	NA	NA	NA
13	0.103	0.129	0.116	0.129	0.103	0.125	0.112
14	40.6	35.7	25.0	31.6	33.0	20.4	28.6
15	500.3	476.6	343.1	415.1	423.7	268.2	363.8
16	307.6	221.0	685.9	792.0	449.8	626.1	497.1
17	13.291	8.403	37.595	48.252	25.124	31.626	30.856
18	13130962	6653443	23933120	24881460	19456260	19639820	21045320
19	2058.7	1109.8	3819.2	5346.8	2650.3	3204.7	3102.0
20	44.3	33.6	101.5	153.4	56.4	93.6	69.0
21	0.271	0.076	0.174	0.367	0.250	0.238	0.245
22	55.030	200.519	136.462	192.125	85.898	119.330	151.300
23	0.361	0.417	0.981	0.898	0.636	0.748	0.826
24	0.417	0.204	0.337	0.594	0.453	0.358	0.586
25	1.823	2.179	1.059	1.290	1.022	1.443	1.143
26	−12.720	−13.077	−12.408	−13.138	−12.827	−12.677	−13.003
27	28.560	29.173	28.565	29.963	31.465	31.661	31.462
28	NA	67.303	69.978	68.160	72.923	67.295	76.050
29	6785.6	14171.8	21989.2	13038.3	10639.6	NA	14682.2
30	14.975	20.277	21.868	18.888	18.942	23.163	21.965
31	756.2	573.1	2299.1	3152.2	1392.1	1579.3	1438.0
32	16.799	17.540	62.192	89.345	29.968	46.760	33.521
33	NA	NA	0.542	0.641	NA	NA	NA
34	17.088	12.280	38.105	43.998	24.989	34.782	27.619
35	74.400	106.000	115.200	89.600	85.400	102.000	86.200
36	611.9	996.2	1115.4	782.2	736.1	945.3	745.5
37	NA	148.6	143.0	132.0	NA	150.8	113.0
38	NA	1579.1	1498.6	1343.5	NA	1610.7	1084.0
39	530.3	945.3	945.3	740.6	693.3	879.3	709.0
40	1112.2	1472.8	1458.5	1197.3	1159.8	1213.4	1109.2
41	NA	NA	1.211	1.089	NA	NA	NA
42	3.564	4.343	3.259	2.881	2.377	7.275	2.811
43	0.971	1.152	1.116	1.598	0.782	0.972	0.872
44	0.665	3.191	3.362	2.569	1.450	NA	1.450
45	94.615	88.734	89.247	89.338	90.476	91.910	91.291
46	52.657	54.712	52.455	57.742	53.535	50.162	54.922
47	47.168	55.997	52.395	57.607	56.565	52.338	54.393
48	40.922	35.689	41.167	43.278	44.881	40.239	42.969
49	4.103	1.835	NA	5.049	1.249	NA	NA
50	166.853	108.385	139.894	164.925	164.415	NA	156.660
51	NA	57.267	68.469	53.460	79.583	NA	84.561
52	0.242	0.722	0.627	0.457	0.251	NA	0.277
53	0.015	0.044	0.053	0.049	0.025	0.035	0.026
54	3.500	4.833	1.000	1.200	2.067	1.200	1.000
55	22218	27333	15850	13893	16300	17150	14650
56	NA	NA	169.680	105.928	NA	NA	NA
57	49.924	292.635	293.874	134.600	70.658	NA	81.484
58	0.068	0.249	0.298	0.240	0.119	0.176	0.123
59	8.244	8.408	11.429	10.412	9.618	11.290	11.574
60	0.200	0.654	0.589	0.405	0.198	NA	0.208
61	0.008	0.036	0.035	0.020	0.014	0.022	0.011
62	41.331	265.000	276.375	119.138	55.650	NA	61.170
63	0.062	0.234	0.219	0.087	0.064	0.153	0.089
64	7.551	6.500	27.784	25.602	13.995	30.555	17.432
65	0.661	0.392	1.217	1.618	0.958	1.253	1.068
66	0.515	0.579	2.497	2.901	0.923	2.422	1.173
67	20.552	11.458	43.991	53.278	25.074	31.330	26.607

Table 65: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 66
Measured parameters in additional Sorghum accessions under normal conditions
L-29	L-30	L-31	L-32	L-33	L-34	L-35	L-36
85.797	88.767	92.567	87.286	81.636	90.129	66.243	82.308
0.090	0.127	0.300	0.171	0.033	0.087	0.240	0.131
0.000	0.018	0.168	0.256	0.117	0.148	0.226	0.263
NA	NA	1.841	NA	NA	1.557	NA	1.840
NA	NA	1.927	NA	NA	1.704	NA	2.047
NA	NA	1.324	NA	NA	1.235	NA	1.340
NA	NA	0.971	NA	NA	1.231	NA	0.631
25.949	28.407	26.752	21.833	25.432	23.457	22.609	28.331
14471.9	11682.4	12897.2	27195.9	18515.8	16533.5	14367.4	45771.7
14.808	12.239	9.899	29.627	37.964	17.009	18.987	24.612
NA	NA	NA	0.214	0.189	0.172	0.168	0.156
NA	NA	32.593	NA	NA	26.714	NA	19.842
0.110	0.120	0.111	0.102	0.111	0.109	0.104	0.116
42.5	42.5	40.2	26.8	32.5	30.0	31.4	33.4
525.9	525.9	493.6	352.0	425.1	394.9	413.3	438.2
693.9	663.0	668.8	861.9	904.6	757.3	874.2	653.2
35.499	35.632	29.956	55.999	52.706	46.218	48.680	27.175
25439325	22595225	23516220	35903040	35910300	30637940	37887500	22720400
3607.6	2713.3	3012.8	5869.7	5994.7	4733.1	4927.1	3710.2
91.9	74.1	80.3	130.1	122.6	108.7	112.8	99.9
0.358	0.345	0.316	0.284	0.312	0.307	0.308	0.135
115.146	141.714	99.027	174.094	245.323	194.992	180.424	136.020
0.816	0.810	0.845	1.027	1.014	0.968	1.139	0.787
0.545	0.583	0.549	0.466	0.556	0.464	0.472	0.223
1.152	1.124	1.215	1.060	1.142	1.100	1.000	1.458
−13.360	−13.000	−13.074	−12.850	NA	−12.561	−12.790	−13.138
28.573	29.033	28.020	30.095	30.456	30.082	30.047	30.042
NA	NA	NA	52.561	44.281	35.418	75.142	65.973
10885.3	9702.0	12009.2	20599.4	16039.3	17728.8	17360.8	15975.6
17.356	16.629	15.102	21.631	20.556	19.409	15.657	20.886
1964.2	1191.6	1513.4	2925.2	3386.4	2454.2	2247.4	2021.1
50.815	34.030	40.866	65.669	79.769	57.320	62.729	56.619
NA	NA	0.600	NA	NA	0.416	NA	0.365
38.550	36.836	37.154	47.882	50.257	42.075	48.569	36.288
74.000	74.000	74.000	94.000	88.500	93.000	90.000	92.000
607.3	607.3	607.3	840.0	769.5	826.7	786.8	814.0
NA	NA	NA	146.2	NA	NA	NA	141.3
NA	NA	NA	1544.8	NA	NA	NA	1473.8
563.9	537.3	591.0	769.5	715.1	756.1	756.1	768.4
1133.1	1133.1	1100.8	1191.9	1194.6	1221.5	1200.0	1252.2
NA	NA	1.259	NA	NA	1.475	NA	1.753
4.767	4.959	5.747	6.056	5.245	6.680	3.387	4.763
1.023	0.956	0.985	0.836	1.123	0.878	0.941	1.778
0.815	0.635	0.635	4.936	4.053	3.010	2.100	2.885
92.400	91.807	91.379	87.241	87.942	85.656	90.903	92.520
53.863	60.083	51.130	49.700	57.019	55.100	53.853	53.908
51.479	54.694	50.473	54.407	55.754	53.633	52.791	55.657
43.450	47.839	43.086	44.086	45.079	46.697	44.811	41.231
0.547	0.412	6.979	3.442	6.650	1.205	NA	7.502
173.345	151.866	167.177	104.022	82.278	66.905	172.576	131.264
NA	NA	NA	20.553	37.994	37.398	70.132	66.732
0.330	0.271	0.286	1.226	1.098	0.814	0.478	0.751
0.030	0.024	0.027	0.051	0.046	0.040	0.040	0.079
3.583	3.542	2.893	2.167	1.000	1.067	1.133	2.733
19875	17979	21600	14064	16583	15400	16500	21250
NA	NA	91.382	NA	NA	88.568	NA	129.502
68.156	56.023	59.009	403.078	323.425	264.537	140.877	231.139
0.141	0.110	0.128	0.250	0.227	0.198	0.198	0.397
10.101	8.910	8.771	10.075	11.503	8.806	8.564	10.101
0.258	0.212	0.238	1.136	0.969	0.761	0.414	0.672
0.014	0.012	0.013	0.027	0.020	0.022	0.021	0.061
53.348	43.784	49.111	373.451	285.461	247.528	121.890	206.527
0.056	0.062	0.074	0.128	0.072	0.083	0.083	0.283
16.317	15.588	16.523	32.231	27.382	25.113	27.842	20.006
1.491	1.424	1.437	1.744	1.811	1.516	1.773	1.289
1.198	0.805	1.121	2.499	2.397	1.923	2.014	1.840
37.987	21.984	32.670	54.300	58.941	46.085	50.530	39.929

Table 66: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section

TABLE 67
Measured parameters in Sorghum accessions under drought conditions
Line/
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	78.352	78.010	71.044	63.415	69.908	73.119	77.679
2	0.265	0.395	0.250	0.227	0.572	0.118	0.259
3	0.482	0.689	0.627	0.645	0.648	0.499	0.407
4	27.439	28.686	34.531	28.119	25.842	22.918	17.494
5	13008	13795	11883	22788	31653	9741	19460
6	17.990	13.835	9.456	12.471	25.544	9.745	9.906
7	0.150	0.131	0.144	0.134	0.131	0.187	0.109
8	0.117	0.126	0.135	0.130	0.122	0.103	0.092
9	31.8	32.2	32.0	31.6	25.4	32.6	23.4
10	415.250	404.350	403.300	409.850	330.450	408.850	306.550
11	539.551	494.005	653.565	568.314	358.361	474.717	364.646
12	29.007	16.979	17.260	22.347	22.506	35.358	15.765
13	19183840	17265920	20151620	18904060	12652960	19240800	18560870
14	2226.7	2367.6	2602.6	3022.6	2051.1	2957.7	2089.8
15	59.176	62.690	77.535	82.570	53.302	67.111	37.943
16	0.212	0.219	0.273	0.306	0.194	0.360	0.126
17	102.633	79.927	82.531	78.496	72.276	72.389	81.281
18	0.705	0.617	0.724	0.630	0.492	0.548	0.568
19	0.337	0.344	0.381	0.450	0.332	0.558	0.317
20	0.991	1.898	2.072	1.700	1.085	1.008	0.980
21	−13.414	−13.017	−13.382	−13.459	−13.873	−13.370	−13.373
22	31.247	32.383	33.132	31.790	30.903	30.877	30.608
23	62.944	NA	70.943	69.165	52.282	76.835	60.839
24	13806.8	10419.0	10992.0	10397.8	10516.7	6092.0	6199.8
25	18.287	14.355	14.355	19.096	16.932	14.936	14.148
26	1095.968	998.732	1092.335	1171.034	1082.701	1401.898	1073.967
27	30.359	29.024	37.874	32.879	28.818	32.257	19.801
28	89.6	82.6	83.4	87.4	90.6	82.2	95.0
29	784.8	704.9	714.2	757.7	795.5	700.4	853.3
30	130.5	114.2	114.0	122.4	114.2	126.7	121.4
31	1325.3	1100.8	1098.1	1213.0	1100.8	1274.7	1199.2
32	748.2	634.9	654.4	723.6	754.3	624.8	779.1
33	1200.0	1109.2	1117.5	1167.5	1125.9	1109.2	1159.8
34	4.029	3.966	3.795	3.048	3.039	3.921	3.843
35	0.878	2.066	1.571	1.326	1.870	1.130	2.069
36	2.156	1.293	1.270	1.381	2.127	0.784	1.403
37	83.152	84.266	86.926	81.749	82.840	89.485	77.472
38	52.365	49.910	45.253	50.397	43.083	51.762	45.108
39	53.561	49.293	47.657	51.112	42.562	54.852	45.172
40	48.936	43.208	42.797	42.117	35.542	47.492	35.083
41	0.040	4.854	4.636	14.192	3.058	1.145	3.180
42	126.869	146.608	158.066	160.683	116.771	135.768	83.774
43	42.918	75.713	75.807	77.106	66.004	75.820	71.374
44	0.937	0.625	0.532	0.498	0.847	0.370	0.577
45	0.056	0.063	0.058	0.055	0.051	0.036	0.061
46	1.107	3.200	3.433	3.300	1.000	1.100	4.379
47	17250	29257	36000	23967	15250	12688	21430
48	161.6	96.1	82.7	84.2	145.3	56.0	109.1
49	0.157	0.163	0.152	0.148	0.134	0.093	0.162
50	9.327	9.114	7.802	10.150	9.824	8.717	7.802
51	0.833	0.535	0.472	0.424	0.698	0.306	0.525
52	0.039	0.042	0.036	0.031	0.034	0.016	0.042
53	143.638	82.260	73.275	71.738	119.795	46.255	99.235
54	0.082	0.086	0.083	0.075	0.087	0.046	0.105
55	17.070	15.356	20.624	17.892	14.011	14.573	15.448
56	1.936	1.922	2.481	2.108	1.386	1.847	1.374
57	0.978	1.052	1.354	1.393	1.162	1.014	0.946
58	20.591	25.638	29.817	32.103	27.309	28.434	26.690

Table 67: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 68
Measured parameters in additional Sorghum accessions under drought conditions
Line/
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14
1	NA	91.009	NA	80.988	70.467	79.809	75.754
2	0.000	0.321	0.278	0.314	0.234	0.115	0.301
3	0.210	0.625	0.760	0.675	0.573	0.364	0.427
4	21.718	21.765	12.299	28.297	23.752	23.529	27.665
5	7925	15391	46856	26600	13235	8101	9566
6	5.942	11.074	8.455	15.925	7.906	9.860	8.572
7	NA	0.165	0.145	0.171	0.145	0.163	0.162
8	0.113	0.097	0.070	0.120	0.106	0.105	0.121
9	37.0	28.3	18.3	28.8	37.2	30.6	29.8
10	453.500	369.250	193.900	391.700	469.150	384.250	374.550
11	176.209	586.838	95.022	321.492	275.869	459.694	426.101
12	10.824	23.190	6.566	16.696	9.493	25.781	22.166
13	8106154	25074700	6470276	10728240	11082880	17810750	14047538
14	922.6	3192.6	1275.3	2368.5	1297.7	2280.5	1687.8
15	18.754	68.585	17.454	66.288	29.768	53.878	46.381
16	0.192	0.296	0.027	0.174	0.180	0.252	0.349
17	188.433	128.804	80.847	114.857	78.775	70.477	54.292
18	0.265	0.706	0.227	0.354	0.443	0.566	0.588
19	0.464	0.469	0.083	0.291	0.421	0.434	0.500
20	1.048	1.362	0.948	1.121	1.458	1.193	1.045
21	−14.197	−13.146	−13.423	−13.618	−12.775	−13.560	−13.117
22	NA	31.738	NA	30.612	30.143	31.090	32.813
23	71.130	68.444	65.265	63.310	79.049	75.830	71.806
24	2894.0	9764.5	13474.8	14964.6	9651.0	6615.4	10532.6
25	9.019	19.935	23.125	21.705	17.476	13.403	17.250
26	363.433	1590.208	817.400	1579.043	630.300	898.267	875.433
27	7.775	35.168	11.282	45.210	15.017	21.266	24.160
28	76.0	90.3	132.0	112.4	80.4	83.4	84.2
29	630.5	791.9	1343.3	1080.7	679.7	713.9	723.6
30	111.8	143.3	150.0	150.6	147.3	113.0	114.0
31	1068.3	1501.6	1599.4	1607.3	1558.9	1084.0	1098.2
32	630.5	736.4	NA	945.3	625.3	607.3	709.0
33	1092.4	1161.1	1602.8	1472.4	1148.8	1098.1	1098.1
34	NA	6.238	NA	3.233	3.167	4.803	3.799
35	2.470	0.697	1.100	1.001	0.795	1.036	0.982
36	NA	1.062	NA	2.547	0.929	0.797	0.822
37	89.690	79.575	NA	85.392	86.918	84.460	84.347
38	NA	48.829	NA	50.915	50.778	52.048	50.596
30	55.544	50.777	NA	52.813	51.510	52.922	48.402
40	47.150	44.642	39.311	44.153	42.039	44.369	46.417
41	0.487	6.895	NA	0.837	1.119	0.373	2.202
42	188.735	106.494	96.881	104.467	161.086	116.682	152.401
43	83.199	68.185	53.838	56.668	78.389	74.750	77.709
44	0.179	0.560	1.177	0.873	0.429	0.414	0.384
45	0.014	0.048	0.109	0.058	0.033	0.041	0.030
46	1.200	2.826	1.067	1.667	3.267	2.828	2.759
47	16700	23063	12450	13300	29500	17843	18813
48	22.4	96.9	398.9	209.7	61.0	63.0	61.6
49	0.040	0.119	0.363	0.195	0.085	0.105	0.077
50	7.244	9.316	7.956	11.011	8.584	8.321	8.269
51	0.128	0.496	1.151	0.806	0.373	0.350	0.330
52	0.007	0.026	0.100	0.041	0.019	0.023	0.016
53	16.467	85.863	390.344	193.770	53.124	53.161	53.048
54	0.035	0.067	0.280	0.119	0.044	0.060	0.041
55	4.415	20.909	4.676	10.447	7.355	14.829	14.568
56	0.636	2.234	0.286	0.948	1.073	1.789	1.658
57	0.163	1.322	0.529	1.561	0.411	0.693	0.836
58	7.748	33.179	NA	29.546	13.347	17.038	18.455

Table 68: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 69
Measured parameters in additional Sorghum accessions under drought conditions
Line/
Corr. ID	Line-15	Line-16	Line-17	Line-18	Line-19	Line-20	Line-21
1	63.087	82.774	61.843	91.397	69.406	78.023	72.962
2	0.334	0.437	0.113	0.298	0.073	0.293	0.134
3	0.362	0.589	0.628	0.312	0.398	0.356	0.151
4	23.399	17.180	36.532	15.755	24.586	17.806	21.837
5	12813	12286	19751	12768	11090	9924	6585
6	12.260	9.462	37.025	10.638	12.846	20.468	7.308
7	0.195	0.129	0.207	0.166	0.163	0.169	NA
8	0.121	0.082	0.145	0.087	0.111	0.092	0.105
9	23.6	28.0	30.3	23.0	32.6	22.4	40.2
10	309.550	365.550	397.938	311.800	413.550	291.750	493.550
11	267.312	311.951	289.762	124.816	507.414	430.251	254.426
12	8.790	14.785	12.626	3.997	34.067	23.355	13.395
13	10846278	15582420	8247885	6942220	8592480	21713380	10884158
14	1724.4	1891.7	1683.0	927.2	2955.1	2902.0	2221.1
15	39.728	34.499	56.862	15.114	73.525	52.512	48.784
16	0.196	0.176	0.163	0.060	0.362	0.218	0.265
17	65.790	120.481	84.266	59.883	116.994	73.911	60.152
18	0.324	0.441	0.367	0.278	0.557	0.476	0.298
19	0.366	0.341	0.300	0.187	0.530	0.313	0.405
20	0.734	1.160	1.863	1.590	1.037	1.090	1.855
21	−13.373	−13.297	−13.463	−13.000	−13.203	−13.147	−13.527
22	32.431	32.053	31.146	29.935	30.208	31.477	29.370
23	68.133	63.313	72.543	61.273	75.180	49.663	NA
24	15978.1	11762.4	17356.5	13226.2	12471.0	14010.0	4967.2
25	21.798	17.391	21.641	17.464	19.075	18.937	14.289
26	1008.699	932.233	871.419	440.900	1460.132	1488.968	836.533
27	23.657	16.936	31.881	7.227	36.169	27.165	19.778
28	98.6	89.2	94.3	109.0	83.6	94.0	74.0
29	900.5	777.6	843.1	1032.8	715.2	840.0	607.3
30	NA	NA	143.8	148.0	131.0	114.5	116.0
31	NA	NA	1508.4	1570.0	1332.1	1105.0	1126.0
32	859.8	733.3	775.3	945.3	655.5	757.7	526.3
33	1210.0	1143.1	1241.1	1344.6	1129.0	1131.7	1100.8
34	2.459	4.882	2.622	3.599	3.541	4.223	3.209
35	0.667	0.889	0.955	1.271	0.827	0.677	0.811
36	2.778	1.012	4.227	1.878	1.183	2.788	0.645
37	86.631	78.462	85.828	86.589	89.624	82.927	90.251
38	50.103	51.082	57.487	48.753	53.703	46.738	50.180
39	49.012	53.950	58.408	NA	55.637	48.493	47.695
40	43.775	40.133	46.703	38.442	45.961	40.678	43.003
41	2.029	2.358	2.628	1.459	4.934	0.103	1.396
42	153.212	128.423	145.795	87.743	182.987	81.273	115.342
43	49.028	74.303	52.289	58.046	74.117	33.404	NA
44	0.914	0.489	1.302	0.722	0.534	1.213	0.377
45	0.038	0.047	0.065	0.039	0.040	0.052	0.027
46	2.700	1.321	4.000	3.767	2.367	1.679	4.900
47	12750	19493	20833	28979	14650	16950	18229
48	179.3	82.6	240.6	171.0	81.5	219.4	47.1
49	0.106	0.120	0.191	0.123	0.102	0.132	0.069
50	9.990	7.644	11.805	6.583	9.750	7.259	7.540
51	0.852	0.433	1.096	0.646	0.449	1.102	0.319
52	0.024	0.024	0.045	0.031	0.019	0.037	0.016
53	166.994	73.170	203.563	152.470	68.615	198.943	39.832
54	0.074	0.057	0.118	0.102	0.054	0.080	0.124
55	11.247	11.185	9.840	6.220	15.757	19.331	6.372
56	0.968	1.214	0.998	0.405	1.974	1.674	0.990
57	1.037	0.640	1.137	0.381	1.188	1.234	0.531
58	21.530	18.176	16.057	NA	27.647	30.353	18.934

Table 69 Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 70
Measured parameters in additional Sorghum accessions under drought conditions
Line/
Corr. ID	Line-22	Line-23	Line-24	Line-25	Line-26	Line-27	Line-28
1	90.725	89.322	63.403	58.656	90.324	69.266	78.521
2	0.268	0.441	0.344	0.215	0.406	0.239	0.225
3	0.725	0.843	0.630	0.396	0.709	0.517	0.283
4	26.528	25.814	27.598	21.848	26.829	18.373	24.199
5	19859	29904	18695	7513	15653	14606	8279
6	17.594	14.916	32.575	10.572	17.710	20.438	18.601
7	0.157	0.154	0.147	0.140	0.175	0.157	NA
8	0.124	0.113	0.130	0.105	0.123	0.098	0.107
9	32.4	25.4	29.2	32.8	25.0	26.6	40.3
10	445.700	349.800	381.150	418.800	338.100	337.300	494.375
11	73.585	443.706	475.258	346.323	243.625	317.094	537.350
12	6.229	28.228	33.821	21.880	11.814	21.905	32.903
13	2607623	15608820	16427920	14660064	8494728	15105380	10961625
14	344.2	2572.2	3186.7	2510.2	1468.4	2754.9	3990.9
15	7.619	66.818	86.304	54.757	38.833	53.782	97.093
16	0.026	0.179	0.309	0.303	0.136	0.209	0.382
17	85.966	101.763	116.926	76.034	47.587	129.080	105.902
18	0.160	0.645	0.554	0.463	0.268	0.652	0.598
19	0.105	0.345	0.536	0.494	0.210	0.603	0.576
20	1.488	0.922	1.171	1.048	1.154	1.013	1.794
21	−13.460	−13.526	−13.860	−13.320	−13.280	−12.893	−13.197
22	31.150	29.908	31.025	31.742	31.675	30.970	28.544
23	61.602	68.320	52.744	73.423	58.117	72.016	NA
24	14354.0	14782.2	9583.3	9224.8	12185.8	11844.8	10118.5
25	21.338	21.533	17.566	18.666	19.557	20.497	14.358
26	130.167	1545.898	1637.460	1351.168	533.701	1425.000	1736.125
27	3.526	40.537	45.368	29.841	16.072	28.463	41.775
28	113.0	116.2	88.8	84.8	107.2	86.4	74.0
29	1086.6	1128.6	773.0	730.0	1010.7	746.7	607.3
30	148.0	144.8	114.0	118.0	144.0	113.0	116.0
31	1570.2	1524.0	1098.2	1154.5	1512.2	1084.0	1126.0
32	854.5	945.3	734.5	688.7	801.9	709.0	607.8
33	1532.3	1478.4	1154.1	1148.8	1348.8	1084.0	1101.6
34	3.535	3.439	2.707	2.399	4.568	3.537	4.244
35	0.877	0.697	1.425	0.745	0.803	0.821	1.134
36	2.442	2.285	2.053	1.118	1.526	1.204	1.035
37	87.868	87.156	75.524	84.972	89.151	85.963	90.046
38	44.029	48.585	47.358	52.498	47.105	53.847	51.967
39	41.940	48.005	45.902	51.158	45.948	53.493	49.990
40	39.201	38.294	42.158	45.281	39.606	42.350	45.856
41	0.538	NA	0.434	1.437	9.145	NA	3.368
42	96.152	113.450	107.560	144.486	93.734	143.428	122.910
43	55.471	58.489	61.581	74.220	63.845	80.472	NA
44	0.887	0.775	0.750	0.390	0.588	0.488	0.658
45	0.045	0.063	0.058	0.049	0.045	0.043	0.045
46	3.800	1.033	1.143	2.172	2.067	1.000	2.826
47	20283	13450	12802	14000	18717	12750	16564
48	277.3	203.2	126.7	64.4	137.2	80.3	82.2
49	0.152	0.214	0.153	0.126	0.138	0.110	0.115
50	8.073	11.180	11.875	8.761	9.334	10.738	8.701
51	0.817	0.719	0.557	0.326	0.511	0.364	0.509
52	0.040	0.042	0.026	0.021	0.036	0.017	0.019
53	204.688	188.310	94.100	53.816	119.455	59.885	63.629
54	0.178	0.116	0.061	0.052	0.113	0.094	0.063
55	2.497	17.864	16.291	10.780	10.579	12.072	13.243
56	0.217	1.309	1.806	1.348	0.794	1.234	2.091
57	0.131	1.633	1.550	0.945	1.023	1.077	1.047
58	4.432	32.085	35.929	26.706	18.687	26.870	35.317

Table 70: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 71
Measured parameters in additional Sorghum accessions under drought conditions
Line/
Corr. ID	Line-29	Line-30	Line-31	Line-32	Line-33	Line-34	Line-35
1	81.125	91.194	91.259	75.635	84.772	64.819	81.827
2	0.163	0.453	0.350	0.220	0.227	0.408	0.416
3	0.356	0.602	0.633	0.361	0.365	0.561	0.591
4	25.929	24.781	21.284	21.644	23.479	23.959	25.378
5	8487	10491	18823	11730	13869	16143	25030
6	10.982	11.531	22.167	49.007	13.313	32.109	12.350
7	NA	NA	0.174	0.177	0.178	0.155	0.146
8	0.114	0.109	0.101	0.102	0.112	0.109	0.110
9	39.0	39.0	23.8	30.8	26.0	29.3	35.6
10	476.750	476.750	311.250	403.500	341.250	383.125	470.650
11	542.866	561.268	582.815	506.799	712.873	625.018	397.261
12	32.227	32.258	39.815	41.732	45.253	43.942	17.384
13	18615532	21411860	25679300	23005825	29206300	27920025	15769504
14	4001.9	2671.3	4808.2	4663.8	4845.4	4510.1	2317.9
15	107.428	67.195	101.624	98.272	110.299	99.760	54.332
16	0.351	0.324	0.274	0.329	0.317	0.294	0.117
17	147.091	102.130	142.655	141.282	157.432	113.911	80.454
18	0.648	0.693	0.691	0.648	0.800	0.748	0.455
19	0.605	0.558	0.446	0.538	0.471	0.439	0.195
20	1.702	1.090	1.135	0.961	1.319	1.040	1.580
21	−13.110	−13.302	−13.168	NA	−12.932	−12.773	−13.641
22	29.020	29.218	32.127	31.510	30.367	34.529	31.704
23	NA	NA	69.854	65.961	52.714	68.984	62.975
24	3717.8	7510.6	15198.4	15660.3	26643.7	16453.5	16261.8
25	15.715	15.002	21.254	17.991	21.412	18.684	18.087
26	1588.502	1445.366	2590.168	2483.498	2041.557	1695.668	1071.869
27	42.428	36.053	55.958	54.938	48.327	39.825	26.772
28	74.0	74.0	93.4	89.5	95.0	89.5	93.4
29	607.3	607.3	831.9	781.0	853.3	781.0	831.8
30	115.3	113.0	136.6	134.0	136.5	139.0	143.3
31	1116.3	1084.0	1406.8	1369.0	1405.5	1442.0	1501.9
32	534.3	563.9	775.3	727.2	779.1	753.6	761.3
33	1084.0	1084.0	1143.1	1184.5	1194.5	1164.1	1260.6
34	4.092	5.577	6.098	3.935	4.908	3.233	3.997
35	0.959	1.048	0.888	0.858	0.819	1.038	1.575
36	0.735	0.658	2.563	4.152	3.913	2.742	2.504
37	91.805	90.937	76.228	80.929	NA	81.235	81.174
38	58.130	50.575	48.289	55.185	52.586	52.328	51.328
39	51.912	50.607	50.565	56.933	51.072	50.317	50.353
40	52.578	44.669	43.089	46.904	47.917	44.097	43.414
41	13.560	16.258	4.592	4.237	2.973	3.416	2.669
42	90.902	109.171	130.887	121.179	100.865	133.746	113.632
43	NA	NA	31.224	25.069	33.729	63.166	61.858
44	0.473	0.480	1.287	1.818	1.752	1.027	1.114
45	0.053	0.046	0.075	0.063	0.055	0.060	0.090
46	2.172	3.107	1.500	1.625	1.111	1.708	2.900
47	15183	18906	13300	10875	14778	14000	23500
48	59.1	60.0	233.7	307.3	331.2	173.5	205.7
49	0.136	0.117	0.193	0.175	0.156	0.158	0.276
50	8.566	8.981	8.582	9.918	8.551	9.355	8.996
51	0.385	0.387	1.164	1.528	1.682	0.837	1.046
52	0.021	0.020	0.042	0.029	0.029	0.033	0.073
53	48.091	48.428	211.564	258.277	317.871	141.388	193.358
54	0.069	0.058	0.108	0.055	0.103	0.095	0.152
55	13.920	14.391	24.759	16.537	27.693	21.381	11.370
56	2.112	2.184	2.268	1.836	2.501	2.352	1.293
57	1.366	0.864	2.452	1.905	1.895	1.425	0.829
58	37.747	25.922	52.124	45.984	41.342	35.700	24.229

Table 71: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (“L”=Line) under drought conditions. Growth conditions are specified in the experimental procedure section.

TABLE 72
Measured parameters in Sorghum accessions under low N conditions
Line/
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	70.982	80.778	71.062	62.932	65.104	74.278	83.123
2	0.149	0.204	0.123	0.140	0.289	0.063	0.099
3	0.303	0.177	0.091	0.303	0.321	0.048	0.275
4	2.012	NA	1.641	1.494	NA	1.565	NA
5	1.617	NA	2.306	1.380	NA	2.062	NA
6	1.223	NA	1.005	1.417	NA	1.674	NA
7	0.925	NA	0.667	0.580	NA	0.992	NA
8	29.775	30.575	35.404	30.667	29.218	23.386	20.149
9	21836	19319	15291	24497	44649	13715	30944
10	19.635	17.315	9.965	11.714	38.660	12.445	13.735
11	0.179	0.147	0.153	0.130	0.135	0.200	0.149
12	24.772	NA	29.657	37.888	NA	28.942	NA
13	0.121	0.127	0.132	0.133	0.130	0.103	0.094
14	33.8	29.6	35.0	28.5	26.3	33.6	21.8
15	444.5	380.4	439.7	373.5	273.3	428.2	285.2
16	661.8	769.5	745.2	653.3	610.1	581.2	324.5
17	34.150	35.096	23.132	18.830	42.755	38.924	15.023
18	22070840	24438020	21504340	21499680	20685020	21825800	16454200
19	3110.7	3929.4	2654.6	3987.6	4127.2	3314.9	2216.5
20	88.128	115.995	87.409	113.013	114.984	79.512	42.224
21	0.238	0.281	0.245	0.294	0.270	0.300	0.126
22	135.426	108.347	102.784	108.131	133.977	94.102	97.673
23	0.871	0.883	0.818	0.737	0.685	0.673	0.505
24	0.419	0.408	0.364	0.414	0.390	0.447	0.310
25	1.154	1.349	1.635	2.158	0.990	1.127	1.147
26	−12.781	-13.107	−12.994	−12.832	−13.047	−13.437	−12.963
27	30.750	29.233	30.853	30.262	29.008	30.268	29.357
28	70.470	NA	71.859	71.849	61.250	76.638	65.094
29	16770.4	10615.2	9361.4	12263.6	12503.9	7283.2	7295.8
30	19.657	14.270	14.101	17.056	17.317	15.079	16.105
31	1700.3	2239.1	1281.7	1754.3	2275.7	1569.7	1123.2
32	49.898	68.289	45.839	53.946	66.982	37.499	23.114
33	0.498	NA	0.487	0.566	NA	0.453	NA
34	330.902	384.754	372.597	326.628	305.061	290.601	162.240
35	92.000	86.800	81.200	89.600	89.500	84.000	95.800
36	814.0	751.3	689.4	782.2	781.0	720.7	863.7
37	139.0	117.0	122.6	133.0	115.3	NA	126.4
38	1442.0	1139.8	1215.2	1357.9	1115.5	NA	1266.7
39	762.250	669.063	675.083	757.650	757.650	649.438	823.417
40	1258.5	1131.7	1129.0	1154.5	1123.3	1148.8	1148.8
41	14.711	NA	12.003	8.510	NA	9.037	NA
42	3.949	4.099	3.362	3.023	2.144	3.819	4.352
43	0.899	2.178	1.923	1.476	2.094	1.370	2.046
44	2.746	1.271	1.287	1.557	3.225	0.899	1.665
45	91.270	90.888	91.349	87.339	89.630	87.146	84.594
46	56.305	49.677	46.965	48.598	42.805	54.763	43.717
47	54.540	51.730	47.538	48.722	44.574	52.847	47.843
48	50.167	39.128	42.389	38.897	36.192	41.514	37.042
49	6.429	0.789	3.957	18.903	5.833	0.137	2.175
50	155.139	162.491	161.900	181.391	148.290	144.063	100.333
51	49.466	81.590	76.055	77.961	60.221	79.401	72.605
52	0.546	0.360	0.326	0.308	0.639	0.243	0.407
53	0.0384	0.0497	0.0458	0.0529	0.0563	0.0281	0.0392
54	1.143	2.233	5.034	2.200	1.100	2.793	3.000
55	19050.0	19500.0	30600.0	29007.1	13250.0	14125.0	19550.0
56	93.293	NA	120.520	126.608	NA	99.805	NA
57	166.039	103.715	85.701	90.811	205.656	66.689	138.327
58	0.200	0.231	0.213	0.243	0.262	0.131	0.183
59	10.718	9.678	7.879	9.474	10.835	9.783	8.964
60	0.482	0.300	0.287	0.269	0.522	0.198	0.367
61	0.022	0.030	0.029	0.033	0.034	0.016	0.027
62	146.546	86.400	75.736	79.097	166.996	54.244	124.591
63	0.114	0.114	0.102	0.083	0.101	0.085	0.127
64	19.977	26.227	21.485	21.746	22.048	16.902	14.848
65	1.277	1.653	1.601	1.328	1.311	1.249	0.697
66	1.574	2.346	1.430	2.426	2.855	1.139	1.153
67	32.656	43.472	30.906	52.059	57.152	29.519	25.534

Table 72: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Line) under low N conditions. Growth conditions are specified in the experimental procedure section.

TABLE 73
Measured parameters in additional Sorghum accessions under low N conditions
Line/
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14
1	NA	87.393	85.484	93.116	55.446	74.116	67.367
2	0.000	0.105	0.200	0.037	0.240	0.165	0.244
3	0.199	0.416	0.590	0.344	0.186	0.032	0.206
4	NA	1.759	NA	NA	NA	NA	NA
5	NA	1.160	NA	NA	NA	NA	NA
6	NA	1.314	NA	NA	NA	NA	NA
7	NA	0.892	NA	NA	NA	NA	NA
8	23.746	22.838	16.503	24.820	25.570	25.177	29.479
9	8654	22139	48188	46278	15265	9785	13167
10	6.745	10.983	10.180	31.720	7.650	10.130	9.523
11	NA	0.169	0.131	0.175	0.168	0.185	0.181
12	NA	22.900	NA	NA	NA	NA	NA
13	0.121	0.096	0.083	0.111	0.110	0.108	0.123
14	37.0	33.3	22.0	27.8	34.8	31.6	28.6
15	453.5	437.0	303.1	381.1	448.5	400.9	366.1
16	152.0	633.4	389.1	306.5	283.0	558.3	690.4
17	12.901	27.970	27.662	20.911	9.965	27.625	34.066
18	6420783	26192733	21156820	10734122	10820540	21581650	22437200
19	1326.9	4021.6	3454.5	1697.2	1472.7	3041.2	2942.7
20	31.060	90.240	58.679	44.118	35.686	74.674	84.101
21	0.194	0.225	0.065	0.085	0.165	0.357	0.296
22	235.316	156.903	136.671	190.285	117.019	75.922	78.987
23	0.200	0.756	0.509	0.470	0.499	0.627	0.783
24	0.360	0.363	0.122	0.176	0.469	0.510	0.460
25	1.067	1.414	0.949	1.126	1.464	1.258	1.110
26	−13.617	−12.690	−13.107	−13.168	−12.587	−13.127	−12.997
27	NA	30.044	32.523	32.462	29.503	29.288	30.948
28	71.939	69.210	68.575	69.279	79.731	76.658	73.608
29	3501.0	12503.7	15699.7	22712.4	8595.4	8279.6	14579.4
30	8.967	19.410	20.615	22.694	18.017	13.931	16.957
31	520.9	1874.6	1912.8	732.1	810.6	1593.3	1572.2
32	12.331	43.669	32.983	19.063	19.801	40.775	46.400
33	NA	0.403	NA	NA	NA	NA	NA
34	75.982	316.713	194.545	153.235	141.521	279.168	345.200
35	76.000	91.000	120.600	113.800	85.800	84.400	86.800
36	630.5	802.3	1189.1	1097.1	740.6	725.2	751.6
37	112.0	147.0	145.5	154.2	148.0	137.0	119.0
38	1070.9	1554.5	1534.3	1659.7	1570.2	1412.0	1165.8
39	630.500	734.917	NA	945.250	661.900	670.000	717.083
40	1084.0	1239.3	1492.2	1478.1	1189.1	1126.0	1117.6
41	NA	11.607	NA	NA	NA	NA	NA
42	NA	5.217	4.975	6.281	2.147	4.017	2.835
43	2.500	0.647	1.153	0.958	0.711	0.999	1.122
44	NA	1.351	2.875	2.149	1.060	0.877	1.046
45	92.267	87.171	86.652	88.087	86.867	85.891	91.490
46	NA	51.189	46.238	57.363	49.617	53.647	48.521
47	50.112	53.108	42.777	56.933	49.052	50.500	48.795
48	41.900	40.083	36.017	39.369	36.297	40.442	45.400
49	5.200	10.090	NA	5.248	1.450	9.657	NA
50	189.473	125.519	140.628	160.009	159.603	178.499	157.837
51	84.085	67.668	73.146	71.748	82.454	74.350	79.973
52	0.118	0.381	0.482	0.437	0.196	0.232	0.231
53	0.0179	0.0436	0.0742	0.0518	0.0253	0.0269	0.0361
54	1.826	2.471	1.200	2.267	2.533	3.833	1.536
55	12833.3	20833.3	13166.7	14150.0	25900.0	18950.0	18250.0
56	NA	104.355	NA	NA	NA	NA	NA
57	26.195	119.974	240.975	200.845	55.271	64.623	68.036
58	0.078	0.223	0.418	0.292	0.122	0.125	0.168
59	7.894	9.503	6.876	11.006	9.427	8.680	8.355
60	0.086	0.346	0.462	0.368	0.169	0.195	0.199
61	0.011	0.028	0.063	0.043	0.014	0.013	0.015
62	19.450	108.992	230.795	169.125	47.621	54.493	58.513
63	0.053	0.119	0.467	0.192	0.059	0.052	0.071
64	3.976	18.907	17.986	11.876	8.179	17.225	24.337
65	0.316	1.246	0.690	0.544	0.567	1.199	1.483
66	0.489	1.511	1.518	0.747	0.606	1.417	1.635
67	12.034	40.630	40.858	13.330	17.471	34.938	31.887

Table 73: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Line) under low N conditions. Growth conditions are specified in the experimental procedure section.

TABLE 74
Measured parameters in additional Sorghum accessions under low N conditions
Line/
Corr. ID	Line-15	Line-16	Line-17	Line-18	Line-19	Line-20	Line-21
1	71.204	87.744	66.577	88.729	69.236	82.991	61.314
2	0.280	0.108	0.142	0.197	0.044	0.176	0.009
3	0.276	0.215	0.080	0.227	0.034	0.151	0.057
4	NA	NA	NA	NA	NA	NA	NA
5	NA	NA	NA	NA	NA	NA	NA
6	NA	NA	NA	NA	NA	NA	NA
7	NA	NA	NA	NA	NA	NA	NA
8	22.654	16.496	36.959	16.850	26.577	17.793	21.080
9	14934	18163	28962	18746	12235	15453	7724
10	9.865	11.363	19.744	16.135	17.348	13.860	8.299
11	0.177	0.165	0.199	0.160	0.183	0.185	NA
12	NA	NA	NA	NA	NA	NA	NA
13	0.116	0.079	0.144	0.089	0.113	0.088	0.101
14	22.2	29.2	29.5	30.0	35.4	24.6	42.6
15	293.6	384.4	389.3	405.6	454.6	323.1	527.5
16	605.1	366.7	423.1	280.2	590.6	454.7	263.7
17	37.096	17.573	16.101	5.704	36.432	28.131	13.219
18	25344720	20035920	11582823	14659840	20818740	23299560	11431484
19	3864.4	2620.7	1944.0	1369.3	3561.9	3839.1	1999.4
20	85.481	44.335	66.859	23.580	95.691	68.241	43.298
21	0.327	0.196	0.146	0.074	0.351	0.258	0.290
22	107.039	176.320	83.007	66.675	117.480	98.120	47.498
23	0.693	0.580	0.474	0.577	0.679	0.508	0.262
24	0.492	0.352	0.257	0.203	0.526	0.390	0.367
25	1.064	1.108	1.779	2.298	1.154	1.220	2.537
26	−12.960	−13.070	−12.937	−12.773	−13.347	−12.603	−12.827
27	29.694	30.343	30.742	32.608	29.950	29.898	27.933
28	68.654	70.917	73.210	65.330	75.551	62.980	NA
29	16710.4	13218.2	14464.5	11759.2	8621.8	13816.8	6363.6
30	21.007	20.015	21.476	17.659	18.518	20.684	14.810
31	2037.5	1422.1	854.8	449.6	1466.9	1989.8	659.5
32	46.213	24.508	31.902	7.677	40.562	35.605	14.155
33	NA	NA	NA	NA	NA	NA	NA
34	302.543	183.331	211.574	140.091	295.283	227.327	131.841
35	103.800	94.000	97.750	107.400	84.600	95.800	74.000
36	967.4	840.0	889.3	1013.4	726.8	863.6	607.3
37	143.0	NA	149.0	148.4	144.0	137.0	NA
38	1498.3	NA	1584.5	1576.2	1512.8	1412.0	NA
39	892.583	769.500	814.250	905.750	641.550	772.950	534.250
40	1261.0	1224.4	1278.5	1419.0	1181.3	1186.6	1134.7
41	NA	NA	NA	NA	NA	NA	NA
42	3.567	5.907	3.218	6.071	3.701	4.375	2.217
43	0.773	0.767	1.074	1.261	0.695	0.637	0.878
44	2.347	1.034	3.932	1.500	1.318	1.683	0.782
45	91.398	84.469	92.502	85.150	88.160	87.006	92.399
46	46.307	50.003	56.171	49.742	51.292	48.132	52.547
47	47.387	55.860	55.535	49.918	51.232	48.133	44.398
48	39.886	39.142	41.953	41.992	44.542	39.442	38.208
49	0.852	0.498	6.537	3.625	4.036	0.617	11.122
50	153.250	149.854	148.157	123.344	147.837	130.549	150.061
51	47.458	78.799	48.808	65.768	74.641	43.761	NA
52	0.412	0.277	0.691	0.319	0.321	0.411	0.233
53	0.0270	0.0265	0.0507	0.0345	0.0239	0.0265	0.0198
54	1.241	1.300	4.792	4.267	2.367	1.433	4.933
55	15050.0	18650.0	26500.0	47771.4	15378.6	14791.3	23437.3
56	NA	NA	NA	NA	NA	NA	NA
57	159.390	90.693	240.230	133.705	88.750	138.098	48.102
58	0.139	0.134	0.267	0.194	0.115	0.129	0.092
59	9.779	8.566	12.728	7.753	10.945	7.753	7.522
60	0.387	0.242	0.634	0.280	0.259	0.368	0.193
61	0.014	0.017	0.038	0.028	0.011	0.016	0.012
62	149.525	79.330	220.486	117.570	71.401	123.368	39.803
63	0.069	0.055	0.147	0.106	0.071	0.092	0.092
64	27.277	13.002	14.810	9.341	16.670	18.492	6.211
65	1.183	0.731	0.793	0.497	1.229	0.934	0.566
66	2.106	0.885	1.349	0.366	1.251	1.460	0.593
67	44.016	26.275	19.654	11.967	31.069	41.683	25.750

Table 74: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Line) under low N conditions. Growth conditions are specified in the experimental procedure section.

TABLE 75
Measured parameters in additional Sorghum accessions under low N conditions
Line/
Corr. ID	Line-22	Line-23	Line-24	Line-25	Line-26	Line-27	Line-28
1	90.328	85.738	71.241	60.074	94.779	60.588	81.112
2	0.194	0.209	0.145	0.151	NA	0.074	0.012
3	0.407	0.693	0.225	0.277	0.472	0.179	0.050
4	NA	1.466	1.411	NA	NA	NA	NA
5	NA	1.976	1.639	NA	NA	NA	NA
6	NA	0.695	0.986	NA	NA	NA	NA
7	NA	0.488	0.700	NA	NA	NA	NA
8	26.721	22.723	31.566	20.307	31.218	21.468	25.958
9	32880	62130	28010	8133	NA	18762	13549
10	20.358	19.750	36.955	10.978	NA	18.170	14.521
11	0.156	0.164	0.178	0.146	NA	0.188	NA
12	NA	18.142	40.260	NA	NA	NA	NA
13	0.129	0.105	0.136	0.102	0.133	0.105	0.109
14	29.0	29.2	32.8	31.8	22.4	29.4	42.3
15	395.4	404.3	428.3	411.5	295.7	380.9	522.0
16	145.5	282.2	605.5	378.0	581.1	291.8	671.5
17	9.494	19.131	36.400	21.959	36.595	19.138	33.894
18	4496747	11541518	18740650	16305080	20382340	12164286	23557125
19	592.6	1907.3	3702.6	2806.6	3624.3	2363.9	3599.6
20	17.465	43.235	111.350	59.062	109.255	52.912	93.946
21	0.052	0.086	0.312	0.237	0.218	0.206	0.364
22	178.349	124.018	150.210	82.476	123.731	113.667	108.224
23	0.347	0.485	0.710	0.503	0.720	0.639	0.774
24	0.158	0.235	0.518	0.439	0.342	0.426	0.518
25	1.687	0.978	1.341	1.021	1.531	1.163	1.431
26	−12.900	−12.356	−13.100	−13.060	−12.753	−12.897	−13.027
27	28.392	28.580	30.164	30.863	30.922	30.485	28.167
28	60.372	72.783	66.842	73.948	NA	76.292	NA
29	16953.3	26482.6	15781.4	8543.0	NA	15080.6	9350.7
30	20.918	24.373	18.204	16.931	NA	21.535	16.783
31	161.4	1071.8	2162.9	1311.7	1900.6	1326.5	1619.0
32	4.767	24.813	66.886	27.138	58.639	30.343	42.588
33	NA	0.266	0.568	NA	NA	NA	NA
34	72.738	141.110	302.756	188.981	290.536	145.891	335.752
35	111.000	118.000	88.600	86.600	102.800	87.800	74.000
36	1060.4	1153.7	771.5	748.3	955.2	762.3	607.3
37	148.3	149.2	125.3	134.0	152.2	NA	NA
38	1575.3	1586.7	1250.8	1369.0	1631.0	NA	NA
39	912.250	NA	751.550	677.800	901.250	727.250	574.750
40	1483.8	1558.0	1199.7	1159.8	1250.9	1143.1	1129.3
41	NA	8.785	7.165	NA	NA	NA	NA
42	4.003	2.981	2.915	2.884	6.847	2.319	3.891
43	0.839	0.854	1.546	0.817	0.830	0.572	0.740
44	3.399	4.557	2.643	0.907	NA	1.354	0.847
45	88.581	88.916	89.900	93.134	90.596	92.356	93.272
46	47.819	47.105	54.950	50.338	43.192	50.742	55.121
47	48.950	41.013	49.182	49.587	48.732	52.500	52.931
48	35.946	38.519	40.503	48.417	40.564	41.089	44.604
49	1.761	NA	3.736	10.924	36.793	0.502	6.363
50	96.895	165.864	153.371	165.165	NA	153.072	143.283
51	52.295	62.874	56.192	78.702	NA	81.757	NA
52	0.629	0.804	0.614	0.185	NA	0.274	0.340
53	0.0332	0.0443	0.0442	0.0268	0.0536	0.0296	0.0281
54	5.333	1.000	1.433	1.833	1.400	1.067	3.500
55	26033.3	13200.0	14404.8	13600.0	15500.0	13466.7	20520.8
56	NA	194.870	128.452	NA	NA	NA	NA
57	306.075	385.010	180.831	53.288	NA	80.795	70.308
58	0.204	0.250	0.214	0.127	0.272	0.138	0.133
59	9.426	11.937	12.746	9.969	NA	10.982	9.123
60	0.591	0.762	0.489	0.147	NA	0.213	0.270
61	0.027	0.034	0.021	0.015	0.035	0.017	0.014
62	285.717	365.260	143.876	42.310	NA	62.625	55.786
63	0.244	0.267	0.076	0.069	0.187	0.064	0.057
64	7.562	9.868	19.784	12.093	25.950	9.999	15.852
65	0.333	0.501	1.267	0.799	1.134	0.627	1.409
66	0.389	0.869	2.190	1.009	2.435	1.045	1.125
67	4.993	23.220	44.882	30.093	36.307	25.426	33.842

Table 75: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Line) under low N conditions. Growth conditions are specified in the experimental procedure section.

TABLE 76
Measured parameters in additional Sorghum accessions under low N conditions
	Line
Corr. ID	Line-29	Line-30	Line-31	Line-32	Line-33	Line-34
1	73.956	88.152	94.306	84.535	68.632	84.006
2	0.084	0.254	0.088	0.118	0.220	0.205
3	0.092	0.069	0.175	0.137	0.326	0.404
4	NA	1.684	NA	1.326	NA	2.015
5	NA	1.532	NA	1.478	NA	1.703
6	NA	1.380	NA	1.137	NA	1.584
7	NA	0.856	NA	0.808	NA	0.539
8	27.928	28.402	20.911	24.414	23.544	26.070
9	9492	14554	27231	18260	18322	42073
10	10.883	11.098	16.014	22.554	19.837	14.741
11	NA	NA	0.200	0.178	0.159	0.158
12	NA	35.158	NA	43.484	NA	15.477
13	0.118	0.116	0.098	0.113	0.104	0.109
14	42.3	42.0	26.3	31.3	29.8	33.2
15	522.5	518.8	344.9	412.3	391.0	437.0
16	510.9	774.6	816.4	922.4	828.4	485.5
17	27.858	40.001	57.513	50.774	48.677	26.396
18	16479475	25747580	36116975	36860650	33562075	18000140
19	2406.1	3436.2	6082.5	5855.7	4395.8	3020.8
20	68.157	95.293	127.781	139.390	101.239	76.087
21	0.344	0.334	0.256	0.366	0.300	0.114
22	138.647	112.243	185.571	222.258	140.774	115.633
23	0.635	0.926	0.969	0.996	1.040	0.585
24	0.610	0.533	0.425	0.535	0.486	0.176
25	1.080	1.161	1.018	1.144	1.062	1.281
26	−13.023	−12.976	−13.033	−12.842	−12.637	−13.032
27	27.846	27.982	30.517	29.685	32.517	29.522
28	NA	NA	67.302	68.590	71.740	69.007
29	5454.0	9065.6	20008.0	21922.8	15977.0	18430.4
30	15.374	15.420	21.194	20.837	17.496	20.502
31	1259.4	1724.0	3230.2	3170.3	2099.3	1383.3
32	36.016	48.781	69.211	79.250	49.550	36.400
33	NA	0.592	NA	0.577	NA	0.312
34	255.429	387.307	408.199	461.182	414.199	242.755
35	74.000	74.000	96.500	96.000	92.500	92.000
36	607.3	607.3	872.8	866.3	820.0	813.4
37	NA	125.0	145.0	NA	136.5	135.5
38	NA	1247.5	1528.0	NA	1405.5	1392.6
39	574.750	607.250	814.250	749.083	769.500	772.950
40	1129.8	1126.0	1217.6	1278.6	1211.0	1750.3
41	NA	11.089	NA	10.961	NA	13.237
42	3.177	5.365	6.861	4.959	3.385	4.381
43	0.852	1.174	0.823	0.772	0.914	1.537
44	0.600	0.655	3.127	3.279	1.837	4.079
45	93.540	94.229	85.910	87.606	92.159	92.029
46	55.483	49.848	45.775	51.031	45.042	50.562
47	52.167	49.887	47.292	53.750	45.912	50.865
48	46.864	41.394	39.913	41.771	39.519	38.342
49	5.117	1.572	NA	12.827	0.765	5.673
50	151.126	142.923	152.429	133.144	159.389	139.693
51	NA	NA	30.298	39.911	72.543	50.458
52	0.220	0.284	0.866	0.811	0.385	1.105
53	0.0226	0.0310	0.0526	0.0398	0.0319	0.0801
54	3.458	3.400	2.250	1.000	1.083	2.833
55	16495.8	17950.0	12910.7	15812.5	15567.9	18400.0
56	NA	102.189	NA	112.370	NA	154.249
57	45.408	58.552	293.949	275.478	124.359	343.974
58	0.105	0.145	0.263	0.212	0.163	0.405
59	8.627	8.781	9.046	9.396	9.412	9.063
60	0.167	0.230	0.819	0.745	0.324	1.058
61	0.009	0.015	0.030	0.018	0.017	0.066
62	34.524	47.455	277.935	252.924	104.523	329.233
63	0.045	0.075	0.147	0.091	0.083	0.217
64	12.154	18.443	31.944	29.922	27.784	14.902
65	1.097	1.664	1.634	1.740	1.686	0.962
66	0.910	1.176	2.673	2.661	1.671	1.316
67	26.885	35.287	69.844	61.562	45.610	31.897

Table 76: Provided are the values of each of the parameters (as described above) measured in Sorghum accessions (Line) under low N conditions. Growth conditions are specified in the experimental procedure section.

TABLE 77
Correlation between the expression level of selected genes of some
embodiments of the invention in various tissues and the phenotypic
performance under normal conditions across Sorghum accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	ID	Name	R	P value	set	ID
LBY149	0.79	3.32E−02	2	12	LBY150	0.74	5.56E−02	2	41
LBY153	0.82	2.28E−02	1	5	LBY155	0.93	2.49E−03	1	5
LBY156	0.82	2.43E−02	2	33	LBY156	0.76	4.94E−02	2	12
LBY156	0.81	2.82E−02	1	33	LBY158	0.84	1.75E−02	2	33
LBY158	0.77	4.12E−02	2	12	LBY160	0.71	7.56E−02	2	5
LBY160	0.72	6.56E−02	2	12	LBY160	0.76	2.20E−06	1	63
LBY160	0.71	2.01E−05	1	53	LBY160	0.77	3.16E−06	1	9
LBY160	0.74	7.02E−06	1	58	LBY160	0.71	2.65E−05	1	61
LBY161	0.91	4.87E−03	2	56	LBY162	0.74	5.71E−02	2	33
LBY162	0.72	6.94E−02	2	56	LBY162	0.83	2.20E−02	1	5
LBY163	0.80	4.11E−07	1	63	LBY163	0.72	6.61E−02	1	56
LBY164	0.82	2.29E−02	2	56	LBY164	0.87	1.08E−02	1	5
LBY165	0.79	3.59E−02	1	33	LBY165	0.75	4.99E−02	1	12
LBY167	0.80	3.21E−02	2	4	LBY167	0.89	7.78E−03	2	41
LBY168	0.72	6.66E−02	1	7	LBY168	0.87	1.04E−02	1	5
LBY168	0.73	6.14E−02	1	4	LBY168	0.81	2.60E−02	1	6
LBY170	0.77	4.08E−02	1	4	LBY171	0.99	4.33E−06	2	56
LBY171	0.71	1.05E−04	1	49	LBY171	0.79	3.49E−02	1	4
LBY173	0.72	7.08E−02	2	5	LBY173	0.73	6.37E−02	2	33
LBY173	0.94	1.58E−03	2	56	LBY177	0.85	1.56E−02	2	7
LBY177	0.70	7.82E−02	2	6	LBY178	0.77	4.17E−02	2	6
LBY178	0.77	4.36E−02	1	4	LBY179	0.73	6.07E−02	2	56
LBY180	0.97	3.03E−04	2	56	LBY180	0.78	3.88E−02	1	33
LBY180	0.72	6.98E−02	1	12	LBY185	0.79	6.32E−07	1	63
LBY185	0.72	2.10E−05	1	62	LBY185	0.80	6.38E−07	1	9
LBY185	0.70	2.90E−05	1	58	LBY185	0.72	2.31E−05	1	57
LBY185	0.83	2.03E−02	1	56	LBY185	0.74	5.61E−06	1	61
LBY186	0.78	4.01E−02	2	5	LBY186	0.73	6.40E−02	2	12
LBY186	0.70	7.76E−02	2	56	LBY186	0.73	6.51E−02	1	12
LBY187	0.71	7.18E−02	1	4	LBY187	0.75	5.46E−02	1	41
LBY189	0.76	4.94E−02	2	7	LBY189	0.92	3.21E−03	2	6
LBY190	0.78	4.03E−02	2	4	LBY191	0.76	4.58E−02	1	4
LBY192	0.73	6.34E−02	1	4	LGN3	0.71	7.66E−02	2	33
LGN4	0.72	6.56E−02	2	12	LGN5	0.89	6.83E−03	2	7
LGN5	0.77	4.14E−02	2	6	LGN5	0.79	3.31E−02	1	7
LGN5	0.76	4.96E−02	1	6	LGN57	0.83	1.98E−02	2	33
LGN7	0.95	1.09E−03	2	56

Table 77. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 60. “Exp. Set”—Expression set specified in Table 59. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 78
Correlation between the expression level of selected genes of some
embodiments of the invention in various tissues and the phenotypic
performance under drought stress conditions across Sorghum accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	ID	Name	R	P value	set	ID
LBY163	0.71	6.44E−05	3	52	LBY185	0.70	8.87E−05	3	49
LBY185	0.70	9.21E−05	3	45	LBY185	0.70	8.32E−05	3	52

Table 78. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 61. “Exp. Set”—Expression set specified in Table 59. “R”=Pearson correlation coefficient; “P”=p value

TABLE 79
Correlation between the expression level of selected genes of some
embodiments of the invention in various tissues and the phenotypic
performance under Low N growth stress conditions across Sorghum accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	ID	Name	R	P value	set	ID
LBY14	0.73	6.20E−02	4	6	LBY151	0.74	5.82E−02	4	41
LBY156	0.82	2.32E−02	4	33	LBY156	0.83	1.98E−02	4	12
LBY159	0.80	2.92E−02	4	33	LBY159	0.73	6.10E−02	4	12
LBY161	0.86	1.35E−02	4	5	LBY162	0.73	6.00E−02	4	33
LBY162	0.76	4.85E−02	4	12	LBY166	0.87	1.08E−02	4	4
LBY166	0.71	7.46E−02	4	41	LBY168	0.73	6.48E−02	4	56
LBY177	0.81	2.81E−02	4	56	LBY178	0.76	4.89E−02	4	7
LBY181	0.72	6.86E−02	4	4	LBY186	0.90	5.68E−03	4	56
LBY192	0.80	2.97E−02	4	56	LGN54	0.88	9.25E−03	4	7
LGN57	0.72	6.55E−02	4	5	LGN6	0.93	2.47E−03	4	6

Table 79. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 60. “Exp. Set”—Expression set specified in Table 59. “R”=Pearson correlation coefficient; “P”=p value

Example 10

Production of Maize Transcriptome and High Throughput Correlation Analysis Using 60K Maize Oligonucleotide Micro-Array

To produce a high throughput correlation analysis, the present inventors utilized a Maize oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60K Maize genes and transcripts designed based on data from Public databases (Example 1). To define correlations between the levels of RNA expression and yield, biomass components or vigor related parameters, various plant characteristics of 12 different Maize hybrids were analyzed. Among them, 10 hybrids encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

All 10 selected maize hybrids were sampled in three time points (TP2=V2−V3 (when two to three collar leaf are visible, rapid growth phase and kernel row determination begins), TP5=R1−R2 (silking-blister), TP6=R3−R4 (milk-dough). Four types of plant tissues [Ear, flag leaf indicated in Table as leaf, grain distal part, and internode] were sampled and RNA was extracted as described in “GENERAL EXPERIMENTAL AND BIOINFORMATICS METHODS”. For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 80 below.

TABLE 80
Tissues used for Maize transcriptome expression sets
Expression Set                   Set ID
Ear under normal conditions at reproductive stage: R1-R2 1
Ear under normal conditions at reproductive stage: R3-R4 2
Internode under normal conditions at vegetative stage: 3
Vegetative V2-3
Internode under normal conditions at reproductive stage: R1-R2 4
Internode under normal conditions at reproductive stage: R3-R4 5
Leaf under normal conditions at vegetative stage: Vegetative 6
V2-3
Leaf under normal conditions at reproductive stage: R1-R2 7
Grain distal under normal conditions at reproductive stage: 8
R1-R2

Table 80: Provided are the identification (ID) number of each of the Maize expression sets

The following parameters were collected:

Grain Area (cm²)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Grain Length and Grain width (cm)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths/or width (longest axis) was measured from those images and was divided by the number of grains.

Ear Area (cm²)—At the end of the growing period 6 ears were, photographed and images were processed using the below described image processing system. The Ear area was measured from those images and was divided by the number of Ears.

Ear Length and Ear Width (cm)—At the end of the growing period 6 ears were photographed and images were processed using the below described image processing system. The Ear length and width (longest axis) was measured from those images and was divided by the number of ears.

Filled per Whole Ear—it was calculated as the length of the ear with grains out of the total ear.

Percent Filled Ear—At the end of the growing period 6 ears were photographed and images were processed using the below described image processing system. The percent filled Ear grain was the ear with grains out of the total car and was measured from those images and was divided by the number of Ears.

The image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37. Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Additional parameters were collected either by sampling 6 plants per plot or by measuring the parameter across all the plants within the plot.

Normalized Grain Weight per plant (gr.), measurement of yield parameter—At the end of the experiment all ears from plots within blocks A-C were collected. Six ears were separately threshed and grains were weighted, all additional ears were threshed together and weighted as well. The grain weight was normalized using the relative humidity to be 0%. The normalized average grain weight per ear was calculated by dividing the total normalized grain weight by the total number of ears per plot (based on plot). In case of 6 ears, the total grains weight of 6 ears was divided by 6.

Ear fresh weight (FW) (gr.)—At the end of the experiment (when ears were harvested) total and 6 selected ears per plots within blocks A-C were collected separately. The plants' ears (total and 6) were weighted (gr.) separately and the average ear per plant was calculated for total (Ear FW per plot) and for 6 (Ear FW per plant).

Plant height and Ear height—Plants were characterized for height at harvesting. In each measure, 6 plants were measured for their height using a measuring tape. Height was measured from ground level to top of the plant below the tassel. Ear height was measured from the ground level to the place were the main ear is located

Leaf number per plant—Plants were characterized for leaf number during growing period at 5 time points. In each measure, plants were measured for their leaf number by counting all the leaves of 3 selected plants per plot.

Relative Growth Rate was calculated using regression coefficient of leaf number change a long time course.

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 64 days post sowing. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot. Data were taken after 46 and 54 days after sowing (DPS).

Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours.

Dry weight per plant—At the end of the experiment when all vegetative material from plots within blocks A-C were collected, weight and divided by the number of plants.

Ear diameter [cm]—The diameter of the ear at the mid of the ear was measured using a ruler.

Cob diameter [cm]—The diameter of the cob without grains was measured using a ruler.

Kernel Row Number per Ear—The number of rows in each ear was counted. The average of 6 ears per plot was calculated.

Leaf area index [LAI]=total leaf area of all plants in a plot. Measurement was performed using a Leaf area-meter.

Yield/LAI [kg]—is the ratio between total grain yields and total leaf area index.

TABLE 81
Maize correlated parameters (vectors)
Correlated parameter with        Correlation ID
Cob Diameter (mm)                1
DW per Plant based on 6 (gr.)    2
Ear Area (cm2)                   3
Ear FW per Plant based on 6 (gr.) 4
Ear Height (cm)                  5
Ear Length (cm)                  6
Ear Width (cm)                   7
Ears FW per plant based on all (gr.) 8
Filled per Whole Ear             9
Grain Area (cm2)                 10
Grain Length (cm)                11
Grain Width (cm)                 12
Growth Rate Leaf Number          13
Kernel Row Number per Ear        14
Leaf Number per Plant            15
Normalized Grain Weight per Plant based on all (gr.) 16
Normalized Grain Weight per plant based on 6 (gr.) 17
Percent Filled Ear               18
Plant Height per Plot (cm)       19
SPAD R1                          20
SPAD R2                          21

Table 81.

Experimental Results

Twelve maize varieties were grown and characterized for parameters, as described above. The average for each parameter was calculated using the JMP software, and values are summarized in Tables 82-83 below. Subsequent correlation between the various transcriptome sets for all or sub sets of lines was done by the bioinformatic unit and results were integrated into the database (Table 84 below).

TABLE 82
Measured parameters in Maize Hybrid
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1	28.96	25.08	28.05	25.73	28.72	25.78
2	657.50	491.67	641.11	580.56	655.56	569.44
3	85.06	85.84	90.51	95.95	91.62	72.41
4	245.83	208.33	262.22	263.89	272.22	177.78
5	135.17	122.33	131.97	114.00	135.28	94.28
6	19.69	19.05	20.52	21.34	20.92	18.23
7	5.58	5.15	5.67	5.53	5.73	5.23
8	278.19	217.50	288.28	247.88	280.11	175.84
9	0.916	0.922	0.927	0.917	0.908	0.950
10	0.75	0.71	0.75	0.77	0.81	0.71
11	1.17	1.09	1.18	1.20	1.23	1.12
12	0.81	0.81	0.80	0.80	0.82	0.80
13	0.28	0.22	0.28	0.27	0.31	0.24
14	16.17	14.67	16.20	15.89	16.17	15.17
15	12.00	11.11	11.69	11.78	11.94	12.33
16	153.90	135.88	152.50	159.16	140.46	117.14
17	140.68	139.54	153.67	176.98	156.61	119.67
18	80.62	86.76	82.14	92.71	80.38	82.76
19	278.08	260.50	275.13	238.50	286.94	224.83
20	51.67	56.41	53.55	55.21	55.30	59.35
21	54.28	57.18	56.01	59.68	54.77	59.14

TABLE 83
Measured parameters in Maize Hybrid additional parameters
Ecotype/
Treatment	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1	26.43	25.19		26.67
2	511.11	544.44		574.17	522.22
3	74.03	76.53		55.20	95.36
4	188.89	197.22		141.11	261.11
5	120.94	107.72		60.44	112.50
6	19.02	18.57		16.69	21.70
7	5.22	5.33		4.12	5.58
8	192.47	204.70		142.72	264.24
9	0.87	0.94		0.80	0.96
10	0.71	0.75		0.50	0.76
11	1.14	1.13		0.92	1.18
12	0.79	0.84		0.67	0.81
13	0.24	0.27		0.19	0.30
14	16.00	14.83		14.27	15.39
15	12.44	12.22		9.28	12.56
16	123.24	131.27		40.84	170.66
17	119.69	133.51		54.32	173.23
18	73.25	81.06		81.06	91.60
19	264.44	251.61		163.78	278.44
20	58.48	55.88	52.98	53.86	59.75	49.99
21	57.99	60.36	54.77	51.39	61.14	53.34

Table 83

TABLE 84
Correlation between the expression level of selected genes of some
embodiments of the invention in various tissues and the phenotypic
performance under normal conditions across maize varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY103	0.80	5.38E−02	1	1	LBY103	0.83	4.17E−02	2	12
LBY104	0.77	7.55E−02	7	1	LBY104	0.71	7.40E−02	1	15
LBY104	0.72	6.85E−02	1	9	LBY104	0.76	4.90E−02	1	12
LBY104	0.83	1.07E−02	8	1	LBY104	0.81	1.53E−02	8	14
LBY104	0.93	7.12E−04	8	13	LBY104	0.92	1.32E−03	8	11
LBY104	0.74	3.47E−02	8	6	LBY104	0.84	9.30E−03	8	10
LBY104	0.92	1.05E−03	8	2	LBY104	0.96	1.42E−04	8	7
LBY104	0.79	2.05E−02	8	8	LBY104	0.81	1.47E−02	8	4
LBY104	0.72	1.03E−01	2	14	LBY104	0.79	6.28E−02	2	9
LBY105	0.77	4.07E−02	4	3	LBY105	0.73	6.18E−02	4	16
LBY105	0.83	2.19E−02	4	14	LBY105	0.72	6.98E−02	4	6
LBY105	0.80	3.15E−02	4	19	LBY105	0.87	1.14E−02	4	5
LBY105	0.77	4.17E−02	4	7	LBY105	0.92	3.50E−03	4	8
LBY105	0.82	2.37E−02	4	4	LBY105	0.72	6.90E−02	1	14
LBY105	0.76	4.61E−02	1	11	LBY105	0.76	4.84E−02	1	10
LBY105	0.72	6.82E−02	1	19	LBY105	0.75	5.20E−02	1	7
LBY105	0.71	7.64E−02	1	12	LBY105	0.77	2.57E−02	8	9
LBY105	0.72	3.00E−02	3	14	LBY105	0.71	3.36E−02	3	11
LBY105	0.71	3.15E−02	3	10	LBY105	0.78	1.28E−02	3	18
LBY105	0.74	2.13E−02	3	19	LBY105	0.83	5.48E−03	3	5
LBY105	0.77	1.63E−02	3	7	LBY105	0.81	8.53E−03	3	8
LBY105	0.72	2.95E−02	3	4	LBY105	0.77	7.04E−02	2	14
LBY105	0.87	2.56E−02	2	2	LBY105	0.81	5.01E−02	2	5
LBY106	0.71	4.65E−02	5	12	LBY106	0.74	5.58E−02	4	8
LBY107	0.79	2.02E−02	5	9	LBY107	0.71	7.11E−02	4	6
LBY107	0.77	4.25E−02	4	18	LBY107	0.71	7.14E−02	4	2
LBY107	0.74	5.78E−02	7	15	LBY107	0.75	5.06E−02	7	21
LBY107	0.82	2.37E−02	7	9	LBY107	0.84	1.93E−02	7	12
LBY107	0.76	1.08E−02	6	3	LBY107	0.77	9.15E−03	6	16
LBY107	0.76	1.06E−02	6	17	LBY107	0.83	4.32E−02	2	9
LBY107	0.74	9.17E−02	2	18	LBY107	0.72	1.05E−01	2	12
LBY110	0.70	7.69E−02	7	3	LBY110	0.77	4.38E−02	7	16
LBY110	0.74	5.64E−02	7	15	LBY110	0.91	3.87E−03	7	13
LBY110	0.79	3.46E−02	7	21	LBY110	0.79	3.38E−02	7	11
LBY110	0.78	3.82E−02	7	6	LBY110	0.76	4.61E−02	7	10
LBY110	0.75	5.09E−02	7	7	LBY110	0.74	5.50E−02	7	4
LBY110	0.78	3.70E−02	7	17	LBY110	0.72	4.21E−02	8	1
LBY110	0.77	1.51E−02	3	9	LBY110	0.75	8.75E−02	2	12
LBY112	0.71	7.35E−02	4	14	LBY112	0.78	3.73E−02	1	15
LBY112	0.78	3.89E−02	1	9	LBY112	0.72	6.88E−02	1	10
LBY112	0.77	4.48E−02	1	12	LBY112	0.73	9.94E−02	2	14
LBY113	0.80	3.14E−02	1	15	LBY113	0.82	2.40E−02	1	9
LBY113	0.82	2.48E−02	1	12	LBY113	0.78	2.26E−02	8	1
LBY113	0.92	1.35E−03	8	13	LBY113	0.82	1.33E−02	8	11
LBY113	0.88	3.82E−03	8	10	LBY113	0.80	1.70E−02	8	2
LBY113	0.82	1.19E−02	8	7	LBY113	0.71	4.78E−02	8	8
LBY113	0.70	5.15E−02	8	4	LBY114	0.73	6.49E−02	4	3
LBY116	0.74	3.44E−02	5	6	LBY116	0.89	1.89E−02	7	1
LBY116	0.77	4.21E−02	7	2	LBY116	0.73	4.16E−02	8	13
LBY116	0.76	3.00E−02	8	11	LBY116	0.76	3.03E−02	8	2
LBY116	0.87	2.37E−02	2	14	LBY117	0.77	4.17E−02	1	15
LBY117	0.78	3.82E−02	1	9	LBY117	0.71	7.41E−02	1	12
LBY117	0.86	5.61E−03	8	15	LBY117	0.97	1.59E−03	2	14
LBY117	0.92	9.96E−03	2	5	LBY118	0.70	7.89E−02	1	5
LBY118	0.75	3.26E−02	8	13	LBY118	0.80	1.63E−02	8	2
LBY118	0.79	6.29E−02	2	14	LBY119	0.71	7.40E−02	1	16
LBY119	0.89	7.69E−03	1	15	LBY119	0.76	4.62E−02	1	11
LBY119	0.94	1.93E−03	1	9	LBY119	0.86	1.41E−02	1	10
LBY119	0.73	6.33E−02	1	19	LBY119	0.80	3.21E−02	1	7
LBY119	0.93	2.20E−03	1	12	LBY119	0.74	3.57E−02	8	13
LBY119	0.78	2.25E−02	8	2	LBY120	0.72	1.08E−01	4	1
LBY120	0.70	5.17E−02	8	14	LBY120	0.72	4.19E−02	8	13
LBY120	0.73	4.09E−02	8	11	LBY120	0.85	7.21E−03	8	2
LBY120	0.81	1.55E−02	8	7	LBY120	0.74	9.26E−02	2	14
LBY121	0.82	2.25E−02	7	19	LBY121	0.73	6.24E−02	7	5
LBY121	0.75	5.18E−02	7	12	LBY121	0.94	1.45E−03	1	3
LBY121	0.86	1.27E−02	1	16	LBY121	0.82	2.43E−02	1	14
LBY121	0.74	5.70E−02	1	13	LBY121	0.84	1.88E−02	1	11
LBY121	0.92	3.46E−03	1	6	LBY121	0.79	3.31E−02	1	9
LBY121	0.77	4.36E−02	1	10	LBY121	0.70	7.96E−02	1	18
LBY121	0.73	6.00E−02	1	19	LBY121	0.82	2.31E−02	1	5
LBY121	0.80	3.00E−02	1	7	LBY121	0.89	7.17E−03	1	8
LBY121	0.89	7.24E−03	1	12	LBY121	0.95	1.07E−03	1	4
LBY121	0.91	4.34E−03	1	17	LBY121	0.73	1.03E−01	2	15
LBY123	0.79	3.30E−02	4	14	LBY123	0.79	3.62E−02	1	3
LBY123	0.74	5.72E−02	1	16	LBY123	0.84	1.68E−02	1	14
LBY123	0.79	3.57E−02	1	13	LBY123	0.71	7.65E−02	1	11
LBY123	0.86	1.36E−02	1	6	LBY123	0.71	7.60E−02	1	19
LBY123	0.74	5.80E−02	1	7	LBY123	0.90	6.03E−03	1	8
LBY123	0.87	1.07E−02	1	4	LBY123	0.73	6.36E−02	1	17
LBY123	0.73	3.82E−02	8	1	LBY123	0.79	1.06E−02	3	3
LBY123	0.76	1.82E−02	3	11	LBY123	0.81	7.96E−03	3	6
LBY123	0.75	2.03E−02	3	10	LBY123	0.78	1.34E−02	3	19
LBY123	0.72	2.89E−02	3	7	LBY123	0.76	1.76E−02	3	4
LBY123	0.79	1.19E−02	3	17	LBY233	0.88	2.10E−02	2	14
LBY233	0.71	1.13E−01	2	5	LBY5	0.76	4.59E−02	7	15
LBY5	0.75	2.07E−02	6	1	LBY5	0.74	1.44E−02	6	14
LBY5	0.76	1.09E−02	6	2	LBY5	0.73	1.67E−02	6	5
LBY5	0.78	8.34E−03	6	8	LBY5	0.76	2.84E−02	3	1
LBY5	0.78	6.53E−02	2	9	LBY5	0.78	6.57E−02	2	18
LBY5	0.96	2.27E−03	2	12	LBY6	0.77	4.29E−02	4	13
LBY6	0.78	3.67E−02	4	6	LBY6	0.87	1.03E−02	1	13
LBY6	0.74	5.80E−02	1	6	LBY6	0.74	5.76E−02	1	4
LGN17	0.72	4.42E−02	5	18	LGN17	0.84	3.85E−02	4	1
LGN17	0.85	1.63E−02	4	2	LGN17	0.76	7.70E−02	1	1
LGN17	0.74	5.57E−02	1	2	LGN17	0.89	1.71E−02	2	9
LGN17	0.88	2.20E−02	2	18	LGN20	0.70	7.85E−02	4	3
LGN20	0.81	2.63E−02	4	18	LGN20	0.73	6.22E−02	7	3
LGN20	0.72	6.58E−02	7	5	LGN20	0.74	5.85E−02	1	19
LGN20	0.71	7.17E−02	1	12	LGN20	0.72	2.97E−02	3	3
LGN20	0.73	2.51E−02	3	13	LGN20	0.73	2.52E−02	3	19
LGN20	0.74	2.37E−02	3	5	LGN20	0.75	1.91E−02	3	8
LGN20	0.77	1.51E−02	3	4	LGN20	0.80	5.37E−02	2	13
LGN20	0.71	1.15E−01	2	9	LGN20	0.92	1.04E−02	2	10
LGN20	0.71	1.11E−01	2	18	LGN20	0.74	9.14E−02	2	12
LGN20	0.73	1.02E−01	2	17	LGN23	0.91	6.58E−04	6	1
LGN23	0.79	6.88E−03	6	13	LGN23	0.85	2.00E−03	6	2
LGN23	0.83	2.68E−03	6	8	LGN23	0.78	7.60E−03	6	4
LGN24	0.76	8.07E−02	2	9	LGN26	0.77	2.65E−02	5	10
LGN26	0.73	9.62E−02	1	1	LGN26	0.82	1.22E−02	8	1
LGN26	0.73	3.78E−02	8	14	LGN26	0.77	2.58E−02	8	13
LGN26	0.71	4.85E−02	8	11	LGN26	0.73	4.08E−02	8	2
LGN26	0.71	4.99E−02	8	5	LGN26	0.72	4.39E−02	8	7
LGN26	0.70	5.25E−02	8	8	LGN33	0.73	1.02E−01	2	9
LGN33	0.96	2.67E−03	2	12	LGN34	0.79	1.87E−02	5	9
LGN34	0.85	1.43E−02	4	3	LGN34	0.92	3.81E−03	4	16
LGN34	0.79	3.46E−02	4	14	LGN34	0.80	3.02E−02	4	15
LGN34	0.86	1.40E−02	4	11	LGN34	0.79	3.40E−02	4	6
LGN34	0.91	5.03E−03	4	9	LGN34	0.89	6.98E−03	4	10
LGN34	0.92	2.89E−03	4	19	LGN34	0.90	5.43E−03	4	5
LGN34	0.90	5.75E−03	4	7	LGN34	0.88	8.56E−03	4	8
LGN34	0.87	1.09E−02	4	12	LGN34	0.82	2.39E−02	4	4
LGN34	0.87	1.17E−02	4	17	LGN34	0.86	1.38E−02	1	3
LGN34	0.92	3.40E−03	1	16	LGN34	0.78	4.06E−02	1	14
LGN34	0.94	1.95E−03	1	15	LGN34	0.74	5.79E−02	1	13
LGN34	0.93	2.15E−03	1	11	LGN34	0.77	4.40E−02	1	6
LGN34	0.96	7.52E−04	1	9	LGN34	0.93	2.48E−03	1	10
LGN34	0.86	1.37E−02	1	19	LGN34	0.88	8.85E−03	1	5
LGN34	0.95	1.06E−03	1	7	LGN34	0.78	4.01E−02	1	8
LGN34	0.86	1.37E−02	1	12	LGN34	0.79	3.47E−02	1	4
LGN34	0.89	7.17E−03	1	17	LGN34	0.81	1.39E−02	8	1
LGN34	0.75	3.17E−02	8	2	LGN34	0.83	5.24E−03	3	3
LGN34	0.88	1.89E−03	3	16	LGN34	0.83	5.86E−03	3	15
LGN34	0.88	1.92E−03	3	13	LGN34	0.90	1.08E−03	3	11
LGN34	0.75	1.93E−02	3	6	LGN34	0.84	4.77E−03	3	9
LGN34	0.93	2.61E−04	3	10	LGN34	0.83	5.17E−03	3	19
LGN34	0.78	1.38E−02	3	5	LGN34	0.94	2.12E−04	3	7
LGN34	0.82	6.92E−03	3	8	LGN34	0.89	1.28E−03	3	12
LGN34	0.83	6.02E−03	3	4	LGN34	0.89	1.40E−03	3	17
LGN34	0.77	7.59E−02	2	15	LGN35	0.77	2.45E−02	5	5
LGN35	0.84	4.42E−03	6	1	LGN35	0.79	7.08E−03	6	2
LGN35	0.70	1.19E−01	2	7	LGN36	0.74	8.96E−02	7	1
LGN36	0.78	8.34E−03	6	18	LGN36	0.79	5.95E−02	2	12
LGN39	0.71	7.54E−02	4	16	LGN39	0.74	5.83E−02	4	15
LGN39	0.82	2.34E−02	4	13	LGN39	0.75	5.34E−02	4	6
LGN39	0.74	9.14E−02	1	1	LGN39	0.74	5.97E−02	1	14
LGN39	0.71	7.50E−02	1	13	LGN39	0.72	7.02E−02	1	6
LGN39	0.71	7.30E−02	1	8	LGN39	0.73	6.52E−02	1	4
LGN39	0.78	2.16E−02	8	19	LGN39	0.77	2.62E−02	8	5
LGN49	0.70	7.73E−02	4	9	LGN49	0.82	1.27E−02	8	1
LGN49	0.78	2.34E−02	8	2	LGN61	0.83	1.10E−02	5	2

Table 84. Provided are the correlations (R) between the expression levels of the yield improving genes and their homologs in various tissues [Expression (Exp) sets. Table 80] and the phenotypic performance [yield, biomass, growth rate and/or vigor components (Table 82-83) as determined using the Correlation vector (Corr.) in Table 81)] under normal conditions across maize varieties. P=p value.

Example 11

Production of Maize Transcriptome and High Throughput Correlation Analysis with Yield, Nue, and Abst Related Parameters Measured in Semi-Hydroponics Conditions Using 60K Maize Oligonucleotide Micro-Arrays

Maize vigor related parameters under low nitrogen, 100 mM NaC, low temperature (10 t 2° C.) and normal growth conditions—Twelve Maize hybrids were grown in 5 repetitive plots, each containing 7 plants, at a net house under semi-hydroponics conditions. Briefly, the growing protocol was as follows: Maize seeds were sown in trays filled with a mix of vermiculite and peat in a 1:1 ratio. Following germination, the trays were transferred to the high salinity solution (100 mM NaCl in addition to the Full Hoagland solution at 28±2° C. low temperature (“cold conditions” of 10±2° C. in the presence of Full Hoagland solution), low nitrogen solution (the amount of total nitrogen was reduced in 90% from the full Hoagland solution (i.e., to a final concentration of 10% from full Hoagland solution, final amount of 1.6 mM N, at 28±2° C.) or at Normal growth solution (Full Hoagland containing 16 mM N solution, at 28±2° C.). Plants were grown at 28±2° C.

Full Hoagland solution consists of: KNO₃—0.808 grams/liter, MgSO₄—0.12 grams/liter, KH₂PO₄—0.136 grams/liter and 0.01% (volume/volume) of ‘Super coratin’ micro elements (Iron-EDDHA [ethylenediamine-N,N′-bis(2-hydroxyphenylacetic acid)]—40.5 grams/liter, Mn—20.2 grams/liter; Zn 10.1 grams/liter; Co 1.5 grams/liter; and Mo 1.1 grams/liter), solution's pH should be 6.5-6.8].

Analyzed Maize tissues—Twelve selected Maize hybrids were sampled per each treatment. Two tissues [leaves and root tip] growing at 100 mM NaCl, low temperature (10±2° C.), low Nitrogen (1.6 mM N) or under Normal conditions were sampled at the vegetative stage (V4-5) and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 85-88 below.

TABLE 85
Maize transcriptome expression sets under semi hydroponics and normal
conditions
Expression set                   Set ID
leaf at vegetative stage (V4-V5) under Normal conditions 1
root tip at vegetative stage (V4-V5) under Normal conditions 2

Table 85: Provided are the Maize transcriptome expression sets at normal conditions.

TABLE 86
Maize transcriptome expression sets under semi hydroponics and
cold conditions
Expression set                   Set ID
leaf at vegetative stage (V4-V5) under cold conditions 1
root tip at vegetative stage (V4-V5) under cold conditions 2

Table 86: Provided are the Maize transcriptome expression sets at cold conditions.

TABLE 87
Maize transcriptome expression sets under semi hydroponics and low N
(Nitrogen deficient) conditions
Expression set                   Set ID
leaf at vegetative stage (V4-V5) under low N conditions 1
(1.6 mM N)
root tip at vegetative stage (V4-V5) under low N conditions 2
(1.6 mM N)

Table 87: Provided are the Maize transcriptome expression sets at low nitrogen conditions 1.6 mM Nitrogen.

TABLE 88
Maize transcriptome expression sets under semi hydroponics and
salinity conditions
Expression set                   Set ID
leaf at vegetative stage (V4-V5) under salinity conditions 1
(NaCl 100 mM)
root tip at vegetative stage (V4-V5) under salinity conditions 2
(NaCl 100 mM)

Table 88: Provided are the Maize transcriptome expression sets at 100 mM NaCl.

The following parameters were collected:

Leaves DW—leaves dry weight per plant (average of five plants).

Plant Height growth—was calculated as regression coefficient of plant height [cm] along time course (average of five plants).

Root DW—root dry weight per plant, all vegetative tissue above ground (average of four plants).

Root length—the length of the root was measured at V4 developmental stage.

Shoot DW—shoot dry weight per plant, all vegetative tissue above ground (average of four plants) after drying at 70° C. in oven for 48 hours.

Shoot FW—shoot fresh weight per plant, all vegetative tissue above ground (average of four plants).

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 30 days post sowing. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Experimental Results

12 different Maize hybrids were grown and characterized at the vegetative stage (V4-5) for different parameters. The correlated parameters are described in Table 89 below. The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 90-97 below. Subsequent correlation analysis was performed (Table 98-101). Results were then integrated to the database.

TABLE 89
Maize correlated parameters (vectors)
Correlated parameter with    Correlation ID
Leaves DW [gr]               1
Plant height growth [cm/day] 2
Root DW [gr]                 3
Root length [cm]             4
SPAD                         5
Shoot DW [gr]                6
Shoot FW [gr]                7

Table 89: Provided are the Maize correlated parameters. “DW”—dry weight; “FW”—fresh weight.

TABLE 90
Maize accessions, measured parameters under
low nitrogen growth conditions
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1	0.57	0.45	0.46	0.48	0.36	0.51
2	0.75	0.81	0.88	0.69	0.83	0.84
3	0.38	0.35	0.25	0.36	0.31	0.30
4	44.50	45.63	44.25	43.59	40.67	42.03
5	21.43	21.24	22.23	24.56	22.75	26.47
6	2.56	1.96	2.01	1.94	1.94	2.52
7	23.27	20.58	19.26	20.02	17.98	22.06

Table 90: Provided are the values of each of the parameters (as described above) measured in Maize accessions (Seed ID) under low nitrogen (nitrogen deficient) conditions. Growth conditions are specified in the experimental procedure section.

TABLE 91
Maize accessions, measured parameters under
low nitrogen growth conditions
Ecotype/
Treatment	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1	0.53	0.58	0.55	0.51	0.56	0.39
2	0.78	0.92	0.89	0.85	0.80	0.64
3	0.29	0.31	0.29	0.32	0.43	0.17
4	42.65	45.06	45.31	42.17	41.03	37.65
5	22.08	25.09	23.73	25.68	25.02	19.51
6	2.03	2.37	2.09	2.17	2.62	1.53
7	21.28	22.13	20.29	19.94	22.50	15.93

Table 91: Provided are the values of each of the parameters (as described above measured in Maize accessions (Seed ID) under low nitrogen (nitrogen deficient) conditions. Growth conditions are specified in the experimental procedure section.

TABLE 92
Maize accessions, measured parameters under
100 mM NaCl growth conditions
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1	0.41	0.50	0.43	0.48	0.43	0.56
2	0.46	0.40	0.45	0.32	0.32	0.31
3	0.05	0.05	0.03	0.07	0.05	0.03
4	10.88	11.28	11.82	10.08	8.46	10.56
5	36.55	39.92	37.82	41.33	40.82	44.40
6	2.43	2.19	2.25	2.26	1.54	1.94
7	19.58	20.78	18.45	19.35	15.65	16.09

Table 92: Provided are the values of each of the parameters (as described above measured in Maize accessions (Seed ID) under 100 mM NaCl (salinity) growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 93
Maize accessions, measured parameters under
100 mM NaCl growth conditions
Ecotype/
Treatment	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1	0.33	0.51	0.47	0.98	0.48	0.15
2	0.29	0.36	0.37	0.35	0.31	0.27
3	0.10	0.06	0.02	0.04	0.05	0.01
4	10.14	11.83	10.55	11.18	10.09	8.90
5	37.92	43.22	39.83	38.20	38.14	37.84
6	1.78	1.90	1.89	2.20	1.86	0.97
7	12.46	16.92	16.75	17.64	15.90	9.40

Table 93: Provided are the values of each of the parameters (as described above) measured in Maize accessions (Seed ID) under 100 mM NaCl (salinity) growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 94
Maize accessions, measured parameters under cold growth conditions
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1	1.19	1.17	1.02	1.18	1.04	1.23
2	2.15	1.93	2.12	1.80	2.32	2.15
3	0.05	0.07	0.10	0.08	0.07	0.07
5	28.88	29.11	27.08	32.38	32.68	32.89
6	5.74	4.86	3.98	4.22	4.63	4.93
7	73.79	55.46	53.26	54.92	58.95	62.36

Table 94: Provided are the values of each of the parameters (as described above) measured in Maize accessions (Seed ID) under cold growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 95
Maize accessions, measured parameters under cold growth conditions
Ecotype/
Treatment	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1	1.13	0.98	0.88	1.28	1.10	0.60
2	2.49	2.01	1.95	2.03	1.85	1.21
3	0.14	0.07	0.07	0.02	0.05	0.06
5	31.58	33.01	28.65	31.43	30.64	30.71
6	4.82	4.03	3.57	3.99	4.64	1.89
7	63.65	54.90	48.25	52.83	55.08	29.61

Table 95: Provided are the values of each of the parameters (as described above) measured in Maize accessions (Seed ID) under cold growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 96
Maize accessions, measured parameters
under regular growth conditions
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1	1.16	1.10	0.92	1.01	0.93	0.91
2	1.99	1.92	1.93	1.93	2.15	1.95
3	0.14	0.11	0.23	0.16	0.08	0.05
4	20.15	15.89	18.59	18.72	16.38	14.93
5	34.50	35.77	34.70	34.42	35.26	37.52
6	5.27	4.67	3.88	5.08	4.10	4.46
7	79.00	62.85	59.73	63.92	60.06	64.67

Table 96: Provided are the values of each of the parameters (as described above) measured in Maize accessions (Seed ID) under regular growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 97
Maize accessions, measured parameters
under regular growth conditions
Ecotype/
Treatment	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1	1.11	1.01	1.01	1.02	1.23	0.44
2	2.23	1.94	1.97	2.05	1.74	1.26
3	0.17	0.10	0.07	0.10	0.14	0.03
4	17.48	15.74	15.71	17.58	16.13	17.43
5	36.50	36.07	33.74	34.34	35.74	29.04
6	4.68	4.59	4.08	4.61	5.42	2.02
7	68.10	65.81	58.31	61.87	70.04	35.96

Table 97: Provided are the values of each of the parameters (as described above) measured in Maize accessions (Seed ID) under regular growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 98
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions across
Maize accessions
				Corr.					Corr.
Gene			Exp.	Set	Gene			Exp.	Set
Name	R	P value	set	ID	Name	R	P value	set	ID
LBY107	0.77	9.51E−03	1	1	LBY114	0.74	2.34E−02	2	4
LBY120	0.73	2.64E−02	2	7	LBY120	0.72	3.00E−02	2	3
LGN17	0.80	1.03E−02	2	7	LGN33	0.77	8.77E−03	1	7
LGN36	0.81	8.75E−03	2	5	LGN36	0.70	2.29E−02	1	5
LGN49	0.73	2.53E−02	2	7	LGN49	0.78	1.35E−02	2	5

Table 98. Provided are the correlations (R) between the expression levels of yield improving genes and their homologues in tissues [Leaves or roots; Expression sets (Exp), Table 85] and the phenotypic performance in various biomass, growth rate and/or vigor components [Tables 96-97 using the Correlation vector (corr.) as described in Table 89] under normal conditions across Maize accessions. P=p value.

TABLE 99
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under low nitrogen conditions
across Maize accessions
				Corr.					Corr.
Gene			Exp.	Set	Gene			Exp.	Set
Name	R	P value	set	ID	Name	R	P value	set	ID
LGN34	0.77	1.51E−02	2	2	LGN36	0.79	1.13E−02	2	2
LGN36	0.83	5.33E−03	2	5	LGN49	0.88	1.76E−03	2	5
LGN62	0.71	2.05E−02	1	5	LGN62	0.76	1.14E−02	1	6

Table 99. Provided are the correlations (R) between the expression levels of yield improving genes and their homologues in tissues [Leaves or roots; Expression sets (Exp), Table 87] and the phenotypic performance in various biomass, growth rate and/or vigor components [Tables 90-91 using the Correlation vector (corr.) as described in Table 89] under low nitrogen conditions across Maize accessions. P=p value.

TABLE 100
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under cold conditions across
Maize accessions
				Corr.					Corr.
Gene			Exp.	Set	Gene			Exp.	Set
Name	R	P value	set	ID	Name	R	P value	set	ID
LBY104	0.71	3.27E−02	2	6	LBY117	0.70	3.45E−02	2	7
LBY5	0.71	4.78E−02	1	6	LGN17	0.81	1.42E−02	1	3
LGN18	0.71	3.08E−02	2	7

Table 100. Provided are the correlations (R) between the expression levels of yield improving genes and their homologues in tissues [Leaves or roots; Expression sets (Exp), Table 86] and the phenotypic performance in various biomass, growth rate and/or vigor components [Tables 94-95 using the Correlation vector (corr.) as described in Table 89] under cold conditions (10±2° C.) across Maize accessions. P=p value.

TABLE 101
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under salinity conditions across
Maize accessions
				Corr.					Corr.
Gene			Exp.	Set	Gene			Exp.	Set
Name	R	P value	set	ID	Name	R	P value	set	ID
LBY105	0.72	3.00E−02	2	2	LBY107	0.74	2.13E−02	2	1
LBY107	0.76	1.11E−02	1	7	LBY113	0.77	1.60E−02	2	3
LBY121	0.75	2.10E−02	2	1	LBY121	0.76	1.15E−02	1	1
LGN26	0.80	9.46E−03	2	3	LGN36	0.79	7.08E−03	1	2

Table 101. Provided are the correlations (R) between the expression levels of yield improving genes and their homologues in tissues [Leaves or roots; Expression sets (Exp), Table 88] and the phenotypic performance in various biomass, growth rate and/or vigor components [Tables 92-93 using the Correlation vector (corr.) as described in Table 89] under salinity conditions (100 mM NaCl) across Maize accessions. P=p value.

Example 12

Production of Maize Transcriptome and High Throughput Correlation Analysis when Grown Under Normal Conditions and Defoliation Treatment Using 60K Maize Oligonucleotide Micro-Array

To produce a high throughput correlation analysis, the present inventors utilized a Maize oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60K Maize genes and transcripts designed based on data from Public databases (Example 1). To define correlations between the levels of RNA expression and yield, biomass components or vigor related parameters, various plant characteristics of 13 different Maize hybrids were analyzed under normal and defoliation conditions. Same hybrids were subjected to RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

13 maize hybrids lines were grown in 6 repetitive plots, in field. Maize seeds were planted and plants were grown in the field using commercial fertilization and irrigation protocols. After silking, 3 plots in every hybrid line underwent the defoliation treatment. In this treatment all the leaves above the ear (about 75% of the total leaves) were removed. After the treatment, all the plants were grown according to the same commercial fertilization and irrigation protocols.

Three tissues at flowering developmental (R1) and grain filling (R3) stage including leaf (flowering -R1), stem (flowering -R1 and grain filling -R3), and flowering meristem (flowering -R1) representing different plant characteristics, were sampled from treated and untreated plants. RNA was extracted as described in “GENERAL EXPERIMENTAL AND BIOINFORMATICS METHODS”. For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Tables 102-103 below.

TABLE 102
Tissues used for Maize transcriptome expression sets (Under
normal conditions)
Expression Set                   Set ID
Female meristem at flowering stage under normal conditions 1
leaf at flowering stage under normal conditions 2
stem at flowering stage under normal conditions 3
stem at grain filling stage under normal conditions 4

Table 102: Provided are the identification (ID) numbers of each of the Maize expression sets.

TABLE 103
Tissues used for Maize transcriptome expression sets (Under
defoliation treatment)
Expression Set                   Set ID
Female meristem at flowering stage under defoliation treatment 1
Leaf at flowering stage under defoliation treatment 2
Stem at flowering stage under defoliation treatment 3
Stem at grain filling stage under defoliation treatment 4

Table 103: Provided are the identification (ID) numbers of each of the Maize expression sets.

The image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37. Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

The following parameters were collected by imaging.

1000 grain weight—At the end of the experiment all seeds from all plots were collected and weighed and the weight of 1000 was calculated.

Ear Area (cm²)—At the end of the growing period 5 ears were photographed and images were processed using the below described image processing system. The Ear area was measured from those images and was divided by the number of ears.

Ear Length and Ear Width (cm)—At the end of the growing period 6 ears were, photographed and images were processed using the below described image processing system. The Ear length and width (longest axis) was measured from those images and was divided by the number of ears.

Grain Area (cm²)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Grain Length and Grain width (cm)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths/or width (longest axis) was measured from those images and was divided by the number of grains.

Grain Perimeter (cm)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain perimeter was measured from those images and was divided by the number of grains.

Ear filled grain area (cm²)—At the end of the growing period 5 ears were photographed and images were processed using the below described image processing system. The Ear area filled with kernels was measured from those images and was divided by the number of Ears.

Filled per Whole Ear—was calculated as the length of the ear with grains out of the total ear.

Additional parameters were collected either by sampling 6 plants per plot or by measuring the parameter across all the plants within the plot.

Cob width [cm]—The diameter of the cob without grains was measured using a ruler.

Ear average weight [kg]—At the end of the experiment (when ears were harvested) total and 6 selected ears per plots were collected. The ears were weighted and the average ear per plant was calculated. The ear weight was normalized using the relative humidity to be 0%.

Plant height and Ear height—Plants were characterized for height at harvesting. In each measure, 6 plants were measured for their height using a measuring tape. Height was measured from ground level to top of the plant below the tassel. Ear height was measured from the ground level to the place were the main ear is located

Ear row num—The number of rows per ear was counted.

Ear fresh weight per plant (GF)—During the grain filling period (GF) and total and 6 selected ears per plot were collected separately. The ears were weighted and the average ear weight per plant was calculated.

Ears dry weight—At the end of the experiment (when ears were harvested) total and 6 selected ears per plots were collected and weighted. The ear weight was normalized using the relative humidity to be 0%.

Ears fresh weight—At the end of the experiment (when ears were harvested) total and 6 selected ears per plots were collected and weighted.

Ears per plant—number of ears per plant were counted.

Grains weight (Kg.)—At the end of the experiment all ears were collected. Ears from 6 plants from each plot were separately threshed and grains were weighted.

Grains dry weight (Kg.)—At the end of the experiment all ears were collected. Ears from 6 plants from each plot were separately threshed and grains were weighted. The grain weight was normalized using the relative humidity to be 0%.

Grain weight per ear (Kg.)—At the end of the experiment all ears were collected. 5 ears from each plot were separately threshed and grains were weighted. The average grain weight per ear was calculated by dividing the total grain weight by the number of ears.

Leaves area per plant at GF and HD [LAI41, leaf area index]=Total leaf area of 6 plants in a plot his parameter was measured at two time points during the course of the experiment; at heading (HD) and during the grain filling period (GF). Measurement was performed using a Leaf area-meter at two time points in the course of the experiment; during the grain filling period and at the heading stage (VT).

Leaves fresh weight at GF and HD—This parameter was measured at two time points during the course of the experiment; at heading (HD) and during the grain filling period (GF). Leaves used for measurement of the LAI were weighted.

Lower stem fresh weight at GF, HD and H—This parameter was measured at three time points during the course of the experiment: at heading (HD), during the grain filling period (GF) and at harvest (H). Lower internodes from at least 4 plants per plot were separated from the plant and weighted. The average internode weight per plant was calculated by dividing the total grain weight by the number of plants.

Lower stem length at GF, HD and H—This parameter was measured at three time points during the course of the experiment; at heading (HD), during the grain filling period (GF) and at harvest (H). Lower internodes from at least 4 plants per plot were separated from the plant and their length was measured using a ruler. The average internode length per plant was calculated by dividing the total grain weight by the number of plants.

Lower stem width at GF, HD, and H—This parameter was measured at three time points during the course of the experiment: at heading (HD), during the grain filling period (GF) and at harvest (H). Lower internodes from at least 4 plants per plot were separated from the plant and their diameter was measured using a caliber. The average internode width per plant was calculated by dividing the total grain weight by the number of plants.

Plant height growth—the relative growth rate (RGR) of Plant Height was calculated as described in Formula III above.

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 64 days post sowing. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot. Data were taken after 46 and 54 days after sowing (DPS).

Stem fresh weight at GF and HD—This parameter was measured at two time points during the course of the experiment: at heading (HD) and during the grain filling period (GF). Stems of the plants used for measurement of the LAI were weighted.

Total dry matter—Total dry matter was calculated using Formula XXI above.

Upper stem fresh weight at GF, HD and H—This parameter was measured at three time points during the course of the experiment; at heading (HD), during the grain filling period (GF) and at harvest (H). Upper internodes from at least 4 plants per plot were separated from the plant and weighted. The average internode weight per plant was calculated by dividing the total grain weight by the number of plants.

Upper stem length at GF, HD, and H—This parameter was measured at three time points during the course of the experiment; at heading (HD), during the grain filling period (GF) and at harvest (H). Upper internodes from at least 4 plants per plot were separated from the plant and their length was measured using a ruler. The average internode length per plant was calculated by dividing the total grain weight by the number of plants.

Upper stem width at GF, HD and H (mm)—This parameter was measured at three time points during the course of the experiment; at heading (HD), during the grain filling period (GF) and at harvest (H). Upper internodes from at least 4 plants per plot were separated from the plant and their diameter was measured using a caliber. The average internode width per plant was calculated by dividing the total grain weight by the number of plants.

Vegetative dry weight (Kg.)—total weight of the vegetative portion of 6 plants (above ground excluding roots) after drying at 70° C. in oven for 48 hours weight by the number of plants.

Vegetative fresh weight (Kg.)—total weight of the vegetative portion of 6 plants (above ground excluding roots).

Node number—nodes on the stem were counted at the heading stage of plant development.

TABLE 104
Maize correlated parameters (vectors) under normal grown conditions and under the
treatment of defoliation
Normal conditions	Defoliation treatment
Correlated parameter with	Corr. ID	Correlated parameter with	Corr. ID
1000 grains weight [gr.]	1	1000 grains weight [gr.]	1
Cob width [mm]	2	Cob width [mm]	2
Ear Area [cm2]	3	Ear Area [cm2]	3
Ear Filled Grain Area [cm2]	4	Ear Filled Grain Area [cm2]	4
Ear Width [cm]	5	Ear Width [cm]	5
Ear avr. Weight [gr.]	6	Ear avr weight [gr.]	6
Ear height [cm]	7	Ear height [cm]	7
Ear length [feret's diameter]	8	Ear length (feret's diameter)	8
[cm]		[cm]
Ear row number [num]	9	Ear row number [num]	9
Ears FW per plant (GF)	10	Ears dry weight (SP) [gr.]	10
[gr./plant]
Ears dry weight (SP) [kg]	11	Ears fresh weight (SP) [kg]	11
Ears fresh weight (SP) [kg]	12	Ears per plant (SP) [num]	12
Ears per plant (SP) [num]	13	Filled/Whole Ear [ratio]	13
Filled/Whole Ear [ratio]	14	Grain Perimeter [cm]	14
Grain Perimeter [cm]	15	Grain area [cm2]	15
Grain area [cm2]	16	Grain length [cm]	16
Grain length [cm]	17	Grain width [mm]	17
Grain width [cm]	18	Grains dry yield (SP) [kg]	18
Grains dry yield (SP) [kg]	19	Grains yield (SP) [kg]	19
Grains yield (SP) [kg]	20	Grains yield per ear (SP) [kg]	20
Grains yield per ear (SP) [kg]	21	Leaves FW (HD) [gr.]	21
Leaves FW (GF) [gr.]	22	Leaves area PP (HD) [cm2]	22
Leaves FW (HD) [gr.]	23	Leaves temperature_[GF] [° C.]	23
Leaves area PP (GF) [cm2]	24	Lower Stem FW [H] [gr.]	24
Leaves area PP (HD) [cm2]	25	Lower Stem FW (HD) [gr.]	25
Leaves temperature (GF) [° C.]	26	Lower Stem length [H] [cm]	26
Lower Stem FW (GF) [gr.]	27	Lower Stem length (HD) [cm]	27
Lower Stem FW (H) [gr.]	28	Lower Stem width [H] [mm]	28
Lower Stem FW (HD) [gr.]	29	Lower Stem width (HD) [mm]	29
Lower Stem length (GF) [cm]	30	Node number [num]	30
Lower Stem length (H) [cm]	31	Plant_height [cm]	31
Lower Stem length (HD) [cm]	32	Plant height growth [cm/day]	32
Lower Stem width (GF) [mm]	33	SPAD (GF) [SPAD unit]	33
Lower Stem width (H) [mm]	34	Stem FW (HD) [gr.]	34
Lower Stem width (HD) [mm]	35	Total dry matter (SP) [kg]	35
Node number [num]	36	Upper Stem FW (H)[gr.]	36
Plant height [cm]	37	Upper Stem length (H) [cm]	37
Plant height growth [cm/day]	38	Upper Stem width (H) [mm]	38
SPAD (GF) [SPAD unit]	39	Vegetative DW (SP) [kg]	39
Stem FW (GF) [gr.]	40	Vegetative FW (SP) [kg]	40
Stem FW (HD) [gr.]	41
Total dry matter (SP) [kg]	42
Upper Stem FW (GF) [gr.]	43
Upper Stem FW (H) [gr.]	44
Upper Stem length (GF) [cm]	45
Upper Stem length (H) [cm]	46
Upper Stem width (GF) [mm]	47
Upper Stem width (H) [mm]	48
Vegetative DW (SP) [kg]	49
Vegetative FW (SP) [kg]	50

Table 104.

Thirteen maize varieties were grown, and characterized for parameters, as described above. The average for each parameter was calculated using the JMP software, and values are summarized in Tables 105-108 below. Subsequent correlation between the various transcriptome sets for all or sub set of lines was done and results were integrated into the database (Tables 109 and 110 below).

TABLE 105
Measured parameters in Maize Hybrid under normal conditions
Line/Corr.
ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	296.50	263.25	303.61	304.70	281.18	330.45	290.88
2	24.63	25.11	23.21	23.69	22.81	22.40	23.18
3	82.30	74.63	77.00	90.15	83.80	96.63	78.36
4	80.89	72.42	73.43	85.96	80.64	95.03	74.41
5	4.656	4.787	4.961	4.998	4.650	4.802	4.786
6	209.50	164.63	177.44	218.53	205.58	135.77	147.49
7	121.67	134.24	149.64	152.14	143.83	133.65	118.39
8	22.09	19.62	20.02	23.21	22.63	23.74	20.31
9	13.00	14.94	14.56	14.56	13.56	13.06	16.12
10	351.26	323.08	307.87	330.60	320.51	434.60	325.08
11	1.257	1.087	1.065	1.311	1.234	1.354	1.159
12	1.687	1.457	1.412	1.699	1.519	1.739	1.800
13	1.000	1.111	1.000	1.000	1.000	1.056	1.000
14	0.982	0.969	0.953	0.953	0.949	0.937	0.930
15	3.299	3.233	3.275	3.338	3.178	3.382	3.246
16	0.720	0.667	0.706	0.722	0.671	0.753	0.665
17	1.125	1.123	1.133	1.170	1.081	1.159	1.142
18	0.808	0.753	0.789	0.782	0.787	0.823	0.740
19	0.907	0.800	0.766	0.923	0.833	0.986	0.820
20	1.037	0.913	0.869	1.058	0.953	1.123	0.940
21	0.151	0.133	0.128	0.154	0.139	0.164	0.137
22	230.13	197.64	201.03	205.53	224.81	204.49	212.41
23	110.97	80.57	157.21	128.83	100.57	111.80	116.75
24	7034.60	6402.80	6353.07	6443.92	6835.50	6507.33	7123.48
25	4341.25	3171.00	4205.50	4347.50	3527.00	4517.33	3984.75
26	33.11	33.52	33.87	34.18	33.78	32.85	33.19
27	35.40	25.03	26.51	21.74	26.13	34.44	27.61
28	23.52	20.34	25.08	14.18	17.53	25.74	20.60
29	72.99	59.90	74.72	90.48	69.52	66.91	60.36
30	19.35	20.40	20.93	21.38	20.03	20.31	18.08
31	16.76	20.02	22.59	21.68	22.34	21.39	17.07
32	14.50	17.75	20.00	19.35	20.33	20.75	15.00
33	19.86	16.84	16.14	16.37	17.01	17.53	18.11
34	19.42	17.19	16.09	16.92	17.52	17.88	17.96
35	24.14	20.53	20.97	24.43	21.70	19.49	23.47
36	15.22	14.56	14.61	14.83	15.00	13.83	14.28
37	265.11	255.94	271.11	283.89	279.72	268.78	244.25
38	6.30	6.52	7.14	6.98	7.41	7.50	5.60
39	59.77	53.17	53.21	54.95	53.99	55.24	55.38
40	649.03	489.32	524.06	512.66	542.16	627.76	507.78
41	758.61	587.88	801.32	794.80	721.87	708.38	660.70
42	2.57	2.06	2.32	2.44	2.36	2.57	2.23
43	19.61	15.54	17.82	10.79	14.41	20.31	15.85
44	12.94	11.21	12.98	6.50	7.99	12.08	9.72
45	16.63	18.75	18.38	17.92	17.60	18.79	17.07
46	16.93	18.76	18.72	20.01	19.40	19.65	16.42
47	16.00	14.11	13.50	11.89	13.08	14.34	15.04
48	14.93	13.00	12.44	12.04	12.89	13.28	13.10
49	1.308	0.971	1.251	1.131	1.128	1.213	1.073
50	3.157	2.252	2.607	2.596	2.416	2.640	2.220

Table 105.

TABLE 106
Measured parameters in Maize Hybrid under
normal conditions, additional maize lines
Line/Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13
1	250.26	306.20	253.19	277.03	269.53	274.81
2	24.88	26.47	23.09	22.69	23.55	26.31
3	93.91	96.77	85.44	76.77	97.99
4	92.31	95.43	83.28	74.35	96.88
5	5.182	5.001	4.952	4.786	5.426
6	207.11	228.44	215.92	198.69	188.50	254.42
7	145.24	133.78	143.71	134.17	143.00	147.78
8	22.60	23.84	21.74	20.04	22.41
9	15.89	14.00	15.44	14.89	14.94	16.78
10	327.15	363.70	405.72	338.24	345.32	369.69
11	1.292	1.371	1.296	1.192	1.131	1.527
12	1.595	1.739	1.681	1.565	1.421	1.891
13	1.056	1.000	1.000	1.000	1.000	1.000
14	0.982	0.986	0.974	0.966	0.989
15	3.182	3.291	3.269	3.216	3.155	3.384
16	0.646	0.705	0.678	0.670	0.652	0.723
17	1.118	1.151	1.163	1.124	1.090	1.206
18	0.730	0.774	0.739	0.756	0.757	0.760
19	0.921	1.017	0.942	0.852	0.813	1.142
20	1.050	1.155	1.076	0.974	0.924	1.287
21	0.154	0.169	0.157	0.142	0.136	0.190
22	181.43	199.22	206.91	168.54	199.42	200.12
23	106.95	85.97	102.71	105.73	102.12	143.06
24	6075.21	6597.67	6030.40	6307.06	6617.65	6848.03
25	3696.75	3926.67	3127.67	3942.75	3955.00	4854.00
26	33.66	33.78	32.64	33.95	33.28	33.90
27	25.26	26.18	34.31	25.50	23.06	25.59
28	16.35	18.90	27.30	22.35	19.26	22.82
29	63.07	55.89	82.13	60.02	58.70	116.12
30	20.18	19.81	22.89	19.81	19.53	21.40
31	20.69	18.48	23.31	19.39	19.66	19.97
32	18.68	20.50	22.57	19.83	14.50	20.33
33	17.09	16.87	17.49	16.62	17.10	17.38
34	18.42	17.43	18.07	17.68	17.61	18.93
35	20.97	21.46	21.41	22.12	23.25	24.31
36	14.72	15.44	14.33	14.44	14.89	14.39
37	273.56	273.22	295.33	259.25	257.89	277.19
38	6.96	7.02	7.83	6.98	6.56	7.25
39	56.76	55.81	58.54	51.68	55.16	54.16
40	549.34	509.74	662.13	527.43	474.68	544.03
41	724.58	618.46	837.56	612.81	728.00	950.29
42	2.73	2.33	2.40	2.20	2.08	2.84
43	14.39	17.85	20.42	13.93	13.05	16.45
44	6.98	9.40	13.58	9.20	7.69	10.17
45	17.52	18.15	18.61	17.69	18.15	18.64
46	18.34	16.63	19.38	16.71	16.27	15.92
47	13.63	14.73	14.61	13.17	12.77	14.15
48	13.48	13.42	13.27	13.14	12.53	13.79
49	1.438	0.961	1.100	1.007	0.953	1.313
50	2.897	2.224	2.827	2.295	2.151	2.900

Table 106.

TABLE 107
Measured parameters in Maize Hybrid under defoliation treatment
Line/
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	280.03	251.86	294.29	295.36	288.40	308.25	230.12
2	19.03	22.12	16.31	21.54	19.84	18.21	19.77
3	53.60	45.50	38.31	58.47	53.89	63.54	39.83
4	51.50	42.95	34.59	55.67	51.36	61.44	36.31
5	4.181	4.207	3.919	4.773	4.506	4.612	4.099
6	89.20	100.75	73.39	129.84	129.78	115.06	85.04
7	119.44	131.56	145.53	156.06	145.28	129.53	123.38
8	16.34	13.63	12.89	15.94	15.34	17.53	13.21
9	12.71	14.36	13.00	14.12	13.47	13.07	14.06
10	0.747	0.583	0.440	0.742	0.779	0.576	0.454
11	0.973	0.833	0.629	0.979	1.010	0.803	0.648
12	1.000	0.944	1.000	0.944	1.000	0.941	0.889
13	0.954	0.915	0.873	0.950	0.948	0.961	0.905
14	3.109	3.144	3.179	3.207	3.196	3.230	3.130
15	0.649	0.632	0.669	0.675	0.677	0.683	0.631
16	1.052	1.080	1.079	1.110	1.087	1.094	1.066
17	0.777	0.740	0.781	0.765	0.786	0.788	0.750
18	0.523	0.400	0.289	0.517	0.547	0.398	0.302
19	0.604	0.456	0.331	0.588	0.624	0.458	0.345
20	0.087	0.069	0.048	0.090	0.091	0.080	0.056
21	112.27	94.99	125.14	144.48	112.50	116.16	113.78
22	3914.00	3480.00	4276.50	4985.50	4643.50	4223.00	3436.00
23	32.47	33.09	33.64	32.29	32.87	33.40	33.43
24	23.02	26.50	26.98	15.24	18.19	37.21	27.88
25	64.16	53.81	56.41	80.95	71.27	66.69	64.19
26	16.29	21.44	20.85	22.58	22.94	21.62	18.76
27	15.15	18.50	16.67	18.07	18.00	19.83	16.10
28	19.54	16.90	15.79	17.01	17.12	18.17	18.21
29	24.30	20.57	21.06	24.87	20.85	20.46	20.96
30	15.17	14.39	15.00	15.11	14.50	14.22	14.39
31	251.42	248.64	268.06	285.11	278.83	261.88	254.64
32	6.38	6.32	6.31	6.93	6.83	7.14	6.48
33	61.21	57.36	58.02	62.36	60.72	62.22	59.65
34	713.54	538.04	705.53	803.33	703.36	664.23	673.24
35	1.539	1.365	1.440	1.532	1.571	1.574	1.337
36	8.68	11.08	14.10	4.89	6.04	13.95	10.93
37	16.24	18.83	17.74	19.64	20.74	20.14	17.18
38	14.27	12.82	12.69	11.09	12.00	13.03	14.25
39	0.792	0.782	1.000	0.790	0.792	0.998	0.883
40	2.511	1.955	2.797	2.107	2.205	2.785	2.541

Table 107.

TABLE 108
Measured parameters in Maize Hybrid under
defoliation treatment, additional maize lines
Line/Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13
1	271.25	259.43	243.98	262.41	248.64	244.16
2	22.44	20.28	19.64	22.32	23.31	27.78
3	47.33	65.90	43.83	43.28	52.30	58.31
4	43.34	64.80	39.56	40.43	49.28	55.69
5	4.202	4.664	4.056	4.012	4.407	4.975
6	33.10	161.76	89.36	87.68	88.18	124.58
7	135.00	136.50	136.39	130.32	139.71	143.44
8	14.82	17.60	13.78	13.75	15.53	14.87
9	13.75	13.94	12.79	13.00	14.29	15.83
10	0.630	0.803	0.536	0.552	0.512	0.748
11	0.819	1.148	0.877	0.791	0.693	0.991
12	1.000	0.882	1.000	1.056	0.944	1.000
13	0.905	0.983	0.890	0.918	0.940	0.950
14	3.016	3.117	3.086	3.030	2.976	3.153
15	0.610	0.623	0.619	0.600	0.583	0.631
16	1.024	1.084	1.054	1.025	0.995	1.095
17	0.750	0.724	0.741	0.738	0.733	0.725
18	0.439	0.667	0.359	0.377	0.344	0.531
19	0.505	0.767	0.411	0.435	0.394	0.609
20	0.073	0.124	0.060	0.063	0.059	0.088
21	93.74	89.86	86.98	117.27	150.68	161.65
22	4593.00	4315.50	4020.50	4154.00	4851.50	3750.00
23	33.42	33.98	33.12	32.64	33.55	33.27
24	17.33	20.51	25.36	28.41	23.16	38.80
25	76.23	57.85	69.98	67.30	72.90	83.58
26	20.88	17.83	20.70	20.43	20.11	24.13
27	14.83	17.50	23.67	19.00	16.45	20.60
28	17.23	17.88	17.12	17.53	18.63	19.87
29	22.47	21.23	19.85	21.29	23.58	21.37
30	14.67	15.61	14.39	14.06	14.61	14.00
31	261.94	268.88	272.71	262.50	266.33	279.14
32	6.28	7.04	7.20	7.34	6.94	7.27
33	59.99	56.76	65.70	57.94	60.31	57.71
34	738.37	692.23	619.79	729.23	794.64	847.52
35	1.474	1.663	1.477	1.314	1.476	1.715
36	6.48	9.01	10.69	10.38	8.49	12.29
37	19.12	16.74	15.96	17.31	18.19	17.77
38	12.77	13.52	13.08	13.43	13.21	14.72
39	0.844	0.860	0.940	0.762	0.964	0.967
40	2.475	2.350	2.595	2.406	2.699	2.721

Table 108.

Tables 109 and 110 hereinbelow provide the correlations (R) between the expression levels of yield improving genes and their homologs in various tissues [Expression (Exp) sets, Tables 102-103] and the phenotypic performance [yield, biomass, growth rate and/or vigor components described in Tables 105-108 using the Correlation vector (Corr.) described in Table 104] under normal conditions (Table 109) and defoliation treatment (Table 110) across maize varieties. P=p value.

TABLE 109
Correlation between the expression level of selected genes of some
embodiments of the invention in various tissues and the phenotypic performance
under normal conditions across maize varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY104	0.86	3.65E−04	3	46	LBY104	0.70	1.62E−02	2	46
LBY104	0.76	2.78E−03	1	13	LBY105	0.81	1.39E−03	3	46
LBY105	0.74	6.40E−03	3	10	LBY107	0.71	1.34E−02	2	76
LBY109	0.75	5.28E−03	3	23	LBY111	0.70	1.11E−02	3	46
LBY114	0.70	1.59E−02	2	9	LBY115	0.74	3.61E−03	1	39
LBY115	0.73	4.23E−03	1	40	LBY116	0.84	7.06E−04	3	23
LBY116	0.76	4.45E−03	3	25	LBY116	0.75	7.63E−03	2	35
LBY118	0.83	1.57E−03	2	1	LBY120	0.73	1.12E−02	3	14
LBY120	0.89	2.52E−04	2	37	LBY120	0.73	1.09E−02	2	31
LBY120	0.91	9.25E−05	2	30	LBY120	0.74	9.23E−03	2	38
LBY121	0.74	3.50E−03	1	33	LBY121	0.84	2.95E−04	1	39
LBY121	0.74	3.63E−03	1	40	LBY121	0.76	2.73E−03	1	50
LBY122	0.71	1.03E−02	3	10	LBY122	0.76	2.69E−03	1	73
LBY123	0.74	6.00E−03	3	18	LBY233	0.73	1.08E−02	2	37
LBY233	0.82	3.90E−03	2	8	LBY5	0.70	1.05E−02	3	2
LBY5	0.81	7.49E−04	1	42	LBY5	0.73	4.29E−03	1	11
LBY6	0.86	6.98E−04	2	43	LBY6	0.73	1.12E−02	2	27
LBY6	0.71	6.91E−03	1	48	LGN24	0.70	1.11E−02	3	6
LGN24	0.71	6.18E−03	1	33	LGN24	0.74	4.09E−03	1	48
LGN26	0.78	2.49E−03	3	15	LGN26	0.77	3.48E−03	3	16
LGN26	0.78	3.07E−03	3	25	LGN26	0.76	3.86E−03	3	10
LGN33	0.80	1.90E−03	3	26	LGN35	0.72	8.40E−03	3	40
LGN35	0.73	6.49E−03	3	10	LGN35	0.71	1.01E−02	3	28
LGN35	0.70	1.64E−02	2	31	LGN36	0.74	5.86E−03	3	42
LGN36	0.70	1.07E−02	3	19	LGN36	0.71	9.84E−03	3	11
LGN36	0.70	1.05E−02	3	20	LGN36	0.70	1.07E−02	3	21
LGN39	0.76	3.77E−03	3	45	LGN39	0.71	1.38E−02	2	28
LGN49	0.71	1.34E−02	2	18	LGN49	0.73	1.71E−02	2	8
LGN62	0.75	8.49E−03	2	28

Table 109: Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 104. “Exp. Set”—Expression set specified in Table 102. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 110
Correlation between the expression level of selected genes of some
embodiments of the invention in various tissues and the phenotypic
performance under defoliation treatment across maize varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY103	0.79	2.17E−03	1	30	LBY105	0.73	6.78E−03	3	33
LBY105	0.70	1.08E−02	1	34	LBY105	0.72	8.24E−03	1	29
LBY105	0.80	1.73E−03	1	27	LBY107	0.77	3.31E−03	1	31
LBY107	0.81	1.30E−03	1	5	LBY107	0.74	6.04E−03	1	18
LBY107	0.81	1.36E−03	1	7	LBY107	0.72	8.14E−03	1	10
LBY107	0.75	5.02E−03	1	19	LBY107	0.72	8.33E−03	2	23
LBY108	0.73	6.71E−03	3	1	LBY108	0.76	3.96E−03	1	2
LBY108	0.72	7.93E−03	1	9	LBY109	0.72	8.23E−03	2	38
LBY109	0.84	5.43E−04	2	28	LBY110	0.72	8.37E−03	1	29
LBY111	0.78	3.02E−03	1	27	LBY111	0.88	1.90E−04	2	12
LBY112	0.79	2.05E−03	1	21	LBY115	0.81	1.54E−03	1	2
LBY116	0.37	3.37E−03	1	9	LBY116	0.71	1.02E−02	2	28
LBY121	0.76	3.90E−03	3	37	LBY121	0.72	7.83E−03	3	17
LBY121	0.72	8.01E−03	3	9	LBY122	0.72	7.74E−03	1	27
LBY13	0.71	9.28E−03	1	39	LBY13	0.74	5.59E−03	1	27
LBY233	0.72	8.71E−03	3	33	LBY233	0.74	5.79E−03	2	21
LBY233	0.76	3.87E−03	2	31	LBY233	0.74	5.61E−03	2	5
LBY233	0.83	9.17E−04	2	34	LBY233	0.79	2.10E−03	2	25
LBY233	0.75	4.83E−03	2	9	LBY233	0.76	4.36E−03	2	7
LBY5	0.71	9.09E−03	1	32	LBY5	0.81	1.30E−03	2	12
LBY6	0.32	8.87E−03	1	11	LBY6	0.76	4.09E−03	1	18
LBY6	0.76	3.94E−03	1	19	LBY6	0.83	8.60E−04	1	20
LGN18	0.72	8.27E−03	2	30	LGN20	0.75	5.28E−03	3	29
LGN24	0.79	2.28E−03	3	4	LGN24	0.79	2.05E−03	3	3
LGN24	0.85	5.35E−04	3	8	LGN24	0.77	3.46E−03	1	11
LGN24	0.79	2.23E−03	1	18	LGN24	0.71	9.31E−03	1	10
LGN24	0.79	2.00E−03	1	19	LGN24	0.80	1.79E−03	1	20
LGN26	0.72	8.76E−03	3	1	LGN26	0.71	9.06E−03	1	18
LGN26	0.70	1.06E−02	1	19	LGN26	0.78	2.98E−03	1	20
LGN26	0.76	3.82E−03	2	4	LGN26	0.73	7.11E−03	2	13
LGN26	0.76	3.75E−03	2	6	LGN26	0.72	7.74E−03	2	18
LGN26	0.75	5.01E−03	2	3	LGN26	0.72	7.71E−03	2	19
LGN26	0.84	6.89E−04	2	20	LGN33	0.71	1.03E−02	3	1
LGN34	0.81	1.38E−03	1	15	LGN34	0.79	2.21E−03	1	17
LGN39	0.76	4.26E−03	3	37	LGN39	0.74	5.82E−03	1	30
LGN39	0.82	1.06E−03	2	21	LGN49	0.85	4.62E−04	3	29
LGN49	0.72	7.97E−03	1	15	LGN49	0.78	2.67E−03	1	17

Table 110: Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 104. “Exp. Set”—Expression set specified in Table 103. “R”=Pearson correlation coefficient: “P”=p value.

Example 13 Production of Maize Transcriptome and High Throughput Correlation Analysis with Yield and Nue Related Parameters Using 60K Maize Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a maize oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60.000 maize genes and transcripts.

Correlation of Maize hybrids across ecotypes grown under low Nitrogen conditions

Experimental Procedures 12 Maize hybrids were grown in 3 repetitive plots in field. Maize seeds were planted and plants were grown in the field using commercial fertilization and irrigation protocols, which included 485 m³ water per dunam per entire growth period and fertilization of 30 units of nitrogen (using URAN® 21% fertilization) per dunam per entire growth period (normal conditions) or under low nitrogen conditions which included 50% percent less Nitrogen as compared to the amount of nitrogen provided under the normal conditions. In order to define correlations between the levels of RNA expression with NUE and yield components or vigor related parameters the 12 different maize hybrids were analyzed. Among them, 11 hybrids encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Analyzed Maize tissues—All 10 selected maize hybrids were sampled per each treatment (low N and normal conditions), in three time points (TP2=V6-V8 (six to eight collar leaf are visible, rapid growth phase and kernel row determination begins). TP5=R1-R2 (silking-blister), TP6=R3-R4 (milk-dough). Four types of plant tissues [Ear, “flag leaf” indicated in Table as “leaf”, grain distal part, and internode] were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Tables 111-112 below.

TABLE 111
Maize transcriptome expression sets under low nitrogen conditions
                                 Set
Expression Set                   ID
Ear under low nitrogen conditions at reproductive stage: R1-R2 1
Ear under low nitrogen conditions at reproductive stage: R3-R4 2
Internode under low nitrogen conditions at vegetative stage: V6-V8 3
Internode under low nitrogen conditions at reproductive stage: R1-R2 4
Internode under low nitrogen conditions at reproductive stage: R3-R4 5
Leaf under low nitrogen conditions at vegetative stage: V6-V8 6
Leaf under low nitrogen conditions at reproductive stage: R1-R2 7
Leaf under low nitrogen conditions at reproductive stage: R3-R4 8

Table 111: Provided are the maize transcriptome expression sets under low nitrogen conditions Leaf=the leaf below the main ear; Flower meristem=Apical meristem following male flower initiation; Ear=the female flower at the anthesis day. Grain Distal=maize developing grains from the cob extreme area, Grain Basal=maize developing grains from the cob basal area; Internodes=internodes located above and below the main ear in the plant.

TABLE 112
Maize transcriptome expression sets
under normal growth conditions
                                 Set
Expression Set                   ID
Ear at R1-R2 stage under normal conditions 1
Grain distal at R4-R5 stage under normal conditions 2
Internode at R3-R4 stage under normal conditions 3
Leaf at R1-R2 stage under normal conditions 4
Ear at R3-R4 stage under normal conditions 5
Internode at R1-R2 stage under normal conditions 6
Internode at V6-V8 stage under normal conditions 7
Leaf at V6-V8 stage under normal conditions 8

Table 112: Provided are the maize transcriptome expression sets under normal growth conditions. Leaf=the leaf below the main ear; Flower meristem=Apical meristem following male flower initiation; Ear=the female flower at the anthesis day. Grain Distal=maize developing grains from the cob extreme area, Grain Basal=maize developing grains from the cob basal area; Internodes=internodes located above and below the main ear in the plant.

The following parameters were collected using digital imaging system: Grain Area (cm²)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Grain Length and Grain width (cm)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths/or width (longest axis) was measured from those images and was divided by the number of grains.

Ear Area (cm²)—At the end of the growing period 5 ears were photographed and images were processed using the below described image processing system. The Ear area was measured from those images and was divided by the number of Ears.

Ear Length and Ear Width (cm)—At the end of the growing period 5 ears were photographed and images were processed using the below described image processing system. The Ear length and width (longest axis) was measured from those images and was divided by the number of ears.

The image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Additional parameters were collected either by sampling 6 plants per plot or by measuring the parameter across all the plants within the plot.

Normalized Grain Weight per plant (gr.)—At the end of the experiment all ears from plots within blocks A-C were collected. Six ears were separately threshed and grains were weighted, all additional ears were threshed together and weighted as well. The average grain weight per ear was calculated by dividing the total grain weight by number of total ears per plot (based on plot). In case of 6 ears, the total grains weight of 6 ears was divided by 6.

Ear FW (gr.)—At the end of the experiment (when ears were harvested) total and 6 selected ears per plots within blocks A-C were collected separately. The plants (total and 6) were weighted (gr.) separately and the average ear per plant was calculated for total (Ear FW per plot) and for 6 (Ear FW per plant).

Plant height and Ear height—Plants were characterized for height at harvesting. In each measure. 6 plants were measured for their height using a measuring tape. Height was measured from ground level to top of the plant below the tassel. Ear height was measured from the ground level to the place were the main ear is located.

Leaf number per plant—Plants were characterized for leaf number during growing period at 5 time points. In each measure, plants were measured for their leaf number by counting all the leaves of 3 selected plants per plot.

Relative Growth Rate was calculated using Formulas II-XIII, XXVIII, and/or XXXIV (described above).

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at early stages of grain filling (R1-R2) and late stage of grain filling (R3-R4). SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot. Data were taken after 46 and 54 days after sowing (DPS).

Dry weight per plant—At the end of the experiment (when inflorescence were dry) all vegetative material from plots within blocks A-C were collected.

Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours.

Harvest Index (HI) (Maize)—The harvest index per plant was calculated using Formula XVII above.

Percent Filled Ear [%]—The percent of filled ear was calculated as the percentage of the Ear area with grains out of the total ear.

Cob diameter [cm]—The diameter of the cob without grains was measured using a ruler.

Kernel Row Number per Ear—The number of rows in each ear was counted.

Experimental Results 11 different maize hybrids were grown and characterized for different parameters. Tables 111-112 describe the Maize expression sets, and Tables 113-114 below describe the Maize correlated parameters. The average for each of the measured parameters was calculated using the JMP software (Tables 115-118) and a subsequent correlation analysis was performed (Table 119-120). Results were then integrated to the database.

TABLE 113
Maize correlated parameters (vectors)
under low nitrogen conditions
                                 Correlation
Correlated parameter with        ID
Ear Length under Low N conditions [cm] 1
Ear Length of filled area under Low N conditions [cm] 2
Ear width under Low N conditions [mm] 3
Final Leaf Number under Low N conditions [num] 4
Final Main Ear Height under Low N conditions [cm] 5
Final Plant Height under Low N conditions [cm] 6
No of rows per ear under Low N conditions [num] 7
SPAD at R1-R2 under Low N conditions [SPAD unit] 8
SPAD at R3-R4 under Low N conditions [SPAD unit] 9
Stalk width at TP5 under Low N conditions [mm] 10
Ears weight per plot under Low N conditions [kg] 11
Final Plant DW under Low N conditions [kg] 12
NUE yield/N applied in soil under Low N conditions [ratio] 13
NUE at early grain filling (R1-R2) yield [kg]/N in plant per 14
SPAD under Low N conditions
NUE at grain filling (R3-R4) yield [kg]/N in plant per 15
SPAD under Low N conditions
NUpE under Low N conditions [biomass/N applied] 16
Seed yield per dunam under Low N conditions [kg] 17
Yield/LAI under Low N conditions [ratio] 18
Yield/stalk width under Low N conditions [ratio] 19
seed yield per plant under Low N conditions [kg] 20

Table 113. “cm”=centimeters' “mm”=millimeters; “kg”=kilograms; SPAD at R1-R2 and SPAD R3-R4: Chlorophyll level after early and late stages of grain filling; “NUE”=nitrogen use efficiency; “NUpE”=nitrogen uptake efficiency; “LAI”=leaf area index; “N”=nitrogen; Low N=under low Nitrogen conditions; “dunam”=1000 m².

TABLE 114
Maize correlated parameters (vectors) under normal conditions
                                 Corr.
Correlated parameter with        ID
Final Plant DW under Normal conditions [kg] 1
Ear Length under Normal conditions [cm] 2
Ear Length of filled area under Normal conditions [cm] 3
Ear width under Normal conditions [mm] 4
Final Leaf Number under Normal conditions [num] 5
Final Main Ear Height under Normal conditions [cm] 6
Final Plant Height under Normal conditions [cm] 7
No of rows per ear under Normal conditions [num] 8
SPAD at R1-R2 under Normal conditions [SPAD unit] 9
SPAD at R3-R4 under Normal conditions [SPAD unit] 10
Stalk width at TP5 under Normal conditions [cm] 11
Ears weight per plot under Normal conditions [kg] 12
NUE yield/N applied in soil under Normal conditions [ratio] 13
NUE at early grain filling [R1-R2] yield [kg]/N in plant per SPAD 14
under Normal conditions [ratio]
NUE at grain filling [R3-R4] yield [kg]/N in plant per SPAD 15
under Normal conditions [ratio]
NUpE under Normal conditions [biomass/N applied] 16
Seed yield per dunam [kg] under Normal conditions [kg] 17
Yield/LAI under Normal conditions [ratio] 18
Yield/stalk width under Normal conditions [ratio] 19
Seed yield per plant under Normal conditions [kg] 20

Table 114. “cm”=centimeters' “mm”=millimeters; “kg”=kilograms; SPAD at R1-R2 and SPAD R3-R4: Chlorophyll level after early and late stages of grain filling; “NUE”=nitrogen use efficiency; “NUpE”=nitrogen uptake efficiency; “LAr”=leaf area index; “N”=nitrogen; “Normal”=under normal conditions; “dunam”=1000 nm2.

TABLE 115
Measured parameters in Maize accessions under Low nitrogen conditions
Line/
Corr. ID	1	2	3	4	5	6	7	8	9	10
Line-1	20.614	18.398	46.713	15.024	158.076	305.836	14.181	60.236	59.286	2.764
Line-2	20.976	18.417	48.222	11.643	136.238	270.992	15.214	57.938	57.621	2.419
Line-3	20.222	19.778	48.323	13.500	128.389	290.611	15.000	58.761	58.400	2.650
Line-4	20.111	18.833	49.863	11.611	133.056	252.167	15.667	59.478	59.189	2.767
Line-5	20.111	16.222	52.873	11.833	137.833	260.222	16.000	58.500	58.194	2.672
Line-6	18.500	16.000	47.436	11.889	99.556	227.222	15.944	64.039	62.667	2.594
Line-7	19.056	15.278	49.609	12.556	130.167	271.722	15.556	56.422	61.044	2.983
Line-8	18.250	15.694	48.567	11.667	114.611	248.611	14.500	60.000	59.867	2.611
Line-9	20.095	16.771	52.406	12.443	143.862	279.329	16.410	58.317	57.467	2.650
Line-10	17.806	14.056	42.634	9.278	61.611	171.278	14.367	53.061	49.461	2.278
Line-11	21.250	19.556	50.003	13.167	114.444	269.778	15.744	61.717	61.867	2.817

Table 115. Provided are the values of each of the parameters (as described above) measured in maize accessions (line) under low nitrogen growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 116
Additional parameters in Maize accessions under Low nitrogen conditions
Line/
Corr. ID	11	12	13	14	15	16	17	19	20	18
Line-1	6.605	1.593	7.225	18.023	18.352	0.0106	1083.749	416.532	0.135	341.501
Line-2	7.794	1.429	8.411	21.787	21.919	0.0095	1261.635	528.383	0.158	408.093
Line-3	9.634	1.533	10.328	26.335	26.479	0.0102	1549.245	583.458	0.194	464.768
Line-4	9.222	1.950	9.986	25.144	25.333	0.0130	1497.865	541.017	0.187	522.258
Line-5	7.630	1.483	7.626	19.547	19.685	0.0099	1143.850	428.089	0.143	439.525
Line-6	7.215	1.600	7.728	18.049	18.541	0.0107	1159.260	444.294	0.145	312.581
Line-7	7.917	1.583	8.049	21.388	19.785	0.0106	1207.424	407.200	0.151	345.901
Line-8	28.961	1.283	8.334	20.788	20.917	0.0086	1250.052	477.438	0.156	287.735
Line-9	7.797	1.514	7.640	19.676	19.935	0.0101	1146.036	445.604	0.143
Line-10	2.410	0.433	2.555	7.213	7.722	0.0029	383.219	167.902	0.048
Line-11	9.775	1.517	10.599	25.702	25.902	0.0101	1589.914	562.294	0.199	501.239

Table 116. Provided are the values of each of the parameters (as described above) measured in maize accessions (line) under low nitrogen growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 117
Measured parameters in Maize accessions under normal growth conditions
Line/
Corr. ID	1	2	3	4	5	6	7	8	9	10
Line-1	1.267	19.944	16.233	51.075	11.800	130.311	273.456	16.111	56.889	59.933
Line-2	1.300	20.167	17.500	46.290	11.111	122.333	260.500	14.667	57.161	60.900
Line-3	1.333	18.111	17.722	45.919	13.278	127.667	288.000	15.444	59.272	56.892
Line-4	1.500	19.889	18.444	47.632	11.778	113.022	238.500	15.889	61.611	58.700
Line-5	1.300	19.500	15.667	51.407	11.944	135.278	286.944	16.167	58.628	58.700
Line-6	1.583	17.722	14.667	47.420	12.333	94.278	224.833	15.167	61.228	63.158
Line-7	1.417	17.667	12.944	47.253	12.444	120.944	264.444	16.000	60.167	59.750
Line-8	1.367	17.278	14.028	46.846	12.222	107.722	251.611	14.833	61.089	62.350
Line-9	11.383	20.500	18.778	49.275	12.556	112.500	278.444	15.389	62.200	61.925
Line-10	1.700	17.500	12.333	48.283	11.667	139.667	279.000	17.667	57.506	57.225
Line-11	0.417	19.856	16.067	41.837	9.278	60.444	163.778	14.267	52.044	49.342

Table 117. Provided are the values of each of the parameters (as described above) measured in maize accessions (line) under normal growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 118
Additional measured parameters in Maize accessions under normal growth conditions
Line/
Corr. ID	11	12	13	14	15	16	17	19	20	18
Line-1	2.911	8.943	4.452	23.431	24.978	0.0084	1335.625	456.707	0.167	426.086
Line-2	2.644	7.023	3.624	19.052	17.807	0.0087	1087.058	412.434	0.136	312.975
Line-3	2.711	7.533	4.008	20.293	20.332	0.0089	1202.532	443.368	0.150	307.277
Line-4	2.900	7.991	4.237	20.719	19.957	0.0100	1271.204	438.705	0.159	362.442
Line-5	2.700	8.483	4.010	20.486	19.026	0.0087	1202.966	446.659	0.150	314.138
Line-6	2.622	5.632	3.124	15.360	13.904	0.0106	937.083	356.950	0.117	224.582
Line-7	2.922	6.100	3.286	16.383	16.234	0.0094	985.893	337.486	0.123	266.437
Line-8	2.722	6.659	3.500	17.191	17.214	0.0091	1050.131	385.790	0.131	261.664
Line-9	2.844	8.402	4.551	21.955	21.017	0.0759	1365.293	481.942	0.171	482.329
Line-10	2.656	8.215	4.087	20.994	21.529	0.0038	1226.077	471.568	0.153
Line-11	2.256	1.879	1.003	5.725	5.519	0.0028	300.928	139.728	0.038

Table 118. Provided are the values of each of the parameters (as described above) measured in maize accessions (line) under normal growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 119
Correlation netween the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under low nitrogen conditions
across maize accession
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY103	0.77	1.56E−02	5	10	LBY103	0.80	9 38E−03	5	16
LBY103	0.92	4.29E−04	5	9	LBY103	0.71	3.27E−02	5	3
LBY103	0.80	9.37E−03	5	8	LBY103	0.80	9.38E−03	5	12
LBY103	0.85	3.33E−02	6	5	LBY103	0.72	1.03E−01	6	6
LBY103	0.71	2.18E−02	3	17	LBY103	0.71	2.18E−02	3	13
LBY103	0.71	2.18E−02	3	20	LBY103	0.87	1.02E−02	8	18
LBY103	0.74	3.46E−02	8	2	LBY103	0.70	5.20E−02	8	1
LBY103	0.73	3.86E−02	2	10	LBY103	0.72	4.41E−02	2	9
LBY103	0.75	3.05E−02	2	3	LBY103	0.84	9.84E−03	2	11
LBY103	0.74	5.68E−02	4	11	LBY104	0.96	5.49E−04	1	10
LBY104	0.71	7.37E−02	1	16	LBY104	0.83	2.05E−02	1	9
LBY104	0.88	9.55E−03	1	3	LBY104	0.75	5.31E−02	1	5
LBY104	0.74	5.97E−02	1	11	LBY104	0.71	7.11E−02	1	6
LBY104	0.71	7.37E−02	1	12	LBY104	0.96	2.61E−03	6	5
LBY104	0.90	1.48E−02	6	6	LBY104	0.72	6.67E−02	4	5
LBY104	0.87	1.02E−02	4	8	LBY104	0.85	1.60E−02	4	7
LBY105	0.81	2.73E−02	1	17	LBY105	0.70	7.80E−02	1	16
LBY105	0.77	4.13E−02	1	5	LBY105	0.81	2.73E−02	1	13
LBY105	0.90	6.26E−03	1	19	LBY105	0.78	3.75E−02	1	6
LBY105	0.82	2.43E−02	1	14	LBY105	0.70	7.80E−02	1	12
LBY105	0.74	9.58E−02	1	18	LBY105	0.97	3.17E−04	1	2
LBY105	0.91	4.16E−03	1	1	LBY105	0.81	2.73E−02	1	20
LBY105	0.86	1.40E−02	1	15	LBY105	0.72	2.97E−02	5	4
LBY105	0.91	1.29E−02	6	5	LBY105	0.81	5.33E−02	6	6
LBY105	0.73	1.58E−02	3	10	LBY105	0.81	1.38E−02	8	16
LBY105	0.83	1.11E−02	8	9	LBY105	0.86	5.96E−03	8	5
LBY105	0.80	1.70E−02	8	8	LBY105	0.74	3.71E−02	8	7
LBY105	0.81	1.52E−02	8	6	LBY105	0.81	1.38E−02	8	12
LBY105	0.74	5.58E−02	8	18	LBY105	0.89	3.15E−03	7	17
LBY105	0.75	3.33E−02	7	9	LBY105	0.94	5.63E−04	7	4
LBY105	0.76	2.87E−02	7	3	LBY105	0.89	3.15E−03	7	13
LBY105	0.84	9.72E−03	7	19	LBY105	0.78	2.14E−02	7	6
LBY105	0.86	6.76E−03	7	14	LBY105	0.75	3.16E−02	7	2
LBY105	0.89	3.15E−03	7	20	LBY105	0.86	5.79E−02	7	15
LBY105	0.70	7.97E−02	4	16	LBY105	0.81	2.78E−02	4	5
LBY105	0.93	2.02E−03	4	6	LBY105	0.79	3.36E−02	4	14
LBY105	0.70	7.97E−02	4	12	LBY106	0.96	5.18E−04	8	18
LBY106	0.76	2.73E−02	8	2	LBY107	0.73	1.02E−01	6	17
LBY107	0.72	1.08E−01	6	4	LBY107	0.76	8.05E−02	6	3
LBY107	0.85	3.20E−02	6	8	LBY107	0.71	1.15E−01	6	7
LBY107	0.73	1.02E−01	6	13	LBY107	0.73	1.02E−01	6	20
LBY107	0.75	3.21E−02	8	17	LBY107	0.80	1.62E−02	8	9
LBY107	0.78	2.29E−02	8	3	LBY107	0.70	5.31E−02	8	7
LBY107	0.75	3.21E−02	8	13	LBY107	0.73	4.08E−02	8	14
LBY107	0.75	3.21E−02	8	20	LBY107	0.73	3.98E−02	7	17
LBY107	0.77	2.47E−02	7	4	LBY107	0.79	1.84E−02	7	8
LBY107	0.73	3.98E−02	7	13	LBY107	0.74	3.57E−02	7	19
LBY107	0.81	1.39E−02	7	2	LBY107	0.89	3.43E−03	7	1
LBY107	0.73	3.98E−02	7	20	LBY107	0.70	5.13E−02	7	15
LBY107	0.80	1.78E−02	2	9	LBY107	0.74	5.79E−02	4	9
LBY107	0.73	6.09E−02	4	4	LBY107	0.81	2.70E−02	4	7
LBY108	0.80	2.97E−02	4	4	LBY108	0.92	3.40E−03	4	6
LBY109	0.70	7.92E−02	1	8	LBY109	0.83	1.97E−02	1	11
LBY109	0.74	5.94E−02	4	6	LBY110	0.77	4.48E−02	1	8
LBY110	0.73	1.62E−02	3	8	LBY110	0.72	4.38E−02	7	11
LBY110	0.79	1.95E−02	2	9	LBY110	0.86	6.62E−03	2	8
LBY110	0.74	5.53E−02	4	9	LBY111	0.87	2.44E−02	1	18
LBY111	0.71	1.16E−01	6	10	LBY111	0.78	6.66E−02	6	5
LBY111	0.72	1.08E−01	6	6	LBY111	0.74	3.55E−02	8	1
LBY111	0.75	3.35E−02	2	8	LBY112	0.70	7.69E−02	1	9
LBY112	0.81	2.70E−02	1	3	LBY112	0.82	2.35E−02	1	5
LBY112	0.77	4.24E−02	1	6	LBY112	0.70	1.19E−01	6	3
LBY113	0.88	8.41E−03	1	10	LBY114	0.73	9.84E−02	1	18
LBY114	0.76	4.76E−02	1	1	LBY114	0.75	2.08E−02	5	10
LBY114	0.76	1.64E−02	5	16	LBY114	0.77	1.55E−02	5	4
LBY114	0.71	3.18E−02	5	6	LBY114	0.76	1.64E−02	5	12
LBY114	0.76	1.65E−02	5	2	LBY114	0.70	3.57E−02	5	1
LBY114	0.83	4.29E−02	6	5	LBY114	0.73	9.64E−02	6	6
LBY114	0.74	3.48E−02	8	10	LBY114	0.82	2.37E−02	4	5
LBY116	0.79	6.12E−02	6	5	LBY116	0.75	5.31E−02	8	18
LBY116	0.88	9.23E−03	4	17	LBY116	0.80	2.97E−02	4	3
LBY116	0.88	9.84E−03	4	5	LBY116	0.88	9.23E−03	4	13
LBY116	0.75	5.01E−02	4	6	LBY116	0.90	5.51E−03	4	14
LBY116	0.86	1.23E−02	4	18	LBY116	0.88	9.23E−03	4	20
LBY116	0.84	1.71E−02	4	15	LBY117	0.77	4.09E−02	1	10
LBY117	0.90	6.40E−03	1	11	LBY117	0.81	8.68E−03	5	17
LBY117	0.81	7.98E−03	5	10	LBY117	0.75	2.07E−02	5	16
LBY117	0.78	1.35E−02	5	2	LBY117	0.81	8.68E−03	5	13
LBY117	0.79	1.05E−02	5	14	LBY117	0.75	2.07E−02	5	12
LBY117	0.71	4.81E−02	5	18	LBY117	0.81	8.68E−03	5	20
LBY117	0.78	1.33E−02	5	15	LBY118	0.81	2.74E−02	1	10
LBY118	0.71	7.65E−02	1	5	LBY118	0.83	4.19E−02	6	1
LBY119	0.81	2.69E−02	1	10	LBY119	0.75	5.24E−02	1	16
LBY119	0.80	3.20E−02	1	9	LBY119	0.71	7.15E−02	1	4
LBY119	0.80	3.12E−02	1	3	LBY119	0.75	5.46E−02	1	5
LBY119	0.74	5.86E−02	1	7	LBY119	0.72	6.95E−02	1	6
LBY119	0.75	5.24E−02	1	12	LBY120	0.85	1.55E−02	1	11
LBY120	0.86	2.91E−02	6	5	LBY120	0.78	2.33E−02	8	5
LBY120	0.84	1.89E−02	7	18	LBY120	0.87	1.08E−02	4	8
LBY121	0.93	2.68E−03	1	17	LBY121	0.89	7.74E−03	1	16
LBY121	0.74	5.51E−02	1	9	LBY121	0.78	3.72E−02	1	4
LBY121	0.84	1.89E−02	1	3	LBY121	0.78	3.83E−02	1	5
LBY121	0.71	7.14E−02	1	7	LBY121	0.93	2.68E−03	1	13
LBY121	0.85	1.44E−02	1	19	LBY121	0.71	7.49E−02	1	6
LBY121	0.90	6.39E−03	1	14	LBY121	0.89	7.74E−03	1	12
LBY121	0.70	7.74E−02	1	2	LBY121	0.87	1.15E−02	1	1
LBY121	0.93	2.68E−03	1	20	LBY121	0.91	5.00E−03	1	15
LBY121	0.74	2.32E−02	5	4	LBY121	0.72	1.04E−01	6	10
LBY121	0.90	1.55E−02	6	5	LBY121	0.86	2.81E−02	6	6
LBY121	0.70	5.28E−02	7	11	LBY121	0.70	5.29E−02	2	9
LBY121	0.75	5.30E−02	4	9	LBY121	0.72	6.88E−02	4	5
LBY122	0.90	1.39E−02	1	18	LBY122	0.78	3.69E−02	1	2
LBY122	0.78	3.81E−02	1	1	LBY122	0.72	4.41E−02	8	6
LBY123	0.74	5.70E−02	1	17	LBY123	0.76	4.76E−02	1	4
LBY123	0.80	3.26E−02	1	5	LBY123	0.74	5.70E−02	1	13
LBY123	0.83	2.16E−02	1	19	LBY123	0.84	1.74E−02	1	6
LBY123	0.77	4.33E−02	1	14	LBY123	0.70	1.20E−01	1	18
LBY123	0.73	6.17E−02	1	2	LBY123	0.80	3.01E−02	1	1
LBY123	0.74	5.70E−02	1	20	LBY123	0.74	5.67E−02	1	15
LBY123	0.79	3.33E−02	4	6	LBY13	0.70	7.91E−02	1	10
LBY13	0.72	6.86E−02	1	3	LBY13	0.75	5.46E−02	1	5
LBY13	0.84	4.63E−03	5	16	LBY13	0.80	9.98E−03	5	5
LBY13	0.84	4.63E−03	5	12	LBY13	0.80	5.81E−02	6	5
LBY13	0.77	2.51E−02	8	16	LBY13	0.78	2.36E−02	8	5
LBY13	0.77	2.51E−02	8	12	LBY13	0.71	4.65E−02	2	16
LBY13	0.71	4.65E−02	2	12	LBY233	0.87	2.31E−02	6	4
LBY233	0.72	1.09E−01	6	6	LBY233	0.80	3.06E−02	2	18
LBY233	0.87	1.07E−02	4	9	LBY5	0.71	1.11E−01	1	18
LBY5	0.76	1.69E−02	5	10	LBY5	0.79	1.08E−02	5	3
LBY5	0.87	2.56E−02	6	10	LBY5	0.94	6.07E−03	6	3
LBY5	0.76	1.11E−02	3	10	LBY5	0.89	3.02E−03	8	16
LBY5	0.72	4.53E−02	8	5	LBY5	0.89	3.02E−03	8	12
LBY5	0.78	2.36E−02	7	16	LBY5	0.86	5.74E−03	7	9
LBY5	0.85	6.96E−03	7	8	LBY5	0.77	2.49E−02	7	7
LBY5	0.78	2.36E−02	7	12	LBY6	0.90	1.35E−02	6	9
LBY6	0.72	6.74E−02	8	18	LBY6	0.80	3.16E−02	2	18
LBY6	0.84	8.43E−03	2	2	LBY6	0.71	4.77E−02	2	1
LGN17	0.75	5.26E−02	1	4	LGN17	0.72	6.62E−02	1	19
LGN17	0.79	3.65E−02	1	2	LGN17	0.70	7.78E−02	1	15
LGN17	0.75	1.34E−02	3	5	LGN17	0.83	2.75E−03	3	1
LGN18	0.82	2.48E−02	1	8	LGN18	0.73	1.03E−01	6	17
LGN18	0.73	1.03E−01	6	13	LGN18	0.77	7.38E−02	6	18
LGN18	0.78	6.48E−02	6	1	LGN18	0.73	1.03E−01	6	20
LGN18	0.74	3.59E−02	8	11	LGN18	0.72	4.32E−02	7	4
LGN18	0.76	2.73E−02	7	2	LGN18	0.75	3.32E−02	7	1
LGN18	0.81	2.81E−02	4	11	LGN20	0.76	4.59E−02	1	5
LGN20	0.76	4.88E−02	1	19	LGN20	0.74	5.47E−02	1	2
LGN20	0.83	1.98E−02	1	1	LGN20	0.70	7.84E−02	1	15
LGN20	0.73	2.51E−02	5	11	LGN20	0.75	8.85E−02	6	1
LGN20	0.90	2.30E−03	8	4	LGN20	0.82	1.34E−02	8	5
LGN20	0.91	1.50E−03	8	6	LGN20	0.74	3.48E−02	7	17
LGN20	0.78	2.31E−02	7	3	LGN20	0.70	5.11E−02	7	5
LGN20	0.74	3.48E−02	7	13	LGN20	0.74	1.44E−02	7	19
LGN20	0.73	3.83E−02	7	14	LGN20	0.73	4.14E−02	7	2
LGN20	0.86	5.55E−03	7	1	LGN20	0.74	3.48E−02	7	20
LGN20	0.75	3.13E−02	7	15	LGN20	0.78	3.79E−02	4	3
LGN23	0.81	5.02E−02	6	16	LGN23	0.81	5.02E−02	6	12
LGN23	0.92	3.11E−03	8	18	LGN23	0.90	5.96E−03	7	18
LGN23	0.74	5.74E−02	4	7	LGN24	0.92	2.90E−03	4	5
LGN24	0.79	3.56E−02	4	6	LGN26	0.99	1.68E−04	1	18
LGN26	0.78	3.69E−02	4	17	LGN26	0.78	3.69E−02	4	13
LGN26	0.88	8.52E−03	4	19	LGN26	0.72	7.03E−02	4	6
LGN26	0.87	1.11E−02	4	14	LGN26	0.79	3.36E−02	4	18
LGN26	0.85	1.45E−02	4	2	LGN26	0.79	3.37E−02	4	1
LGN26	0.78	3.69E−02	4	20	LGN26	0.88	8.31E−03	4	15
LGN33	0.91	1.27E−02	6	5	LGN33	0.73	9.89E−02	6	6
LGN33	0.91	1.93E−03	8	5	LGN33	0.83	1.08E−02	8	6
LGN33	0.84	9.65E−03	7	5	LGN34	0.94	1.42E−03	1	17
LGN34	0.76	4.79E−02	1	10	LGN34	0.87	1.11E−02	1	16
LGN34	0.83	1.94E−02	1	9	LGN34	0.84	1.94E−02	1	4
LGN34	0.94	1.72E−03	1	3	LGN34	0.97	3.64E−04	1	5
LGN34	0.94	1.80E−03	1	8	LGN34	0.94	1.42E−03	1	13
LGN34	0.94	1.58E−03	1	19	LGN34	0.94	1.98E−03	1	6
LGN34	0.95	1.16E−03	1	14	LGN34	0.87	1.11E−02	1	12
LGN34	0.72	6.72E−02	1	2	LGN34	0.84	1.73E−02	1	1
LGN34	0.94	1.42E−03	1	20	LGN34	0.93	2.14E−03	1	15
LGN34	0.78	1.33E−02	5	16	LGN34	0.77	1.62E−02	5	9
LGN34	0.78	1.33E−02	5	12	LGN34	0.75	2.09E−02	5	1
LGN34	0.86	1.47E−03	3	17	LGN34	ft79	6.21E−03	3	16
LGN34	0.79	6.29E−03	3	9	LGN34	0.81	4.15E−03	3	8
LGN34	0.86	1.47E−03	3	13	LGN34	0.87	1.15E−03	3	19
LGN34	0.75	1.33E−02	3	11	LGN34	0.81	4.89E−03	3	14
LGN34	0.79	6.21E−03	3	12	LGN34	0.77	9.35E−03	3	2
LGN34	0.78	7.88E−03	3	1	LGN34	0.86	1.47E−03	3	20
LGN34	0.84	2.58E−03	3	15	LGN34	0.70	5.09E−02	8	11
LGN34	0.75	3.06E−02	7	8	LGN34	0.79	2.08E−02	7	7
LGN34	0.76	3.00E−02	7	2	LGN34	0.74	3.43E−02	7	1
LGN34	0.91	1.70E−03	2	10	LGN34	0.93	9.01E−04	2	16
LGN34	0.91	1.73E−03	2	9	LGN34	0.71	4.74E−02	2	4
LGN34	0.81	1.51E−02	2	3	LGN34	0.90	2.66E−03	2	5
LGN34	0.77	2.58E−02	2	6	LGN34	0.93	9.01E−04	2	12
LGN34	0.70	7.84E−02	4	17	LGN34	0.70	7.84E−02	4	13
LGN34	0.83	2.13E−02	4	19	LGN34	0.87	1.06E−02	4	2
LGN34	0.84	1.86E−02	4	1	LGN34	0.70	7.84E−02	4	20
LGN35	0.76	4.54E−02	1	11	LGN35	0.73	9.65E−02	6	10
LGN35	0.88	2.20E−02	6	3	LGN35	0.93	7.85E−03	6	5
LGN35	0.73	1.02E−01	6	6	LGN35	0.75	5.38E−02	4	5
LGN35	0.86	1.29E−02	4	1	LGN36	0.80	5.60E−02	6	17
LGN36	0.80	5.60E−02	6	13	LGN36	0.85	3.21E−02	6	19
LGN36	0.90	1.55E−02	6	6	LGN36	0.90	1.32E−02	6	14
LGN36	0.79	6.42E−02	6	18	LGN36	0.84	3.47E−02	6	2
LGN36	0.80	5.60E−02	6	20	LGN36	0.90	1.49E−02	6	15
LGN36	0.70	7.74E−02	4	4	LGN36	0.90	6.28E−03	4	8
LGN36	0.71	7.47E−02	4	6	LGN39	0.73	6.51E−02	1	19
LGN39	0.78	6.87E−02	1	18	LGN39	0.87	1.06E−02	1	2
LGN39	0.88	9.78E−03	1	1	LGN39	0.84	3.85E−02	6	19
LGN39	0.78	6.56E−02	6	18	LGN39	0.75	8.58E−02	6	2
LGN39	0.73	9.65E−02	6	1	LGN39	0.76	8.15E−02	6	15
LGN39	0.73	4.04E−02	8	4	LGN39	0.77	2.63E−02	7	11
LGN39	0.87	5.35E−03	2	10	LGN39	0.83	1.16E−02	2	16
LGN39	0.86	5.63E−03	2	5	LGN39	0.73	3.89E−02	2	6
LGN39	0.83	1.16E−02	2	12	LGN39	0.83	2.01E−02	4	5
LGN39	0.70	7.99E−02	4	19	LGN49	0.81	2.66E−02	1	17
LGN49	0.77	4.42E−02	1	10	LGN49	0.71	7.31E−02	1	16
LGN49	0.80	3.26E−02	1	4	LGN49	0.89	7.61E−03	1	3
LGN49	0.95	1.20E−03	1	5	LGN49	0.81	2.66E−02	1	13
LGN49	0.75	5.30E−02	1	19	LGN49	0.92	3.41E−03	1	6
LGN49	0.87	1.07E−02	1	14	LGN49	0.71	7.31E−02	1	12
LGN49	0.81	2.81E−02	1	1	LGN49	0.81	2.66E−02	1	20
LGN49	0.82	2.44E−02	1	15	LGN49	0.88	6.75E−04	3	10
LGN49	0.75	1.23E−02	3	16	LGN49	0.75	1.23E−02	3	12
LGN49	0.91	1.95E−03	7	11	LGN49	0.84	1.94E−02	4	11
LGN61	0.79	3.41E−02	1	4	LGN61	0.70	7.75E−02	1	6
LGN61	0.77	2.47E−02	2	16	LGN61	0.70	5.12E−02	2	4
LGN61	0.79	2.00E−02	2	5	LGN61	0.77	2.47E−02	2	12

Table 119. Correlations (R) between the genes expression levels in various tissues and the phenotypic performance under low nitrogen conditions. “Corr. ID”=correlation set ID according to the correlated parameters Table 113 above. “Exp. Set”=Expression set (According to Table 111). “R”=Pearson correlation coefficient; “P”=p value.

TABLE 120
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions across
maize accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY103	0.75	3.25E−02	2	12	LBY103	0.88	3.76E−03	2	4
LBY104	0.86	1.35E−02	1	7	LBY104	0.77	4.18E−02	1	12
LBY104	0.71	7.30E−02	1	11	LBY104	0.73	6.09E−02	1	5
LBY104	0.80	3.01E−02	1	14	LBY104	0.76	4.77E−02	1	13
LBY104	0.78	3.95E−02	1	15	LBY104	0.90	5.25E−03	1	10
LBY104	0.90	5.22E−03	1	6	LBY104	0.76	4.77E−02	1	17
LBY104	0.76	4.77E−02	1	20	LBY104	0.79	3.53E−02	1	9
LBY104	0.82	2.51E−02	1	19	LBY104	0.80	5.74E−02	5	11
LBY104	0.80	5.36E−02	5	6	LBY104	0.93	7.49E−03	5	8
LBY104	0.72	4.61E−02	2	13	LBY104	0.72	4.61E−02	2	17
LBY104	0.72	4.61E−02	2	20	LBY104	0.71	4.78E−02	2	19
LBY104	0.85	3.11E−02	4	18	LBY104	0.81	1.52E−02	3	5
LBY104	0.74	9.02E−02	6	18	LBY105	0.75	5.16E−02	1	11
LBY105	0.73	6.14E−02	1	5	LBY105	0.80	3.00E−02	1	8
LBY105	0.71	7.13E−02	1	9	LBY105	0.95	4.44E−03	5	5
LBY105	0.86	5.88E−03	2	5	LBY105	0.71	4.69E−02	3	7
LBY105	0.84	1.88E−02	6	7	LBY105	0.71	7.13E−02	6	12
LBY105	0.77	4.35E−02	6	5	LBY105	0.75	5.00E−02	6	14
LBY105	0.71	7.46E−02	6	13	LBY105	0.77	4.48E−02	6	15
LBY105	0.86	1.39E−02	6	6	LBY105	0.71	7.46E−02	6	17
LBY105	0.71	7.46E−02	6	20	LBY105	0.74	5.63E−02	6	19
LBY105	0.70	3.50E−02	7	7	LBY105	0.80	9.87E−03	7	12
LBY105	0.72	2.83E−02	7	5	LBY105	0.81	8.79E−03	7	14
LBY105	0.75	2.05E−02	7	13	LBY105	0.87	2.08E−03	7	15
LBY105	0.72	2.72E−02	7	6	LBY105	0.75	2.05E−02	7	17
LBY105	0.75	2.05E−02	7	20	LBY105	0.72	2.78E−02	7	19
LBY105	0.79	1.06E−02	7	2	LBY106	0.86	2.92E−02	5	5
LBY106	0.72	1.07E−01	4	18	LBY107	0.88	1.98E−02	1	18
LBY107	0.86	2.81E−02	5	10	LBY107	0.92	8.90E−03	5	9
LBY107	0.72	1.99E−02	8	12	LBY107	0.75	1.23E−02	8	14
LBY107	0.76	1.11E−02	8	13	LBY107	0.76	1.11E−02	8	17
LBY107	0.76	1.11E−02	8	20	LBY107	0.75	1.25E−02	8	19
LBY107	0.94	1.42E−03	4	10	LBY107	0.72	4.29E−02	3	10
LBY107	0.71	7.42E−02	6	7	LBY107	0.77	4.20E−02	6	4
LBY107	0.81	2.80E−02	6	10	LBY107	0.75	5.42E−02	6	6
LBY107	0.74	5.66E−02	6	8	LBY107	0.71	7.22E−02	6	19
LBY108	0.85	3.24E−02	5	5	LBY108	0.92	1.42E−03	2	16
LBY108	0.92	1.42E−03	2	1	LBY109	0.85	3.02E−02	5	8
LBY109	0.72	4.52E−02	2	11	LBY110	0.78	6.65E−02	5	10
LBY110	0.71	4.64E−02	2	12	LBY110	0.93	8.42E−04	2	4
LBY110	0.78	3.86E−02	4	12	LBY110	0.75	5.19E−02	4	16
LBY110	0.85	1.62E−02	4	11	LBY110	0.75	5.06E−02	4	14
LBY110	0.80	3.23E−02	4	13	LBY110	0.78	3.75E−02	4	4
LBY110	0.76	4.88E−02	4	15	LBY110	0.80	3.23E−02	4	17
LBY110	0.77	4.13E−02	4	8	LBY110	0.80	3.23E−02	4	20
LBY110	0.75	5.19E−02	4	1	LBY110	0.73	6.05E−02	4	9
LBY110	0.89	1.79E−02	4	18	LBY110	0.74	5.65E−02	4	19
LBY110	0.78	1.38E−02	7	10	LBY111	0.86	2.79E−02	5	16
LBY111	0.86	2.79E−02	5	1	LBY111	0.90	1.32E−02	5	9
LBY111	0.74	5.85E−02	4	2	LBY112	0.76	4.86E−02	1	5
LBY112	0.73	6.41E−02	1	4	LBY112	0.87	1.08E−02	1	10
LBY112	0.71	7.51E−02	1	6	LBY112	0.78	3.70E−02	1	9
LBY112	0.73	6.40E−02	1	19	LBY112	0.74	9.50E−02	5	11
LBY112	0.83	4.09E−02	5	8	LBY112	0.72	4.34E−02	2	5
LBY112	0.78	3.91E−02	6	12	LBY112	0.77	4.31E−02	6	11
LBY112	0.80	3.20E−02	6	14	LBY112	0.79	3.46E−02	6	13
LBY112	0.71	7.54E−02	6	4	LBY112	0.75	5.11E−02	6	15
LBY112	0.79	3.46E−02	6	17	LBY112	0.85	1.59E−02	6	8
LBY112	0.79	3.46E−02	6	20	LBY112	0.78	3.83E−02	6	19
LBY113	0.85	1.51E−02	1	10	LBY113	0.83	4.24E−02	5	11
LBY113	0.95	3.52E−03	5	8	LBY113	0.81	1.48E−02	2	12
LBY113	0.92	1.08E−03	2	4	LBY113	0.72	4.45E−02	2	8
LBY114	0.91	1.16E−02	5	5	LBY114	0.83	1.15E−02	2	16
LBY114	0.83	1.15E−02	2	1	LBY114	0.72	6.98E−02	6	6
LBY115	0.91	1.29E−02	5	5	LBY115	0.71	4.64E−02	2	5
LBY116	0.93	7.12E−03	5	8	LBY116	0.75	3.34E−02	3	11
LBY116	0.82	2.24E−02	6	2	LBY117	0.86	1.34E−02	1	10
LBY117	0.80	5.39E−02	5	5	LBY117	0.86	2.87E−02	5	6
LBY117	0.79	6.30E−02	5	8	LBY117	0.75	3.07E−02	2	16
LBY117	0.75	3.07E−02	2	1	LBY117	0.71	4.98E−02	2	9
LBY118	0.72	7.00E−02	1	6	LBY118	0.70	1.18E−01	5	8
LBY118	0.72	4.54E−02	2	4	LBY119	0.73	6.00E−02	1	7
LBY119	0.76	4.66E−02	1	12	LBY119	0.77	4.14E−02	1	14
LBY119	0.76	4.94E−02	1	13	LBY119	0.78	4.01E−02	1	4
LBY119	0.73	6.08E−02	1	15	LBY119	0.93	2.78E−03	1	10
LBY119	0.79	3.44E−02	1	6	LBY119	0.76	4.94E−02	1	17
LBY119	0.76	4.94E−02	1	20	LBY119	0.72	6.77E−02	1	9
LBY119	0.80	3.17E−02	1	19	LBY119	0.73	9.89E−02	5	11
LBY119	0.83	4.24E−02	5	8	LBY121	0.80	2.99E−02	1	7
LBY121	0.86	1.28E−02	1	12	LBY121	0.89	7.02E−03	1	11
LBY121	0.71	7.45E−02	1	5	LBY121	0.85	1.66E−02	1	14
LBY121	0.86	1.39E−02	1	13	LBY121	0.87	1.14E−02	1	15
LBY121	0.78	3.74E−02	1	10	LBY121	0.84	1.67E−02	1	6
LBY121	0.86	1.39E−02	1	17	LBY121	0.86	1.38E−02	1	8
LBY121	0.86	1.39E−02	1	20	LBY121	0.73	9.72E−02	1	18
LBY121	0.81	2.66E−02	1	19	LBY121	0.76	7.70E−02	5	16
LBY121	0.71	1.15E−01	5	8	LBY121	0.76	7.70E−02	5	1
LBY121	0.97	1.37E−03	5	9	LBY121	0.91	1.69E−03	2	4
LBY121	0.82	2.53E−02	4	7	LBY121	0.74	5.68E−02	4	12
LBY121	0.73	6.20E−02	4	14	LBY121	0.71	7.30E−02	4	13
LBY121	0.76	4.68E−02	4	15	LBY121	0.77	4.09E−02	4	6
LBY121	0.71	7.30E−02	4	17	LBY121	0.71	7.30E−02	4	20
LBY121	0.73	6.27E−02	4	19	LBY122	0.71	1.10E−01	5	5
LBY123	0.73	6.37E−02	1	7	LBY123	0.71	7.26E−02	1	12
LBY123	0.80	3.01E−02	1	5	LBY123	0.73	6.44E−02	1	14
LBY123	0.73	6.01E−02	1	13	LBY123	0.74	5.82E−02	1	15
LBY123	0.73	6.34E−02	1	3	LBY123	0.73	6.01E−02	1	17
LBY123	0.77	4.40E−02	1	8	LBY123	0.73	6.01E−02	1	20
LBY123	0.72	6.63E−02	1	19	LBY123	0.75	3.09E−02	2	11
LBY123	0.85	7.42E−03	2	4	LBY123	0.75	3.14E−02	2	8
LBY123	0.99	6.95E−09	8	16	LBY123	0.99	6.95E−09	8	1
LBY123	0.72	3.03E−02	8	18	LBY123	0.90	5.18E−03	6	8
LBY123	0.81	7.80E−03	7	7	LBY123	0.73	2.45E−02	7	6
LBY123	0.71	3.19E−02	7	19	LBY123	0.75	8.76E−02	7	4
LBY13	0.72	4.33E−02	2	12	LBY123	0.80	1.67E−02	2	4
LBY13	0.71	4.95E−02	2	15	LBY123	0.76	3.03E−02	2	18
LBY233	0.78	6.46E−02	5	5	LBY5	0.75	5.37E−02	4	5
LBY6	0.71	7.39E−02	1	11	LBY6	0.71	7.28E−02	1	8
LBY6	0.81	1.49E−02	2	5	LBY6	0.95	9.24E−04	4	16
LBY6	0.95	9.24E−04	4	1	LBY6	0.83	4.31E−02	4	18
LBY6	0.89	6.72E−03	6	16	LBY6	0.89	6.72E−03	6	1
LBY6	0.85	3.03E−02	6	18	LGN17	0.71	2.02E−02	8	3
LGN17	0.74	1.35E−02	8	2	LGN17	0.75	3.12E−02	3	16
LGN17	0.75	3.12E−02	3	1	LGN17	0.73	6.02E−02	6	7
LGN17	0.70	7.71E−02	6	3	LGN17	0.74	5.73E−02	6	6
LGN20	0.70	1.19E−01	5	12	LGN20	0.71	1.17E−01	5	13
LGN20	0.83	3.97E−02	5	4	LGN20	0.71	1.17E−01	5	17
LGN20	0.71	1.17E−01	5	20	LGN20	0.81	5.18E−02	5	19
LGN20	0.81	1.48E−02	2	16	LGN20	0.70	5.09E−02	2	10
LGN20	0.81	1.48E−02	2	1	LGN20	0.73	4.01E−02	2	9
LGN20	0.73	6.45E−02	4	6	LGN20	0.76	2.94E−02	3	2
LGN20	0.84	1.85E−02	6	3	LGN20	0.79	6.32E−02	6	18
LGN20	0.79	3.44E−02	6	2	LGN20	0.79	1.07E−02	7	12
LGN20	0.76	1.66E−02	7	14	LGN20	0.71	3.15E−02	7	13
LGN20	0.79	1.10E−02	7	4	LGN20	0.81	7.58E−03	7	15
LGN20	0.72	2.79E−02	7	6	LGN20	0.71	3.15E−02	7	17
LGN20	0.71	3.15E−02	7	20	LGN23	0.76	7.90E−02	1	18
LGN23	0.70	7.80E−02	1	2	LGN23	0.95	4.30E−03	5	5
LGN24	0.77	7.61E−02	4	18	LGN26	0.87	5.49E−03	2	12
LGN26	0.79	1.99E−02	2	14	LGN26	0.78	2.28E−02	2	13
LGN26	0.90	2.39E−03	2	4	LGN26	0.78	2.33E−02	2	15
LGN26	0.70	5.20E−02	2	6	LGN26	0.78	2.28E−02	2	17
LGN26	0.83	1.00E−02	2	8	LGN26	0.78	2.28E−02	2	20
LGN26	0.76	2.73E−02	2	18	LGN26	0.86	1.21E−02	6	16
LGN26	0.86	1.21E−02	6	1	LGN26	0.80	5.36E−02	6	18
LGN33	0.83	1.06E−02	2	10	LGN33	0.72	6.57E−02	4	8
LGN34	0.93	2.19E−03	1	7	LGN34	0.93	2.40E−03	1	12
LGN34	0.87	1.19E−02	1	11	LGN34	0.93	2.53E−03	1	5
LGN34	0.95	1.28E−03	1	14	LGN34	0.94	1.59E−03	1	13
LGN34	0.93	2.60E−03	1	4	LGN34	0.94	1.80E−03	1	15
LGN34	0.87	1.11E−02	1	10	LGN34	0.90	5.48E−03	1	6
LGN34	0.94	1.59E−03	1	17	LGN34	0.78	4.07E−02	1	8
LGN34	0.94	1.59E−03	1	20	LGN34	0.90	5.43E−03	1	9
LGN34	0.96	7.23E−04	1	19	LGN34	0.72	4.41E−02	2	12
LGN34	0.97	5.99E−05	2	4	LGN34	0.93	2.18E−03	4	16
LGN34	0.93	2.18E−03	4	1	LGN34	0.76	7.81E−02	4	18
LGN34	0.75	3.27E−02	3	11	LGN34	0.79	1.88E−02	3	10
LGN34	0.92	3.33E−03	6	7	LGN34	0.92	3.51E−03	6	12
LGN34	0.83	2.22E−02	6	11	LGN34	0.82	2.33E−02	6	5
LGN34	0.93	2.12E−03	6	14	LGN34	0.92	3.53E−03	6	13
LGN34	0.86	1.40E−02	6	4	LGN34	0.91	4.76E−03	6	15
LGN34	0.84	1.71E−02	6	10	LGN34	0.92	3.31E−03	6	6
LGN34	0.92	3.53E−03	6	17	LGN34	0.80	3.26E−02	6	8
LGN34	0.92	3.53E−03	6	20	LGN34	0.78	3.69E−02	6	9
LGN34	0.95	1.07E−03	6	19	LGN34	0.82	6.64E−03	7	7
LGN34	0.89	1.15E−03	7	12	LGN34	0.84	4.23E−03	7	11
LGN34	0.75	1.87E−02	7	5	LGN34	0.89	1.31E−03	7	14
LGN34	0.90	1.00E−03	7	13	LGN34	0.82	6.32E−03	7	4
LGN34	0.86	3.21E−03	7	15	LGN34	0.80	9.97E−03	7	10
LGN34	0.75	2.00E−02	7	6	LGN34	0.90	1.00E−03	7	17
LGN34	0.90	1.00E−03	7	20	LGN34	0.73	2.62E−02	7	9
LGN34	0.93	2.40E−04	7	19	LGN35	0.81	5.27E−02	1	18
LGN35	0.97	1.69E−03	5	5	LGN35	0.94	5.78E−04	7	18
LGN35	0.83	6.16E−03	7	2	LGN36	0.72	2.00E−02	8	16
LGN36	0.72	2.00E−02	8	1	LGN39	0.84	1.69E−02	1	3
LGN39	0.76	7.95E−02	1	18	LGN39	0.78	6.69E−02	5	10
LGN39	0.72	4.50E−02	2	12	LGN39	0.80	1.82E−02	2	4
LGN39	0.79	2.04E−02	2	6	LGN39	0.73	3.82E−02	2	2
LGN39	0.78	3.73E−02	4	7	LGN39	0.71	7.21E−02	4	12
LGN39	0.74	5.61E−02	4	14	LGN39	0.71	7.67E−02	4	15
LGN39	0.76	4.64E−02	4	10	LGN39	0.84	1.68E−02	4	6
LGN39	0.76	4.88E−02	4	19	LGN39	0.72	4.28E−02	3	2
LGN39	0.74	5.69E−02	6	7	LGN39	0.75	5.24E−02	6	12
LGN39	0.93	2.44E−03	6	16	LGN39	0.72	7.03E−02	6	5
LGN39	0.77	4.43E−02	6	14	LGN39	0.78	3.97E−02	6	13
LGN39	0.87	1.08E−02	6	4	LGN39	0.72	7.06E−02	6	15
LGN39	0.92	3.65E−03	6	10	LGN39	0.78	3.97E−02	6	17
LGN39	0.78	3.97E−02	6	20	LGN39	0.93	2.44E−03	6	1
LGN39	0.73	6.20E−02	6	9	LGN39	0.76	8.17E−02	6	18
LGN39	0.80	3.04E−02	6	19	LGN39	0.71	4.78E−02	7	18
LGN49	0.76	7.74E−02	5	11	LGN49	0.74	9.43E−02	5	4
LGN49	0.74	9.55E−02	5	8	LGN49	0.75	3.05E−02	2	12
LGN49	0.72	4.59E−02	2	14	LGN49	0.91	1.95E−03	2	4
LGN49	0.73	4.12E−02	2	15	LGN49	0.83	2.00E−02	6	5

Table 120. Correlations (R) between the genes expression levels in various tissues and the phenotypic performance under normal conditions; “Corr. ID”=correlation set ID according to the correlated parameters described in Table 114 above. “Exp. Set”=Expression set as described in Table 112 above. “R”=Pearson correlation coefficient; “P”=p value.

Example 14

Production of Brachypodium Transcriptome and High Throughput Correlation Analysis Using 60K Brachypodium Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis comparing between plant phenotype and gene expression level, the present inventors utilized a brachypodium oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60K brachypodium genes and transcripts. In order to define correlations between the levels of RNA expression and yield or vigor related parameters, various plant characteristics of 24 different brachypodium accessions were analyzed. Among them. 22 accessions encompassing the observed variance were selected for RNA expression analysis and comparative genomic hybridization (CGH) analysis.

The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (do( ) com/hyperstat/A34739 (dot) html].

Additional correlation analysis was done by comparing plant phenotype and gene copy number. The correlation between the normalized copy number hybridization signal and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Analyzed Brachypodium tissues—two tissues [leaf and spike] were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 121 below.

TABLE 121
Brachypodium transcriptome expression sets
                                 Set
Expression Set                   ID
Leaf at flowering stage under normal growth conditions 1
Spike at flowering stage under normal growth conditions 2

Table 121. Provided are the brachypodium transcriptome expression sets under normal conditions.

Brachypodium yield components and vigor related parameters assessment—24 brachypodium accessions were grown in 4-6 repetitive plots (8 plants per plot) in a green house. The growing protocol was as follows: brachypodium seeds were sown in plots and grown under normal condition (6 mM of Nitrogen as ammonium nitrate). Plants were continuously phenotyped during the growth period and at harvest (Table 123-124, below). The image analysis system include d a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

At the end of the growing period the grains were separated from the spikes and the following parameters were measured using digital imaging system and collected:

Number of tillering—all tillers were counted per plant at harvest (mean per plot).

Head number—At the end of the experiment, heads were harvested from each plot and were counted.

Total Grains weight per plot (gr.)—At the end of the experiment (plant ‘Heads’) heads from plots were collected, the heads were threshed and grains were weighted. In addition, the average grain weight per head was calculated by dividing the total grain weight by number of total heads per plot (based on plot).

Highest number of spikelets—The highest spikelet number per head was calculated per plant (mean per plot).

Mean number of spikelets—The mean spikelet number per head was calculated per plot.

Plant height—Each of the plants was measured for its height using measuring tape. Height was measured from ground level to spike base of the longest spike at harvest.

Vegetative dry weight and spike yield—At the end of the experiment (50% of the spikes were dry) all spikes and vegetative material from plots were collected. The biomass and spikes weight of each plot was separated, measured and divided by the number of plants/plots.

Dry weight—total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours; Spike yield per plant=total spike weight per plant (gr) after drying at 30° C. in oven for 48 hours.

Spikelets weight (gr.)—The biomass and spikes weight of each plot was separated and measured per plot.

Average head weight—calculated by dividing spikelets weight with head number (gr.).

Harvest Index—The harvest index was calculated using Formula XV (described above).

Spikelets Index—The Spikelets index is calculated using Formula XXXI above.

Percent Number of heads with spikelets—The number of heads with more than one spikelet per plant were counted and the percent from all heads per plant was calculated.

Total dry mater per plot—Calculated as Vegetative portion above ground plus all the spikelet dry weight per plot.

1000 grain weight—At the end of the experiment all grains from all plots were collected and weighted and the weight of 1000 grains was calculated.

The following parameters were collected using digital imaging system:

At the end of the growing period the grains were separated from the spikes and the following parameters were measured and collected:

(i) Average Grain Area (cm²)—A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

(ii) Average Grain Length, perimeter and width (cm)—A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths and width (longest axis) was measured from those images and was divided by the number of grains.

The image processing system that was used consisted of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

TABLE 122
Brachypodium correlated parameters (vectors)
                                 Correlation
Correlated parameter with        ID
1000 grain weight [gr.]          1
Average head weight [gr.]        2
Grain Perimeter [mm]             3
Grain area [mm2]                 4
Grain length [mm]                5
Grain width [mm]                 6
Grains weight per plant [gr.]    7
Grains weight per plot [gr.]     8
Harvest index                    9
Heads per plant [number]         10
Heads per plot [number]          11
Highest number of spikelets per plot [number] 12
Mean number of spikelets per plot [number] 13
Num of heads with spikelets per plant [number] 14
Percent Number of heads with spikelets [%] 15
Plant Vegetative DW [gr]         16
Plant height [cm]                17
Plants number [number]           18
Spikelets DW per plant [gr]      19
Spikelets weight [gr]            20
Spikes index [gr]                21
Tillering [number]               22
Total dry mater per plant [gr]   23
Total dry mater per plot [gr]    24
Vegetative DW [gr]               25

Experimental Results

24 different Brachypodium accessions were grown and characterized for different parameters as described above. The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 123-125 below. Subsequent correlation analysis between the various transcriptome sets and the average parameters (Table 126) was conducted. Follow, results were integrated to the database.

TABLE 123
Measured parameters of correlation IDs in Brachypodium
accessions under normal conditions
Line/
Corr. ID	1	2	3	4	5	6	7	8
Line-1	3.748	0.0569	1.672	0.1025	0.7330	0.1777	0.1399	1.051
Line-2	3.775	0.0436	1.615	0.0955	0.7195	0.1679	0.0555	0.444
Line-3	3.345	0.0495	1.624	0.0944	0.7170	0.1670	0.0768	0.614
Line-4	4.885	0.0749	1.686	0.0945	0.7400	0.1619	0.2552	1.960
Line-5	5.540	0.0402	1.820	0.1052	0.8329	0.1611	0.1403	1.110
Line-6	4.983	0.0558	1.829	0.1115	0.8237	0.1722	0.1398	1.072
Line-7	4.827	0.0475	1.745	0.1025	0.7813	0.1664	0.1383	1.089
Line-8	5.535	0.0416	1.931	0.1095	0.8961	0.1554	0.1050	0.840
Line-9	3.842	0.0780	1.683	0.1008	0.7476	0.1715	0.0767	0.498
Line-10	4.761	0.0552	1.819	0.1114	0.7888	0.1801	0.0658	0.387
Line-11	4.730	0.0478	1.690	0.0996	0.7481	0.1693	0.3927	3.070
Line-12	5.239	0.0529	1.910	0.1244	0.8568	0.1850	0.1361	1.089
Line-13	4.964	0.0574	1.706	0.1005	0.7437	0.1715	0.1257	1.066
Line-14	4.004	0.1037	1.806	0.0963	0.8395	0.1457	0.3742	2.993
Line-15	4.257	0.0789	1.755	0.0899	0.8018	0.1426	0.4937	3.522
Line-16	5.991	0.0819	1.866	0.1173	0.8421	0.1772	0.3117	2.406
Line-17	4.336	0.0638	1.664	0.0913	0.7357	0.1575	0.2027	1.468
Line-18	3.700	0.0872	1.646	0.0884	0.7497	0.1494	0.3478	2.583
Line-19	3.904	0.0404	1.602	0.0862	0.7240	0.1510	0.2688	2.035
Line-20	4.823	0.0596	1.795	0.1047	0.7941	0.1682	0.3226	2.581
Line-21	4.873	0.0867	1.903	0.1132	0.8712	0.1649	0.4361	3.403
Line-22	3.758	0.0901	1.683	0.0916	0.7638	0.1515	0.3032	1.919

Table 123. Correlation IDs: 1, 2, 3, 4, 5, . . . etc. refer to those described in Table 122 above I[Brachypodium correlated parameters (vectors)].

TABLE 124
Measured parameters of correlation IDs in brachypodium
accessions under normal conditions
Line/
Corr. ID	9	10	11	12	13	14	15	16
Line-1	0.1308	16.29	121.75	3.000	2.103	1 5.272	27.61	0.4159
Line-2	0.1401	7.08	56.60	2.600	2.100	2.500	35.33	0.1188
Line-3	0.1483	6.59	52.75	3.000	1.719	2.063	21.67	0.1328
Line-4	0.2049	11.63	83.40	2.200	1.692	2.083	14.00	0.3758
Line-5	0.1991	10.48	82.40	2.000	1.382	0.707	5.42	0.3228
Line-6	0.1576	9.09	70.13	2.250	1.645	1.940	15.42	0.3244
Line-7	0.1355	14.13	110.33	1.833	1.426	1.080	6.40	0.3895
Line-8	0.2552	5.88	47.00	2.000	1.250	0.350	4.51	0.1250
Line-9	0.0668	11.89	81.50	3.500	2.411	7.594	55.41	0.4375
Line-10	0.1063	8.02	48.60	2.000	1.563	1.868	16.51	0.3084
Line-11	0.2163	23.75	185.50	2.500	1.763	4.982	15.52	0.8713
Line-12	0.0888	16.06	125.00	2.400	1.825	3.700	20.34	0.6933
Line-13	0.1753	9.74	80.75	2.000	1.424	0.889	8.11	0.3438
Line-14	0.0934	22.19	177.50	3.500	2.708	12.583	53.21	1.7244
Line-15	0.1577	24.32	172.80	3.800	2.607	12.130	47.81	1.3159
Line-16	0.1806	13.25	98.60	2.800	2.121	6.350	42.81	0.4779
Line-17	0.1118	19.22	143.17	2.833	2.155	7.146	34.92	0.6278
Line-18	0.2108	16.11	123.50	2.833	2.174	9.440	52.40	0.8175
Line-19	0.1714	21.40	156.83	2.333	1.850	5.016	20.84	0.6747
Line-20	0.1492	25.88	207.00	2.600	1.925	4.900	17.55	0.8700
Line-21	0.1807	17.05	135.00	4.500	2.854	7.719	47.73	1.0473
Line-22	0.0879	25.54	177.00	3.167	2.790	15.355	59.01	1.7313

Table 124. Correlation IDs: 1, 2, 3, 4, 5, . . . etc. refer to those described in Table 122 above [Brachypodium correlated parameters (vectors)].

TABLE 125
Measured parameters of correlation IDs in brachypodium
accessions under normal conditions
Line/
Corr.
ID	17	18	19	20	21	22	23	24	15
Line-1	31.65	7.500	0.9605	7.180	0.7061	16.84	1.376	10.26	3.078
Line-2	23.44	8.000	0.3123	2.498	0.7236	7.20	0.431	3.45	0.950
Line-3	22.75	8.000	0.3344	2.675	0.7276	7.00	0.467	3.74	1.063
Line-4	31.95	7.200	0.8758	6.424	0.7060	11.97	1.252	9.12	2.692
Line-5	34.36	7.800	0.4372	3.452	0.5759	10.67	0.760	6.00	2.546
Line-6	28.65	7.750	0.5587	4.293	0.6573	9.38	0.883	6.78	2.483
Line-7	28.88	7.833	0.6741	5.290	0.6359	14.58	1.064	8.34	3.053
Line-8	24.74	8.000	0.2555	2.044	0.6577	6.35	0.381	3.04	1.000
Line-9	31.40	6.500	0.9224	6.250	0.6869	12.38	1.360	9.21	2.960
Line-10	29.15	6.400	0.4496	2.658	0.6046	8.60	0.758	4.47	1.814
Line-11	37.30	7.750	1.1370	8.893	0.5896	25.50	2.008	15.79	6.893
Line-12	45.09	8.000	0.8318	6.654	0.5429	16.56	1.525	12.20	5.546
Line-13	22.39	8.250	0.5910	4.915	0.6776	10.53	0.935	7.76	2.843
Line-14	55.04	8.000	2.2685	18.148	0.5628	27.15	3.993	31.94	13.795
Line-15	45.34	7.000	1.9113	13.494	0.5931	26.30	3.227	22.78	9.284
Line-16	40.20	7.600	1.0916	8.346	0.6981	13.56	1.570	12.04	3.696
Line-17	39.18	7.333	1.2591	9.418	0.6623	20.79	1.887	14.14	4.718
Line-18	45.35	7.500	1.4640	11.312	0.6829	16.99	2.282	17.78	6.468
Line-19	29.41	7.333	0.9560	7.162	0.6004	23.61	1.631	12.29	5.130
Line-20	38.39	8.000	1.5555	12.444	0.6465	27.20	2.426	19.40	6.960
Line-21	46.74	7.875	1.4182	11.046	0.5749	18.25	2.466	19.27	8.228
Line-22	58.82	6.833	2.2523	15.548	0.5686	29.09	3.984	27.67	12.117

Table 125. Correlation IDs: 1, 2, 3, 4, 5, . . . etc. refer to those described in Table 122 above [Brachypodium correlated parameters (vectors)].

TABLE 126
Correlation between the expression level of selected genes of some embodiments
of the invention in various tissues and the phenotypic performance
under normal conditions across brachypodium varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY37	0.73	1.68E−02	2	7	LBY37	0.71	2.26E−02	2	8
LBY37	0.86	7.69E−04	1	11	LBY37	0.88	3.85E−04	1	22
LBY37	0.82	1.84E−03	1	24	LBY37	0.85	9.14E−04	1	19
LBY37	0.78	4.41E−03	1	12	LBY37	0.82	2.06E−03	1	25
LBY37	0.75	7.35E−03	1	15	LBY37	0.85	9.29E−04	1	16
LBY37	0.86	6.29E−04	1	14	LBY37	0.82	2.22E−03	1	20
LBY37	0.85	8.20E−04	1	13	LBY37	0.74	9.92E−03	1	17
LBY37	0.87	4.88E−04	1	10	LBY37	0.86	7.61E−04	1	23

Table 126. Provided are the correlations (R) between the expression levels yield improving genes and their homologs in various tissues [Expression (Exp) sets, Table 121] and the phenotypic performance [yield, biomass, growth rate and/or vigor components as described in Tables 123-125 using the Correlation vectors (Corr.) described in Table 122] under normal conditions across brachypodium varieties. P=p value.

Example 15

Production of Soybean (Glycine Max) Transcriptome and High Throughput Correlation Analysis with Yield Parameters Using 44K B. Soybean Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis, the present inventors utilized a Soybean oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 42,000 Soybean genes and transcripts. In order to define correlations between the levels of RNA expression with yield components or plant architecture related parameters or plant vigor related parameters, various plant characteristics of 29 different Glycine max varieties were analyzed and 26 varieties were further used for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test.

Correlation of Glycine max Genes' Expression Levels with Phenotypic Characteristics Across Ecotype

Experimental Procedures

29 Soybean varieties were grown in three repetitive plots in field. Briefly, the growing protocol was as follows: Soybean seeds were sown in soil and grown under normal conditions (no irrigation, good organomic particles) which included high temperature about 82.38 (° F.), low temperature about 58.54 (° F.); total precipitation rainfall from May through September (from sowing until harvest) was about 16.97 inch.

In order to define correlations between the levels of RNA expression with yield components or plant architecture related parameters or vigor related parameters, 26 different Soybean varieties (out of 29 varieties) were analyzed and used for gene expression analyses. Analysis was performed at two pre-determined time periods: at pod set (when the soybean pods are formed) and at harvest time (when the soybean pods are ready for harvest, with mature seeds).

TABLE 127
Soybean transcriptome expression sets
                                 Set
Expression Set                   ID
Apical meristem at vegetative stage under normal growth condition 1
Leaf at vegetative stage under normal growth condition 2
Leaf at flowering stage under normal growth condition 3
Leaf at pod setting stage under normal growth condition 4
Root at vegetative stage under normal growth condition 5
Root at flowering stage under normal growth condition 6
Root at pod setting stage under normal growth condition 7
Stem at vegetative stage under normal growth condition 8
Stem at pod setting stage under normal growth condition 9
Flower bud at flowering stage under normal growth condition 10
Pod (R3-R4) at pod setting stage under normal growth condition 11

Main branch base diameter [mm] at pod set—the diameter of the base of the main branch (based diameter) average of three plants per plot.

Fresh weight [gr./plant] at pod set]—total weight of the vegetative portion above ground (excluding roots) before drying at pod set, average of three plants per plot.

Dry weight [gr./plant] at pod set—total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours at pod set, average of three plants per plot.

Total number of nodes with pods on lateral branches [value/plant]—counting of nodes which contain pods in lateral branches at pod set, average of three plants per plot.

Number of lateral branches at pod set [value/plant]—counting number of lateral branches at pod set, average of three plants per plot.

Total weight of lateral branches at pod set [gr./plant]—weight of all lateral branches at pod set, average of three plants per plot.

Total weight of pods on main stem at pod set [gr./plant]—weight of all pods on main stem at pod set, average of three plants per plot.

Total number of nodes on main stem [value/plant]—count of number of nodes on main stem starting from first node above ground, average of three plants per plot.

Total number of pods with 1 seed on lateral branches at pod set [value/plant]—count of the number of pods containing 1 seed in all lateral branches at pod set, average of three plants per plot.

Total number of pods with 2 seeds on lateral branches at pod set [value/plant/]—count of the number of pods containing 2 seeds in all lateral branches at pod set, average of three plants per plot.

Total number of pods with 3 seeds on lateral branches at pod set [value/plant]—count of the number of pods containing 3 seeds in all lateral branches at pod set, average of three plants per plot.

Total number of pods with 4 seeds on lateral branches at pod set [value/plant]—count of the number of pods containing 4 seeds in all lateral branches at pod set, average of three plants per plot.

Total number of pods with 1 seed on main stem at pod set [value/plant]—count of the number of pods containing 1 seed in main stem at pod set, average of three plants per plot.

Total number of pods with 2 seeds on main stem at pod set [value/plant]—count of the number of pods containing 2 seeds in main stem at pod set, average of three plants per plot.

Total number of pods with 3 seeds on main stem at pod set [value/plant]—count of the number of pods containing 3 seeds in main stem at pod set, average of three plants per plot.

Total number of pods with 4 seeds on main stem at pod set [value/plant]—count of the number of pods containing 4 seeds in main stem at pod set, average of three plants per plot.

Total number of seeds per plant at pod set [value/plant]—count of number of seeds in lateral branches and main stem at pod set, average of three plants per plot.

Total number of seeds on lateral branches at pod set [value/plant]—count of total number of seeds on lateral branches at pod set, average of three plants per plot.

Total number of seeds on main stem at pod set [value/plant]—count of total number of seeds on main stem at pod set, average of three plants per plot.

Plant height at pod set [cm/plant]—total length from above ground till the tip of the main stem at pod set, average of three plants per plot.

Plant height at harvest [cm/plant]—total length from above ground till the tip of the main stem at harvest, average of three plants per plot.

Total weight of pods on lateral branches at pod set [gr./plant]—weight of all pods on lateral branches at pod set, average of three plants per plot.

Ratio of the number of pods per node on main stem at pod set—calculated in Formula XXIII (above), average of three plants per plot.

Ratio of total number of seeds in main stem to number of seeds on lateral branches—calculated in Formula XXIV above, average of three plants per plot.

Total weight of pods per plant at pod set [gr./plant]—weight of all pods on lateral branches and main stem at pod set, average of three plants per plot.

Days till 50% flowering [days]—number of days till 50% flowering for each plot.

Days till 100% flowering [days]—number of days till 100% flowering for each plot.

Maturity [days]—measure as 95% of the pods in a plot have ripened (turned 100% brown). Delayed leaf drop and green stems are not considered in assigning maturity. Tests are observed 3 days per week, every other day, for maturity. The maturity date is the date that 95% of the pods have reached final color. Maturity is expressed in days after August 31 [according to the accepted definition of maturity in USA. Descriptor list for SOYBEAN, ars-grin (dot) gov/cgi-bin/npgs/html/desclist (dot) pl?51].

Seed quality [ranked 1-5]—measure at harvest; a visual estimate based on several hundred seeds. Parameter is rated according to the following scores considering the amount and degree of wrinkling, defective coat (cracks), greenishness, and moldy or other pigment. Rating is “1”—very good, “2”—good, “3”—fair, “4”—poor, “5”—very poor.

Lodging [ranked 1-5]—is rated at maturity per plot according to the following scores: “1”—most plants in a plot are erected; “2”—all plants leaning slightly or a few plants down; “3”—all plants leaning moderately, or 25%-50% down; “4”—all plants leaning considerably, or 50%-80% down; “5”—most plants down. Note: intermediate score such as 1.5 are acceptable.

Seed size [gr.]—weight of 1000 seeds per plot normalized to 13% moisture, measure at harvest.

Total weight of seeds per plant [gr./plant]—calculated at harvest (per 2 inner rows of a trimmed plot) as weight in grams of cleaned seeds adjusted to 13% moisture and divided by the total number of plants in two inner rows of a trimmed plot.

Yield at harvest [bushels/hectare]—calculated at harvest (per 2 inner rows of a trimmed plot) as weight in grams of cleaned seeds, adjusted to 13% moisture, and then expressed as bushels per acre.

Average lateral branch seeds per pod [number]—Calculate number of seeds on lateral branches-at pod set and divide by the number of pods with seeds on lateral branches-at pod set.

Average main stem seeds per pod [number]—Calculate total number of seeds on main stem at pod set and divide by the number of pods with seeds on main stem at pod setting.

Main stem average internode length [cm]—Calculate plant height at pod set and divide by the total number of nodes on main stem at pod setting.

Total number of pods with seeds on main stem [number]—count all pods containing seeds on the main stem at pod setting.

Total number of pods with seeds on lateral branches [number]—count all pods containing seeds on the lateral branches at pod setting.

Total number of pods per plant at pod set [number]—count pods on main stem and lateral branches at pod setting.

TABLE 128
Soybean correlated parameters (vectors)
                                 Correlation
Correlated parameter with        ID
100 percent flowering (days)     1
50 percent flowering (days)      2
Base diameter at pod set (mm)    3
DW at pod set (gr.)              4
Lodging (score 1-5)              5
Maturity (days)                  6
Num of lateral branches (number) 7
Num of pods with 1 seed on main stem at pod set (number) 8
Num of pods with 2 seed on main stem at pod set (number) 9
Num of pods with 3 seed on main stem at pod set (number) 10
Num of pods with 4 seed on main stem at pod set (number) 11
Plant height at harvest (cm)     12
Plant height at pod set (cm)     13
Ratio number of pods per node on main stem (ratio) 14
Ratio num of seeds-main stem to lateral branches (ratio) 15
Seed quality (score 1-5)         16
1000 seed weight (gr.)           17
Num of Seeds on lateral branches-at pod set 18
Total Number of Seeds on main stem at pod set (number) 19
Num of pods with 1 seed on lateral branch-pod set 20
(number)
Num of pods with 2 seed on lateral branch-pod set 21
(number)
Num pods with 3 seed on lateral branch-at pod set (number) 22
Num pods with 4 seed on lateral branch-at pod set (number) 23
Total number of nodes on main stem (number) 24
Num of nodes with pods on lateral branches-pod set 25
(number)
Total number of seeds per plant (number) 26
Total weight of lateral branches at pod set (gr.) 27
Weight of pods on lateral branches (gr)-at pod set 28
Total weight of pods on main stem at pod set (gr.) 29
Total weight of pods per plant (gr./plant) 30
Total weight of seeds per plant (gr./plant) 31
Fresh weight at pod set (gr.)    32
Yield at harvest (bushel/hectare) 33
Average lateral branch seeds per pod 34
Average main stem seeds per pod  35
Main stem average internode length (cm) 36
Num pods with seeds on lateral branches-at pod set 37
(number)
Total number of pods per plant (number) 38
Total number of pods with seeds on main stem (number) 39
Corrected Seed size (gr.)        40

Table 128.

Experimental Results

29 different Soybean varieties lines were grown and characterized for 40 parameters as specified above. Tissues for expression analysis were sampled from a subset of 12 lines. The correlated parameters are described in Table 128 above. The average for each of the measured parameter was calculated using the JMP software (Tables 129-134) and a subsequent correlation analysis was performed (Table 135).

Results were then integrated to the database.

TABLE 129
Measured parameters in Soybean varieties (lines 1-6)
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1	67.33	71.67	67.67	67.33	60.00	74.00
2	61.00	65.33	60.67	61.00	54.67	68.33
3	8.33	9.54	9.68	8.11	8.82	10.12
4	53.67	50.33	38.00	46.17	60.83	55.67
5	1.67	1.83	1.17	1.67	2.67	2.83
6	24.00	43.67	30.33	30.33	38.33	40.00
7	9.00	8.67	9.11	9.89	7.67	17.56
8	1.11	4.38	1.44	1.44	4.56	1.67
9	16.89	16.25	13.22	16.89	27.00	8.11
10	29.56	1.75	19.78	22.33	11.67	22.78
11	0.00	0.00	0.11	0.11	0.00	0.44
12	96.67	76.67	67.50	75.83	74.17	76.67
13	86.78	69.56	62.44	70.89	69.44	63.89
14	2.87	1.38	2.13	2.26	2.60	1.87
15	0.89	0.90	0.87	0.89	2.32	0.37
16	2.33	3.50	3.00	2.17	2.83	2.00
17	89.00	219.33	93.00	86.00	191.33	71.33
18	150.89	55.89	134.00	160.44	75.44	324.63
19	123.56	43.89	87.67	102.67	93.56	88.00
20	1.56	3.00	1.78	1.78	5.67	5.63
21	17.00	18.75	26.44	32.33	21.56	33.50
22	38.44	2.00	26.44	31.33	8.89	82.00
23	0.00	0.00	0.00	0.00	0.00	1.50
24	16.56	16.78	16.11	18.11	16.78	17.11
25	23.00	16.00	23.11	33.00	15.22	45.25
26	274.44	99.78	221.67	263.11	169.00	412.50
27	67.78	63.78	64.89	74.89	54.00	167.22
28	26.00	14.89	20.11	20.11	21.11	30.25
29	22.11	14.33	16.00	15.00	33.78	9.00
30	48.11	29.22	36.11	35.11	54.89	38.88
31	15.09	10.50	17.23	16.51	12.06	10.25
32	170.89	198.22	152.56	163.89	224.67	265.00
33	47.57	43.77	50.37	56.30	44.00	40.33
34	2.67	1.95	2.43	2.53	2.13	2.68
35	2.60	1.89	2.52	2.53	2.17	2.59
36	5.24	4.15	3.91	3.92	4.15	3.74
37	57.00	28.56	54.67	65.44	36.11	122.63
38	104.56	51.67	89.22	106.22	79.33	155.63
39	47.56	23.11	34.56	40.78	43.22	33.00
40	89.00		93.00	86.00		71.33

Table 129.

TABLE 130
Measured parameters in Soybean varieties (lines 7-12)
Ecotype/
Treatment	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1	73.00	72.33	68.67	73.67	68.00	70.67
2	66.50	65.67	62.33	67.67	61.67	64.33
3	8.46	8.09	8.26	7.73	8.16	7.89
4	48.00	52.00	44.17	52.67	56.00	47.50
5	2.67	2.50	1.83	3.50	3.33	1.50
6	41.00	38.33	31.00	39.00	27.33	32.67
7	11.67	12.11	8.00	9.11	6.78	10.00
8	4.00	4.33	2.11	1.89	3.44	1.22
9	21.33	17.67	20.33	16.11	28.11	16.56
10	11.11	28.22	24.11	36.44	39.67	32.33
11	0.00	0.56	0.00	3.89	0.00	0.00
12	101.67	98.33	75.83	116.67	76.67	71.67
13	89.78	82.11	70.56	101.67	79.56	67.22
14	1.98	2.71	2.78	2.75	3.70	2.84
15	3.90	0.78	1.18	1.98	1.03	0.83
16	3.50	2.50	2.17	2.33	2.17	2.17
17	88.00	75.00	80.67	75.67	76.33	77.33
18	46.88	176.22	143.00	105.44	184.33	187.33
19	80.00	126.56	115.11	159.00	178.67	131.33
20	2.88	3.00	1.25	2.67	1.78	3.00
21	8.50	22.78	21.75	10.67	23.78	25.67
22	9.00	42.11	32.75	25.67	45.00	44.33
23	0.00	0.33	0.00	1.11	0.00	0.00
24	18.78	18.89	16.78	21.11	19.33	20.78
25	8.25	25.44	21.88	16.33	22.56	24.22
26	136.00	302.78	260.50	264.44	363.00	318.67
27	45.44	83.22	64.33	52.00	76.89	67.00
28	4.13	20.11	17.00	9.22	28.11	22.56
29	9.03	16.00	15.89	14.56	30.44	18.00
30	14.25	36.11	32.75	23.78	58.56	40.56
31	7.30	11.38	15.68	10.83	12.98	15.16
32	160.67	196.33	155.33	178.11	204.44	164.22
33	34.23	44.27	53.67	42.47	43.60	52.20
34	2.12	2.58	2.58	2.67	2.62	2.58
35	2.22	2.49	2.47	2.71	2.51	2.61
36	4.80	4.36	4.20	4.82	4.12	3.83
37	20.38	68.22	55.75	40.11	70.56	73.00
38	61.00	119.00	103.25	98.44	141.78	123.11
39	36.44	50.78	43.63	58.33	71.22	50.11
40	88.00	75.00	80.67	75.67	76.33	77.33

Table 130.

TABLE 131
Measured parameters in Soybean varieties (lines 1-8)
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8
1	67.33	67.33	67.33	70.00	68.00	71.67	67.33	67.67
3	8.27	8.00	8.33	7.16	7.78	9.54	8.13	9.68
4	35.83	51.67	53.67	34.67	47.50	50.33	53.50	38.00
5	2.00	2.00	1.67	1.67	1.17	1.83	1.67	1.17
6	27.67	27.67	24.00	30.33	31.33	43.67	27.00	30.33
7	5.11	8.44	9.00	7.00	8.67	8.67	7.11	9.11
8	0.56	2.44	1.11	2.56	0.89	4.38	1.89	1.44
9	16.44	17.22	16.89	25.33	10.44	16.25	20.00	13.22
10	19.33	23.33	29.56	23.33	30.56	1.75	23.56	19.78
11	0.00	0.00	0.00	0.00	2.22	0.00	0.00	0.11
12	69.17	85.00	96.67	75.83	73.33	76.67	75.00	67.50
13	66.78	79.44	86.78	64.11	68.00	69.56	74.11	62.44
14	2.34	2.67	2.87	2.87	2.51	1.38	2.65	2.13
15	1.28	1.13	0.89	1.35	0.86	0.90	1.43	0.87
16	3.00	2.17	2.33	2.33	2.50	3.50	2.67	3.00
17	126.00	116.00	89.00	75.67	84.33	219.33	119.00	93.00
18	92.78	124.00	150.89	122.78	174.89	55.89	112.67	134.00
19	91.44	106.89	123.56	123.22	122.33	43.89	112.56	87.67
20	0.78	0.89	1.56	0.78	1.00	3.00	1.22	1.78
21	15.33	17.56	17.00	23.33	18.11	18.75	21.22	26.44
22	20.44	29.33	38.44	25.11	43.22	2.00	23.00	26.44
23	0.000	0.000	0.000	0.000	2.000	0.000	0.000	0.000
24	15.56	16.11	16.56	17.78	17.67	16.78	17.33	16.11
25	13.89	20.89	23.00	22.44	26.11	16.00	21.56	23.11
26	184.22	230.89	274.44	246.00	297.22	99.78	225.22	221.67
27	57.78	66.67	67.78	57.00	73.67	63.78	64.44	64.89
28	23.00	25.00	26.00	18.33	23.22	14.89	27.89	20.11
29	22.56	22.22	22.11	17.89	17.89	14.33	23.78	16.00
30	45.56	47.22	48.11	36.22	41.11	29.22	51.67	36.11
31	21.35	14.70	15.09	13.44	16.60	10.50	16.03	17.23
32	158.89	185.78	170.89	146.78	172.78	198.22	166.44	152.56
33	55.53	50.33	47.57	46.83	55.87	43.77	51.67	50.37
34	2.53	2.58	2.67	2.51	2.74	1.95	2.46	2.43
35	2.52	2.49	2.60	2.36	2.77	1.89	2.50	2.52
36	4.29	4.93	5.24	3.61	3.85	4.15	4.29	3.91
37	36.56	47.78	57.00	49.22	64.33	28.56	45.44	54.67
38	72.89	90.78	104.56	100.44	108.44	51.67	90.89	89.22
39	36.33	43.00	47.56	51.22	44.11	23.11	45.44	34.56

Table 131

TABLE 132
Measured parameters in Soybean varieties (lines 9-16)
Ecotype/	Line-	Line-	Line-	Line-	Line-	Line-	Line-	Line-
Treatment	9	10	11	12	13	14	15	16
1	71.67	67.33	67.00	69.67	60.00	70.67	71.67	71.67
3	8.41	8.11	7.54	7.83	8.82	8.10	8.72	9.54
4	45.83	46.17	38.67	50.67	60.83	44.33	52.33	54.50
5	1.83	1.67	1.17	2.67	2.67	1.50	3.00	1.83
6	35.33	30.33	28.00	41.00	38.33	31.00	36.00	38.67
7	8.67	9.89	5.33	5.00	7.67	4.78	7.78	8.78
8	2.33	1.44	1.67	1.67	4.56	2.67	4.14	1.89
9	22.33	16.89	17.00	19.22	27.00	32.89	18.71	15.11
10	25.44	22.33	31.89	10.00	11.67	27.89	31.43	41.89
11	0.11	0.11	0.00	0.00	0.00	0.00	1.71	0.44
12	75.00	75.83	66.67	115.83	74.17	72.50	83.33	76.67
13	69.67	70.89	62.33	94.44	69.44	66.78	75.44	68.56
14	2.77	2.26	2.76	1.43	2.60	3.32	3.19	3.17
15	1.38	0.89	1.41	2.40	2.32	1.54	0.80	1.21
16	2.00	2.17	2.00	3.00	2.83	2.17	2.00	2.33
17	84.67	86.00	75.67	169.33	191.33	86.67	85.67	87.67
18	171.11	160.44	139.67	49.44	75.44	112.33	204.67	180.78
19	123.78	102.67	131.33	70.11	93.56	152.11	140.11	159.56
20	2.78	1.78	0.89	0.33	5.67	1.56	5.13	0.67
21	34.44	32.33	19.89	12.56	21.56	21.22	29.63	16.67
22	33.00	31.33	33.00	8.00	8.89	22.78	40.25	48.78
23	0.111	0.000	0.000	0.000	0.000	0.000	0.750	0.111
24	18.00	18.11	18.33	21.56	16.78	19.11	17.33	18.78
25	26.33	33.00	21.33	14.38	15.22	18.56	30.44	28.00
26	294.89	263.11	271.00	119.56	169.00	264.44	344.78	340.33
27	80.33	74.89	58.33	55.25	54.00	52.44	105.00	6 7.00
28	23.00	20.11	19.33	12.00	21.11	15.33	23.78	20.67
29	18.00	15.00	19.63	15.41	33.78	21.56	16.22	26.56
30	41.00	35.11	39.88	27.41	54.89	36.89	40.00	47.22
31	14.64	16.51	17.12	10.52	12.06	15.80	12.64	12.58
32	175.67	163.89	136.56	191.67	224.67	155.33	216.22	192.11
33	52.93	56.30	55.07	40.17	44.00	52.37	46.90	48.57
34	2.43	7.53	2.60	2.34	2.13	2.48	2.47	2.70
35	2.48	2.53	2.60	2.26	2.17	2.40	2.52	2.68
36	3.90	3.92	3.41	4.38	4.15	3.50	4.36	3.67
37	70.33	65.44	53.78	20.89	36.11	45.56	83.11	66.22
38	120.56	106.22	104.33	51.78	79.33	109.00	138.89	125.56
39	50.22	40.78	50.56	30.89	43.22	63.44	55.78	59.33

Table 132

TABLE 133
Measured parameters in Soybean varieties (lines 17-23)
Ecotype/	Line-	Line-	Line-	Line-	Line-	Line-	Line-
Treatment	17	18	19	20	21	22	23
1	74.00	73.00	72.33	73.33	6 7.33	68.67	69.33
3	10.12	8.46	8.09	8.11	7.09	8.26	7.57
4	55.67	48.00	52.00	45.17	57.00	44.17	43.33
5	2.83	2.67	2.50	1.67	2.50	1.83	2.00
6	40.00	41.00	38.33	37.00	24.67	31.00	37.67
7	17.56	11.67	12.11	10.44	8.00	8.00	9.00
8	1.67	4.00	4.33	1.89	1.78	2.11	0.44
9	8.11	21.33	17.67	20.00	17.44	20.33	11.22
10	22.78	11.11	28.22	27.89	25.11	24.11	25.22
11	0.44	0.00	0.56	0.56	0.44	0.00	0.11
17	76.67	101.67	98.33	89.17	93.33	75.83	78.33
13	63.89	89.78	82.11	81.11	85.67	70.56	70.78
14	1.87	1.98	2.71	2.58	2.45	2.78	2.15
15	0.37	3.90	0.78	1.36	0.92	1.18	0.82
16	2.00	3.50	2.50	2.10	2.50	2.17	2.17
17	71.33	88.00	75.00	78.67	91.67	80.67	80.67
18	324.63	46.88	176.22	121.56	151.56	143.00	144.00
19	88.00	80.00	126.56	127.78	113.78	115.11	99.00
20	5.63	2.88	3.00	2.33	1.67	1.25	0.89
21	33.50	8.50	22.78	21.89	22.89	21.75	13.22
22	82.00	9.00	42.11	24.56	34.11	32.75	38.89
23	1.500	0.000	0.333	0.444	0.444	0.000	0.000
24	17.11	18.78	18.89	19.44	19.89	16.78	17.00
25	45.25	8.25	25.44	22.67	23.00	21.88	23.78
26	412.50	136.00	302.78	249.33	265.33	260.50	243.00
27	167.22	45.44	83.22	63.67	69.67	64.33	76.22
28	30.25	4.13	20.11	14.89	24.33	17.00	19.22
29	9.00	9.03	16.00	14.57	19.78	15.89	14.67
30	38.88	14.25	36.11	29.46	44.11	32.75	33.89
31	10.25	7.30	11.38	13.86	14.63	15.68	14.77
32	265.00	160.67	196.33	166.33	171.44	155.33	175.78
33	40.33	34.23	44.27	46.23	49.70	53.67	52.53
34	2.68	2.12	2.58	2.48	2.61	2.58	2.70
35	2.59	2.22	2.49	2.53	2.53	2.47	2.67
36	3.74	4.80	4.36	4.18	4.89	4.20	4.16
37	122.63	20.38	68.22	49.22	59.11	55.75	53.00
38	155.63	61.00	119.00	99.56	103.89	103.25	90.00
39	33.00	36.44	50.78	50.33	44.78	46.56	37.00

Table 133.

TABLE 134
Measured parameters in Soybean varieties (lines 24-29)
Ecotype/
Treatment	Line-24	Line-25	Line-26	Line-27	Line-28	Line-29
1	73.67	68.00	68.67	68.00	67.00	70.67
3	7.73	8.16	8.18	6.88	7.82	7.89
4	52.67	56.00	56.17	43.50	46.00	47.50
5	3.50	3.33	1.83	1.50	2.33	1.50
6	39.00	27.33	27.67	27.33	36.33	32.67
7	9.11	6.78	7.11	4.33	9.11	10.00
8	1.89	3.44	3.22	1.67	3.33	1.22
9	16.11	28.11	24.67	14.67	14.33	16.56
10	36.44	39.67	35.78	31.67	37.56	32.33
11	3.89	0.00	0.00	0.78	0.78	0.00
12	116.67	76.67	85.00	78.33	79.17	71.67
13	101.67	79.56	77.44	73.67	73.67	67.22
14	2.75	3.70	3.58	3.06	3.34	2.84
15	1.98	1.03	1.48	1.82	1.35	0.83
16	2.33	2.17	2.17	2.33	2.17	2.17
17	75.67	76.33	88.00	93.33	79.00	77.33
18	105.44	184.33	166.22	92.33	143.78	187.33
19	159.00	178.67	159.89	129.11	147.78	131.33
20	2.67	1.78	1.00	0.56	2.11	3.00
21	10.67	23.78	26.78	10.22	15.89	25.67
22	25.67	45.00	37.22	23.78	35.89	44.33
23	1.111	0.000	0.000	0.000	0.556	0.000
24	21.11	19.33	17.78	15.89	16.67	20.78
75	16.33	22.56	19.89	11.78	16.00	24.22
26	264.44	363.00	326.11	221.44	291.56	318.67
27	52.00	76.89	74.78	35.33	52.11	67.00
28	9.22	28.11	24.22	14.33	15.13	22.56
29	14.56	30.44	24.22	26.36	21.44	18.00
30	23.78	58.56	48.44	40.69	35.75	40.56
31	10.83	12.98	16.38	16.64	15.82	15.16
32	178.11	204.44	205.89	144.67	176.44	164.22
33	42.47	43.60	51.90	52.50	46.43	52.20
34	2.67	2.62	2.37	2.67	2.62	2.58
35	2.71	2.51	2.53	2.64	2.65	2.61
36	4.82	4.12	4.36	4.64	4.47	3.57
37	40.11	70.56	71.67	34.56	54.44	73.00
38	98.44	141.78	135.33	83.33	110.44	123.11
39	58.33	71.22	63.67	48.78	56.00	50.11

Table 134.

TABLE 135
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions across
soybean varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY193	0.82	1.02E−03	11	15	LBY193	0.71	4.99E−02	9	16
LBY193	0.77	2.59E−02	9	17	LBY193	0.78	2.57E−03	1	23
LBY193	0.72	8.44E−03	10	33	LBY194	0.72	1.80E−02	7	18
LBY194	0.72	1.82E−02	7	27	LBY194	0.77	9.00E−03	7	7
LBY194	0.74	1.50E−02	7	25	LBY194	0.84	8.52E−03	9	22
LBY194	0.85	7.48E−03	9	18	LBY194	0.81	1.40E−02	9	21
LBY194	0.77	2.52E−02	9	32	LBY194	0.77	2.39E−02	9	23
LBY194	0.83	1.09E−02	9	27	LBY194	0.78	2.26E−02	9	25
LBY194	0.81	1.53E−02	9	26	LBY195	0.78	7.97E−03	7	32
LBY195	0.72	1.91E−02	7	20	LBY195	0.70	1.08E−02	11	1
LBY195	0.92	1.34E−04	5	15	LBY195	0.72	1.77E−02	8	17
LBY195	0.73	4.06E−02	9	22	LBY195	0.76	2.87E−02	9	18
LBY195	0.73	3.91E−02	9	21	LBY195	0.96	1.10E−04	9	32
LBY195	0.81	1.43E−02	9	4	LBY195	0.72	4.45E−02	9	5
LBY195	0.82	1.21E−02	9	23	LBY195	0.87	5.44E−03	9	27
LBY195	0.77	2.57E−02	9	25	LBY195	0.71	4.66E−02	9	28
LBY195	0.70	5.27E−02	9	26	LBY195	0.75	4.95E−03	4	9
LBY195	0.74	5.96E−03	10	30	LBY195	0.78	2.66E−03	10	29
LGN2	0.81	4.49E−03	8	9	LGN2	0.73	3.95E−02	9	6
LGN2	0.78	2.35E−02	9	2	LGN2	0.82	1.33E−02	9	1
LGN2	0.76	7.13E−03	2	20	LGN2	0.88	1.35E−04	1	32
LGN2	0.72	8.28E−03	1	3	LGN2	0.80	1.63E−03	1	20
LGN2	0.80	1.68E−03	10	15	LBY194	0.73	1.57E−02	5	36
LBY194	0.75	1.33E−02	7	37	LBY194	0.81	1.51E−02	9	38
LBY194	0.85	7.25E−03	9	37	LBY195	0.73	4.11E−02	9	38
LBY195	0.77	2.56E−02	9	37	LBY194	0.80	1.81E−02	8	40
LBY194	0.98	3.36E−05	5	40

Table 135. Provided are the correlations (R) between the expression levels yield improving genes and their homologs in various tissues [Expression (Exp) sets, Table 127] and the phenotypic performance [yield, biomass, and plant architecture as described in Tables 129-134 using the Correlation vectors (Corr.) described in Table 128] under normal conditions across soybean varieties. P=p value.

Example 16

Production of Tomato Transcriptome and High Throughput Correlation Analysis Using 44K Tomato Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis between NUE related phenotypes and gene expression, the present inventors utilized a Tomato oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 44,000 Tomato genes and transcripts. In order to define correlations between the levels of RNA expression with NUE, ABST, yield components or vigor related parameters various plant characteristics of 18 different Tomato varieties were analyzed. Among them, 10 varieties encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

I. Correlation of Tomato Varieties Across Ecotypes Grown Under Low Nitrogen, Drought and Regular Growth Conditions

Experimental Procedures:

10 Tomato varieties were grown in 3 repetitive blocks, each containing 6 plants per plot were grown at net house. Briefly, the growing protocol was as follows:

1. Regular growth conditions: Tomato varieties were grown under normal conditions: 4-6 Liters/m² of water per day and fertilized with NPK (nitrogen, phosphorous and potassium at a ratio 6:6:6, respectively) as recommended in protocols for commercial tomato production.

2. Low Nitrogen fertilization conditions: Tomato varieties were grown under normal conditions (4-6 Liters/m² per day and fertilized with NPK as recommended in protocols for commercial tomato production) until flower stage. At this time, Nitrogen fertilization was stopped.

3. Drought stress: Tomato variety was grown under normal conditions (4-6 Liters/m² per day) until flower stage. At this time, irrigation was reduced to 50% compared to normal conditions.

Plants were phenotyped on a daily basis following the standard descriptor of tomato (Table 137). Harvest was conducted while 50% of the fruits were red (mature). Plants were separated to the vegetative part and fruits, of them, 2 nodes were analyzed for additional inflorescent parameters such as size, number of flowers, and inflorescent weight. Fresh weight of all vegetative material was measured. Fruits were separated to colors (red vs. green) and in accordance with the fruit size (small, medium and large). Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute). Data parameters collected are summarized in Tables 138-140, herein below.

Analyzed Tomato tissues—Two tissues at different developmental stages [flower and leaf], representing different plant characteristics, were sampled and RNA was extracted as described above. For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 136 below.

TABLE 136
Tomato transcriptome expression sets
                                 Set
Expression Set                   ID
Leaf at reproductive stage under normal conditions 1
Flower under normal conditions   2
Leaf at reproductive stage under low N conditions 3
Flower under low N conditions    4
Leaf at reproductive stage under drought conditions 5
Flower under drought conditions  6

Table 136: Provided are the identification (ID) digits of each of the tomato expression sets.

The collected data parameters were as follows:

Fruit Weight (gr)—At the end of the experiment [when 50% of the fruits were ripe (red)] all fruits from plots within blocks A-C were collected. The total fruits were counted and weighted. The average fruits weight was calculated by dividing the total fruit weight by the number of fruits.

Yield/SLA—Fruit yield divided by the specific leaf area, gives a measurement of the balance between reproductive and vegetative processes.

Yield/total leaf area—Fruit yield divided by the total leaf area, gives a measurement of the balance between reproductive and vegetative processes.

Plant vegetative Weight (FW) (gr)—At the end of the experiment [when 50% of the fruit were ripe (red)] all plants from plots within blocks A-C were collected. Fresh weight was measured (grams).

Inflorescence Weight (gr)—At the end of the experiment [when 50% of the fruits were ripe (red)] two Inflorescence from plots within blocks A-C were collected. The Inflorescence weight (gr.) and number of flowers per inflorescence were counted.

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at time of flowering. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Water use efficiency (WUE)—can be determined as the biomass produced per unit transpiration. To analyze WUE, leaf relative water content was measured in control and transgenic plants. Fresh weight (FW) was immediately recorded; then leaves were soaked for 8 hours in distilled water at room temperature in the dark, and the turgid weight (TW) was recorded. Total dry weight (DW) was recorded after drying the leaves at 60° C. to a constant weight. Relative water content (RWC) was calculated according to the following Formula I as described above.

Plants that maintain high relative water content (RWC) compared to control lines were considered more tolerant to drought than those exhibiting reduced relative water content.

TABLE 137
Tomato correlated parameters (vectors)
                                 Correlation
Correlated parameter with        ID
100 weight green fruit [gr.] (Drought conditions) 1
100 weight green fruit [gr.] (Low N conditions) 2
100 weight green fruit [gr.] (Normal conditions) 3
100 weight red fruit [gr.] (Drought conditions) 4
100 weight red fruit [gr.] (Low N conditions) 5
100 weight red fruit [gr.] (Normal conditions) 6
Cluster Weight (Low N/Normal conditions) 7
FW NUE [gr.] (Normal conditions) 8
FW (Drought conditions/Normal conditions) 9
FW/Plant [gr./number] (Low N conditions) 10
FW/Plant [gr./number] (Normal) conditions 11
FW/Plant [gr./number] (Drought conditions) 12
Fruit (Drought conditions/Low N conditions) 13
Fruit NUE [number] (Normal conditions) 14
Fruit Yield (Drought conditions/Normal conditions) 15
Fruit Yield/Plant [gr./number] (Low N conditions) 16
Fruit Yield/Plant [gr./number] (Drought conditions) 17
Fruit yield/Plant [gr.] (Normal conditions) 18
HI [yield/yield + biomass] (Low N conditions) 19
HI [yield/yield + biomass] (Normal conditions) 20
Leaflet Length [cm] (Low N conditions) 21
Leaflet Length [cm] (Normal conditions) 22
Leaflet Length [cm]) (Drought conditions) 23
Leaflet Width [cm] (Low N conditions) 24
Leaflet Width [cm] (Normal conditions) 25
Leaflet Width [cm] (Drought conditions) 26
NUE [yield/SPAD] (Low N conditions) 27
NUE [yield/SPAD] [gr./number] (Normal conditions) 28
NUE2 [total biomass/SPAD] (Low N conditions) 29
NUE2 [total biomass/SPAD] [gr./number] 30
(Normal conditions)
NUpE [biomass/SPAD] (Low N conditions) 31
NUpE [biomass/SPAD] [gr./number] (Normal conditions) 32
No flowers (Low N conditions)    33
Number of flowers (Normal conditions) 34
Number of Flower (Drought conditions/Low N conditions) 35
Number of Flower (Drought conditions/Normal conditions) 36
Number of flowers (Drought conditions) 37
Num. Flowers (Low N conditions/Normal conditions) 38
RWC (Normal conditions)          39
RWC (Drought conditions)         40
RWC (Drought conditions/Normal conditions) 41
RWC (Low N conditions)           42
RWC (Low N conditions/Normal conditions) 43
SPAD 100% RWC (Low N conditions/Normal conditions) 44
SLA [leaf area/plant biomass] [cm2/gr] (Low N conditions) 45
SLA [leaf area/plant biomass] [cm2/gr] (Normal conditions) 46
SPAD (Normal conditions)         47
SPAD 100% RWC (Low N conditions) 48
SPAD 100% RWC (Normal conditions) 49
SPAD (Low N conditions)          50
SPAD (Low N conditions/Normal conditions) 51
Total Leaf Area [cm2] (Low N conditions) 52
Total Leaf Area [cm2] (Normal conditions) 53
Total Leaf Area [cm2]) (Drought conditions) 54
Weight Flower clusters [gr.] (Normal conditions) 55
Weight clusters (flowers) (Low N conditions) 56
Weight flower clusters [gr.] (Drought conditions) 57
Yield/SLA [gr./(cm2/gr.)] (Low N conditions) 58
Yield/SLA [gr./(cm2/gr.)] (Normal conditions) 59
Yield/total leaf area [gr/cm2] (Low N conditions) 60
Yield/total leaf area [gr./cm2] (Normal conditions) 61
Average red fruit weight [gr.] (Low N conditions) 62
Average red fruit weight [gr.] (Normal conditions) 63
Average red fruit weight [gr.] (Drought conditions) 64
Flower cluster weight (Drought conditions/Low N 65
conditions)
Flower cluster weight (Drought conditions/Normal 66
conditions)
Red fruit weight (Drought conditions/Normal conditions) 67

Table 137. Provided are the tomato correlated parameters. “gr.”=grams; “FW”=fresh weight; “NUE”=nitrogen use efficiency: “RWC”=relative water content; “NUpE”=nitrogen uptake efficiency; “SPAD”=chlorophyll levels; “HI”=harvest index (vegetative weight divided on yield); “SLA”=specific leaf area (leaf area divided by leaf dry weight), Treatment in the parenthesis.

Experimental Results

Table 137 provides the tomato correlated parameters (Vectors). The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 138-140 below. Subsequent correlation analysis was conducted (Table 141). Results were integrated to the database.

TABLE 138
Measured parameters in Tomato accessions (lines 1-6)
Ecotype/
Treatment	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6
1
2	0.57	0.37	3.40	0.68	0.45	0.47
3	0.56	3.05	0.24	2.58	6.32	5.75
4
5	0.65	0.53	7.17	0.44		0.55
6	0.82	2.46	0.50	2.76	5.32	5.24
7	0.44	0.01	1.08	0.02	0.37	0.81
8	0.74	3.01	0.83	1.54	3.70	1.22
9	0.61	2.63	1.18	1.36	4.02	1.01
10	2.25	2.54	1.85	3.06	3.13	2.54
11	3.02	0.84	2.24	1.98	0.85	2.09
12	1.85	2.22	2.63	2.71	3.41	2.11
13	1.32	0.76	1.51	0.71	5.06	0.89
14	0.97	3.80	2.78	0.78	0.02	1.16
15	1.27	2.88	4.20	0.55	0.09	1.03
16	0.48	0.46	1.35	0.35	0.01	0.51
17	0.63	0.35	2.04	0.25	0.05	0.45
18	0.49	0.12	0.49	0.45	0.53	0.44
19	0.18	0.15	0.42	0.10	0.00	0.17
20	0.14	0.12	0.18	0.19	0.38	0.17
21	3.69	5.43	6.95	3.73	4.39	6.72
22	6.34	7.99	5.59	7.70	7.85	6.22
23
24	1.79	2.55	3.52	1.73	1.87	3.54
25	3.69	4.77	3.43	4.56	4.44	3.15
26
27	0.01	0.02	0.04	0.01	0.00	0.02
28	0.009	0.003	0.010	0.010	0.012	0.008
29	0.08	0.13	0.09	0.11	0.11	0.09
30	0.063	0.021	0.057	0.056	0.032	0.047
31	0.07	0.11	0.05	0.09	0.11	0.08
32	0.054	0.018	0.046	0.046	0.020	0.039
33	9.00	13.00	10.67	16.67	6.00	16.00
34	6.33	7.67	9.67	8.33	5.00	8.33
35	1.74	1.56	1.09	1.52	4.96	1.08
36	2.47	2.65	1.21	3.04	5.95	2.08
37	15.67	20.33	11.67	25.33	29.73	17.33
38	1.42	1.70	1.10	2.00	1.20	1.92
39	64.29	67.07	54.79	77.61	58.18	66.51
40	65.33	72.22	66.13	68.33	78.13	18.46
41	1.02	1.08	1.21	0.88	1.34	0.28
42	69.49	63.24	77.36	77.91	80.49	67.40
43	1.08	0.94	1.41	1.00	1.38	1.01
44	0.92	0.75	1.31	0.97	1.11	0.95
45	131.29	148.82	257.51	64.34	144.60	246.05
46	140.99	689.67	130.22	299.12	1117.74	111.77
47	55.80	46.40	48.20	43.40	42.90	53.30
48	33.01	23.42	34.53	32.51	27.66	33.68
49	35.89	31.09	26.38	33.68	24.98	35.47
50	47.50	37.00	44.60	41.70	34.40	50.00
51	0.85	0.80	0.93	0.96	0.80	0.94
52	294.83	378.00	476.39	197.08	453.24	625.51
53	426.10	582.38	291.40	593.58	947.59	233.35
54
55	0.69	56.35	0.44	11.31	0.79	0.58
56	0.31	0.35	0.47	0.25	0.29	0.47
57	0.33	0.29	0.55	0.31	0.45	0.56
58	0.004	0.003	0.005	0.006	0.000	0.002
59	0.004	0.000	0.004	0.002	0.000	0.004
60	0.002	0.001	0.003	0.002	0.000	0.001
61	0.001	0.000	0.002	0.001	0.001	0.002
62	0.006	0.005	0.096	0.004	0.006	0.007
63	0.01	0.29	0.01	0.05	0.23	0.29
64	0.209	0.005	0.102	0.002	0.035	0.006
65	1.06	0.82	1.16	1.25	1.52	1.19
66	0.47	0.01	1.25	0.03	0.56	0.96
67	25.38	0.02	20.26	0.04	0.15	0.02

Table 138.

TABLE 139
Measured parameters in Tomato accessions (lines 7-12)
Ecotype/
Treatment	Line-7	Line-8	Line-9	Line-10	Line-11	Line-12
1				0.80	0.28	0.38
2	0.54	0.39	0.97	0.91	0.36	0.35
3	0.38	0.30	1.95	2.53	1.42	2.03
4				0.89	0.35	0.63
5	0.75	0.58	1.27	1.34	0.52	0.57
6	0.61	0.66	2.70	0.70	2.64	4.67
7	0.55	0.36	0.95	0.80	0.34	0.61
8	0.58	0.55	1.06	0.49	1.31	1.36
9	0.61	0.64	0.95	0.51	1.17	1.94
10	1.84	1.52	1.91	1.86	2.47	2.62
11	3.21	2.75	1.81	3.77	1.89	1.93
12	1.95	1.76	1.72	1.92	2.21	3.73
13	0.67	2.17	0.38	1.27	0.84	1.51
14	2.07	1.51	2.41	2.06	0.38	1.64
15	1.39	3.28	0.91	2.62	0.32	2.48
16	0.44	0.47	1.59	0.39	0.32	0.45
17	0.29	1.02	0.60	0.49	0.27	0.68
18	0.21	0.31	0.66	0.19	0.85	0.27
19	0.19	0.24	0.45	0.17	0.12	0.15
20	0.06	0.10	0.27	0.05	0.31	0.12
21	6.66	4.39	3.90	5.29	6.32	5.11
22	6.16	5.65	4.39	4.44	6.77	7.42
23				5.15	3.38	7.14
24	3.28	2.52	2.61	2.61	3.58	2.56
25	3.37	3.13	2.40	2.02	3.80	3.74
26				2.55	2.04	4.17
27	0.01	0.01	0.06	0.01	0.01	0.02
28	0.004	0.006	0.017	0.004	0.015	0.006
29	0.08	0.06	0.14	0.06	0.06	0.12
30	0.058	0.060	0.062	0.083	0.047	0.046
31	0.06	0.04	0.08	0.05	0.05	0.10
32	0.055	0.054	0.045	0.079	0.033	0.040
33	15.00	6.00	17.00	13.00	8.67	9.33
34	10.00	7.00	9.00	8.00	5.33	8.00
35	0.98	4.94	0.88	0.79	2.12	1.29
36	1.47	4.24	1.67	1.29	3.44	1.50
37	14.67	29.67	15.00	10.33	18.33	12.00
38	1.50	0.86	1.89	1.63	1.63	1.17
39	64.71	75.25	66.23	63.21	56.77	35.96
40	73.21	62.50	67.21	75.76	62.82	70.69
41	1.13	0.83	1.01	1.20	1.11	1.97
42	67.16	66.07	69.57	69.30	100.00	57.66
43	1.04	0.88	1.05	1.10	1.76	1.60
44	0.79	0.92	0.94	1.36	1.44	1.50
45	405.55	299.32	86.19	182.32	160.18	90.10
46	106.2.9	123.14	104.99	111.88	307.95	419.37
47	58.50	51.10	40.00	47.60	57.90	48.30
48	30.04	35.50	24.81	40.77	47.47	26.06
49	37.87	38.43	26.49	30.07	32.89	17.35
50	44.70	53.70	35.70	58.80	47.50	45.20
51	0.76	1.05	0.89	1.24	0.82	0.94
52	748.01	453.96	164.85	338.30	396.00	236.15
53	340.73	339.11	190.14	421.79	581.33	807.51
54				337.63	130.78	557.93
55	0.73	0.83	0.86	0.50	1.02	0.70
56	0.40	0.30	0.82	0.40	0.35	0.43
57	0.304	0.315	0.308	0.311	8.360	0.288
58	0.001	0.002	0.018	0.002	0.002	0.005
59	0.002	0.003	0.006	0.002	0.003	0.001
60	0.001	0.001	0.010	0.001	0.001	0.002
61	0.001	0.001	0.003	0.000	0.001	0.000
62	0.006	0.013	0.021	0.005	0.006	0.047
63	0.006	0.007	0.058	0.007	0.026	0.261
64	0.005	0.005	0.005	0.012	0.005	0.006
65	0.76	1.04	0.38	0.78	24.12	0.67
66	0.42	0.38	0.36	0.62	8.20	0.41
67	0.86	0.74	0.09	1.72	0.17	0.02

Table 139.

TABLE 140
Measured parameters in Tomato accessions (lines 13-18)
Ecotype/
Treatment	Line-13	Line-14	Line-15	Line-16	Line-17	Line-18
1	0.63	2.86	1.16	4.40
2	0.57	4.38	2.02	8.13	0.87	3.66
3	1.39	2.27	0.45	0.42
4	2.27	7.40	2.94	11.60
5	0.94	6.17	3.67	11.33	1.06	6.87
6	2.17	0.49	0.34	0.75
7	0.94	0.68	0.40	1.44	0.46	1.07
8	0.51	0.71	0.31	0.47	2.65	0.38
9	0.35	1.06	0.21	0.48	1.72	0.34
10	1.08	1.17	0.92	1.09	4.04	1.21
11	2.14	1.65	3.01	2.29	1.53	3.17
12	0.75	1.76	0.63	1.11	2.62	1.09
13	0.98	1.34	0.38	0.84	1.15	0.73
14	0.41	1.21	4.59	1.70	0.49	1.93
15	0.41	1.62	1.76	1.42	0.57	1.41
16	0.14	0.40	1.44	0.50	0.41	0.66
17	0.14	0.53	0.55	0.41	0.47	0.48
18	0.35	0.33	0.31	0.29	0.83	0.34
19	0.12	0.25	0.61	0.31	0.09	0.35
20	0.14	0.17	0.09	0.11	0.35	0.10
21	4.72	6.83	7.10	8.21	6.40	5.92
22	6.71	5.87	4.16	10.29
23	5.48	8.62	6.35	6.77
24	2.48	3.43	3.30	3.69	3.47	1.97
25	2.98	3.22	2.09	5.91
26	3.09	4.69	3.87	2.91
27	0.00	0.01	0.04	0.01	0.01	0.02
28	0.008	0.006	0.008	0.005	0.017	0.009
29	0.03	0.05	0.06	0.04	0.16	0.05
30	0.057	0.036	0.080	0.044	0.047	0.095
31	0.03	0.04	0.02	0.03	0.14	0.03
32	0.049	0.030	0.072	0.039	0.031	0.085
33	12.67	6.67	9.33	8.00	19.00	5.33
34	7.67	9.00	10.67	9.00	5.67	19.33
35	1.61	1.90	1.36	1.42	0.88	1.22
36	2.65	1.41	1.19	1.26	2.94	0.34
37	20.33	12.67	12.67	11.33	16.67	6.50
38	1.65	0.74	0.88	0.89	3.35	0.28
39	77.62	100.00	63.16	75.13	72.83	76.47
40	55.75	75.22	63.68	62.31	72.12	74.51
41	0.72	0.75	1.01	0.83	0.99	0.97
42	90.79	68.00	59.65	72.17	74.07	99.08
43	1.17	0.68	0.94	0.96	1.02	1.30
44	1.05	0.56	1.48	0.84	0.79	1.37
45	160.99	379.03	531.08	650.68	140.04	317.12
46	365.81	212.93	84.94	469.87
47	43.60	54.50	41.60	59.10	49.70	37.20
48	35.38	30.60	38.97	37.46	28.47	39.04
49	33.82	54.47	26.25	44.43	36.17	28.45
50	39.00	45.00	65.30	51.90	38.40	39.40
51	0.89	0.83	1.57	0.88	0.77	1.06
52	174.58	441.78	489.18	707.80	565.93	384.77
53	784.06	351.80	255.78	1078.10
54	176.67	791.86	517.05	832.27
55	0.38	0.66	0.70	0.33	1.17	0.34
56	0.35	0.45	0.28	0.47	0.53	0.37
57	0.34	0.44	0.27	0.43	0.37	0.41
58	0.001	0.001	0.003	0.001	0.003	0.002
59	0.001	0.002	0.004	0.001
60	0.001	0.001	0.003	0.001	0.001	0.002
61	0.000	0.001	0.001	0.000
62	0.357	0.037	0.626		0.024	0.191
63	0.029	0.005	0.003	0.009	0.048	0.008
64	0.30	0.14	0.04	0.09	0.01	0.19
65	0.97	0.99	0.95	0.91	0.69	1.11
66	0.91	0.67	0.38	1.31	0.32	1.19
67	10.50	27.89	11.79	9.98	0.19	24.37

Table 140: Provided are the values of each of the parameters (as described above) measured in tomato accessions (Seed ID) under all growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 141
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal and stress
conditions across tomato ecotypes
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY212	0.70	5.16E−02	2	46	LBY212	0.82	1.29E−02	2	53
LBY213	0.71	2.23E−02	4	45	LBY213	0.86	1.27E−03	4	2
LBY213	0.86	1.45E−03	4	5	LBY213	0.71	2.11E−02	4	7

Table 141. Provided are the correlations (R) between the expression levels yield improving genes and their homologs in various tissues [Expression (Exp) sets, Table 136] and the phenotypic performance [yield, biomass, growth rate and/or vigor components described in Tables 138-140 using the correlation vectors (Corr.) described in Table 137] under normal, low N and drought conditions across tomato ecotypes. P=p value.

II. Correlation of early vigor traits across collection of Tomato ecotypes under 300 mM NaC, low nitrogen and normal growth conditions—Ten tomato hybrids were grown in 3 repetitive plots, each containing 17 plants, at a net house under semi-hydroponics conditions. Briefly, the growing protocol was as follows: Tomato seeds were sown in trays filled with a mix of vermiculite and peat in a 1:1 ratio. Following germination, the trays were transferred to the high salinity solution (300 mM NaCl in addition to the Full Hoagland solution), low nitrogen solution (the amount of total nitrogen was reduced in a 90% from the full Hoagland solution, final amount of 0.8 mM N), or at Normal growth solution (Full Hoagland containing 8 mM N solution, at 28±2° C.). All the plants were grown at 28±2° C.

Full Hoagland solution consists of: KNO₃—0.808 grams/liter. MgSO₄—0.12 grams/liter. KH₂PO₄—0.172 grams/liter and 0.01% (volume/volume) of ‘Super coratin’ micro elements (Iron-EDDHA [ethylenediamine-N,N′-bis(2-hydroxyphenylacetic acid)]—40.5 grams/liter; Mn—20.2 grams/liter, Zn 10.1 grams/liter; Co 1.5 grams/liter; and Mo 1.1 grams/liter), solution's pH should be 6.5-6.8.

Analyzed tomato tissues—All 10 selected Tomato varieties were sample per each treatment. Two types of tissues [leaves and roots] were sampled and RNA was extracted as described above. For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 142 below.

TABLE 142
Tomato transcriptome expression sets
                               Set
Expression Set                 IDs
Leaf - normal conditions       1 + 10
Root - normal conditions       2 + 9
Leaf - low nitrogen conditions 3 + 8
Root - low nitrogen conditions 4 + 7
Leaf - salinity conditions     5 + 12
Root - salinity conditions     6 + 11

Table 142. Provided are the tomato transcriptome experimental sets.

Tomato vigor related parameters—following 5 weeks of growing, plant were harvested and analyzed for leaf number, plant height, chlorophyll levels (SPAD units), different indices of nitrogen use efficiency (NUE) and plant biomass. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute). Data parameters collected are summarized in Table 143, herein below.

Leaf number—number of opened leaves.

RGR Leaf Number—was calculated based on Formula VIII (above).

Shoot/Root ratio—was calculated based on Formula XXX (above).

NUE total biomass—nitrogen use efficiency (NUE) calculated as total biomass divided by nitrogen concentration.

NUE root biomass—nitrogen use efficiency (NUE) of root growth calculated as root biomass divided by nitrogen concentration.

NUE shoot biomass—nitrogen use efficiency (NUE) of shoot growth calculated as shoot biomass divided by nitrogen concentration.

Percent of reduction of root biomass compared to normal—the difference (reduction in percent) between root biomass under normal and under low nitrogen conditions.

Percent of reduction of shoot biomass compared to normal—the difference (reduction in percent) between shoot biomass under normal and under low nitrogen conditions.

Percent of reduction of total biomass compared to normal—the difference (reduction in percent) between total biomass (shoot and root) under normal and under low nitrogen conditions.

Plant height—Plants were characterized for height during growing period at 5 time points. In each measure, plants were measured for their height using a measuring tape. Height was measured from ground level to top of the longest leaf.

SPAD [SPAD unit]—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 64 days post sowing.

SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Root Biomass [DW, gr.]/SPAD—root biomass divided by SPAD results.

Shoot Biomass [DW, gr.]/SPAD—shoot biomass divided by SPAD results.

Total Biomass (Root+Shoot) [DW, gr.]/SPAD—total biomass divided by SPAD results.

TABLE 143
Tomato correlated parameters (vectors)
                                 Correlation
Correlated parameter with        ID
Leaf number (Low N conditions/Normal conditions) [ratio] 1
Leaf number (Salinity conditions/Normal conditions) [ratio] 2
Leaf number (Salinity conditions/Low N conditions) [ratio] 3
N level/Leaf [SPAD unit/leaf] (Low N conditions, Normal 4
conditions and salinity conditions)
NUE roots (Root Biomass DW/SPAD) [gr./SPAD unit] 5
(Low N conditions and Normal conditions)
NUE shoots (shoot Biomass DW/SPAD) [gr./SPAD unit] 6
(Low N conditions and Normal conditions)
NUE total biomass (Total Biomass DW/SPAD) [gr./SPAD 7
unit] (Low N conditions and Normal conditions)
Percent of reduction of root biomass compared to normal 8
[%] (Low N conditions/Normal conditions) [ratio]
Percent of reduction of shoot biomass compared to normal 9
[%] (Low N conditions/Normal conditions) [ratio]
Plant Height (Low N conditions/Normal conditions) [ratio] 10
Plant Height (Salinity conditions/Low N conditions) [ratio] 11
Plant Height (Salinity conditions/Normal conditions) [ratio] 12
Plant biomass (Salinity conditions) [gr.] 13
Plant height (Low N conditions) [cm] 14
Plant height (Salinity conditions) [cm] 15
Plant height (Normal conditions) [cm] 16
NUE Root Biomass DW/SPAD [gr./SPAD unit] 17
(Low N conditions and Normal conditions)
SPAD (Low N conditions/Normal conditions) [ratio] 18
SPAD (Low N conditions) [SPAD unit] 19
SPAD (Normal conditions) [SPAD unit] 20
NUE Shoot Biomass DW/SPAD [gr./SPAD unit] 21
(Low N conditions, Normal conditions and salinity
conditions)
Shoot/Root [ratio] (Low N conditions and Normal 22
conditions)
NUE Total Biomass (Root + Shoot DW)/SPAD [gr/SPAD 23
unit] (Low N conditions, Normal conditions and salinity
conditions)
Plant height (Normal conditions) [cm] 24
Leaf number (Low N conditions) [number] 25
Leaf number (Normal conditions) [number] 26
Leaf number (Salinity conditions) [number] 27

Table 143. Provided are the tomato correlated parameters. “NUE”=nitrogen use efficiency; “DW”=dry weight; “cm”=centimeter: “num”—number; “SPAD”=chlorophyll levels; “gr”=gram;

Experimental Results

10 different Tomato varieties were grown and characterized for parameters as described above (Table 143). The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 144-147 below. Subsequent correlation analysis was conducted (Table 148). Follow, results were integrated to the database.

TABLE 144
Measured parameters in Tomato accessions under low nitrogen conditions
	Corr. ID
Line	1	10	14	18	19	24	25	4	5
Line-	0.85	0.810	36.78	1.01	34.57	45.33	5.56	10.854	6.99
1
Line-	0.90	0.830	39.89	0.98	24.87	47.78	6.22	11.409	2.54
2
Line-	0.98	0.840	34.44	1.02	28.58	40.78	7.22
3
Line-	1.09	0.850	47.00	1.00	31.58	55.33	6.78	10.438	7.04
4
Line-	0.88	0.830	46.44	0.98	29.72	56.22	5.56	11.169	5.04
5
Line-	1.02	0.930	45.44	0.98	31.83	48.67	6.56	8.929	8.01
6
Line-	0.87	0.850	47.67	0.93	30.33	55.78	5.11	7.926	15.09
7
Line-	1.06	1.050	39.33	1.05	30.29	37.44	5.89	7.993	9.02
8
Line-	0.91	0.840	41.78	1.01	31.32	49.56	5.56	10.304	8.78
9
Line-	1.12	0.880	41.00	0.99	28.77	46.33	6.33	8.585	7.25
10
Line-								11.528	7.73
11
Line-								14.491	15.94
12

Table 144. Provided are the values of each of the parameters (as described above) measured in Tomato accessions (Line) under low nitrogen growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 145
Additional measured parameters in Tomato accessions under low nitrogen conditions
	Corr. ID
Line	6	7	8	9	17	21	22	23
Line-1	35.35	58.47	62.592	75.380	0.00082	0.0041	5.010	0.0050
Line-2	24.09	63.75	54.158	55.112	0.00032	0.0030	11.393	0.0034
Line-3
Line-4	65.02	69.29	70.547	49.726	0.00079	0.0072	9.494	0.0080
Line-5	46.71	71.1	59.685	63.189	0.00055	0.0049	11.600	0.0055
Line-6	46.67	60.54	96.129	82.667	0.00086	0.0052	8.200	0.0060
Line-7	120.07	73.9	106.502	66.924	0.00139	0.0115	10.375	0.0129
Line-8	60.09	68.81	111.905	107.983	0.00102	0.0069	10.523	0.0079
Line-9	66.27	66.74	81.644	55.401	0.00088	0.0068	8.242	0.0077
Line-10	56.46	70.82	32.214	54.433	0.00086	0.0067	7.967	0.0076
Line-11	38.35	69.7	143.714	62.155	0.00085	0.0042	6.414	0.0050
Line-12	60.32	49.72	87.471	59.746	0.00148	0.0056	3.909	0.0070

Table 145. Provided are the values of each of the parameters (as described above) measured in Tomato accessions (Line) under low nitrogen growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 146
Measured parameters in Tomato accessions under normal conditions
	Corr. ID
Line	16	20	26	4	5	6	7	17	21	22	23
Line-1	45.33	34.30	6.56	9.29	1.12	4.69	7.47	0.0012	0.0052	5.40	0.0064
Line-2	47.78	25.31	6.89	8.87	0.47	4.37	8.63	0.0006	0.0052	10.02	0.0058
Line-3	40.78	28.12	7.33
Line-4	55.33	31.43	6.22	8.43	1	13.08	8.85	0.0011	0.0144	15.42	0.0155
Line-5	56.22	30.24	6.33	9.83	0.84	7.39	7.22	0.0010	0.0084	8.83	0.0093
Line-6	48.67	32.43	6.44	8.57	0.83	5.65	7.87	0.0011	0.0054	7.52	0.0065
Line-7	55.78	32.58	5.89	6.57	0.94	17.94	9.09	0.0014	0.0174	12.61	0.0188
Line-8	37.44	28.77	5.56	6.97	0.81	5.56	7.91	0.0010	0.0072	7.99	0.0082
Line-9	49.56	30.92	6.11	8.71	1.08	11.96	8.55	0.0010	0.0109	14.31	0.0119
Line-10	46.33	28.99	5.67	7.35	2.25	10.37	8.68	0.0025	0.0117	4.80	0.0143
Line-11				10.18	0.54	6.17	9.1	0.0005	0.0061	12.65	0.0066
Line-12				9.37	1.82	10.1	6.24	0.0017	0.0094	6.29	0.0110

Table 146. Provided are the values of each of the parameters (as described above) measured in Tomato accessions (Line) under normal growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 147
Measured parameters in Tomato accessions under salinity conditions
	Corr. ID
Line	2	3	11	12	13	15	27	4	21	17	23
Line-1	0.54	0.64	0.15	0.12	0.36	5.60	3.56	11.40	0.0005	0.000060	0.0007
Line-2	0.57	0.63	0.16	0.14	0.44	6.46	3.94	11.64	0.0007	0.000107	0.0008
Line-3	0.68	0.69	0.25	0.21	0.26	8.47	5.00
Line-4	0.64	0.59	0.18	0.15	0.71	8.56	4.00	10.79	0.0012	0.000095	0.0014
Line-5	0.56	0.64	0.19	0.16	0.46	8.87	3.56	10.78	0.0017	0.000068	0.0018
Line-6	0.68	0.67	0.17	0.16	0.54	7.56	4.39	6.95	0.0010	0.000087	0.0011
Line-7	0.54	0.62	0.18	0.15	0.66	8.64	3.17	9.21	0.0012	0.000099	0.0013
Line-8	0.67	0.63	0.14	0.15	0.40	5.57	3.72	8.54	0.0007	0.000083	0.0008
Line-9	0.65	0.72	0.14	0.12	0.52	5.82	4.00	10.37	0.0010	0.000094	0.0011
Line-10	0.75	0.68	0.23	0.20	0.45	9.36	4.28	8.84	0.0010
Line-11								10.43	0.0007	0.000054	0.0006
Line-12								12.43	0.0007	0.000055	0.0007

Table 147. Provided are the values of each of the parameters (as described above) measured in Tomato accessions (Line) under salinity growth conditions. Growth conditions are specified in the experimental procedure section.

TABLE 148
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under low nitrogen, normal or
salinity stress conditions across Tomato accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY212	0.75	3.13E−02	3	25	LBY213	0.81	1.38E−02	3	10
LBY213	0.85	3.95E−03	3	9	LBY213	0.74	2.18E−02	3	8

Table 148. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 143. “Exp. Set”—Expression set specified in Table 142. “R”=Pearson correlation coefficient; “P”=p value.

Example 17

Plant Fiber Development in Cotton Production of Cotton Transcriptom and High Throughput Correlation Analysis Using Cotton Oligonucleotide Microarray

In order to conduct high throughput gene expression correlation analysis, the present inventors used cotton oligonucleotide microarray, designed and produced by “Comparative Evolutionary Genomics of Cotton” [cottonevolution (dot) info/]. This Cotton Oligonucleotide Microarray is composed of 12.006 Integrated DNA Technologies (IDT) oligonucleotides derived from an assembly of more than 180.000 Gossypium ESTs sequenced from 30 cDNA libraries. For additional details see PCT/IL2005/000627 and PCT/IL2007/001590 which are fully incorporated herein by reference.

TABLE 149
Cotton transcriptome experimental sets
                  Set
Expression Set    ID
cotton fiber 5 d  1
cotton fiber 15 d 2
cotton fiber 10 d 3

Table 149. Provided are the cotton transcriptome expression sets. “Sd”=5 days post anthesis; “10d”=10 days post anthesis; “15d”=15 days post anthesis. “DPA”=days-past-anthesis.

In order to define correlations between the levels of RNA expression and fiber length, fibers from 8 different cotton lines were analyzed. These fibers were selected showing very good fiber quality and high lint index (Pima types, originating from other cotton species, namely G. barbadense), different levels of quality and lint indexes from various G. hirsutum lines: good quality and high lint index (Acala type), and poor quality and short lint index (Tamcot type, and old varieties). A summary of the fiber length of the different lines is provided in Table 150.

Experimental Procedures

RNA extraction—Fiber development stages, representing different fiber characteristics, at 5, 10 and 15 DPA were sampled and RNA was extracted as described above.

Fiber length assessment—Fiber length of the selected cotton lines was measured using fibrograph. The fibrograph system was used to compute length in terms of “Upper Half Mean” length. The upper half mean (UHM) is the average length of longer half of the fiber distribution. The fibrograph measures length in span lengths at a given percentage point World Wide Web (dot) cottoninc (dot) com/ClassificationofCotton/?Pg=4#Length].

Experimental Results

Eight different cotton lines were grown, and their fiber length was measured. The fibers UHM values are summarized in Table 150 herein below. The R square was calculated (Table 151).

TABLE 150
Summary of the fiber length of the 8 different cotton lines
Line/Correlation ID Fiber Length (UHM)
Line-1              1.21
Line-2              1.10
Line-3              1.36
Line-4              1.26
Line-5              0.89
Line-6              1.01
Line-7              1.06
Line-8              1.15

Table 150: Presented are the fiber length means of 8 different cotton lines.

TABLE 151
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions in
cotton
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY48	0.73	6.24E−02	3	1	LBY53	0.74	3.67E−02	2	1
LBY93	0.81	1.59E−02	1	1	LBY96	0.73	4.06E−02	2	1

Table 151. Correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr.”=correlation: “set ID 1”=fiber length. “Exp. Set”—Expression set (according to Table 149). “R”=Pearson correlation coefficient; “P”=p value.

Example 18

Production of Cotton Transcriptome and High Throughput Correlation Analysis with Yield and Abst Related Parameters Using 60K Cotton Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a cotton oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60.000 cotton genes and transcripts. In order to define correlations between the levels of RNA expression with ABST and yield and components or vigor related parameters, various plant characteristics of 13 different cotton ecotypes were analyzed and further used for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Correlation of Cotton Varieties Across Ecotypes Grown Under Regular and Drought Growth Conditions

Experimental Procedures

13 Cotton ecotypes were grown in 5-11 repetitive plots, in field. Briefly, the growing protocol was as follows:

Regular growth conditions: Cotton plants were grown in the field using commercial fertilization and irrigation protocols [623 m³ water per dunam (1000 square meters) per entire growth period, fertilization of 24 units of 12% nitrogen, 12 units of 6% phosphorous and 12 units of 6% potassium per entire growth periods]. Plot size was of 5 meter long, two rows, 8 plants per meter.

Drought growth conditions: Cotton seeds were sown in soil and grown under normal condition until first squares were visible (40 days from sowing), and then drought treatment was induced by irrigating with 75% water in comparison to the normal treatment [472 m³ water per dunam (1000 square meters) per entire growth period], while maintaining normal fertilization.

Analyzed Cotton tissues—Eight tissues [mature leaf, lower and upper main stem, flower, main mature boll, fruit, ovule with fiber (Day) and ovule with fiber (Night)] from plants growing under normal conditions were sampled and RNA was extracted as described above.

Eight tissues [mature leaf (Day), mature leaf (Night), lower main stem, upper main stem, main flower, main mature boll, ovule and fiber (Day) and ovule with fiber (night)] from plants growing under drought conditions were sampled and RNA was extracted as described above.

Each micro-array expression information tissue type has received a Set ID as summarized in Tables 152-154 below.

TABLE 152
Cotton transcriptome expression sets under
normal conditions (normal expression set 1)
                                 Set
Expression Set                   ID
Fruit at 10 DPA at reproductive stage under normal growth 1
conditions
Lower main stem at reproductive sage under normal growth 2
conditions
Main flower at reproductive stage under normal growth conditions 3
Main mature boll at reproductive stage under normal growth 4
conditions
Mature leaf (day) at reproductive stage under normal conditions 5
Mature leaf (night) at reproductive stage under normal conditions 6
Ovule and fiber (day) at reproductive stage under normal conditions 7
Ovule and fiber (night) at reproductive stage under normal conditions 8
Upper main stem at reproductive stage under normal growth 9
conditions

Table 152: Provided are the cotton transcriptome expression sets. “Mature leaf”=Full expanded leaf; Lower main stem=the main stem adjacent to main mature boll; Upper main stem=the main stem adjacent to the main flower; Main flower=reproductive organ on the third position on the main stem (position 3); Fruit at 10 DPA=reproductive organ ten days after anthesis on the main stem (position 2); Main mature boll=reproductive organ on the first position on the main stem (position 1). “DPA”=days post anthesis.

TABLE 153
Additional Cotton transcriptome expression sets
under normal conditions (normal expression set 2)
                                 Set
Expression Set                   ID
Mature leaf at reproductive stage during day under normal growth 1
conditions
Ovule and fiber at reproductive stage during day under normal growth 2
conditions
Ovule and fiber at reproductive stage during night under normal 3
growth conditions

Table 153: Provided are the cotton transcriptome expression sets. “Mature lea”Full expanded leaf; Ovule and fiber were sampled either at day or night hours.

TABLE 154
Cotton transcriptome expression sets under drought
conditions (drought expression set 1)
                                 Set
Expression Set                   ID
Lower main stem at reproductive stage under drought growth 1
conditions
Main flower at reproductive stage under drought growth conditions 2
Main mature boll at reproductive stage under drought growth 3
conditions
Mature leaf during night at reproductive stage under drought growth 4
conditions
Ovule with fiber at reproductive stage during day under drought 5
growth conditions
Ovule with fiber at reproductive stage during night under drought 6
growth conditions
Upper main stem at reproductive stage under drought growth 7
conditions

Table 154: Provided are the cotton transcriptome expression sets. Lower main stem=the main stem adjacent to main mature boll; Upper main stem=the main stem adjacent to the main flower; Main flower=reproductive organ on the third position on the main stem (position 3); Main mature boll=reproductive organ on the first position on the main stem (position 1); Ovule and fiber were sampled either at day or night hours.

Cotton yield components and vigor related parameters assessment—13 Cotton ecotypes in 5-11 repetitive plots, each plot containing approximately 80 plants were grown in field. Plants were regularly fertilized and watered during plant growth until harvesting (as recommended for commercial growth). Plants were continuously phenotyped during the growth period and at harvest (Tables 155-156). The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

The following parameters were measured and collected:

Total Bolls yield (RP) [gr.]—Total boll weight (including fiber) per plot.

Total bolls yield per plant (RP) [gr.]—Total boll weight (including fiber) per plot divided by the number of plants.

Fiber yield (RP) [gr.]—Total fiber weight per plot.

Fiber yield per plant (RP) [gr.]—Total fiber weight in plot divided by the number of plants.

Fiber yield per boll (RP) [gr.]—Total fiber weight in plot divided by the number of bolls.

Estimated Average Fiber yield (MB) po_1 (H) [gr.]—Weight of the fiber on the main branch in position 1 at harvest.

Estimated Average Fiber yield (MB) po_3 (H) [gr.]—Weight of the fiber on the main branch in position 3 at harvest.

Estimated Average Bolls FW (MB) po_(H) [gr.]—Weight of the fiber on the main branch in position 1 at harvest.

Estimated Average Bolls FW (MB) po_3 (H) [gr.]—Weight of the fiber on the main branch in position 3 at harvest.

Fiber Length (RP)—Measure Fiber Length in inch from the rest of the plot.

Fiber Length Position 1 (SP)—Fiber length at position 1 from the selected plants. Measure Fiber Length in inch.

Fiber Length Position 3 (SP)—Fiber length at position 3 from the selected plants. Measure Fiber Length in inch.

Fiber Strength (RP)—Fiber Strength from the rest of the plot. Measured in grams per denier.

Fiber Strength Position 3 (SP)—Fiber strength at position 3 from the selected plants. Measured in grams per denier.

Micronaire (RP)—fiber fineness and maturity from the rest of the plot. The scale that was used was 3.7-4.2—for Premium; 4.3-4.9—Base Range; above 5—Discount Range.

Micronaire Position 1 (SP)—fiber fineness and maturity from position 1 from the selected plants. The scale that was used was 3.7-4.2—for Premium; 4.3-4.9—Base Range: above 5—Discount Range.

Micronaire Position 3 (SP)—fiber fineness and maturity from position 3 from the selected plants. The scale that was used was 3.7-4.2—for Premium; 4.3-4.9—Base Range; above 5—Discount Range.

Short Fiber Content (RP (%)—short fiber content from the rest of the plot.

Uniformity (RP) (%)—fiber uniformity from the rest of the plot.

Carbon isotope discrimination—(%)—isotopic ratio of 13C to 12C in plant tissue was compared to the isotopic ratio of 13C to 12C in the atmosphere measured in units of Per-mille (%), i.e., parts per thousand, e.g., 1%=1/1000=0.001.

Leaf temp (V) (0 celsius)—leaf temperature was measured at vegetative stage using Fluke IR thermometer 568 device. Measurements were done on 4 plants per plot.

Leaf temp (10DPA) (celsius)—Leaf temperature was measured 10 days post anthesis using Fluke IR thermometer 568 device. Measurements were done on 4 plants per plot.

Stomatal conductance (10DPA)—(mmol m⁻² s⁻¹)—plants were evaluated for their stomata conductance using SC-1 Leaf Porometer (Decagon devices) 10 days post anthesis. Stomata conductance readings were done on fully developed leaf, for 2 leaves and 2 plants per plot.

Stomatal conductance (17DPA)—(mmol m⁻² s⁻¹)—plants were evaluated for their stomata conductance using SC-1 Leaf Porometer (Decagon devices) 17 days post anthesis. Stomata conductance readings were done on fully developed leaf, for 2 leaves and 2 plants per plot.

% Canopy coverage (10DPA) (F)—percent Canopy coverage 10 days post anthesis and at flowering stage. The % Canopy coverage is calculated using Formula XXXII above.

Leaf area (10 DPA) (cm²)—Total green leaves area 10 days post anthesis.

PAR_LAI (10 DPA)—Photosynthetically active radiation 10 days post anthesis.

SPAD (17 DPA) [SPAD unit]—Plants were characterized for SPAD rate 17 days post anthesis. Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter. Four measurements per leaf were taken per plot.

SPAD (pre F)—Plants were characterized for SPAD rate during pre-flowering stage. Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter. Four measurements per leaf were taken per plot.

SPAD rate—the relative growth rate (RGR) of SPAD (Formula IV) as described above.

Leaf mass fraction (10DPA) [cm/g]—leaf mass fraction 10 days post anthesis. The leaf mass fraction is calculated using Formula XXXIII above.

Lower Stem width (H) [mm]—This parameter was measured at harvest. Lower internodes from 8 plants per plot were separated from the plant and the diameter was measured using a caliber. The average internode width per plant was calculated by dividing the total stem width by the number of plants.

Upper Stem width (H) [mm]—This parameter was measured at harvest. Upper internodes from 8 plants per plot were separated from the plant and the diameter was measured using a caliber. The average internode width per plant was calculated by dividing the total stem width by the number of plants.

Plant height (H) [cm]—plants were measured for their height at harvest using a measuring tape. Height of main stem was measured from ground to apical meristem base. Average of eight plants per plot was calculated.

Plant height growth [cm/day]—the relative growth rate (RGR) of Plant Height (Formula III above) as described above.

Shoot DW (V) [gr.]—Shoot dry weight at vegetative stage after drying at 70° C. in oven for 48 hours. Total weight of 3 plants in a plot.

Shoot DW (10DPA) [gr.]—Shoot dry weight at 10 days post anthesis, after drying at 70° C. in oven for 48 hours. Total weight of 3 plants in a plot.

Bolls number per plant (RP) [num]—Average bolls number per plant from the rest of the plot.

Reproductive period duration [num]—number of days from flowering to harvest for each plot.

Closed Bolls number per plant (RP) num—Average closed bolls number per plant from the rest of the plot.

Closed Bolls number per plant (SP) [num]—Average closed bolls number per plant from selected plants.

Open Bolls number per plant (SP) [num]—Average open bolls number per plant from selected plants, average of eight plants per plot.

Number of lateral branches with open bolls (H) [num]—count of number of lateral branches with open bolls at harvest, average of eight plants per plot.

Number of nodes with open bolls (MS) (H) [num]—count of number of nodes with open bolls on main stem at harvest, average of eight plants per plot.

Seeds yield per plant (RP) [gr.]—Total weight of seeds in plot divided in plants number.

Estimated Average Seeds yield (MB) po_1 (H) [gr.]—Total weight of seeds in position one per plot divided by plants number.

Estimated Average Seeds yield (MB) po_3 (H) [gr.]—Total weight of seeds in position three per plot divided by plants number.

Estimated Average Seeds number (MB) po_1 (H) [num]—Total number of seeds in position one per plot divided by plants number.

Estimated Average Seeds number (MB) po_3 (H) [num]—Total number of seeds in position three per plot divided by plants number.

1000 seeds weight (RP) [gr.]—was calculated based on Formula XIV.

Experimental Results

13 different cotton varieties were grown and characterized for different parameters (Tables 155-160). The average for each of the measured parameter was calculated using the JMP software (Tables 157-162) and a subsequent correlation analysis between the various transcriptome sets (Tables 152-154) and the average parameters, was conducted (Tables 163-165). Results were then integrated to the database.

TABLE 155
Cotton correlated parameters under normal growth
conditions (vectors) (parameters set 1)
                                 Correlation
Correlated parameter with        ID
% Canopy coverage (10 DPA) [%]   1
1000 seeds weight (RP) [gr.]     2
Bolls num per plant (RP) [number] 3
Closed Bolls num per plant (RP) [number] 4
Closed Bolls num per plant (SP) [number] 5
Fiber Length (RP) [in]           6
Fiber Length Position 3 (SP) [in] 7
Fiber Strength (RP) [in]         8
Fiber Strength Position 3 (SP) [gr./denier] 9
Fiber yield per boll (RP) [gr.]  10
Fiber yield per plant (RP) [gr.] 11
Leaf area (10 DPA) [cm2]         12
Lower Stem width (H) [mm]        13
Micronaire (RP) [scoring 3.7-5]  14
Micronaire Position 3 (SP) [scoring 3.7-5] 15
Num of lateral branches with open bolls (H) [number] 16
Num of nodes with open bolls (MS) (H) [number] 17
Open Bolls num per plant (SP) [number] 18
PAR_LAI (10 DPA) [μmol m−2 S−1]  19
Plant height (H) [cm]            20
Plant height growth [cm/day]     21
Reproductive period duration [number] 22
SPAD (17 DPA) [SPAD unit]        23
SPAD (pre F) [SPAD unit]         24
SPAD rate [SPAD unit/day]        25
Seeds yield per plant (RP) [gr.] 26
Shoot DW (10 DPA) [gr.]          27
Shoot DW (V) [gr.]               28
Shoot FW (10 DPA) [gr.]          29
Shoot FW (V) [gr.]               30
Total Bolls yield (SP) [gr.]     31
Upper Stem width (H) [mm]        32
bolls num in position 1 [number] 33
bolls num in position 3 [number] 34
estimated Avr Bolls FW (MB) po_1 (H) [gr.] 35
estimated Avr Bolls FW (MB) po_3 (H) [gr.] 36
estimated Avr Fiber yield (MB) po_1 (H) [gr.] 37
estimated Avr Fiber yield (MB) po_3 (H) [gr.] 38
estimated Avr Seeds num (MB) po_1 (H) [number] 39
estimated Avr Seeds num (MB) po_3 (H) [number] 40
estimated Avr Seeds yield (MB) po_1 (H) [gr.] 41
estimated Avr Seeds yield (MB) po_3 (H) [gr.] 42
Leaf mass fraction (10 DPA) [cm2/gr.] 43

Table 155. Provided are the Cotton correlated parameters (vectors). “RP”—Rest of plot; “SP”=selected plants; “gr.”=grams; “H”=Harvest; “in”—inch; “SP”—Selected plants; “SPAD”=chlorophyll levels; “FW”=Plant Fresh weight; “DPA”—Days post anthesis; “mm”—millimeter; “cm”—centimeter; “num”—number; “Avr”=average; “DPA”=days post anthesis; “v”=vegetative stage; “H”=harvest stage;

TABLE 156
Cotton correlated parameters under normal and drought
growth conditions (vectors) (parameters set 2)
                                 Correlation
Correlated parameter with        ID
% Canopy coverage (10 DPA) [%]   1
1000 seeds weight (RP) [gr.]     2
Bolls num per plant (RP) [number] 3
Closed Bolls num per plant (RP) [number] 4
Closed Bolls num per plant (SP) [number] 5
Fiber Length (RP) [in]           6
Fiber Length Position 1 (SP) [in] 7
Fiber Length Position 3 (SP) [in] 8
Fiber Strength (RP) [in]         9
Fiber Strength Position 3 (SP) [gr./denier] 10
Fiber yield (RP) [gr.]           11
Fiber yield per boll (RP) [gr.]  12
Fiber yield per plant (RP) [gr.] 13
Leaf area (10 DPA) [cm2]         14
Lower Stem width (H) [mm]        15
Micronaire (RP) [scoring 3.7-5]  16
Micronaire Position 1 (SP) [scoring 3.7-5] 17
Micronaire Position 3 (SP) [scoring 3.7-5] 18
Num of lateral branches with open bolls (H) [number] 19
Num of nodes with open bolls (MS) (H) [number] 20
Open Bolls num per plant (SP) [number] 21
PAR_LAI (10 DPA) [μmol m−2 S−1]  22
Plant height (H) [cm]            23
Plant height growth [cm/day]     24
Reproductive period duration [number] 25
SPAD (17 DPA) [SPAD unit]        26
SPAD (pre F) [SPAD unit]         27
SPAD rate [SPAD unit/day]        28
Seeds yield per plant (RP) [gr.] 29
Shoot DW (10 DPA) [gr.]          30
Shoot DW (V) [gr.]               31
Short Fiber Content (RP) [%]     32
Stomatal conductance (10 DPA) [mmol m−2 s−1] 33
Stomatal conductance (17 DPA) [mmol m−2 s−1] 34
Total Bolls yield (RP) [gr.]     35
Total Bolls yield per plant (RP) [gr.] 36
Uniformity (RP) [%]              37
Upper Stem width (H) [mm]        38
Carbon isotope discrimination (‰) 39
Estimated Avr Bolls FW (MB) po_1 (H) [gr.] 40
Estimated Avr Bolls FW (MB) po_3 (H) [gr.] 41
Estimated Avr Fiber yield (MB) po_1 (H) [gr.] 42
Estimated Avr Fiber yield (MB) po_3 (H) [gr.] 43
Estimated Avr Seeds num (MB) po_1 (H) [number] 44
Estimated Avr Seeds num (MB) po_3 (H) [number] 45
Estimated Avr Seeds yield (MB) po_1 (H) [number] 46
Estimated Avr Seeds yield (MB) po_3 (H) [gr.] 47
Leaf mass fraction (10 DPA) [cm2/gr.] 48
Leaf temp (10 DPA) [° C.]        49
Leaf temp (V) [° C.)             50

Table 156. Provided are the Cotton correlated parameters (vectors). “RP”—Rest of plot; “SP”=selected plants; “gr.”=grams; “H”=Harvest; “in”—inch; “SP”—Selected plants; “SPAD”=chlorophyll levels; “FW”=Plant Fresh weight; “DPA”—Days post anthesis; “mm”—millimeter; “cm”—centimeter: “num”—number; “Avr”=average; “DPA”=days post anthesis; “v”=vegetative stage; “H”=harvest stage;

TABLE 157
Measured parameters in Cotton accessions (1-7) under normal conditions
(parameters set 1)
	Line
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	84.01	94.86	92.93	89.23	84.88	87.15	79.89
2	105.24	113.64	98.49	84.74	111.74	82.47	91.64
3	11.01	19.11	11.83	15.49	22.62	11.78	13.45
4	4.23	NA	NA	NA	NA	NA	4.56
5	5.55	2.08	3.39	2.09	3.07	2.41	5.89
6	1.159	1.279	1.146	1.117	1.411	1.073	0.895
7	1.150	1.295	1.142	1.100	1.435	0.962	0.842
8	28.80	34.47	25.88	29.20	39.66	22.60	22.58
9	29.60	36.55	26.17	29.63	39.53	20.10	21.57
10	2.30	1.37	2.22	1.81	1.12	0.40	1.80
11	25.18	26.00	25.37	27.87	25.35	4.67	24.02
12	7007.67	6622.34	5544.74	8196.02	8573.30	8155.29	5291.27
13	12.79	13.71	11.83	12.38	12.97	10.92	12.97
14	4.31	3.63	3.95	4.37	4.10	6.05	5.01
15	4.57	3.89	3.99	4.71	4.75	5.69	5.25
16	1.02	1.46	0.81	0.96	1.21	1.69	1.29
17	8.15	10.90	9.00	11.04	10.14	7.85	8.48
18	11.98	22.56	11.80	18.75	27.65	16.42	15.00
19	5.67	6.87	6.45	5.86	5.61	6.59	4.09
20	112.80	110.77	100.59	115.45	103.26	98.52	121.91
21	1.864	1.998	1.729	1.724	1.662	1.719	2.086
22	121.33	108.11	108.00	103.80	102.88	108.00	126.00
23	34.29	33.52	31.41	29.66	37.10	27.43	33.39
24	32.13	35.30	35.99	35.80	35.03	32.92	35.89
25	0.040	−0.059	−0.255	−0.219	0.103	−0.291	−0.142
26	32.49	34.86	32.48	35.06	36.32	26.74	33.06
27	169.15	183.58	171.09	172.70	190.03	149.03	193.14
28	39.20	64.68	44.79	38.06	46.23	36.68	48.20
29	842.47	792.64	804.23	766.97	745.20	725.93	922.57
30	168.94	256.04	194.76	155.69	154.56	172.13	193.28
31	505.37	564.21	544.17	585.47	536.54	317.18	488.33
32	3.02	3.64	3.32	3.13	3.23	2.73	2.80
33	5.0	5.0	5.0	5.0	5.0	5.0	5.0
34	5.0	5.0	5.0	5.0	5.0	5.0	5.0
35	6.62	4.88	7.08	5.34	4.08	3.58	5.66
36	6.42	2.93	5.95	4.16	2.72	2.73	5.13
37	2.53	1.88	2.69	2.02	1.50	0.38	2.04
38	2.46	1.13	2.34	1.69	1.06	0.50	1.87
39	31.56	24.16	36.01	31.31	20.94	32.59	30.77
40	31.23	15.50	33.29	26.13	14.87	31.25	32.63
41	3.33	2.70	3.83	2.99	2.43	3.02	3.03
42	3.29	1.58	3.06	2.19	1.64	2.29	2.76
43	41.10	36.48	33.99	47.95	44.56	54.74	28.14

Table 157. Provided are the values of each of the parameters (as described above) measured in cotton accessions (Line). Growth conditions are specified in the experimental procedure section.

TABLE 158
1Measured parameters in additional Cotton accessions (8-13) under normal conditions
(parameters set 1)
	Line
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13
1	85.19	83.55	84.53	95.90	95.92	83.89
2	116.68	99.58	99.55	97.72	102.72	109.95
3	21.94	13.92	11.56	17.33	14.98	12.15
4	NA	NA	3.16	1.11	NA	NA
5	2.34	3.75	3.31	1.84	2.74	3.09
6	1.376	1.181	1.119	1.122	1.185	1.179
7	1.406	1.138	1.072	1.107	1.204	1.196
8	42.63	28.87	25.87	28.98	30.82	29.77
9	42.70	28.38	23.67	30.30	31.97	30.53
10	1.24	2.23	1.99	1.18	1.74	2.39
11	26.64	30.80	23.14	20.49	25.97	29.14
12	8854.54	5650.67	6003.34	6691.84	9004.97	7268.00
13	13.07	14.26	11.84	14.48	12.57	14.00
14	3.88	3.98	4.10	4.55	4.76	4.93
15	4.48	4.19	4.51	4.21	4.25	4.74
16	1.13	0.80	0.58	0.13	0.15	0.71
17	11.29	10.83	8.73	12.33	9.19	10.65
18	30.79	17.90	12.40	19.56	14.67	15.67
19	5.63	5.62	5.33	7.41	7.54	5.51
20	102.22	127.29	105.85	151.27	117.64	119.24
21	1.631	2.068	1.860	1.573	1.868	1.942
22	102.71	104.36	126.00	145.17	109.50	106.17
23	33.79	31.91	32.87	22.08	28.07	31.13
24	33.63	35.26	38.12	32.77	34.44	35.33
25	−0.083	−0.132	−0.243	−0.515	−0.244	−0.237
26	39.54	39.68	30.15	47.61	37.79	35.85
27	196.45	199.76	179.43	134.30	198.46	165.53
28	50.81	51.71	39.70	35.34	42.12	42.05
29	802.23	861.63	930.97	591.63	911.42	791.81
30	230.40	176.68	176.53	163.68	164.66	170.94
31	620.54	715.10	421.32	531.77	405.27	715.72
32	2.99	3.45	2.88	3.40	3.28	3.29
33	5.0	5.0	5.0	NA	5.0	5.0
34	5.0	5.0	5.0	5.0	5.0	5.0
35	3.13	6.37	6.14	NA	4.95	6.95
36	3.31	4.71	5.44	4.14	4.60	6.25
37	1.14	2.47	2.29	NA	1.77	2.92
38	1.19	1.91	2.02	1.12	1.65	2.65
39	15.45	31.45	29.29	NA	25.62	34.56
40	18.21	25.13	28.98	29.15	25.92	32.67
41	1.87	3.21	3.00	NA	2.82	3.87
42	2.06	2.25	2.65	2.73	2.55	3.56
43	45.41	28.05	33.48	47.94	45.95	44.01

Table 158. Provided are the values of each of the parameters (as described above) measured in cotton accessions (Line). Growth conditions are specified in the experimental procedure section

TABLE 159
Measured parameters in Cotton accessions (1-7) under normal conditions
(parameters set 2)
	Line
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	84.01	94.86	92.93	89.23	84.88	87.15	79.89
2	105.24	113.64	98.49	84.74	111.74	82.47	91.64
3	11.01	19.11	11.83	15.49	22.62	11.78	13.45
4	4.23	NA	NA	NA	NA	NA	4.56
5	5.55	2.08	3.39	2.09	3.07	2.41	5.89
6	1.159	1.279	1.146	1.117	1.411	1.073	0.895
7	1.185	1.285	1.156	1.178	1.407	0.979	0.958
8	1.150	1.295	1.142	1.100	1.435	0.962	0.842
9	28.80	34.47	25.88	29.20	39.66	22.60	22.58
10	29.60	36.55	26.17	29.63	39.53	20.10	21.57
11	956.33	854.00	822.67	882.33	756.67	165.00	700.33
12	2.30	1.37	2.22	1.81	1.12	0.40	1.80
13	25.18	26.00	25.37	27.87	25.35	4.67	24.02
14	7007.67	6622.34	5544.74	8196.02	8573.30	8155.29	5291.27
15	12.79	13.71	11.83	12.38	12.97	10.92	12.97
16	4.31	3.63	3.95	4.37	4.10	6.05	5.01
17	4.675	3.665	4.593	5.200	4.063	6.300	5.620
18	4.568	3.885	3.987	4.713	4.753	5.690	5.247
19	1.021	1.458	0.813	0.958	1.208	1.688	1.292
20	8.15	10.90	9.00	11.04	10.14	7.85	8.48
21	11.98	22.56	11.80	18.75	27.65	16.42	15.00
22	5.67	6.87	6.45	5.86	5.61	6.59	4.09
23	112.80	110.77	100.59	115.45	103.26	98.52	121.91
24	1.86	2.00	1.73	1.72	1.66	1.72	2.09
25	121.33	108.11	108.00	103.80	102.88	108.00	126.00
26	34.29	33.52	31.41	29.66	37.10	27.43	33.39
27	32.132	35.297	35.994	35.800	35.033	32.921	35.892
28	0.040	−0.059	−0.255	−0.219	0.103	−0.291	−0.142
29	32.49	34.86	32.48	35.06	36.32	26.74	33.06
30	169.15	183.58	171.09	172.70	190.03	149.03	193.14
31	39.20	64.68	44.79	38.06	46.23	36.68	48.20
32	8.08	6.22	10.17	10.80	4.84	11.80	12.60
33	NA	NA	NA	NA	NA	NA	NA
34	NA	NA	NA	NA	NA	NA	NA
35	2379.00	2148.89	2050.17	2156.33	1934.22	1221.25	1773.33
36	62.64	65.36	63.24	67.97	64.78	32.52	60.83
37	82.40	83.59	80.90	81.00	84.23	78.45	77.32
38	3.022	3.638	3.316	3.125	3.225	2.728	2.799
39	−28.30	−28.43	−28.22	−28.17	−28.81	−28.77	−28.37
40	6.62	4.88	7.08	5.34	4.08	3.58	5.66
41	6.42	2.93	5.95	4.16	2.72	2.73	5.13
42	2.53	1.88	2.69	2.02	1.50	0.38	2.04
43	2.46	1.13	2.34	1.69	1.06	0.50	1.87
44	31.56	24.16	36.01	31.31	20.94	32.59	30.77
45	31.23	15.50	33.29	26.13	14.87	31.25	32.63
46	3.33	2.70	3.83	2.99	2.43	3.02	3.03
47	3.292	1.582	3.064	2.186	1.636	2.293	2.762
48	41.10	36.48	33.99	47.95	44.56	54.74	28.14
49	37.059	37.033	35.733	35.559	35.556	36.081	36.081
50	30.510	30.281	30.454	30.750	30.246	30.698	30.965

Table 159. Provided are the values of each of the parameters (as described above) measured in cotton accessions (Line). Growth conditions are specified in the experimental procedure section

TABLE 160
Measured parameters in Cotton accessions (8-13) under normal conditions
(parameters set 2)
	Line
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13
1	85.19	83.55	84.53	95.90	95.92	83.89
2	116.68	99.58	99.55	97.72	102.72	109.95
3	21.94	13.92	11.56	17.33	14.98	12.15
4	NA	NA	3.16	1.11	NA	NA
5	2.34	3.75	3.31	1.84	2.74	3.09
6	1.376	1.181	1.119	1.122	1.185	1.179
7	1.396	1.199	1.074	1.143	1.199	1.204
8	1.406	1.138	1.072	1.107	1.204	1.196
9	42.63	28.87	25.87	28.98	30.82	29.77
10	42.70	28.38	23.67	30.30	31.97	30.53
11	772.00	918.36	700.33	592.00	834.67	864.33
12	1.24	2.23	1.99	1.18	1.74	2.39
13	26.64	30.80	23.14	20.49	25.97	29.14
14	8854.54	5650.67	6003.34	6691.84	9004.97	7268.00
15	13.07	14.26	11.84	14.48	12.57	14.00
16	3.88	3.98	4.10	4.55	4.76	4.93
17	4.090	4.288	4.363	4.070	4.667	4.637
18	4.480	4.192	4.507	4.205	4.250	4.737
19	1.125	0.795	0.583	0.125	0.146	0.708
20	11.29	10.83	8.73	12.33	9.19	10.65
21	30.29	17.90	12.40	19.56	14.67	15.67
22	5.63	5.62	5.33	7.41	7.54	5.51
23	102.22	127.29	105.85	151.27	117.64	119.24
24	1.63	2.07	1.86	1.57	1.87	1.94
25	102.71	104.36	126.00	145.17	109.50	106.17
26	33.79	31.91	32.87	22.08	28.07	31.13
27	33.633	35.262	38.124	32.772	34.443	35.332
28	−0.083	−0.132	−0.243	−0.515	−0.244	−0.237
29	39.54	39.68	30.15	47.61	37.79	35.85
30	196.45	199.76	179.43	134.30	198.46	165.53
31	50.81	51.71	39.70	35.34	42.12	42.05
32	4.79	9.12	11.57	8.10	7.80	8.55
33	NA	NA	NA	NA	NA	NA
34	NA	NA	NA	NA	NA	NA
35	1920.00	2326.82	1794.83	2030.67	2211.00	2239.00
36	68.76	80.24	59.15	70.35	68.80	75.54
37	84.63	82.03	80.64	82.02	82.55	82.73
38	2.987	3.449	2.876	3.403	3.280	3.290
39	−29.38	−28.21	−28.81	−28.06	−28.20	−28.57
40	3.13	6.37	6.14	NA	4.95	6.95
41	3.31	4.71	5.44	4.14	4.60	6.25
42	1.14	2.47	2.29	NA	1.77	2.92
43	1.19	1.91	2.02	1.12	1.65	2.65
44	15.45	31.45	29.29	NA	25.62	34.56
45	18.21	25.13	28.98	29.15	25.92	32.67
46	1.87	3.21	3.00	NA	2.82	3.87
47	2.058	2.254	2.652	2.731	2.551	3.555
48	45.41	28.05	33.48	47.94	45.95	44.01
49	35.204	36.163	36.752	35.600	35.581	36.648
50	30.704	30.300	29.579	30.379	29.827	30.492

Table 160. Provided are the values of each of the parameters (as described above) measured in cotton accessions (Line). Growth conditions are specified in the experimental procedure section

TABLE 161
Measured parameters in Cotton accessions (1-7)
under drought conditions (parameters set 2)
Line/
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	68.860	68.215	76.261	65.223	79.612	77.924	71.937
2	99.1	105.4	94.2	80.7	109.0	80.4	92.9
3	9.321	14.463	9.813	12.454	19.889	7.970	10.608
4	NA	NA	NA	NA	NA	NA	4.237
5	3.775	3.697	3.630	2.917	2.500	3.200	4.756
6	1.100	1.220	1.088	1.073	1.390	0.931	0.815
7	1.130	1.236	1.150	1.052	1.400	0.907	0.941
8	1.099	1.057	1.046	1.079	1.354	0.952	0.873
9	27.967	35.313	24.933	29.433	40.878	17.880	21.983
10	27.075	30.700	23.000	27.767	39.900	17.000	26.333
11	622.0	554.3	659.3	683.3	494.7	76.0	467.3
12	2.061	1.078	2.002	1.817	0.840	0.268	1.435
13	19.198	17.542	19.403	20.471	16.713	2.155	15.977
14	3928.3	5090.0	6094.3	6011.0	5919.0	4668.2	4397.7
15	11.436	11.727	10.826	10.823	11.029	9.898	11.269
16	4.277	4.168	4.093	4.715	3.701	6.392	5.565
17	4.978	4.583	4.733	5.367	4.833	7.420	5.843
18	4.630	3.850	4.363	5.130	4.567	7.340	5.523
19	1.041	0.875	1.167	1.083	1.384	1.050	1.229
20	6.980	7.234	7.167	7.417	8.233	5.975	7.604
21	9.755	14.097	10.625	12.234	23.219	10.275	11.938
22	3.656	2.914	3.760	3.330	4.383	4.264	2.866
23	92.9	87.2	79.8	85.6	71.3	77.2	99.4
24	0.988	0.956	0.993	0.985	0.975	0.966	0.996
25	100.2	99.8	99.3	96.2	92.9	99.4	127.0
26	47.378	46.822	48.481	49.347	53.486	46.373	48.633
27	36.256	38.826	39.785	40.718	39.256	37.412	39.187
28	0.336	0.170	0.216	0.279	0.447	0.236	0.281
29	24.90	23.97	25.54	27.10	27.52	16.54	24.05
30	140.2	140.8	184.7	147.4	149.5	116.5	161.3
31	37.22	51.21	46.91	45.57	39.96	28.16	41.39
32	9.140	7.713	10.633	10.683	4.733	16.400	17.317
33	481	428	582	512	451	610	NA
34	392	370	406	483	224	381	554
35	1573	1379	1635	1597	1359	745	1246
36	48.69	43.51	48.24	52.19	45.91	19.38	42.61
37	81.62	82.76	80.17	80.85	84.43	76.42	75.72
38	2.889	3.088	3.085	3.170	3.248	2.843	2.605
39	−28.081	−28.655	−28.723	−27.658	−28.280	−27.948	−28.233
40	6.755	3.054	6.509	NA	NA	NA	NA
41	6.148	4.253	5.902	NA	NA	3.505	4.178
42	2.627	1.203	2.526	NA	NA	NA	NA
43	2.343	1.567	2.317	NA	NA	0.473	1.444
44	32.59	15.60	33.48	NA	NA	NA	NA
45	33.44	21.82	34.57	NA	NA	32.06	27.54
46	3.445	1.661	3.553	NA	NA	NA	NA
47	3.295	2.304	3.163	NA	NA	2.562	2.156
48	28.856	37.427	33.065	40.956	39.797	33.397	26.959
49	35.221	38.604	37.007	34.659	38.511	37.944	37.411
50	33.035	33.621	33.046	34.638	33.091	33.354	33.038

Table 161. Provided are the values of each of the parameters (as described above) measured in Cotton accessions (Line). Growth conditions are specified in the experimental procedure section

TABLE 162
Measured parameters in additional Cotton accessions (8-13) under drought conditions (parameters set 2)
Line/Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13
1	71.615	68.801	59.418	81.208	79.860	60.446
2	108.7	95.5	98.7	99.0	97.2	109.6
3	19.562	11.449	9.117	14.026	10.164	11.008
4	NA	NA	3.977	NA	NA	NA
5	1.625	3.625	4.674	2.300	3.206	3.571
6	1.329	1.113	1.062	1.041	1.102	1.130
7	1.332	1.133	1.071	1.060	1.075	1.133
8	1.324	1.109	0.994	1.073	1.077	1.087
9	43.120	28.110	26.067	28.367	29.183	30.000
10	43.450	27.780	22.300	28.900	31.850	30.267
11	592.6	598.8	558.0	428.0	563.7	614.7
12	0.997	1.824	2.023	1.005	1.593	2.017
13	19.616	18.888	18.292	14.144	16.100	20.158
14	6847.0	4819.7	3690.0	7521.9	6199.3	5593.0
15	11.889	12.473	10.583	11.758	11.264	11.999
16	4.065	4.318	4.263	4.705	4.982	4.687
17	4.460	5.096	5.073	4.875	4.880	4.513
18	3.975	4.634	4.277	4.690	5.350	4.210
19	0.893	0.963	0.875	0.208	0.367	0.875
20	9.393	7.679	7.063	10.313	7.551	8.188
21	22.804	12.679	9.896	14.542	11.653	12.771
22	3.613	3.083	2.585	4.147	4.033	2.457
23	74.8	97.7	85.5	104.4	93.0	93.4
24	0.992	0.993	0.985	0.991	0.986	0.984
25	92.9	97.7	127.0	98.8	98.5	98.8
26	48.831	51.219	52.131	43.782	45.764	48.989
27	38.519	39.099	41.867	37.365	37.744	37.929
28	0.311	0.370	0.298	0.082	0.177	0.308
29	30.40	25.90	23.30	31.74	23.86	30.57
30	162.8	159.8	123.2	192.8	156.6	163.7
31	49.82	44.31	36.49	43.24	38.05	37.82
32	4.733	10.070	12.283	8.883	8.633	9.283
33	328	407	510	542	383	556
34	219	427	421	384	434	499
35	1583	1552	1419	1533	1489	1606
36	52.39	49.13	46.00	50.77	42.42	57.10
37	84.00	80.92	79.52	81.42	80.83	82.22
38	3.170	3.373	2.909	3.460	3.502	3.223
39	−28.403	−27.778	−27.808	−26.931	−27.501	−27.862
40	3.585	5.503	NA	4.197	4.880	5.898
41	2.429	5.167	5.143	3.362	4.454	5.028
42	1.309	2.106	NA	1.129	1.753	2.151
43	0.864	1.954	1.821	0.967	1.641	1.859
44	18.74	29.54	NA	31.17	27.26	28.98
45	13.92	29.19	28.13	24.83	27.79	26.01
46	2.150	2.822	NA	3.179	2.744	3.195
47	1.385	2.643	2.506	2.315	2.533	2.651
48	41.854	30.639	30.062	46.046	39.539	34.155
49	36.985	36.507	37.248	36.341	36.200	35.659
50	33.151	32.598	32.869	33.700	33.542	33.580

Table 162. Provided are the values of each of the parameters (as described above) measured in Cotton accessions (Line). Growth conditions are specified in the experimental procedure section

TABLE 163
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions (set 1)
across Cotton accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY45	0.86	1.21E−02	2	16	LBY45	0.87	2.48E−02	6	2
LBY45	0.79	6.18E−02	6	7	LBY45	0.76	8.08E−02	6	18
LBY45	0.82	4.69E−02	6	8	LBY45	0.76	8.24E−02	6	32
LBY45	0.89	1.81E−02	6	3	LBY45	0.81	5.16E−02	6	26
LBY45	0.72	1.06E−01	6	30	LBY45	0.91	1.11E−02	6	31
LBY45	0.71	1.16E−01	6	6	LBY45	0.93	7.33E−03	6	17
LBY45	0.88	1.93E−02	6	9	LBY45	0.81	4.98E−02	6	13
LBY45	0.78	6.85E−02	6	11	LBY45	0.74	5.54E−03	9	43
LBY45	0.80	5.58E−02	7	12	LBY45	0.85	3.28E−02	7	3
LBY46	0.83	8.40E−04	3	7	LBY46	0.81	1.26E−03	3	18
LBY46	0.91	3.57E−05	3	8	LBY46	0.71	9.91E−03	3	12
LBY46	0.77	3.21E−03	3	3	LBY46	0.84	6.39E−04	3	6
LBY46	0.85	5.28E−04	3	9	LBY46	0.87	2.27E−02	8	2
LBY46	0.91	1.09E−02	8	16	LBY46	0.87	2.59E−02	8	7
LBY46	0.80	5.66E−02	8	8	LBY46	0.76	7.90E−02	8	32
LBY46	0.79	5.92E−02	8	31	LBY46	0.80	5.58E−02	8	6
LBY46	0.83	3.99E−02	8	9	LBY46	0.72	6.96E−02	2	32
LBY46	0.74	5.93E−02	2	17	LBY46	0.72	6.71E−02	2	20
LBY46	0.90	1.56E−02	6	2	LBY46	0.89	1.67E−02	6	7
LBY46	0.86	2.86E−02	6	18	LBY46	0.73	1.00E−01	6	43
LBY46	0.90	1.53E−02	6	8	LBY46	0.91	1.10E−02	6	3
LBY46	0.76	8.01E−02	6	14	LBY46	0.84	3.67E−02	6	31
LBY46	0.84	3.52E−02	6	6	LBY46	0.89	1.80E−02	6	17
LBY46	0.94	4.74E−03	6	9	LBY46	0.82	2.37E−02	5	24
LBY46	0.76	1.10E−02	1	10	LBY46	0.71	3.34E−02	1	35
LBY46	0.70	3.45E−02	1	37	LBY46	0.76	1.12E−02	1	11
LBY46	0.84	3.80E−02	7	43	LBY47	0.77	4.47E−02	2	16
LBY47	0.84	3.72E−02	6	23	LBY47	0.88	2.06E−02	6	25
LBY47	0.77	4.23E−02	5	19	LBY47	0.75	5.44E−02	5	20
LBY48	0.91	1.28E−02	8	5	LBY48	0.83	4.20E−02	8	23
LBY48	0.84	3.76E−02	8	24	LBY48	0.84	3.44E−02	8	27
LBY48	0.73	9.70E−02	8	25	LBY48	0.82	4.42E−02	8	29
LBY48	0.81	1.47E−03	9	28	LBY48	0.75	5.01E−03	9	30
LBY48	0.79	3.59E−02	5	26	LBY48	0.98	7.04E−05	5	19
LBY48	0.73	6.21E−02	5	17	LBY48	0.73	6.28E−02	5	20
LBY48	0.95	8.67E−04	5	1	LBY48	0.70	7.77E−02	5	13
LBY48	0.72	1.07E−01	7	5	LBY48	0.72	1.04E−01	7	28
LBY49	0.86	2.93E−02	8	18	LBY49	0.72	1.08E−01	8	8
LBY49	0.89	1.77E−02	8	3	LBY49	0.70	7.58E−03	4	18
LBY49	0.73	9.83E−02	6	43	LBY49	0.79	5.91E−02	6	14
LBY49	0.71	1.15E−01	6	15	LBY49	0.71	7.28E−02	5	26
LBY49	0.72	1.96E−02	1	18	LBY49	0.71	2.15E−02	1	8
LBY49	0.73	1.60E−02	1	14	LBY49	0.71	2.08E−02	1	6
LBY49	0.85	3.15E−02	7	2	LBY49	0.75	8.54E−02	7	38
LBY49	0.76	7.97E−02	7	10	LBY49	0.78	6.44E−02	7	17
LBY49	0.74	9.17E−02	7	20	LBY49	0.82	4.53E−02	7	13
LBY49	0.79	6.26E−02	7	36	LBY50	0.88	2.16E−02	6	5
LBY50	0.81	5.12E−02	6	21	LBY50	0.77	7.60E−02	6	29
LBY50	0.74	9.04E−02	6	36	LBY50	0.71	9.24E−03	9	19
LBY50	0.88	7.04E−04	1	14	LBY50	0.72	1.10E−01	7	14
LBY51	0.95	3.24E−03	8	38	LBY51	0.77	7.28E−02	8	42
LBY51	0.91	1.25E−02	8	10	LBY51	0.72	1.08E−01	8	31
LBY51	0.90	1.32E−02	8	36	LBY51	0.72	6.72E−02	2	26
LBY51	0.83	2.13E−02	2	31	LBY51	0.86	1.28E−02	2	17
LBY51	0.77	4.18E−02	2	11	LBY51	0.74	9.00E−02	6	43
LBY51	0.88	2.16E−02	6	12	LBY51	0.72	1.06E−01	7	18
LBY51	0.72	1.03E−01	7	20	LBY52	0.83	4.23E−02	8	12
LBY52	0.89	6.75E−03	2	24	LBY52	0.75	3.34E−03	4	30
LBY52	0.71	1.10E−01	6	43	LBY52	0.74	5.94E−02	5	43
LBY53	0.88	2.08E−02	8	18	LBY53	0.75	8.50E−02	8	8
LBY53	0.85	3.10E−02	8	3	LBY53	0.71	1.17E−01	8	25
LBY53	0.73	9.91E−02	8	6	LBY53	0.71	1.15E−01	8	9
LBY53	0.78	4.01E−02	2	16	LBY51	0.75	5.02E−02	2	18
LBY53	0.71	7.27E−02	2	30	LBY53	0.76	2.70E−03	4	7
LBY53	0.77	1.87E−03	4	18	LBY53	0.85	2.43E−04	4	8
LBY53	0.73	4.50E−03	4	3	LBY53	0.75	3.39E−03	4	6
LBY53	0.82	5.71E−04	4	9	LBY53	0.82	4.79E−02	6	2
LBY53	0.85	3.33E−02	6	22	LBY53	0.71	1.16E−01	6	8
LBY53	0.83	4.16E−02	6	30	LBY53	0.79	5.89E−02	6	31
LBY53	0.76	7.99E−02	6	9	LBY53	0.83	3.98E−02	6	20
LBY53	0.74	5.83E−02	5	10	LBY53	0.71	1.11E−01	5	35
LBY53	0.71	7.48E−02	5	36	LBY53	0.75	8.53E−02	7	12
LBY53	0.76	7.65E−02	7	19	LBY53	0.74	9.45E−02	7	9
LBY53	0.82	4.64E−02	7	1	LBY54	0.82	4.46E−02	8	18
LBY54	0.73	9.87E−02	8	8	LBY54	0.73	9.64E−02	8	3
LBY54	0.73	1.00E−01	8	6	LBY54	0.78	6.79E−02	6	43
LBY54	0.73	9.87E−02	6	19	LBY54	0.78	3.83E−02	5	22
LBY54	0.82	2.33E−02	5	26	LBY54	0.84	1.79E−02	5	19
LBY54	0.89	7.19E−03	5	20	LBY54	0.75	5.26E−02	5	1
LBY54	0.76	7.76E−02	7	18	LBY93	0.71	9.89E−03	3	22
LBY93	0.75	4.87E−03	3	42	LBY93	0.79	6.41E−02	8	16
LBY93	0.87	2.54E−02	6	16	LBY93	0.78	6.96E−02	6	15
LBY93	0.75	8.48E−02	6	29	LBY93	0.72	6.92E−02	5	14
LBY93	0.75	5.42E−02	5	20	LBY94	0.84	6.36E−04	3	42
LBY94	0.77	3.59E−03	3	36	LBY94	0.78	6.63E−02	8	7
LBY94	0.83	4.05E−02	8	18	LBY94	0.72	1.07E−01	8	12
LBY94	0.80	5.37E−02	8	3	LBY94	0.85	3.09E−02	8	6
LBY94	0.83	2.20E−02	2	16	LBY94	0.88	9.56E−03	2	18
LBY94	0.81	2.59E−02	2	8	LBY94	0.85	1.56E−02	2	3
LBY94	0.85	1.49E−02	2	25	LBY94	0.74	5.66E−02	2	30
LBY94	0.77	4.41E−02	2	15	LBY94	0.82	2.52E−02	2	6
LBY94	0.70	7.75E−02	2	9	LBY94	0.71	6.99E−03	4	14
LBY94	0.80	1.01E−03	4	15	LBY94	0.82	4.53E−02	6	22
LBY94	0.71	1.14E−01	6	26	LBY94	0.90	1.59E−02	6	20
LBY94	0.80	5.83E−02	6	13	LBY94	0.81	2.67E−02	5	21
LBY94	0.87	2.52E−02	5	35	LBY94	0.88	9.34E−03	5	15
LBY94	0.88	2.09E−02	5	39	LBY94	0.86	2.83E−02	5	37
LBY94	0.86	2.65E−02	5	41	LBY94	0.78	7.96E−03	1	2
LBY94	0.73	1.72E−02	1	8	LBY94	0.78	7.30E−03	1	9
LBY94	0.86	1.30E−03	1	11	LBY94	0.88	2.20E−02	7	23
LBY94	0.98	5.23E−04	7	24	LBY94	0.75	8.70E−02	7	29
LBY95	0.74	5.84E−03	3	38	LBY95	0.82	1.09E−03	3	42
LBY95	0.78	2.62E−03	3	36	LBY95	0.71	1.37E−02	3	41
LBY95	0.78	3.95E−02	2	2	LBY95	0.83	2.20E−02	2	7
LBY95	0.90	5.37E−03	2	28	LBY95	0.71	7.25E−02	2	26
LBY95	0.73	6.09E−02	2	6	LBY95	0.70	7.94E−02	2	9
LBY95	0.88	1.97E−02	6	43	LBY95	0.85	3.06E−02	6	12
LBY96	0.71	9.21E−03	3	31	LBY96	0.83	3.89E−02	8	2
LBY96	0.87	2.33E−02	8	7	LBY96	0.73	1.02E−01	8	18
LBY96	0.80	5.78E−02	8	23	LBY96	0.88	2.01E−02	8	8
LBY96	0.78	6.95E−02	8	25	LBY96	0.84	3.69E−02	8	6
LBY96	0.83	4.29E−02	8	9	LBY96	0.73	1.00E−01	8	11
LBY96	0.71	1.15E−01	6	24	LBY96	0.93	6.61E−03	6	32
LBY96	0.74	5.53E−02	5	2	LBY96	0.71	7.14E−02	5	18
LBY96	0.92	3.48E−03	5	31	LBY96	0.73	6.23E−02	5	17
LBY96	0.78	3.91E−02	5	9	LBY96	0.71	7.36E−02	5	11
LBY96	0.74	9.45E−02	7	28	LBY97	0.82	4.81E−02	8	38
LBY97	0.93	7.96E−03	8	42	LBY97	0.74	9.15E−02	8	10
LBY97	0.80	5.55E−02	8	40	LBY97	0.96	1.99E−03	8	36
LBY97	0.93	2.34E−03	2	31	LBY97	0.74	5.59E−02	2	17
LBY97	0.75	5.19E−02	2	13	LBY97	0.78	6.49E−02	6	43
LBY97	0.75	5.29E−03	9	18	LBY97	0.73	6.82E−03	9	8
LBY97	0.77	4.44E−02	5	32	LBY97	0.73	1.71E−02	1	29
LBY97	0.87	2.57E−02	7	3	LBY97	0.83	3.96E−02	7	1
LGN40	0.71	1.02E−02	3	14	LGN40	0.94	5.43E−03	8	2
LGN40	0.71	1.15E−01	8	7	LGN40	0.73	9.94E−02	8	32
LGN40	0.87	2.36E−02	8	31	LGN40	0.74	9.35E−02	8	9
LGN40	0.82	4.34E−02	8	11	LGN40	0.72	5.88E−03	4	28
LGN40	0.88	7.61E−05	4	30	LGN40	0.91	1.12E−02	6	43
LGN40	0.73	9.84E−02	6	12	LGN40	0.76	8.04E−02	6	19
LGN40	0.75	4.85E−03	9	22	LGN40	0.92	9.66E−03	7	22
LGN40	0.77	7.10E−02	7	3	LGN40	0.81	5.10E−02	7	26
LGN40	0.73	1.01E−01	7	17	LGN40	0.83	4.02E−02	7	20

Table 163. Provided are the correlations (K) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 155. “Exp. Set”—Expression set specified in Table 152. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 164
Correlation between the expression level of selected genes of some embodiments of the
invention in additional tissues and the phenotypic performance under normal conditions (set
2) across Cotton accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY45	0.89	1.27E−03	1	25	LBY45	0.77	1.47E−02	1	32
LBY45	0.77	1.52E−02	1	49	LBY45	0.72	2.75E−02	1	28
LBY45	0.70	3.48E−02	1	41	LBY46	0.81	1.32E−03	2	24
LBY46	0.85	3.38E−03	1	8	LBY46	0.85	3.72E−03	1	32
LBY46	0.81	7.86E−03	1	43	LBY46	0.82	7.06E−03	1	9
LBY46	0.74	2.33E−02	1	47	LBY46	0.77	1.47E−02	1	12
LBY46	0.79	1.08E−02	1	21	LBY46	0.82	7.33E−03	1	40
LBY46	0.80	9.43E−03	1	3	LBY46	0.88	1.54E−03	1	7
LBY46	0.87	2.42E−03	1	6	LBY46	0.84	5.02E−03	1	45
LBY46	0.82	6.81E−03	1	44	LBY46	0.81	7.66E−03	1	42
LBY46	0.78	1.28E−02	1	10	LBY46	0.78	1.23E−02	1	41
LBY46	0.75	2.02E−02	1	37	LBY46	0.81	7.80E−03	1	46
LBY46	0.77	1.88E−03	3	8	LBY46	0.75	3.39E−03	3	7
LBY46	0.77	2.15E−03	3	6	LBY47	0.77	3.56E−03	2	21
LBY47	0.83	5.40E−03	1	8	LBY47	0.88	1.94E−03	1	9
LBY47	0.85	3.43E−03	1	21	LBY47	0.89	1.17E−03	1	3
LBY47	0.71	3.10E−02	1	30	LBY47	0.86	2.65E−03	1	7
LBY47	0.86	3.29E−03	1	6	LBY47	0.88	1.81E−03	1	10
LBY47	0.83	5.95E−03	1	37	LBY48	0.73	7.06E−03	2	8
LBY48	0.70	1.11E−02	2	9	LBY48	0.73	7.25E−03	2	7
LBY48	0.79	2.14E−03	2	6	LBY48	0.85	3.67E−03	1	31
LBY49	0.75	4.83E−03	2	8	LBY49	0.79	2.19E−03	2	9
LBY49	0.72	7.65E−03	2	7	LBY49	0.73	6.96E−03	2	6
LBY49	0.76	4.41E−03	2	10	LBY49	0.74	5.81E−03	2	37
LBY50	0.70	1.11E−02	2	39	LBY50	0.88	1.88E−03	1	32
LBY50	0.72	2.97E−02	1	17	LBY50	0.90	1.10E−03	1	43
LBY50	0.80	9.25E−03	1	47	LBY50	0.96	5.88E−05	1	12
LBY50	0.90	8.24E−04	1	40	LBY50	0.91	6.79E−04	1	45
LBY50	0.90	8.87E−04	1	44	LBY50	0.89	1.16E−03	1	42
LBY50	0.88	1.65E−03	1	41	LBY50	0.86	2.61E−03	1	46
LBY50	0.77	2.03E−03	3	48	LBY51	0.81	8.68E−03	1	8
LBY51	0.75	1.91E−02	1	9	LBY51	0.71	3.23E−02	1	21
LBY51	0.76	1.70E−02	1	3	LBY51	0.75	1.98E−02	1	28
LBY51	0.84	4.90E−03	1	7	LBY51	0.83	5.72E−03	1	6
LBY51	0.73	2.54E−02	1	10	LBY52	0.73	2.54E−02	1	14
LBY52	0.75	3.06E−03	2	14	LBY53	0.71	3.05E−02	1	32
LBY53	0.72	2.88E−02	1	43	LBY53	0.75	2.12E−02	1	12
LBY53	0.74	2.22E−02	1	16	LBY53	0.71	3.22E−02	1	42
LBY53	0.73	2.47E−02	1	23	LBY53	0.70	3.49E−02	1	41
LBY54	0.77	3.47E−03	2	21	LBY54	0.78	2.72E−03	2	3
LBY54	0.73	2.65E−02	1	30	LBY54	0.71	6.34E−03	3	8
LBY54	0.73	4.28E−03	3	9	LBY54	0.73	4.46E−03	3	3
LBY54	0.74	4.07E−03	3	6	LBY93	0.79	1.14E−02	1	32
LBY94	0.71	3.28E−02	1	19	LBY94	0.75	2.09E−02	1	32
LBY94	0.82	7.17E−03	1	43	LBY94	0.74	2.24E−02	1	47
LBY94	0.81	8.73E−03	1	12	LBY94	0.75	2.04E−02	1	40
LBY94	0.75	1.91E−02	1	45	LBY94	0.77	1.50E−02	1	42
LBY94	0.80	9.43E−03	1	41	LBY94	0.73	4.81E−03	3	27
LBY95	0.71	3.26E−02	1	25	LBY95	0.90	9.66E−04	1	32
LBY95	0.73	2.68E−02	1	43	LBY95	0.76	1.81E−02	1	12
LBY95	0.75	1.95E−02	1	45	LBY95	0.76	1.78E−02	1	41
LBY96	0.72	7.69E−03	2	8	LBY96	0.74	5.66E−03	2	9
LBY96	0.70	1.11E−02	2	7	LBY96	0.74	5.87E−03	2	6
LGN40	0.79	1.22E−02	1	16

Table 164. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 156. “Exp. Set”—Expression set specified in Table 153. “R”=Pearson correlation coefficient: “P”=p value

TABLE 165
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under drought conditions
(drought expression set 2) across Cotton accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY45	0.75	7.41E−03	4	2	LBY45	0.79	4.02E−03	4	8
LBY45	0.84	1.27E−03	4	9	LBY45	0.88	3.92E−04	4	21
LBY45	0.84	1.22E−03	4	3	LBY45	0.70	1.56E−02	4	7
LBY45	0.71	1.37E−02	4	20	LBY45	0.91	1.11E−04	4	10
LBY45	0.74	2.29E−02	7	2	LBY45	0.83	5.19E−03	7	8
LBY45	0.81	8.01E−03	7	9	LBY45	0.83	5.18E−03	7	21
LBY45	0.78	1.39E−02	7	3	LBY45	0.75	1.98E−02	7	14
LBY45	0.72	3.02E−02	7	6	LBY45	0.86	2.78E−03	7	20
LBY45	0.91	5.75E−04	7	10	LBY45	0.79	6.36E−03	3	26
LBY45	0.92	1.97E−04	3	21	LBY45	0.88	7.46E−04	3	3
LBY45	0.73	1.65E−02	3	10	LBY45	0.84	1.70E−02	2	40
LBY45	0.79	3.35E−02	2	44	LBY45	0.84	1.72E−02	2	42
LBY45	0.83	1.96E−02	2	46	LBY45	0.79	3.63E−02	1	28
LBY45	0.74	5.57E−02	1	7	LBY45	0.71	9.53E−03	5	16
LBY45	0.78	2.95E−03	5	18	LBY46	0.73	1.01E−02	4	8
LBY46	0.80	3.01E−03	4	31	LBY46	0.81	2.50E−03	4	9
LBY46	0.71	1.39E−02	4	3	LBY46	0.81	2.77E−03	4	7
LBY46	0.81	2.60E−03	4	6	LBY46	0.82	4.47E−02	4	44
LBY46	0.71	1.37E−02	4	10	LBY46	0.85	9.87E−04	4	37
LBY46	0.80	5.56E−02	4	46	LBY46	0.87	1.11E−03	6	31
LBY46	0.82	3.81E−03	6	9	LBY46	0.70	2.37E−02	6	3
LBY46	0.74	L54E−02	6	7	LBY46	0.74	1.36E−02	6	6
LBY46	0.77	9.40E−03	6	10	LBY46	0.72	1.77E−02	6	15
LBY46	0.83	2.89E−03	6	37	LBY46	0.78	1.25E−02	7	48
LBY46	0.72	1.93E−02	3	9	LBY46	0.71	2.05E−02	3	29
LBY46	0.76	1.14E−02	3	7	LBY46	0.75	1.18E−02	3	6
LBY46	0.72	1.91E−02	3	20	LBY46	0.76	1.08E−02	3	37
LBY46	0.71	7.32E−02	1	48	LBY46	0.86	1.21E−02	1	38
LBY46	0.72	6.69E−02	1	50	LBY46	0.71	7.59E−02	1	22
LBY46	0.71	9.38E−03	2	17	LBY47	0.73	1.63E−02	6	8
LBY47	0.70	2.38E−02	6	9	LBY47	0.75	1.23E−02	6	21
LBY47	0.72	1.79E−02	6	3	LBY47	0.74	1.38E−02	6	7
LBY47	0.79	6.64E−03	6	6	LBY47	0.79	1.12E−03	2	7
LBY47	0.76	4.61E−02	1	48	LBY47	0.77	4.35E−02	1	50
LBY48	0.77	5.85E−03	4	48	LBY48	0.78	4.87E−03	4	14
LBY48	0.71	1.39E−02	4	29	LBY48	0.91	9.55E−05	4	20
LBY48	0.73	6.22E−02	7	41	LBY48	0.85	1.44E−02	1	24
LBY48	0.79	2.21E−03	5	9	LBY48	0.76	4.38E−03	5	21
LBY48	0.78	2.68E−03	5	3	LBY48	0.76	4.51E−03	5	10
LBY49	0.86	1.30E−03	6	8	LBY49	0.72	1.82E−02	6	9
LBY49	0.85	1.85E−03	6	21	LBY49	0.81	4.26E−03	6	3
LBY49	0.76	1.15E−02	6	7	LBY49	0.78	8.44E−03	6	6
LBY49	0.71	2.24E−02	6	20	LBY49	0.78	8.46E−03	6	10
LBY49	0.75	1.30E−02	6	37	LBY49	0.90	2.19E−03	7	33
LBY49	0.71	2.06E−02	3	9	LBY49	0.95	3.50E−05	3	21
LBY49	0.91	2.61E−04	3	3	LBY49	0.71	2.21E−02	3	10
LBY49	0.73	7.28E−03	2	31	LBY49	0.81	2.57E−02	1	48
LBY49	0.70	7.79E−02	1	14	LBY49	0.71	7.28E−02	1	10
LBY49	0.80	1.87E−03	2	8	LBY49	0.78	2.64E−03	5	9
LBY49	0.84	7.23E−04	5	21	LBY49	0.82	1.12E−03	5	3
LBY49	0.79	2.29E−03	5	7	LBY49	0.72	7.79E−03	5	6
LBY49	0.78	2.77E−03	5	20	LBY49	0.76	4.26E−03	5	10
LBY50	0.74	9.19E−02	4	44	LBY50	0.71	1.13E−01	4	46
LBY50	0.76	9.95E−03	6	39	LBY50	0.72	7.06E−02	7	47
LBY50	0.81	8.68E−03	7	50	LBY50	0.81	2.76E−02	7	45
LBY50	0.76	7.94E−02	1	43	LBY50	0.72	1.08E−01	1	47
LBY50	0.77	7.58E−02	1	33	LBY50	0.73	6.10E−02	1	11
LBY50	0.70	1.21E−01	1	45	LBY50	0.74	9.11E−02	1	41
LBY50	0.92	2.06E−05	2	17	LBY50	0.91	4.01E−05	5	16
LBY50	0.98	4.18E−08	5	18	LBY51	0.71	1.41E−02	4	8
LBY51	0.78	4.21E−03	4	31	LBY51	0.75	8.13E−03	4	48
LBY51	0.83	1.66E−03	4	9	LBY51	0.71	1.36E−02	4	3
LBY51	0.74	9.89E−03	4	29	LBY51	0.71	1.47E−02	4	7
LBY51	0.75	7.88E−03	4	6	LBY51	0.76	6.98E−03	4	10
LBY51	0.83	1.45E−03	4	37	LBY51	0.79	6.43E−03	6	9
LBY51	0.71	2.06E−02	6	3	LBY51	0.79	6.32E−03	6	10
LBY51	0.80	5.71E−03	6	37	LBY51	0.71	3.21E−02	7	22
LBY51	0.70	2.38E−02	3	30	LBY51	0.82	9.81E−04	2	48
LBY51	0.73	7.37E−03	2	9	LBY51	0.72	7.97E−03	2	3
LBY51	0.75	5.23E−02	1	9	LBY51	0.74	5.90E−02	1	21
LBY51	0.78	3.95E−02	1	3	LBY51	0.74	5.78E−02	1	20
LBY51	0.81	2.85E−02	1	10	LBY51	0.79	2.42E−03	5	7
LBY51	0.70	1.12E−02	5	6	LBY51	0.75	5.22E−03	5	37
LBY52	0.89	5.97E−04	3	50	LBY52	0.80	3.20E−02	1	25
LBY52	0.74	5.93E−02	1	5	LBY52	0.77	4.38E−02	1	49
LBY52	0.79	2.03E−03	5	8	LBY52	0.74	6.05E−03	5	9
LBY52	0.81	1.49E−03	2	21	LBY52	0.74	6.06E−03	5	3
LBY52	0.76	4.17E−03	2	20	LBY52	0.80	1.90E−03	5	10
LBY53	0.71	3.38E−02	7	2	LBY53	0.73	2.55E−02	7	9
LBY53	0.84	4.45E−03	7	21	LBY53	0.81	8.37E−03	7	3
LBY53	0.74	2.36E−02	7	10	LBY53	0.72	1.79E−02	3	8
LBY53	0.72	1.89E−02	3	9	LBY53	0.86	1.28E−03	3	21
LBY53	0.81	4.56E−03	3	3	LBY53	0.78	7.21E−03	3	10
LBY53	0.78	3.85E−02	1	8	LBY53	0.89	7.21E−03	1	9
LBY53	0.97	3.95E−04	1	21	LBY53	0.94	1.41E−03	1	3
LBY53	0.84	1.70E−02	1	29	LBY53	0.80	3.19E−02	1	7
LBY53	0.95	1.28E−03	1	20	LBY53	0.87	1.16E−02	1	10
LBY53	0.72	6.69E−02	1	15	LBY53	0.74	5.76E−03	5	8
LBY53	0.85	4.57E−04	5	9	LBY53	0.87	2.19E−04	5	21
LBY53	0.89	1.13E−04	5	3	LBY53	0.81	1.57E−03	5	7
LBY53	0.76	3.97E−03	5	6	LBY53	0.71	9.24E−03	5	20
LBY53	0.79	2.43E−03	5	10	LBY54	0.79	3.51E−03	4	2
LBY54	0.77	5.63E−03	4	9	LBY54	0.71	1.44E−02	4	21
LBY54	0.80	3.15E−03	4	3	LBY54	0.72	1.20E−02	4	7
LBY54	0.73	1.15E−02	4	10	LBY54	0.73	1.11E−02	4	15
LBY54	0.71	1.46E−02	4	37	LBY54	0.70	2.32E−02	6	48
LBY54	0.78	7.95E−03	6	20	LBY54	0.76	1.84E−02	7	2
LBY54	0.75	2.10E−02	7	8	LBY54	0.72	2.89E−02	7	9
LBY54	0.86	3.07E−03	7	21	LBY54	0.81	8.47E−03	7	3
LBY54	0.76	1.74E−02	7	7	LBY54	0.78	1.41E−02	7	10
LBY54	0.88	7.21E−04	3	17	LBY54	0.84	2.17E−03	3	18
LBY54	0.70	7.81E−02	1	2	LBY54	0.84	1.81E−02	1	8
LBY54	0.92	3.29E−03	1	9	LBY54	0.95	8.32E−04	1	21
LBY54	0.93	2.31E−03	1	3	LBY54	0.85	1.51E−02	1	29
LBY54	0.86	1.32E−02	1	7	LBY54	0.76	4.92E−02	1	6
LBY54	0.93	2.56E−03	1	20	LBY54	0.88	9.72E−03	1	10
LBY54	0.73	6.24E−02	1	15	LBY54	0.78	2.89E−03	5	8
LBY54	0.73	7.10E−03	5	9	LBY54	0.84	6.57E−04	5	21
LBY54	0.79	2.15E−03	5	3	LEW54	0.76	3.75E−03	5	7
LBY54	0.78	2.71E−03	5	6	LBY93	0.75	7.99E−03	4	17
LBY93	0.83	2.96E−03	4	33	LBY93	0.75	1.31E−02	3	21
LBY93	0.73	1.58E−02	3	3	LBY93	0.77	4.29E−02	1	2
LBY93	0.73	6.50E−02	1	8	LBY93	0.74	5.55E−02	1	9
LBY93	0.70	7.93E−02	1	21	LBY93	0.87	1.09E−02	1	7
LBY93	0.77	4.47E−02	1	6	LBY93	0.79	2.34E−03	5	16
LBY94	0.86	6.78E−04	4	17	LBY94	0.78	4.35E−03	4	16
LBY94	0.81	2.43E−03	4	18	LBY94	0.71	2.03E−02	6	19
LBY94	0.77	4.33E−02	7	47	LBY94	0.71	7.67E−02	7	41
LBY94	0.78	2.74E−03	2	17	LBY94	0.72	8.48E−03	2	18
LBY94	0.75	5.06E−02	1	8	LBY94	0.88	8.90E−03	1	35
LBY94	0.78	3.82E−02	1	38	LBY94	0.71	7.12E−02	1	7
LBY94	0.78	3.76E−02	1	6	LBY94	0.90	5.62E−03	1	22
LBY94	0.72	6.61E−02	1	39	LBY94	0.83	2.06E−02	1	37
LBY94	0.85	4.30E−04	2	16	LBY94	0.71	9.77E−03	5	18
LBY94	0.75	4.72E−03	5	20	LBY94	0.75	5.39E−03	5	10
LBY95	0.72	1.31E−02	4	8	LBY95	0.72	1.31E−02	4	9
LBY95	0.76	1.07E−02	6	17	LBY95	0.74	1.39E−02	6	16
LBY95	0.71	2.02E−02	6	18	LBY95	0.73	2.46E−02	7	18
LBY95	0.76	1.68E−02	7	39	LBY95	0.72	1.98E−02	3	8
LBY95	0.87	1.11E−03	3	21	LBY95	0.81	4.21E−03	3	3
LBY95	0.70	2.28E−02	3	7	LBY95	0.70	2.42E−02	2	47
LBY95	0.81	2.79E−02	2	40	LBY95	0.77	5.96E−03	2	33
LBY95	0.72	6.82E−02	2	44	LBY95	0.84	1.90E−02	2	42
LBY95	0.80	2.93E−02	2	46	LBY95	0.77	4.24E−02	1	38
LBY95	0.71	7.62E−02	1	50	LBY95	0.78	3.67E−02	1	39
LBY95	0.71	7.62E−02	1	13	LBY95	0.71	9.62E−03	5	32
LBY95	0.95	3.58E−06	5	17	LBY95	0.90	5.38E−05	5	16
LBY95	0.93	1.15E−05	5	18	LBY96	0.79	4.03E−03	4	39
LBY96	0.72	1.30E−02	4	20	LBY96	0.92	2.88E−03	7	43
LBY96	0.73	2.51E−02	7	30	LBY96	0.82	2.38E−02	7	41
LBY96	0.70	7.75E−02	1	32	LBY96	0.71	7.65E−02	1	17
LBY96	0.76	4.74E−02	1	34	LBY96	0.94	1.79E−03	1	16
LBY96	0.89	7.29E−03	1	18	LBY96	0.83	2.20E−02	1	23
LBY96	0.75	4.91E−03	5	2	LBY96	0.73	6.76E−03	5	8
LBY96	0.79	2.01E−03	5	9	LBY96	0.80	1.87E−03	5	21
LBY96	0.77	3.72E−03	5	3	LBY96	0.74	5.44E−03	5	29
LBY96	0.87	2.46E−04	5	20	LBY96	0.80	1.83E−03	5	10
LBY97	0.71	1.38E−02	4	48	LBY97	0.80	2.83E−03	4	38
LBY97	0.74	1.37E−02	6	32	LBY97	0.96	3.32E−05	7	8
LBY97	0.70	3.44E−02	7	48	LBY97	0.83	5.88E−03	7	9
LBY97	0.90	9.18E−04	7	21	LBY97	0.88	1.96E−03	7	3
LBY97	0.84	4.50E−03	7	7	LBY97	0.88	1.52E−03	7	6
LBY97	0.76	1.65E−02	7	10	LBY97	0.81	7.48E−03	7	37
LBY97	0.75	1.33E−02	5	45	LGN40	0.72	1.22E−02	4	2
LGN40	0.78	4.76E−03	4	9	LGN40	0.88	3.70E−04	4	21
LGN40	0.90	1.32E−04	4	3	LGN40	0.84	1.29E−03	4	10
LGN40	0.71	2.11E−02	6	24	LGN40	0.82	1.31E−02	6	43
LGN40	0.82	3.31E−03	6	12	LGN40	0.91	1.21E−02	6	40
LGN40	0.73	1.03E−01	6	44	LGN40	0.91	1.13E−02	6	42
LGN40	0.73	3.95E−02	6	41	LGN40	0.76	7.90E−02	6	46
LGN40	0.73	1.56E−02	3	9	LGN40	0.90	3.62E−04	3	21
LGN40	0.91	2.35E−04	1	3	LGN40	0.77	9.87E−03	3	10

Table 165. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 156. “Exp. Set”—Expression set specified in Table 154. “R”=Pearson correlation coefficient; “P”=p value.

Example 19

Production of Bean Transcriptome and High Throughput Correlation Analysis with Yield Parameters Using 60K Bean (Phaseolus vulgaris L) OLIGONUCLEOTIDE MICRO-ARRAYS

In order to produce a high throughput correlation analysis, the present inventors utilized a Bean oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60.000 Bean genes and transcripts. In order to define correlations between the levels of RNA expression with yield components or plant architecture related parameters or plant vigor related parameters, various plant characteristics of 40 different commercialized bean varieties were analyzed and further used for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Analyzed Bean Tissues

Six tissues [leaf, Stem, lateral stem, lateral branch flower bud, lateral branch pod with seeds and meristem] growing under normal conditions [field experiment, normal growth conditions which included irrigation with water 2-3 times a week with 524 m³ water per dunam (1000 square meters) per entire growth period, and fertilization of 16 units nitrogen per dunam given in the first month of the growth period] were sampled and RNA was extracted as described above.

For convenience, each micro-array expression information tissue type has received a Set ID as summarized in Table 166 below.

TABLE 166
Bean transcriptome expression sets
                                 Set
Expression Set                   ID
Lateral branch flower bud at flowering stage under normal growth 1
conditions
Lateral branch pod with seeds at pod setting stage under normal 2
growth conditions
Lateral stem at pod setting stage under normal growth conditions 3
Lateral stem at flowering stage under normal growth conditions 4
Leaf at pod setting stage under normal growth conditions 5
Leaf at flowering stage under normal growth conditions 6
Leaf at vegetative stage under normal growth conditions 7
Meristem at vegetative stage under normal growth conditions 8
stem at vegetative stage under normal growth conditions 9

Table 166: Provided are the bean transcriptome expression sets. Lateral branch flower bud=flower bud from vegetative branch; Lateral branch pod with seeds=pod with seeds from vegetative branch; Lateral stem=stem from vegetative branch.

Bean Yield Components and Vigor Related Parameters Assessment

40 Bean varieties were grown in five repetitive plots, in field. Briefly, the growing protocol was as follows: Bean seeds were sown in soil and grown under normal conditions until harvest. Plants were continuously phenotyped during the growth period and at harvest (Table 167). The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

The collected data parameters were as follows:

% Canopy coverage—percent Canopy coverage at grain filling stage, R1 flowering stage and at vegetative stage. The % Canopy coverage is calculated using Formula XXXII above.

1000 seed weight [gr.]—At the end of the experiment all seeds from all plots were collected and weighted and the weight of 1000 were calculated.

Days till 50% flowering [days]—number of days till 50% flowering for each plot.

Avr shoot DW—At the end of the experiment, the shoot material was collected, measured and divided by the number of plants.

Big pods FWper plant (PS) [gr.]˜1 meter big pods fresh weight at pod setting divided by the number of plants.

Big pods number per plant (PS)—number of pods at development stage of R3-4 period above 4 cm per plant at pod setting.

Small pods FW per plant (PS) [gr.]—1 meter small pods fresh weight at pod setting divided by the number of plants.

Small pods num per plant (PS)—number of pods at development stage of R3-4 period below 4 cm per plant at pod setting.

Pod Area [cm²]—At development stage of R3-4 period pods of three plants were weighted, photographed and images were processed using the below described image processing system. The pod area above 4 cm and below 4 cm was measured from those images and was divided by the number of pods.

Pod Length and Pod width [cm]—At development stage of R3-4 period pods of three plants were weighted, photographed and images were processed using the below described image processing system. The sum of pod lengths/or width (longest axis) was measured from those images and was divided by the number of pods.

Num of lateral branches per plant [value/plant]—number of lateral branches per plant at vegetative stage (average of two plants per plot) and at harvest (average of three plants per plot).

Relative growth rate [cm/day]—the relative growth rate (RGR) of Plant Height was calculated using Formula III above.

Leaf area per plant (PS) [cm²]=Total leaf area of 3 plants in a plot at pod setting. Measurement was performed using a Leaf area-meter.

Specific leaf area (PS) [cm²/gr.]—leaf area per leaf dry weight at pod set.

Leaf form—Leaf length (cm)/leaf width (cm); average of two plants per plot.

Leaf number per plant (PS)—Plants were characterized for leaf number during pod setting stage. Plants were measured for their leaf number by counting all the leaves of 3 selected plants per plot.

Plant height [cm]—Plants were characterized for height during growing period at 3 time points. In each measure, plants were measured for their height using a measuring tape. Height of main stem was measured from first node above ground to last node before apex.

Seed yield per area (H) [gr.]˜1 meter seeds weight at harvest.

Seed yield per plant (H) [gr.]—Average seeds weight per plant at harvest in 1 meter plot.

Seeds num per area (H)—1 meter plot seeds number at harvest.

Total seeds per plant (H)—Seeds number on lateral branch per plant+Seeds number on main branch per plant at harvest, average of three plants per plot.

Total seeds weight per plant (PS) [gr.]—Seeds weight on lateral branch+Seeds weight on main branch at pod set per plant, average of three plants per plot.

Small pods FW per plant (PS)—Average small pods (below 4 cm) fresh weight per plant at pod setting per meter.

Small pods num per plant (PS)—Number of Pods below 4 cm per plant at pod setting, average of two plants per plot.

SPAD—Plants were characterized for SPAD rate during growing period at grain filling stage and vegetative stage. Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed 64 days post sowing.

SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Stem width (R2F)[mm]—width of the stem of the first node at R2 flowering stage, average of two plants per plot.

Total pods number per plant (H), (PS)—Pods number on lateral branch per plant+Pods number on main branch per plant at pod setting and at harvest, average of three plants per plot.

Total pods DWper plant (H) [gr.]—Pods dry weight on main branch per plant+Pods dry weight on lateral branch per plant at harvest, average of three plants per plot.

Total pods FW per plant (PS) [gr.]—Average pods fresh weight on lateral branch+Pods weight on main branch at pod setting.

Pods weight per plant (RP) (H) [gr.]—Average pods weight per plant at harvest in 1 meter.

Total seeds per plant (H), (PS)—Seeds number on lateral branch per plant+Seeds number on main branch per plant at pod setting and at harvest, average of three plants per plot.

Total seeds num per pod (H), (PS)—Total seeds num per plant divided in total pods num per plant, average of three plants per plot.

Vegetative FW and DW per plant (PS) [gr/plant]—total weight of the vegetative portion above ground (excluding roots and pods) before and after drying at 70° C. in oven for 48 hours at pod set, average of three plants per plot.

Vigor till flowering [gr./day]—Relative growth rate (RGR) of shoot DW=Regression coefficient of shoot DW along time course (two measurements at vegetative stage and one measurement at flowering stage).

Vigor post flowering [gr./day]—Relative growth rate (RGR) of shoot DW=Regression coefficient of shoot DW measurements along time course (one measurement at flowering stage and two measurements at grain filling stage).

Experimental Results

40 different bean varieties lines 1-40 were grown and characterized for 48 parameters as specified above. Among the 40 varieties, 16 varieties are “fine” and “extra fine”. The average for each of the measured parameters was calculated using the JMP software and values are summarized in Tables 168-169 below. Subsequent correlation analysis between the various transcriptome sets and the average parameters was conducted (Table 170).

TABLE 167
Bean correlated parameters (vectors)
                                 Correlation
Correlated parameter with        ID
% Canopy coverage (GF) [percentage] 1
% Canopy coverage (R1F) [percentage] 2
% Canopy coverage (V) [percentage] 3
% Seed weight (EGF) [gr.]        4
% Seed weight (LGF) [gr.]        5
1000 seed weight [gr.]           6
Avr shoot DW (EGF) [gr.]         7
Avr shoot DW (R2F) [gr.]         8
Avr shoot DW (V) [gr.]           9
Big pods FW per plant (PS) (RP) [gr.] 10
Big pods num per plant (PS) [gr.] 11
CV(Pod_Area_Below_4 cm) [percentage] 12
CV(Pod_Average_Width) [percentage] 13
CV(Pod_Length) [percentage]      14
CV(Pod_Length_Below_4 cm) [percentage] 15
Days to 50% flowering [number]   16
Height Rate [cm/day]             17
Leaf Length [cm]                 18
Leaf Width [cm]                  19
Leaf area per plant (PS) [cm2]   20
Leaf form [cm/cm]                21
Leaf num per plant (PS) [number] 22
Mean (Pod_Area) [cm2]            23
Mean(Pod_Area_Below_4 cm) [cm2]  24
Mean(Pod_Average_Width) [cm]     25
Mean(Pod_Length) [cm]            26
Mean(Pod_Length_Below_4 cm) [cm] 27
Num of lateral branches per plant (H) [number] 28
Num of lateral branches per plant (V) [number] 29
PAR_LAI (EGF) [μmol m−2 S−1]     30
PAR_LAI (LGF) [μmol m−2 S−1]     31
PAR_LAI (R1F) [μmol m−2 S−1]     32
Plant height (GF) [cm]           33
Plant height (V2-V3) [cm]        34
Plant height (V4-V5) [cm]        35
Pods weight per plant (RP) (H) [gr.] 36
SPAD (GF) [SPAD unit]            37
SPAD (V) [SPAD unit]             38
Seed FW/podsW.O seeds FW (EGF) [gr.] 39
Seed FW/podsW.O seeds FW (LGF) [gr.] 40
Seed yield per area (H) (RP) [gr.] 41
Seed yield per plant (RP) (H) [gr.] 42
Seeds num per area (H) (RP) [number] 43
Small pods FW per plant (PS) (RP) [gr.] 44
Small pods num per plant (PS) [number] 45
Specific leaf area (PS) [cm2/gr.] 46
Stem width (R2F) [mm]            47
Total pods DW per plant (H) [gr.] 48
Total pods num per plant (H) [number] 49
Total pods num per plant (PS) [number] 50
Total pods weight per plant (PS) [gr.] 51
Total seeds num per pod (H) [number] 52
Total seeds num per pod (PS) [number] 53
Total seeds per plant (H) [number] 54
Total seeds per plant (PS) [number] 55
Total seeds weight per plant (PS) [gr.] 56
Vegetative DW per plant (PS) [gr.] 57
Vegetative FW per plant (PS) [gr.] 58
Vigor post flowering [gr./day]   59
Vigor till flowering [gr./day]   60

Table 167. Provided are the Ban correlated parameters (vectors). “gr.”=grams; “SPAD”=chlorophyll levels; “PAR”=Photosynthetically active radiation; “FW”=Plant Fresh weight: “normal”=standard growth conditions; “H”=harvest; “PS”=pod setting; “v”=vegetative stage.

TABLE 168
Measured parameters in bean varieties (lines 1-8)
Line/Corr.
ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7	Line-8
1	88.66	91.02	80.76	90.29	84.27	NA	73.90	66.50
2	89.59	78.87	72.28	90.49	73.78	76.45	91.63	72.86
3	70.53	58.56	38.98	83.64	46.91	51.88	59.82	65.28
4	NA	10.668	9.234	8.624	11.535	12.365	NA	12.053
5	45.34	30.72	31.77	37.30	12.62	40.98	37.70	33.54
6	94.43	117.59	69.63	123.75	66.31	93.68	72.75	107.37
7	16.192	18.656	19.292	27.824	14.442	18.024	15.575	31.030
8	7.334	8.283	6.370	11.850	5.418	7.399	8.019	9.338
9	0.302	0.329	0.240	0.443	0.206	0.349	0.243	0.384
10	NA	67.40	38.22	76.45	49.40	43.69	NA	49.94
11	24.25	35.25	65.00	26.50	38.75	35.50	49.75	22.25
12	0.280	0.263	0.211	0.225	0.217	0.231	0.196	0.203
13	20.30	41.79	32.10	19.35	21.75	37.40	41.54	22.06
14	19.39	40.69	36.57	19.08	17.38	41.36	42.84	22.62
15	NA	48.720	38.908	67.375	41.280	55.886	28.705	NA
16	55.0	55.0	55.0	48.0	55.0	55.0	48.0	55.0
17	0.974	0.849	0.907	0.853	0.720	1.062	0.814	1.073
18	13.339	11.638	11.140	13.149	11.989	12.346	12.643	11.987
19	8.161	8.834	7.027	8.422	7.854	8.133	7.781	7.614
20	211.67	307.13	133.13	308.07	157.53	155.00	192.00	273.47
21	1.641	1.315	1.585	1.563	1.528	1.517	1.626	1.577
22	4.733	6.067	4.733	6.167	5.000	5.417	5.867	6.133
23	6.534	4.294	3.692	8.039	5.733	5.696	4.151	6.869
24	1.00	6.00	9.50	3.00	2.00	5.00	8.75	1.00
25	0.714	0.593	0.480	0.825	0.619	0.679	0.471	0.698
26	10.998	7.653	8.335	11.291	10.975	9.066	9.077	11.417
27	0.484	0.432	0.386	0.321	0.532	0.419	0.400	0.404
28	7.933	6.200	7.933	7.000	9.667	7.533	9.200	8.867
29	4.90	4.90	5.80	6.60	5.10	5.70	5.50	6.00
30	8.435	7.845	5.780	7.609	6.286	6.598	6.737	6.771
31	6.146	5.842	4.377	4.013	4.950	NA	3.725	2.884
32	3.270	3.061	1.328	5.006	1.581	1.744	2.251	3.338
33	36.842	34.833	31.517	37.708	28.875	39.827	30.442	41.267
34	4.388	4.800	3.675	5.750	3.925	4.500	4.675	6.163
35	11.433	11.167	7.600	16.567	8.400	9.667	11.233	15.333
36	11.666	15.197	15.962	23.075	17.061	15.121	19.482	18.878
37	40.192	36.219	37.681	NA	39.396	NA	NA	43.006
38	36.000	39.436	31.413	40.147	35.756	35.011	35.751	35.133
39	NA	11.942	10.298	9.438	13.039	14.110	NA	13.705
40	92.310	44.351	25.951	60.205	14.875	51.058	61.491	51.320
41	342.4	457.2	196.7	430.6	198.1	371.1	431.5	533.6
42	6.306	8.291	4.532	9.202	4.018	6.553	7.917	9.622
43	3635.2	3879.6	2875.2	3485.8	3012.2	3953.8	5946.6	4920.2
44	0.622	2.064	1.146	0.602	0.796	1.268	0.001	0.726
45	0.500	6.000	9.500	1.500	1.000	5.000	8.750	0.500
46	226.3	222.3	213.0	207.3	257.8	238.2	248.2	237.7
47	5.785	5.843	5.395	5.831	4.909	6.001	5.292	5.536
48	12.764	20.706	13.886	30.423	15.310	10.754	21.881	23.486
49	27.133	24.733	46.067	38.267	38.267	18.857	44.067	33.933
50	33.067	33.929	31.583	20.938	46.000	24.333	30.267	27.333
51	32.96	105.04	61.14	33.15	41.19	81.76	2.98	42.96
52	3.315	4.685	2.814	3.927	3.093	3.767	3.872	3.776
53	2.635	2.351	1.022	0.632	1.612	0.811	1.577	3.148
54	90.47	111.33	128.60	151.80	138.20	70.53	168.40	128.80
55	87.600	79.000	29.385	9.167	77.929	20.000	50.133	84.600
56	NA	3.448	0.500	0.173	2.877	0.390	NA	2.298
57	16.296	13.525	18.800	12.637	17.034	9.985	12.287	13.708
58	91.613	65.647	61.833	71.071	77.527	56.827	47.664	70.773
59	0.915	2.029	1.675	0.839	1.355	NA	1.524	1.388
60	0.444	0.456	0.352	1.183	0.380	0.390	0.453	0.579

Table 168. Provided are the values of each of the parameters (as described above) measured in Bean accessions (Line). Growth conditions are specified in the experimental procedure section

TABLE 169
Measured parameters in bean varieties (lines 9-16)
Line/Corr.
ID	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14	Line-15	Line-16
1	84.42	NA	83.89	NA	83.40	NA	79.59	75.12
2	83.06	86.63	82.53	83.35	84.21	73.07	71.41	68.05
3	64.09	89.99	62.34	63.42	61.26	38.21	40.2.6	26.24
4	11.762	8.418	NA	NA	9.446	12.067	7.503	NA
5	40.72	35.03	41.72	43.38	17.34	18.21	26.42	28.91
6	121.34	120.75	96.79	116.14	94.55	82.93	111.76	70.74
7	18.653	21.945	21.756	17.003	18.753	14.780	18.542	15.100
8	6.966	11.209	6.313	11.988	10.575	7.351	7.438	5.213
9	0.361	0.537	0.212	0.476	0.361	0.203	0.298	0.209
10	49.06	76.18	NA	NA	61.66	23.67	89.21	NA
11	23.25	28.25	32.00	32.75	34.17	46.50	23.50	68.75
12	0.319	0.233	0.216	0.257	0.256	0.219	NA	0.199
13	30.56	28.44	47.69	27.56	26.13	43.74	29.96	21.54
14	32.83	31.13	46.08	28.64	20.56	46.23	23.70	22.64
15	51.241	51.209	37.343	58.238	82.139	44.704	NA	71.494
16	55.0	48.0	55.0	48.0	55.0	48.0	55.0	55.0
17	1.182	1.303	0.941	0.980	0.876	0.790	0.960	0.705
18	12.787	12.174	10.387	11.156	13.102	11.793	11.632	12.882
19	7.517	7.730	6.259	7.045	8.234	7.099	7.329	8.680
20	180.73	324.07	175.80	242.20	200.60	174.00	146.89	61.67
21	1.700	1.577	1.675	1.593	1.593	1.662	1.590	1.484
22	4.133	7.167	7.000	6.188	5.133	4.533	5.111	3.643
23	7.369	7.532	5.677	7.889	6.264	4.296	8.222	5.230
24	2.33	2.00	6.25	3.00	1.67	9.50	NA	6.50
25	0.718	0.739	0.663	0.725	0.686	0.498	0.811	0.590
26	11.399	11.706	8.774	12.243	10.549	8.658	11.732	10.494
27	0.561	0.499	0.397	0.527	0.690	0.441	NA	0.527
28	9.000	6.941	8.267	6.533	8.200	6.933	8.667	10.667
29	6.00	6.92	7.60	6.40	8.40	6.20	6.00	4.60
30	7.015	7.399	6.210	6.421	8.401	5.108	4.656	4.557
31	5.164	NA	4.777	NA	4.673	NA	4.199	4.005
32	3.628	6.297	3.497	3.068	2.658	1.137	1.283	0.761
33	44.558	53.167	34.742	37.492	35.725	29.542	34.889	26.250
34	5.538	6.163	4.325	6.525	4.610	3.463	4.983	3.500
35	11.667	23.167	7.833	19.133	10.500	8.700	8.722	5.900
36	15.895	17.874	11.825	17.009	11.164	12.831	20.157	19.529
37	42.339	NA	34.000	NA	37.814	NA	31.085	34.700
38	34.162	34.496	30.782	38.376	37.031	34.206	26.070	29.340
39	13.330	9.191	NA	NA	10.432	13.724	8.111	NA
40	68.762	54.786	71.575	87.547	20.980	22.444	36.002	40.671
41	482.2	290.8	426.6	501.1	102.6	170.9	334.6	330.6
42	9.047	5.423	7.366	8.235	1.939	3.699	9.763	10.156
43	3978.6	2416.5	4403.0	4356.2	1164.4	2036.8	2987.2	4661.8
44	1.233	1.467	1.396	0.905	0.607	0.001	1.665	1.027
45	1.750	2.000	6.250	2.250	0.833	9.500	0.000	3.250
46	220.6	250.4	236.9	203.5	211.4	255.6	228.0	251.6
47	5.544	6.054	5.086	5.646	6.279	5.546	5.637	4.628
48	18.859	13.014	18.171	18.924	9.772	23.521	24.595	28.081
49	30.000	22.056	25.200	24.067	23.533	63.571	24.533	43.933
50	22.250	23.167	25.333	24.933	32.400	26.867	22.333	43.400
51	82.63	91.03	85.27	62.23	36.42	1.79	52.44	40.39
52	3.660	3.082	4.793	4.273	3.023	1.819	5.304.	5.118
53	2.515	0.355	3.652	4.930	2.484	1.115	1.828	1.424
54	98.53	65.11	118.07	103.20	70.33	111.93	126.73	224.00
55	58.545	12.538	91.067	97.067	81.400	31.714	45.429	62.286
56	1.528	1.010	NA	NA	3.741	0.303	1.540	NA
57	NA	8.803	11.696	12.911	18.529	10.759	17.398	14.323
58	70.867	66.765	61.767	69.113	86.773	52.760	######	71.507
59	0.838	1.646	0.934	NA	0.368	1.385	1.428	1.336
60	0.345	0.689	0.388	0.635	0.542	0.419	0.355	0.248

Table 169. Provided are the values of each of the parameters (as described above) measured in bean accessions (Line). Growth conditions are specified in the experimental procedure section

TABLE 170
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic petformance under
normal conditions across “fine” and “extra fine” bean varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY33	0.91	5.11E−05	4	6	LBY33	0.76	4.19E−03	4	9
LBY33	0.71	9.29E−03	4	32	LBY33	0.71	1.01E−02	4	33
LBY33	0.84	1.34E−03	2	11	LBY33	0.82	3.50E−03	2	24
LBY33	0.83	1.52E−03	2	45	LBY33	0.78	4.78E−03	2	49
LBY33	0.74	5.54E−02	9	37	LBY33	0.85	3.82E−03	7	57
LBY33	0.71	9.41E−03	6	36	LBY34	0.73	1.24E−03	1	53
LBY34	0.72	1.27E−02	4	27	LBY34	0.76	1.08E−02	2	12
LBY34	0.86	3.30E−03	9	31	LBY34	0.80	1.68E−03	9	51
LBY34	0.85	4.06E−03	9	1	LBY34	0.73	1.10E−02	5	53
LBY34	0.75	1.93E−02	7	10	LBY34	0.77	9.37E−03	7	52
LBY34	0.82	1.91E−03	3	55	LBY34	0.86	7.19E−04	3	53
LBY34	0.88	4.29E−03	3	56	LBY35	0.83	2.65E−03	2	4
LBY35	0.84	2.64E−03	2	39	LBY35	0.70	1.55E−02	5	46
LBY35	0.71	2.10E−02	7	38	LBY36	0.76	6.12E−03	2	29
LBY36	0.81	7.59E−03	2	15	LBY36	0.73	6.49E−03	9	2
LBY36	0.81	2.70E−03	5	55	LBY36	0.86	6.34E−04	5	53
LBY36	0.80	3.20E−03	5	50	LBY36	0.87	1.44E−05	8	11
LBY36	0.75	8.18E−03	3	44	LBY36	0.84	1.20E−03	3	51

Table 170. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 167. “Exp. Set”—Expression set specified in Table 166. “R”=Pearson correlation coefficient; “P”=p value.

Example 20

Production of Foxtail Millet Transcriptome and High Throughput Correlation Analysis Using 60K Foxtail Millet Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis comparing between plant phenotype and gene expression level, the present inventors utilized a foxtail millet oligonucleotide micro-array, produced by Agilent Technologies [World Wide Web (dot) chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60K foxtail millet genes and transcripts. In order to define correlations between the levels of RNA expression and yield or vigor related parameters, various plant characteristics of 15 different foxtail millet accessions were analyzed. Among them, 11 accessions encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Fourteen foxtail millet varieties were grown in 5 repetitive plots, in field. Briefly, the growing protocol was as follows:

1. Regular growth conditions: foxtail millet plants were grown in the field using commercial fertilization and irrigation protocols, which include 283 m³ water per dunam (100 square meters) per entire growth period and fertilization of 16 units of URAN® 32% (Nitrogen Fertilizer Solution; PCS Sales, Northbrook. Ill., USA) (normal growth conditions).

2. Drought conditions: foxtail millet seeds were sown in soil and grown under normal condition until the heading stage (22 days from sowing), and then drought treatment was imposed by irrigating plants with 50% water relative to the normal treatment (171 m³ water per dunam per entire growth period) while maintaining normal fertilization.

Analyzed Foxtail millet tissues—All 15 foxtail millet lines were sample per each treatment. Three tissues [leaf, flower, and stem] at 2 different developmental stages [flowering, grain filling], representing different plant characteristics were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Tables 171-174 below.

TABLE 171
Foxtail millet transcriptome expression sets
under drought conditions at flowering stage
                                 Set
Expression Set                   ID
flower: flowering stage, drought 1
leaf: flowering stage, drought   2
stem: flowering stage, drought   3

Table 171. Provided are the foxtail millet transcriptome expression sets under drought conditions at flowering stage.

TABLE 172
Foxtail millet transcriptome expression sets under
drought conditions at grain filling stage
                                 Set
Expression Set                   ID
grain: grain filling stage, drought 4
leaf: grain filling stage, drought 5
stem: grain filling stage, drought 6

Table 172. Provided are the foxtail millet transcriptome expression sets under ought conditions at grain filling stage.

TABLE 173
Foxtail millet transcriptome expression sets
under normal conditions at flowering stage
                                Set
Expression Set                  ID
flower: flowering stage, normal 1
leaf: flowering stage, normal   2

Table 173. Provided are the foxtail millet transcriptome expression sets under normal conditions at flowering stage.

TABLE 174
Foxtail millet transcriptome expression sets under
normal conditions at grain filling stage
                                 Set
Expression Set                   ID
grain: grain filling stage, normal 4
leaf: grain filling stage, normal 5
stem: grain filling stage, normal 6

Table 174. Provided are the foxtail millet transcriptome expression sets under normal conditions at grain filling stage.

Foxtail millet yield components and vigor related parameters assessment—Plants were continuously phenotyped during the growth period and at harvest (Tables 175-176, below). The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

The following parameters were collected using digital imaging system:

At the end of the growing period the grains were separated from the Plant ‘Head’ and the following parameters were measured and collected:

Average Grain Area (cm²)—A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Average Grain Length and width (cm)—A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths and width (longest axis) were measured from those images and were divided by the number of grains.

At the end of the growing period 14 ‘Heads’ were photographed and images were processed using the below described image processing system.

Average Grain Perimeter (cm)—At the end of the growing period the grains were separated from the Plant ‘Head’. A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The sum of grain perimeter was measured from those images and was divided by the number of grains.

Head Average Area (cm²)—The ‘Head’ area was measured from those images and was divided by the number of ‘Heads’.

Head Average Length and width (cm)—The ‘Head’ length and width (longest axis) were measured from those images and were divided by the number of ‘Heads’.

The image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Additional parameters were collected either by sampling 5 plants per plot or by measuring the parameter across all the plants within the plot.

Head weight (Kg.) and head number (num.)—At the end of the experiment, heads were harvested from each plot and were counted and weighted.

Total Grain Yield (gr.)—At the end of the experiment (plant ‘Heads’) heads from plots were collected, the heads were threshed and grains were weighted. In addition, the average grain weight per head was calculated by dividing the total grain weight by number of total heads per plot (based on plot).

1000 Seeds weight [gr.]—was calculated based on Formula XIV (above).

Biomass at harvest [kg]—At the end of the experiment the vegetative portion above ground (excluding roots) from plots was weighted.

Total dry mater per plot [kg]—Calculated as Vegetative portion above ground plus all the heads dry weight per plot.

Number (num) of days to anthesis—Calculated as the number of days from sowing till 50% of the plot arrives anthesis.

Maintenance of performance under drought conditions—Represent ratio for the specified parameter of Drought condition results divided by Normal conditions results (maintenance of phenotype under drought in comparison to normal conditions).

Data parameters collected are summarized in Tables 175-176, herein below.

TABLE 175
Foxtail millet correlated parameters under
drought and normal conditions (vectors)
                                 Correlation
Correlated parameter with        ID
1000 grain weight [gr.]          1
Biomass at harvest [kg]          2
Grain Perimeter [cm]             3
Grain area [cm2]                 4
Grain length [cm]                5
Grain width [cm]                 6
Grains yield per Head (plot) [gr.] 7
Head Area [cm2]                  8
Head Width [cm]                  9
Head length [cm]                 10
Heads number [number]            11
Num days to Anthesis [days]      12
Total Grains yield [gr.]         13
Total dry matter [kg]            14
Total heads weight [kg]          15

Table 175. Provided are the foxtail millet collected parameters under drought and normal conditions.

TABLE 176
Foxtail millet correlated parameters under drought
vs normal conditions (maintenance) (vectors)
                                 Correlation
Correlated parameter with        ID
1000 grain weight D/N [gr.]      1
Biomass at harvest D/N [kg]      2
Grain Perimeter D/N [cm]         3
Grain area D/N [cm2]             4
Grain length D/N [cm]            5
Grain width D/N [cm]             6
Grains yield per Head (plot) D/N [gr.] 7
Head Area D/N [cm2]              8
Head Width D/N [cm]              9
Head length D/N [cm]             10
Heads num D/N [num]              11
Total Grains yield D/N [gr.]     12
Total dry matter D/N [kg]        13
Total heads weight D/N [kg]      14

Table 176. Provided are the foxtail millet collected parameters under drought vs. normal conditions (maintenance).

Experimental Results

Fifteen different foxtail millet accessions were grown and characterized for different parameters as described above (Table 175-176). The average for each of the measured parameter was calculated using the JMP software and values are summarized in Tables 177-182 below. Subsequent correlation analysis between the various transcriptome sets and the average parameters was conducted (Tables 183-188). Follow, results were integrated to the database.

TABLE 177
Measured parameters of correlation IDs in foxtail millet
accessions under drought conditions
Line/
Corr. ID	1	2	3	4	5	6	7	8
Line-1	2.639	1.528	0.683	0.033	0.242	0.175	3.053	35.748
Line-2	3.329	3.459	0.722	0.037	0.244	0.194	8.832	50.714
Line-3	2.610	2.872	0.689	0.033	0.250	0.171	1.336	18.400
Line-4	2.295	2.935	0.683	0.032	0.254	0.160	1.093	14.938
Line-5	2.304	3.022	0.690	0.033	0.257	0.162	1.309	17.686
Line-6	2.642	2.665	0.692	0.033	0.250	0.170	0.486	9.911
Line-7	2.215	2.975	0.648	0.030	0.233	0.163	1.628	20.986
Line-8	1.837	0.765	0.569	0.024	0.194	0.156	3.737	39.929
Line-9	2.540	2.662	0.661	0.032	0.223	0.181	9.900	42.149
Line-10	1.691	2.946	0.593	0.025	0.203	0.158	4.143	43.524
Line-11	3.096	3.230	0.720	0.037	0.261	0.178	2.975	26.931
Line-12	2.541	3.303	0.675	0.032	0.245	0.167	1.305	21.229
Line-13	3.238	2.632	0.748	0.039	0.270	0.184	0.363	7.302
Line-14	2.245	0.886	0.659	0.030	0.242	0.159	1.741	13.126

Table 177: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (Line). Growth conditions are specified in the experimental procedure section.

TABLE 178
Additional measured parameters of correlation IDs in foxtail
millet accessions under drought conditions
Line/
Corr. ID	9	10	11	12	13	14	15
Line-1	1.871	22.36	374.40	34.00	1141.49	0.504	2.888
Line-2	2.677	21.89	127.00	41.00	1116.18	0.733	6.087
Line-3	1.325	16.50	737.80	51.00	988.21	0.798	5.325
Line-4	1.334	13.31	1100.80	41.00	1202.77	0.616	5.402
Line-5	1.501	14.00	1047.20	41.00	1360.51	0.708	5.570
Line-6	1.166	9.11	2050.00	30.00	995.17	0.470	5.280
Line-7	1.666	15.10	581.50	38.00	946.85	0.608	5.121
Line-8	2.153	21.13	311.60	30.00	1159.78	0.349	2.288
Line-9	2.362	20.02	147.20	38.00	1391.39	0.437	5.834
Line-10	2.322	21.80	95.40	NA	394.51	0.645	4.316
Line-11	1.545	20.80	414.40	44.00	1199.50	0.748	5.639
Line-12	1.590	15.85	667.80	51.00	872.48	0.872	5.132
Line-13	1.254	6.45	2441.00	31.00	873.94	0.523	5.126
Line-14	1.738	9.18	687.50	27.00	1187.98	0.361	2.307

Table 178: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (Line). Growth conditions are specified in the experimental procedure section.

TABLE 179
Measured parameters of correlation IDs in foxtail millet accessions for
Maintenance of performance under drought conditions
Line/
Corr. ID	1	2	3	4	5	6	7
Line-1	107.285	63.803	101.149	103.094	100.719	102.266	89.854
Line-2	97.440	86.662	100.635	101.059	101.132	100.031	121.191
Line-3	99.893	90.611	101.035	102.805	100.392	102.389	76.406
Line-4	97.291	81.978	100.282	100.875	100.432	100.423	83.957
Line-5	95.731	84.030	100.570	101.565	100.177	101.334	83.228
Line-6	99.523	87.176	99.367	99.754	99.501	100.231	70.037
Line-7	101.384	73.573	100.868	101.139	101.033	100.218	77.372
Line-8	102.163	66.771	99.648	99.961	99.169	100.784	111.740
Line-9	94.538	83.217	99.837	98.886	100.709	98.159	86.386
Line-10	102.691	75.471	101.821	102.672	102.004	100.612	57.788
Line-11	97.607	90.154	98.935	97.949	99.401	98.504	68.366
Line-12	97.815	89.810	97.988	96.377	97.778	98.545	57.646
Line-13	101.686	89.510	100.391	101.190	100.335	100.858	83.164
Line-14	99.502	59.886	99.194	99.248	98.983	100.258	132.380

Table 179: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (Line). Growth conditions are specified in the experimental procedure section.

TABLE 180
Additional measured parameters of correlation IDs in foxtail millet
accessions for Maintenance of performance under drought conditions
Line/
Corr. ID	8	9	10	11	11	13	14
Line-1	94.502	98A78	96.690	87.558	78.744	71.703	75.808
Line-2	87.634	98.291	90.250	85.121	104.523	85.768	102.306
Line-3	93.932	99.878	93.972	85.098	64.382	82.890	85.901
Line-4	87.357	98.420	89.958	91.429	76.747	66.681	95.835
Line-5	89.510	97.942	91.006	91.347	75.803	78.325	88.824
Line-6	105.260	98.755	106.443	96.154	67.418	98.019	86.916
Line-7	91.555	98.976	93.881	77.307	59.830	66.278	81.036
Line-8	97.651	101.337	96.594	79.046	88.004	77.030	81.183
Line-9	93.057	94.533	98.097	78.885	65.274	73.539	80.433
Line-10	88.210	95.663	93.498	72.382	42.062	64.635	82.305
Line-11	97.271	99.482	99.655	95.440	63.796	81.972	85.754
Line-12	87.804	100.351	88.132	103.311	61.136	84.963	87.702
Line-13	102.458	100.818	101.471	87.247	71.855	83.890	91.152
Line-14	89.377	95.464	93.807	69.123	91.616	77.761	84.425

Table 180: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (Line). Growth conditions are specified in the experimental procedure section.

TABLE 181
Measured parameters of correlation IDs in foxtail
millet accessions under normal conditions
Line/
Corr. ID	1	2	3	4	5	6	7	8
Line-1	2.460	2.396	0.675	0.032	0.240	0.172	3.398	37.828
Line-2	3.416	3.992	0.717	0.037	0.242	0.194	7.288	57.870
Line-3	2.613	3.170	0.682	0.033	0.249	0.167	1.749	19.588
Line-4	2.359	3.580	0.681	0.032	0.253	0.159	1.302	17.100
Line-5	2.406	3.597	0.686	0.032	0.256	0.160	1.573	19.759
Line-6	2.655	3.057	0.697	0.034	0.252	0.170	0.695	9.415
Line-7	2.185	4.044	0.642	0.029	0.231	0.162	2.104	22.922
Line-8	1.798	1.146	0.571	0.024	0.196	0.155	3.345	40.890
Line-9	2.686	3.198	0.662	0.032	0.221	0.184	11.460	45.294
Line-10	1.647	3.904	0.582	0.025	0.199	0.157	7.169	49.341
Line-11	3.172	3.583	0.728	0.037	0.262	0.181	4.351	27.686
Line-12	2.598	3.678	0.689	0.033	0.250	0.169	2.263	24.178
Line-13	3.184	2.940	0.745	0.039	0.269	0.183	0.436	7.127
Line-14	2.257	1.479	0.665	0.030	0.244	0.158	1.315	14.686

Table 181: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (Line). Growth conditions are specified in the experimental procedure section

TABLE 182
Additional measured parameters of correlation IDs in
foxtail millet accessions under normal conditions
Line/
Corr. ID	9	10	11	12	13	14	15
Line-1	1.905	23.13	427.6	34.0	1449.6	0.703	3.810
Line-2	2.773	24.25	149.2	41.0	1067.9	0.854	5.950
Line-3	1.327	17.56	867.0	45.0	1534.9	0.963	6.199
Line-4	1.356	14.79	1204.0	41.0	1567.2	0.924	5.637
Line-5	1.532	15.38	1146.4	41.0	1794.8	0.904	6.271
Line-6	1.181	8.56	2132.0	30.0	1476.1	0.480	6.075
Line-7	1.683	16.08	752.2	38.0	1582.6	0.917	6.319
Line-8	2.124	21.88	394.2	30.0	1317.9	0.453	2.819
Line-9	2.499	20.41	186.6	38.0	2131.6	0.594	7.253
Line-10	2.427	23.32	131.8	51.0	937.9	0.998	5.244
Line-11	1.553	20.87	434.2	44.0	1880.2	0.913	6.576
Line-12	1.585	17.98	646.4	51.0	1427.1	1.027	5.851
Line-13	1.243	6.35	2797.8	31.0	1216.2	0.623	5.624
Line-14	1.820	9.78	994.6	27.0	1296.7	0.464	2.732

Table 182: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (Line). Growth conditions are specified in the experimental procedure section.

TABLE 183
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic petformance under drought conditions at
flowering stage across foxtail millet varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY3	0.74	2.27E−02	3	9	LBY3	0.85	3.67E−03	3	7
LBY3	0.72	2.91E−02	3	8	LBY3	0.77	8.98E−03	1	14
LBY3	0.78	7.18E−03	1	4	LBY3	0.82	3.64E−03	1	3
LBY55	0.79	6.84E−03	1	1	LBY55	0.78	7.54E−03	1	10
LBY55	0.78	7.27E−03	1	6	LBY55	0.73	1.67E−02	1	8
LBY57	0.72	1.17E−02	2	14	LBY57	0.79	7.01E−03	1	10
LBY59	0.72	1.29E−02	2	14	LBY59	0.72	1.18E−02	2	12
LBY59	0.72	1.99E−02	1	13	LBY66	0.78	1.32E−02	3	4
LBY66	0.81	8.20E−03	3	3	LBY67	0.77	1.54E−02	3	1
LBY67	0.82	6.78E−03	3	4	LBY67	0.80	1.04E−02	3	3
LBY67	0.87	1.06E−03	1	1	LBY67	0.88	8.30E−04	1	4
LBY67	0.84	2.31E−03	1	3	LBY69	0.75	1.88E−02	3	1
LBY69	0.72	2.72E−02	3	4	LBY69	0.76	1.77E−02	3	6
LBY69	0.75	7.89E−03	2	6	LBY70	0.83	3.14E−03	1	11
LBY71	0.72	1.88E−02	1	13	LBY75	0.76	1.13E−02	1	1
LBY75	0.75	1.31E−02	1	4	LBY77	0.74	2.34E−02	3	2
LBY77	0.89	5.26E−04	1	1	LBY77	0.73	1.73E−02	1	10
LBY77	0.79	6.33E−03	1	4	LBY77	0.80	5.12E−03	1	6
LBY77	0.75	1.33E−02	1	8	LBY81	0.87	1.20E−03	1	10
LBY82	0.74	2.13E−02	3	12	LBY85	0.84	2.27E−03	1	1
LBY85	0.75	1.30E−02	1	14	LBY85	0.83	3.08E−03	1	4
LBY85	0.73	1.70E−02	1	2	LBY85	0.74	1.37E−02	1	3
LBY85	0.73	1.64E−02	1	6	LBY89	0.73	1.04E−02	2	13
LGN52	0.83	3.00E−03	1	14	LGN60	0.79	1.15E−02	3	11

Table 183. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 175. “Exp. Set”—Expression set specified in Table 171. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 184
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under drought conditions at
grain filling stage across foxtail millet varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY3	0.91	1.20E−02	1	15	LBY3	0.87	2.60E−02	1	2
LBY3	0.70	2.33E−02	2	9	LBY3	0.75	1.33E−02	2	7
LBY3	0.70	2.35E−02	3	8	LBY55	0.84	3.72E−02	1	1
LBY55	0.82	4.62E−02	1	4	LBY55	0.75	8.61E−02	1	3
LBY55	0.85	3.06E−02	1	6	LBY55	0.72	1.98E−02	2	10
LBY55	0.72	1.83E−02	2	9	LBY55	0.86	1.55E−03	2	7
LBY55	0.83	2.89E−03	2	8	LBY57	0.74	1.44E−02	2	2
LBY57	0.73	1.67E−02	3	15	LBY57	0.76	1.05E−02	3	2
LBY59	0.78	7.01E−02	1	2	LBY59	0.70	2.31E−02	2	7
LBY59	0.73	1.60E−02	3	2	LBY61	0.89	1.86E−02	1	13
LBY63	0.82	4.75E−02	1	11	LBY64	0.89	1.64E−02	1	1
LBY64	0.84	3.75E−02	1	4	LBY64	0.75	8.51E−02	1	3
LBY64	0.94	6.09E−03	1	6	LBY64	0.73	1.76E−02	2	9
LBY65	0.71	1.10E−01	1	15	LBY65	0.76	8.18E−02	1	2
LBY65	0.71	2.06E−02	2	2	LBY65	0.81	4.25E−03	2	9
LBY65	0.74	1.52E−02	2	7	LBY65	0.72	1.85E−02	3	14
LBY65	0.75	1.21E−02	3	2	LBY66	0.75	8.77E−02	1	11
LBY67	0.84	2.61E−03	3	13	LBY67	0.74	1.54E−02	3	14
LBY68	0.71	2.15E−02	2	9	LBY68	0.73	1.76E−02	3	15
LBY68	0.73	1.74E−02	3	12	LBY68	0.76	1.03E−02	3	2
LBY69	0.89	1.83E−02	1	1	LBY69	0.86	2.97E−02	1	13
LBY69	0.79	6.28E−02	1	5	LBY69	0.89	1.68E−02	1	10
LBY69	0.80	5.46E−02	1	12	LBY69	0.93	6.24E−03	1	4
LBY69	0.83	4.00E−02	1	11	LBY69	0.90	1.42E−02	1	3
LBY69	0.80	5.58E−02	1	6	LBY69	0.74	9.30E−02	1	8
LBY69	0.71	2.05E−02	2	11	LBY69	0.73	1.63E−02	3	1
LBY70	0.79	6.07E−02	1	13	LBY70	0.76	1.09E−02	2	10
LBY70	0.71	2.24E−02	2	9	LBY70	0.86	1.59E−03	2	7
LBY70	0.81	4.20E−03	2	8	LBY73	0.70	1.18E−01	1	13
LBY75	0.94	5.65E−03	1	13	LBY75	0.80	5.92E−03	2	9
LBY78	0.80	5.42E−02	1	5	LBY78	0.91	1.11E−02	1	11
LBY79	0.72	1.07E−01	1	4	LBY80	0.70	2.40E−02	2	10
LBY80	0.72	1.81E−02	2	8	LBY80	0.75	1.33E−02	3	13
LBY81	0.75	1.33E−02	2	10	LBY81	0.76	1.00E−02	2	8
LBY82	0.79	6.23E−02	1	10	LBY82	0.86	2.88E−02	1	9
LBY82	0.74	9.18E−02	1	7	LBY82	0.82	4.33E−02	1	8
LBY82	0.73	1.65E−02	2	5	LBY83	0.85	3.17E−02	1	1
LBY83	0.77	7.04E−02	1	4	LBY83	0.92	9.15E−03	1	6
LBY85	0.77	8.50E−03	3	14	LBY86	0.95	3.64E−03	1	13
LBY87	0.76	8.12E−02	1	4	LBY87	0.75	8.83E−02	1	3
LBY88	0.88	8.70E−04	3	14	LBY88	0.89	5.11E−04	3	12
LBY89	0.85	3.06E−02	1	1	LBY89	0.77	7.23E−02	1	4
LBY89	0.80	5.65E−02	1	9	LBY89	0.83	4.27E−02	1	7
LBY89	0.93	7.46E−03	1	6	LBY91	0.79	6.39E−02	1	9
LBY91	0.74	9.51E−02	1	8	LBY92	0.90	1.54E−02	1	13
LBY92	0.78	6.74E−02	1	12	LBY92	0.70	2.30E−02	3	7
LGN52	0.80	5.38E−02	1	11	LGN60	0.95	3.79E−03	1	11

Table 184. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 175. “Exp. Set”—Expression set specified in Table 172. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 185
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions at
flowering stage across foxtail millet varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY3	0.76	6.43E−03	1	12	LBY55	0.74	1.54E−02	2	13
LBY57	0.75	8.25E−03	1	10	LBY59	0.78	4.68E−03	1	12
LBY62	0.74	8.79E−03	1	7	LBY65	0.71	1.46E−02	1	7
LBY77	0.86	1.47E−03	2	9	LBY77	0.80	5.22E−03	2	7
LBY77	0.78	7.84E−03	2	8	LBY81	0.82	2.07E−03	1	12
LBY84	0.73	1.09E−02	1	11	LBY88	0.83	1.60E−03	1	12
LBY91	0.76	6.79E−03	1	7

Table 185. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 175. “Exp. Set”—Expression set specified in Table 173. “R”=Pearson correlation coefficient: “P”=p value.

TABLE 186
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under normal conditions at
grain filling stage across foxtail millet varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY3	0.73	1.76E−02	2	1	LBY3	0.79	1.90E−02	3	1
LBY3	0.77	2.59E−02	3	13	LBY3	0.74	3.71E−02	3	4
LBY3	0.82	1.18E−02	3	9	LBY3	0.92	1.30E−03	3	7
LBY3	0.87	5.15E−03	3	8	LBY3	0.86	2.90E−02	1	11
LBY55	0.73	1.55E−02	2	13	LBY55	0.77	9.15E−03	2	9
LBY55	0.87	1.11E−03	2	7	LBY55	0.70	2.40E−02	2	8
LBY55	0.78	2.27E−02	3	15	LBY55	0.73	1.02E−01	1	10
LBY55	0.95	3.29E−03	1	9	LBY55	0.95	3.11E−03	1	7
LBY55	0.90	1.42E−02	1	6	LBY55	0.89	1.88E−02	1	8
LBY57	0.76	2.88E−02	3	11	LBY57	0.82	4.43E−02	1	10
LBY59	0.76	1.06E−02	2	15	LBY59	0.81	4.79E−03	2	13
LBY59	0.70	5.09E−02	3	15	LBY59	0.93	7.50E−04	3	13
LBY59	0.73	4.00E−02	3	10	LBY59	0.76	2.96E−02	3	9
LBY59	0.92	1.23E−03	3	7	LBY59	0.89	3.18E−03	3	8
LBY61	0.72	1.91E−02	2	4	LBY61	0.76	1.05E−02	2	11
LBY61	0.71	2.15E−02	2	3	LBY61	0.72	4.26E−02	3	12
LBY62	0.76	7.64E−02	1	14	LBY62	0.89	1.84E−02	1	5
LBY62	0.88	1.98E−02	1	11	LBY63	0.95	3.18E−03	1	12
LBY63	0.72	1.05E−01	1	2	LBY64	0.81	1.39E−02	3	7
LBY64	0.80	1.73E−02	3	6	LBY64	0.70	5.17E−02	3	8
LBY64	0.75	8.47E−02	1	1	LBY64	0.84	3.53E−02	1	10
LBY64	0.84	3.80E−02	1	9	LBY64	0.85	3.37E−02	1	6
LBY64	0.88	2.22E−02	1	8	LBY65	0.72	4.53E−02	3	5
LBY65	0.82	4.77E−02	1	15	LBY65	0.70	1.20E−01	1	7
LBY67	0.72	1.86E−02	2	13	LBY67	0.79	6.31E−03	2	9
LBY67	0.95	3.49E−05	2	7	LBY67	0.71	2.09E−02	2	8
LBY67	0.92	1.42E−03	3	13	LBY67	0.83	1.01E−02	3	10
LBY67	0.73	3.99E−02	3	7	LBY67	0.83	1.09E−02	3	8
LBY67	0.83	4.15E−02	1	13	LBY67	0.76	8.17E−02	1	2
LBY67	0.86	2.75E−02	1	11	LBY67	0.71	1.11E−01	1	9
LBY68	0.79	6.86E−03	9	7	LBY68	0.80	1.75E−02	3	11
LBY68	0.73	9.88E−02	1	1	LBY68	0.95	3.68E−03	1	10
LBY68	0.89	1.62E−02	1	9	LBY68	0.80	5.44E−02	1	7
LBY68	0.91	1.30E−02	1	6	LBY68	0.94	4.82E−03	1	8
LBY69	0.78	7.63E−03	2	7	LBY69	0.72	4.25E−02	3	7
LBY70	0.78	7.24E−03	2	9	LBY70	0.86	1.60E−03	2	7
LBY70	0.73	1.75E−02	2	8	LBY70	0.77	7.35E−02	1	10
LBY71	0.86	2.78E−02	1	10	LBY71	0.83	4.11E−02	1	9
LBY71	0.79	5.89E−02	1	6	LBY71	0.85	3.38E−02	1	8
LBY72	0.72	1.05E−01	1	1	LBY72	0.73	9.91E−02	1	4
LBY73	0.76	8.12E−02	1	5	LBY73	0.72	1.09E−01	1	11
LBY74	0.75	1.32E−02	2	9	LBY74	0.80	5.44E−02	1	10
LBY75	0.81	5.03E−02	1	15	LBY75	0.91	1.13E−02	1	1
LBY75	0.89	1.61E−02	1	13	LBY75	0.83	3.91E−02	1	10
LBY75	0.85	3.10E−02	1	4	LBY75	0.96	2.74E−03	1	9
LBY75	0.72	1.07E−01	1	7	LBY75	0.95	4.07E−03	1	6
LBY75	0.95	3.54E−03	1	8	LBY76	0.73	4.11E−02	3	9
LBY76	0.78	6.64E−02	1	10	LBY77	0.79	5.90E−02	1	9
LBY77	0.77	7.20E−02	1	6	LBY77	0.71	1.17E−01	1	8
LBY78	0.71	1.15E−01	1	2	LBY79	0.94	5.31E−03	1	10
LBY79	0.90	1.36E−02	1	9	LBY79	0.73	1.02E−01	1	7
LBY79	0.90	1.56E−02	1	6	LBY79	0.94	5.31E−03	1	8
LBY80	0.89	4.95E−04	2	9	LBY80	0.84	2.34E−03	2	7
LBY80	0.85	1.89E−03	2	8	LBY80	0.73	3.90E−02	3	1
LBY80	0.90	2.21E−03	3	9	LBY80	0.90	2.44E−03	3	7
LBY80	0.79	2.06E−02	3	8	LBY80	0.78	6.56E−02	1	7
LBY81	0.80	5.22E−03	2	9	LBY81	0.82	3.85E−03	2	7
LBY81	0.81	4.65E−03	2	8	LBY81	0.82	1.24E−02	3	15
LBY81	0.81	1.48E−02	3	13	LBY81	0.71	4.82E−02	3	7
LBY81	0.91	1.25E−02	1	9	LBY81	0.85	3.35E−02	1	7
LBY81	0.84	3.57E−02	1	6	LBY81	0.80	5.36E−02	1	8
LBY82	0.71	4.80E−02	3	14	LBY82	0.76	8.01E−02	1	1
LBY82	0.82	4.44E−02	1	10	LBY82	0.81	5.01E−02	1	4
LBY82	0.71	1.17E−01	1	3	LBY82	0.71	1.11E−01	1	8
LBY83	0.80	5.67E−02	1	1	LBY83	0.74	9.45E−02	1	10
LBY83	0.70	1.21E−01	1	4	LBY83	0.76	7.86E−02	1	9
LBY83	0.78	6.66E−02	1	6	LBY83	0.80	5.68E−02	1	8
LBY84	0.74	9.01E−02	1	5	LBY84	0.72	1.09E−01	1	11
LBY85	0.73	1.56E−02	2	10	LBY85	0.78	8.15E−03	2	8
LBY85	0.85	3.31E−02	1	1	LBY85	0.84	3.62E−02	1	4
LRY85	0.82	4.35E−02	1	2	LBY85	0.77	7.32E−02	1	3
LBY86	0.71	1.13E−01	1	14	LBY88	0.74	9.34E−02	1	11
LBY89	0.78	2.24E−02	3	13	LBY89	0.75	3.12E−02	3	9
LBY89	0.95	2.73E−04	3	7	LBY89	0.75	3.23E−02	3	6
LBY89	0.85	7.56E−03	3	8	LBY89	0.78	6.48E−02	1	1
LBY89	0.87	2.33E−02	1	10	LBY89	0.88	2.18E−02	1	9
LBY89	0.88	2.13E−02	1	6	LBY89	0.91	1.17E−02	1	8
LBY91	0.73	1.02E−01	1	1	LGN52	0.77	2.44E−02	3	9
LGN52	0.75	3.12E−02	3	7	LGN52	0.82	4.69E−02	1	5
LGN52	0.70	1.20E−01	1	11	LGN60	0.81	4.26E−03	2	13
LGN60	0.84	2.50E−03	2	10	LGN60	0.74	1.38E−02	2	8
LGN60	0.74	3.57E−02	3	13	LGN60	0.76	8.17E−02	1	7

Table 186. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 175. “Exp. Set”—Expression set specified in Table 174. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 187
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance of maintenance of performance
under drought vs normal conditions at flowering stage across foxtail millet varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY56	0.77	5.90E−03	2	1	LBY57	0.81	2.40E−03	2	11
LBY58	0.82	6.62E−03	3	1	LBY59	0.83	1.50E−03	2	11
LBY61	0.74	2.35E−02	3	12	LBY62	0.78	1.35E−02	3	1
LBY62	0.84	4.57E−03	3	10	LBY62	0.84	4.95E−03	3	8
LBY63	0.72	1.24E−02	2	12	LBY63	0.87	4.23E−04	2	7
LBY64	0.78	7.91E−03	1	3	LBY64	0.80	5.26E−03	1	4
LBY64	0.75	1.32E−02	1	6	LBY65	0.81	7.64E−03	3	1
LBY65	0.74	1.34E−02	1	1	LBY66	0.78	5.03E−03	2	7
LBY67	0.77	5.30E−03	2	6	LBY67	0.85	1.93E−03	1	12
LBY68	0.70	2.31E−02	1	12	LBY68	0.75	1.26E−02	1	7
LBY69	0.74	2.14E−02	3	10	LBY69	0.72	2.98E−02	3	8
LBY70	0.77	1.57E−02	3	12	LBY70	0.79	1.08E−02	3	4
LBY70	0.83	5.73E−03	3	6	LBY70	0.71	2.09E−02	1	13
LBY71	0.81	4.65E−03	1	3	LBY71	0.73	1.73E−02	1	4
LBY71	0.76	1.04E−02	1	5	LBY72	0.76	1.67E−02	3	13
LBY72	0.83	6.03E−03	3	11	LBY73	0.72	3.01E−02	3	12
LBY73	0.82	6.40E−03	3	14	LBY75	0.71	3.13E−02	3	14
LBY75	0.71	3.14E−02	3	7	LBY75	0.77	9.49E−03	1	8
LBY77	0.73	2.49E−02	3	14	LBY78	0.75	7.68E−03	2	7
LBY80	0.76	1.81E−02	3	1	LBY83	0.80	5.35E−03	1	3
LBY83	0.85	2.03E−03	1	5	LBY84	0.79	3.70E−03	2	8
LBY85	0.75	8.32E−03	2	11	LBY85	0.71	2.02E−02	1	2
LBY87	0.72	1.82E−02	1	1	LBY89	0.79	6.80E−03	1	5
LBY92	0.71	1.43E−02	2	2	LBY92	0.74	8.72E−03	2	11
LGN52	0.76	1.82E−02	3	11	LGN52	0.83	1.74E−03	2	7
LGN52	0.70	2.36E−02	1	2	LGN52	0.73	1.61E−02	1	9
LGN52	0.86	1.38E−03	1	11

Table 187. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 176. “Exp. Set”—Expression set specified in Table 171. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 188
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance of maintenance of performance
under drought vs normal conditions at grain filling stage across foxtail millet varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY3	0.83	3.99E−02	1	2	LBY3	0.72	2.00E−02	3	14
LBY56	0.81	5.25E−02	1	1	LBY56	0.87	2.46E−02	1	4
LBY56	0.90	1.42E−02	1	6	LBY57	0.91	1.25E−02	1	4
LBY57	0.87	2.35E−02	1	6	LBY58	0.73	1.03E−01	1	1
LBY58	0.77	7.32E−02	1	3	LBY58	0.72	1.77E−02	2	7
LBY58	0.70	2.33E−02	3	12	LBY61	0.84	3.79E−02	1	12
LBY61	0.76	7.93E−02	1	7	LBY62	0.72	1.08E−01	1	13
LBY62	0.82	4.41E−02	1	10	LBY62	0.76	8.16E−02	1	8
LBY64	0.74	8.97E−02	1	12	LBY64	0.77	7.41E−02	1	7
LBY64	0.75	1.29E−02	2	14	LBY65	0.80	5.42E−02	1	5
LBY68	0.77	7.27E−02	1	1	LBY68	0.90	1.47E−02	1	4
LBY68	0.96	2.83E−03	1	6	LBY68	0.87	1.15E−03	2	12
LBY68	0.74	1.46E−02	2	10	LBY68	0.78	7.16E−03	2	7
LBY68	0.71	2.09E−02	2	8	LBY68	0.82	3.41E−03	3	14
LBY69	0.76	7.86E−02	1	3	LBY69	0.95	3.49E−03	1	9
LBY69	0.82	4.41E−02	1	5	LBY69	0.72	1.08E−01	1	8
LBY69	0.76	1.13E−02	3	14	LBY69	0.74	1.34E−02	3	10
LBY69	0.77	9.69E−03	3	8	LBY70	0.80	5.44E−02	1	12
LBY71	0.82	4.58E−02	1	1	LBY71	0.91	1.30E−02	1	3
LBY71	0.85	3.31E−02	1	4	LBY72	0.90	1.45E−02	1	9
LBY73	0.80	5.45E−02	1	11	LBY74	0.82	4.79E−02	1	1
LBY75	0.74	9.19E−02	1	1	LBY75	0.81	4.97E−02	1	4
LBY75	0.94	6.09E−03	1	6	LBY75	0.75	1.32E−02	2	12
LBY75	0.73	1.58E−02	2	7	LBY75	0.74	1.45E−02	3	12
LBY75	0.89	6.48E−04	3	7	LBY76	0.82	4.53E−02	1	1
LBY76	0.84	3.62E−02	1	4	LBY76	0.94	4.78E−03	1	6
LBY77	0.86	1.53E−03	3	12	LBY77	0.70	2.32E−02	3	7
LBY78	0.77	7.17E−02	1	1	LBY78	0.77	7.15E−02	1	10
LBY78	0.90	1.46E−02	1	4	LBY78	0.87	2.27E−02	1	9
LBY78	0.90	1.43E−02	1	6	LBY78	0.85	3.27E−02	1	8
LBY78	0.72	1.87E−02	2	6	LBY78	0.77	9.44E−03	3	7
LBY80	0.80	5.66E−02	1	1	LBY80	0.84	3.50E−02	1	4
LBY80	0.93	6.96E−03	1	6	LBY81	0.72	1.07E−01	1	3
LBY81	0.87	2.45E−02	1	5	LBY82	0.83	4.26E−02	1	3
LBY82	0.88	2.19E−02	1	5	LBY83	0.71	1.12E−01	1	12
LBY83	0.76	8.23E−02	1	7	LBY84	0.93	6.32E−03	1	11
LBY87	0.70	2.36E−02	2	11	LBY89	0.81	5.12E−02	1	12
LBY89	0.89	1.61E−02	1	7	LBY91	0.84	3.61E−02	1	3
LBY91	0.82	4.69E−02	1	5	LGN60	0.74	9.54E−02	1	1
LGN60	0.82	4.33E−02	1	10	LGN60	0.82	4.63E−02	1	9
LGN60	0.89	1.70E−02	1	6	LGN60	0.88	2.15E−02	1	8
LGN60	0.77	9.77E−03	2	10	LGN60	0.70	2.38E−02	2	4
LGN60	0.73	1.59E−02	2	6	LGN60	0.72	1.83E−02	2	8

Table 188. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 176. “Exp. Set”—Expression set specified in Table 172. “R”=Pearson correlation coefficient; “P”=p value.

Example 21

Production of Foxtail Millet Transcriptome and High Throughput Correlation Analysis Using 60K Foxtail Millet Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis comparing between plant phenotype and gene expression level, the present inventors utilized a foxtail millet oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60K foxtail millet genes and transcripts. In order to define correlations between the levels of RNA expression and yield or vigor related parameters, various plant characteristics of 14 different foxtail millet accessions were analyzed. Among them, 11 accessions encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

Fourteen Foxtail millet accessions in 5 repetitive plots, in the field. Foxtail millet seeds were sown in soil and grown under normal condition [15 units of Nitrogen (kg nitrogen per dunam)], reduced nitrogen fertilization (2.5-3.0 units of Nitrogen in the soil (based on soil measurements) and reduced stands in the field [i.e., 8 plants per meter per row as compared to “standard” stands of 17 plants per meter row].

Analyzed Foxtail millet tissues—three tissues at different developmental stages [leaf, flower, and stem], representing different plant characteristics, were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Tables 189-190 below.

TABLE 189
Foxtail millet transcriptome expression
sets under normal conditions
                                 Set
Expression Set                   ID
flag leaf grown under Normal conditions, grain filling stage 1
flag leaf grown under Normal conditions, heading stage 2
flower grown under Normal conditions, heading stage 3
head grown under Normal conditions, grain filling stage 4
leaf grown under Normal conditions, seedling stage 5
low stem grown under Normal conditions, heading stage 6
mature leaf grown under Normal conditions, grain filling stage 7
root grown under Normal conditions, seedling stage 8
stem grown under Normal conditions, seedling stage 9
stem node grown under Normal conditions, grain filling stage 10
up stem grown under Normal conditions, grain filling stage 11
up stem grown under Normal conditions, heading stage 12
vein grown under Normal conditions, grain filling stage 13

Table 189. Provided are the foxtail millet transcriptome expression sets under normal conditions

TABLE 190
Foxtail millet transcriptome expression sets under low N conditions
                                 Set
Expression Set                   ID
flag leaf grown under Low N conditions, grain filling stage 1
flag leaf grown under Low N conditions, heading stage 2
flower grown under Low N conditions, heading stage 3
head grown under Low N conditions, grain filling stage 4
low stem grown under Low N conditions, heading stage 5
mature leaf grown under Low N conditions, grain filling stage 6
stem node grown under Low N conditions, grain filling stage 7
up stem grown under Low N conditions, grain filling stage 8
up stem grown under Low N conditions, heading stage 9
vein grown under Low N conditions, grain filling stage 10

Table 190. Provided are the foxtail millet transcriptome expression sets under low N conditions.

Foxtail millet yield components and vigor related parameters assessment—Plants were continuously phenotyped during the growth period and at harvest (Tables 191-192, below). The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

The following parameters were collected using digital imaging system:

At the end of the growing period the grains were separated from the Plant ‘Head’ and the following parameters were measured and collected:

(i) Average Grain Area (cm²)—A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

(ii) Average Grain Length and width (cm)—A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths and width (longest axis) was measured from those images and was divided by the number of grains.

At the end of the growing period 14 ‘Heads’ were photographed and images were processed using the below described image processing system.

(i) Head Average Area (cm²)—The ‘Head’ area was measured from those images and was divided by the number of ‘Heads’.

(ii) Head Average Length (mm)—The ‘Head’ length (longest axis) was measured from those images and was divided by the number of ‘Heads’.

The image processing system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Additional parameters were collected either by sampling 5 plants per plot (SP) or by measuring the parameter across all the plants within the plot (RP).

Total Grain Weight (gr.)—At the end of the experiment (plant ‘Heads’) heads from plots were collected, the heads were threshed and grains were weighted. In addition, the average grain weight per head was calculated by dividing the total grain weight by number of total heads per plot (based on plot).

Head weight and head number—At the end of the experiment, heads were harvested from each plot and were counted and weighted (kg.).

Biomass at harvest—At the end of the experiment the vegetative material from plots was weighted.

Dry weight—total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours at harvest.

Total dry mater per plot—Calculated as Vegetative portion above ground plus all the heads dry weight per plot.

Number days to anthesis—Calculated as the number of days from sowing till 50% of the plot arrives anthesis.

Total No. of tillers—all tillers were counted per plot at two time points at the Vegetative growth (30 days after sowing) and at harvest.

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at time of flowering. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Root FW (gr.), root length (cm) and No. of lateral roots—one plant per plot (5 repeated plots) were selected for measurement of root weight, root length and for counting the number of lateral roots formed.

Shoot FW (fresh weight)—weight of one plant per plot were recorded at different time-points.

Grain N (H)—% N (nitrogen) content of dry matter in the grain at harvest.

Head N (GF)—% N content of dry matter in the head at grain filling.

Total shoot N—calculated as the % N content multiplied by the weight of plant shoot

Total grain N—calculated as the % N content multiplied by the weight of plant grain yield.

NUE [kg/kg]—was calculated based on Formula LI.

NUpE [kg/kg]—was calculated based on Formula LII.

Grain NUtE—was calculated based on Formula LV.

Total NUtE was calculated based on Formula LIII.

Stem volume—was calculated based on Formula L above.

Stem density—was calculated based on Formula LIV.

Maintenance of performance under low N conditions—Represent ratio for the specified parameter of low N condition results divided by Normal conditions results (maintenance of phenotype under low N in comparison to normal conditions).

Data parameters collected are summarized in Tables 191-192 herein below

TABLE 191
Foxtail millet correlated parameters under normal
and lowN conditions (vectors) - set 1
                                 Correlation
Correlated parameter with        ID
1000 grain weight [gr.]          1
Grain Perimeter [mm]             2
Grain area [mm2]                 3
Grain length [mm]                4
Grain width [mm]                 5
Grains Yield per plant (RP) [gr.] 6
Grains yield (RP) [gr.]          7
Heads FW (RP) [gr.]              8
Heads FW (SP) [gr.]              9
Heads num (SP) [number]          10
Heads weight (RP) [gr.]          11
Heads weight (SP) [gr.]          12
Heads weight per plant (RP) [gr.] 13
Leaves num_1 [number]            14
Leaves num_2 [number]            15
Leaves num_3 [number]            16
Leaves num_4 [number]            17
Leaves temperature_1 [° C.]      18
Leaves temperature_2 [° C.]      19
Lower Stem DW (F) [gr.]          20
Lower Stem FW (F) [gr.]          21
Lower Stem length (F) [cm]       22
Lower Stem width (F) [cm]        23
Num days to Heading (field) [days] 24
Num days to Maturity [days]      25
Num lateral roots [number]       26
Plant height growth [cm/day]     27
Plant height_1 [cm]              28
Plant height_2 [cm]              29
Plant height_3 [cm]              30
Plant height_4 [cm]              31
Plant num at harvest [number]    32
Plant weight growth [gr./day]    33
Root length [cm]                 34
SPAD (F) [SPAD unit]             35
SPAD_1 [SPAD unit]               36
SPAD_2 [SPAD unit]               37
Shoot DW_1 [gr.]                 38
Shoot DW_2 [gr.]                 39
Shoot DW_3 [gr.]                 40
Tillering_1 [number]             41
Tillering_2 [number]             42
Tillering_3 [number]             43
Upper Stem DW (F) [gr.]          44
Upper Stem FW (F) [gr.]          45
Upper Stem length (F) [cm]       46
Upper Stem width (F) [cm]        47
Vegetative DW (RP) [gr.]         48
Vegetative DW (SP) [gr.]         49
Vegetative DW per plant [gr.]    50
Vegetative FW (RP) [gr.]         51
Vegetative FW (SP) [gr.]         52

Table 191. Provided are the foxtail millet collected parameters under normal conditions. “num”=number; “gr.”=grams; “F”=flowering stage; “H”=harvest stage; “cm”=centimeter; “N”=nitrogen; “GF”=grain filling stage; “FW”=fresh weight, “DW”=dry weight: “num”=number; “NutE”=Nitrogen utilization efficiency; “NUE”=Nitrogen use efficiency; “NHI”=nitrogen harvest index; “NupE”=Nitrogen uptake efficiency; “SPAD”=chlorophyll levels; “Avr”=average; “RGR”=relative growth rate.

TABLE 192
Foxtail millet additional correlated parameters under
normal and low N conditions (vectors) - set 2
                          Correlation
Correlated parameter with ID
Grain N (H) [%]           1
Head C_vs._N (GF) [ratio] 2
Head N (GF) [%]           3
N harvest index [ratio]   4
NUE [ratio]               5
NUpE [ratio]              6
Shoot N (H) [%]           7
Total grain N (H) [mg]    8
Total shoot N (H) [mg]    9
Grain C_vs_N (H) [ratio]  10
Grain NUtE [ratio]        11
Shoot C_vs_N (H) [ratio]  12
Total NUtE [ratio]        13

Table 192. Provided are the foxtail millet collected parameters under normal conditions. “num”=number; “gr.”=grams; “mg”=milligram; “F”=flowering stage; “H”=harvest stage; “cm”=centimeter; “N”=nitrogen; “GF”=grain filling stage; “FW”=fresh weight, “DW”=dry weight; “num”=number; “NutE”=Nitrogen utilization efficiency; “NUE”=Nitrogen use efficiency; “NHI”=nitrogen harvest index; “NupE”=Nitrogen uptake efficiency; “SPAD”=chlorophyll levels; “vs.”=versus.

Experimental Results

Fourteen different foxtail millet accessions were grown and characterized for different parameters as described above. The average for each of the measured parameters was calculated using the JMP software and values are summarized in Tables 193-200 below. Subsequent correlation analysis between the various transcriptome sets and the average parameters was conducted (Tables 201-204). Follow, results were integrated to the database.

TABLE 193
Measured parameters of correlation IDs in foxtail millet accessions under
normal conditions (set 1 parameters)
	Line
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	3.478	2.197	2.486	2.626	2.662	2.664	2.175
2	0.722	0.675	0.685	0.687	0.719	0.723	0.581
3	0.0357	0.0295	0.0308	0.0315	0.0341	0.0339	0.0243
4	0.245	0.256	0.256	0.251	0.268	0.274	0.197
5	0.185	0.147	0.153	0.160	0.162	0.158	0.157
6	34.714	22.998	24.837	31.068	26.644	28.315	34.919
7	1086.0	679.2	727.6	797.6	792.4	856.8	902.8
8	1.799	1.115	1.074	1.344	1.320	1.114	1.364
9	0.245	0.171	0.177	0.271	0.209	0.227	0.282
10	7.2	94.0	87.6	295.4	114.0	122.4	29.8
11	1.306	0.865	0.888	1.069	1.022	0.984	1.103
12	0.181	0.104	0.117	0.245	0.213	0.227	0.222
13	41.780	29.325	30.259	41.568	34.377	32.516	41.812
14	4.067	5.333	4.133	5.067	5.000	4.267	3.667
15	NA	NA	NA	NA	NA	NA	NA
16	5.3	2.9	2.9	3.6	3.9	4.1	4.4
17	7.9	4.7	4.5	5.3	6.6	6.4	7.2
18	NA	NA	NA	27.698	28.019	28.345	28.233
19	30.179	NA	NA	NA	NA	NA	NA
20	0.708	NA	0.304	0.156	0.153	0.198	0.606
21	4.213	NA	1.427	0.685	0.640	0.643	2.495
22	8.350	NA	10.253	8.750	6.688	7.638	8.075
23	7.240	NA	4.157	3.120	3.334	3.179	5.573
24	54.0	63.4	59.4	39.6	46.0	40.8	50.0
25	NA	NA	NA	NA	75.0	75.0	NA
26	NA	NA	NA	NA	NA	NA	NA
27	2.097	1.419	1.321	2.098	1.934	2.445	1.845
28	3.717	2.917	3.250	3.550	3.450	3.683	2.917
29	NA	NA	NA	NA	NA	NA	NA
30	26.625	17.675	18.000	25.825	23.350	28.600	21.525
31	45.975	31.800	29.750	46.075	42.875	53.625	40.675
32	31.4	29.6	29.8	26.0	30.0	30.2	27.8
33	2.849	3.118	5.111	4.353	2.875	3.110	2.932
34	NA	NA	NA	NA	NA	NA	NA
35	60.823	NA	NA	54.677	49.935	57.472	58.590
36	NA	NA	NA	54.677	49.935	57.472	58.590
37	60.823	NA	NA	NA	NA	NA	NA
38	12.746	19.518	14.434	20.696	20.626	21.008	14.012
39	57.056	65.700	54.290	59.784	60.760	71.992	53.975
40	88.870	97.874	162.658	135.962	100.392	103.332	97.308
41	NA	NA	NA	NA	NA	NA	NA
42	1.063	21.150	16.750	34.300	17.150	10.850	3.286
43	1.400	10.300	7.600	10.700	6.400	9.200	2.222
44	0.806	NA	0.241	0.244	0.135	0.208	0.322
45	3.244	NA	0.482	0.670	0.434	0.503	1.279
46	33.667	NA	17.660	36.250	19.600	27.875	26.175
47	3.678	NA	1.776	1.513	1.593	1.499	2.553
48	1.059	1.557	1.166	0.668	0.668	0.712	0.866
49	0.126	0.231	0.206	0.108	0.112	0.128	0.158
50	33.349	52.770	41.100	25.796	22.521	23.543	31.899
51	3.186	3.853	2.777	1.979	2.152	1.574	2.188
52	0.445	0.568	0.528	0.389	0.267	0.374	NA

Table 193: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (L=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available

TABLE 194
Measured parameters of correlation IDs in additional foxtail millet accessions under
normal conditions (set 1 parameters)
	Line
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14
1	2.568	2.897	1.935	2.194	2.816	2.488	3.185
2	0.665	0.684	0.616	0.616	0.707	0.669	0.744
3	0.0295	0.0319	0.0263	0.0262	0.0338	0.0303	0.0372
4	0.242	0.230	0.212	0.221	0.259	0.241	0.272
5	0.156	0.177	0.158	0.151	0.166	0.161	0.174
6	26.396	48.351	22.349	9.376	31.527	30.097	29.978
7	803.6	1120.8	584.4	268.0	818.8	800.8	818.4
8	1.158	1.693	1.441	0.567	1.129	1.232	1.266
9	0.250	0.395	0.245	0.130	0.254	0.312	0.286
10	129.2	11.0	13.2	53.6	32.8	60.6	323.2
11	0.984	1.286	1.035	0.421	0.999	0.990	1.023
12	0.244	0.296	0.178	0.101	0.224	0.244	0.231
13	32.103	60.605	39.914	14.615	38.414	37.473	37.417
14	3.767	3.792	3.733	4.000	3.900	4.033	5.233
15	NA	NA	NA	NA	NA	NA	NA
16	4.1	3.9	4.4	3.3	3.3	3.8	3.7
17	7.0	6.7	5.9	4.8	5.2	5.2	9.3
18	27.962	NA	NA	NA	NA	NA	27.535
19	NA	30.921	NA	NA	NA	NA	NA
20	0.168	0.865	NA	NA	0.548	0.934	0.085
21	0.759	3.128	NA	NA	3.636	5.487	0.393
22	7.150	9.150	NA	NA	10.181	12.256	8.975
23	3.610	6.952	NA	NA	6.229	6.751	2.235
24	39.0	54.0	71.0	61.0	63.0	61.0	42.0
25	75.0	NA	98.0	109.0	98.0	98.0	NA
26	NA	NA	NA	NA	NA	NA	NA
27	2.560	1.905	0.966	1.161	1.348	1.499	2.119
28	3.630	4.117	2.467	3.100	3.583	3.433	3.633
29	NA	NA	NA	NA	NA	NA	NA
30	30.525	26.025	16.775	17.800	19.525	20.750	24.550
31	55.625	42.100	20.525	25.750	30.300	33.300	47.313
32	30.8	23.6	26.0	29.4	26.2	27.0	27.4
33	3.401	4.787	3.153	3.414	3.116	2.036	4.507
34	NA	NA	NA	NA	NA	NA	NA
35	55.397	55.038	NA	NA	NA	NA	55.900
36	55.397	NA	NA	NA	NA	NA	55.900
37	NA	55.038	NA	NA	NA	NA	NA
38	18.796	14.166	11.616	19.620	18.364	10.813	17.130
39	71.678	87.548	52.626	52.328	77.312	63.495	66.484
40	118.420	142.376	98.228	116.824	103.248	72.938	143.646
41	NA	NA	NA	NA	NA	NA	NA
42	11.810	2.200	3.000	9.500	6.800	4.450	39.100
43	4.667	2.700	3.500	6.500	5.800	6.800	16.700
44	0.532	0.411	NA	NA	0.373	0.767	0.083
45	0.928	1.491	NA	NA	0.683	0.890	0.213
46	38.738	24.471	NA	NA	21.925	16.469	21.900
47	1.900	3.191	NA	NA	1.921	2.695	0.966
48	0.584	0.976	1.909	2.798	1.343	1.535	0.883
49	0.116	0.182	0.340	0.566	0.288	0.442	0.175
50	18.926	41.958	73.707	101.164	51.448	57.703	35.066
51	1.679	2.420	5.516	5.171	3.339	3.632	2.047
52	0.367	0.580	0.971	1.100	0.715	1.044	0.442

Table 194: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (L=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available

TABLE 195
Additional measured parameters of correlation IDs in foxtail millet
accessions under normal conditions (set 2 parameters)
	Corr. ID
Line	1	2	3	4	5	6	7
Line-1	1.765	24.763	1.719	1.827	1.827	35.539	1.871
Line-2	2.364	19.628	2.213	1.210	1.210	32.850	1.525
Line-3	NA	NA	NA	1.307	1.307	NA	NA
Line-4	1.976	18.324	2.300	1.635	1.635	34.717	1.778
Line-5	2.071	21.671	1.967	1.402	1.402	31.398	1.989
Line-6	2.126	20.253	2.066	1.490	1.490	33.898	1.786
Line-7	2.127	16.983	2.445	1.838	1.838	41.822	1.625
Line-8	NA	NA	NA	1.389	1.389	NA	NA
Line-9	1.789	21.707	1.929	2.545	2.545	48.899	1.526
Line-10	3.052	24.075	1.808	1.176	1.176	40.598	1.210
Line-11	NA	NA	NA	0.493	0.493	0.000	NA
Line-12	1.851	19.823	2.165	1.659	1.659	34.037	1.225
Line-13	NA	NA	NA	1.584	1.584	NA	NA
Line-14	1.971	18.396	2.265	1.578	1.578	35.904	2.603

Table 195: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (L=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available

TABLE 196
Additional measured parameters of correlation IDs in
additional foxtail millet accessions under normal conditions
(set 2 parameters)
	Corr. ID
Line	8	9	10	11	12	13
Line-1	612.841	62.403	23.774	0.556	22.225	0.101
Line-2	543.686	80.468	17.992	0.286	27.621	0.121
Line-3	NA	NA	NA	NA	NA	NA
Line-4	613.745	45.876	21.319	0.677	23.037	0.086
Line-5	551.781	44.789	20.358	0.595	19.754	0.082
Line-6	602.010	42.048	19.684	0.673	19.987	0.081
Line-7	742.765	51.849	19.477	0.673	23.574	0.084
Line-8	NA	NA	NA	NA	NA	NA
Line-9	865.048	64.025	23.184	0.755	24.995	0.097
Line-10	682.138	89.217	13.645	0.251	31.679	0.125
Line-11	NA	NA	NA	NA	NA	NA
Line-12	583.649	63.049	22.670	0.500	30.770	0.128
Line-13	NA	NA	NA	NA	NA	NA
Line-14	590.902	91.268	21.513	0.328	15.642	0.095

Table 196: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (L=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available

TABLE 197
Measured parameters of correlation IDs in foxtail millet
accessions under low N conditions (set 1 parameters)
Corr.	Line
ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	3.706	2.375	2.523	2.725	2.782	2.824	2.297
2	0.728	0.678	0.690	0.698	0.718	0.728	0.577
3	0.0356	0.0299	0.0311	0.0324	0.0339	0.0343	0.0240
4	0.245	0.256	0.261	0.253	0.266	0.275	0.195
5	0.185	0.149	0.152	0.163	0.162	0.159	0.157
6	29.853	20.461	34.437	29.746	22.314	23.019	22.590
7	936.4	622.8	923.6	819.5	726.8	683.5	622.8
8	1.597	1.007	1.382	1.416	1.140	0.887	0.966
9	0.255	0.162	0.221	0.259	0.155	0.184	0.194
10	8.2	57.0	64.6	214.0	69.2	117.8	31.8
11	1.178	0.807	1.168	1.065	0.879	0.768	0.761
12	0.180	0.157	0.184	0.229	0.168	0.187	0.143
13	37.588	26.525	37.223	38.705	26.978	25.858	27.608
14	4.267	2.600	2.800	2.533	2.600	2.280	3.567
15	NA	NA	NA	NA	NA	NA	NA
16	5.90	3.45	3.20	3.50	3.95	4.15	4.90
17	6.50	3.65	3.15	3.90	3.75	5.05	6.15
18	NA	NA	NA	26.298	27.093	27.808	27.653
19	30.827	NA	NA	NA	NA	NA	NA
20	0.992	NA	0.296	0.180	0.143	0.247	0.553
21	3.569	NA	1.501	0.675	0.536	0.939	1.928
22	6.813	NA	10.456	8.338	6.763	7.463	6.438
23	6.851	NA	3.894	2.958	3.191	3.176	5.075
24	54.0	64.0	58.6	40.4	46.0	41.6	51.6
25	90.0	90.0	90.0	NA	75.0	NA	NA
26	NA	NA	NA	NA	NA	NA	NA
27	1.638	0.998	1.011	1.812	1.497	1.875	1.376
28	4.213	3.757	3.717	3.873	4.270	4.192	3.427
29	NA	NA	NA	NA	NA	NA	NA
30	22.500	13.975	16.200	23.925	20.950	25.050	17.775
31	37.075	24.125	23.545	40.300	34.325	41.906	31.375
32	31.4	31.0	28.6	27.5	32.4	30.0	28.2
33	2.207	3.424	3.313	2.207	2.825	3.793	1.746
34	NA	NA	NA	NA	NA	NA	NA
35	58.570	35.917	39.054	48.283	40.650	52.329	59.100
36	57.919	35.917	39.054	48.283	40.650	52.329	59.100
37	60.614	NA	NA	NA	NA	NA	NA
38	11.042	8.184	9.418	14.438	13.458	14.918	8.044
39	54.660	53.940	70.220	67.833	76.020	85.675	48.275
40	67.282	101.450	95.214	66.740	84.320	100.265	55.045
41	NA	NA	NA	NA	NA	NA	NA
42	1.1	11.0	12.4	22.6	14.0	10.6	1.6
43	1.300	9.100	8.250	17.000	8.100	12.250	2.200
44	0.749	NA	0.313	0.182	0.181	0.252	0.511
45	2.654	NA	0.589	0.543	0.485	0.548	1.565
46	29.075	NA	20.069	34.925	26.950	32.650	28.313
47	3.285	NA	1.709	1.335	1.526	1.536	2.581
48	0.965	1.108	1.143	0.594	0.506	0.578	0.560
49	0.125	0.161	0.183	0.111	0.080	0.115	0.108
50	30.745	35.916	36.871	21.658	15.539	19.349	20.205
51	3.033	2.548	2.862	2.219	1.966	1.208	1.369
52	0.390	0.364	0.437	0.380	0.186	0.321	NA

Table 197: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (L=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available.

TABLE 198
Measured parameters of correlation IDs in additional foxtail
millet accessions under low N conditions (set 1 parameters)
Corr.	Line
ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14
1	2.591	3.152	2.027	2.483	3.448	2.852	3.059
2	0.676	0.686	0.621	0.632	0.719	0.692	0.752
3	0.0303	0.0325	0.0257	0.0277	0.0353	0.0321	0.0373
4	0.246	0.228	0.212	0.227	0.260	0.249	0.276
5	0.157	0.182	0.157	0.155	0.173	0.164	0.173
6	20.658	37.088	25.387	20.968	33.964	34.850	26.215
7	636.5	944.0	693.6	644.8	866.4	896.0	662.5
8	0.980	1.520	1.475	0.992	1.151	1.276	0.985
9	0.172	0.313	0.279	0.146	0.271	0.303	0.226
10	99.2	7.0	14.6	30.8	28.8	68.2	215.3
11	0.781	1.144	1.067	0.805	1.013	1.087	0.824
12	0.177	0.242	0.207	0.121	0.241	0.263	0.169
13	25.301	45.060	39.256	26.079	39.719	42.378	32.667
14	3.000	3.400	3.833	2.900	3.067	3.367	3.200
15	NA	NA	NA	NA	NA	NA	NA
16	5.00	3.95	4.45	3.55	3.75	3.80	3.35
17	5.20	4.75	5.15	3.20	3.65	4.30	3.30
18	27.922	NA	NA	NA	NA	NA	27.175
19	NA	30.606	NA	NA	NA	NA	NA
20	0.162	0.955	NA	NA	0.476	0.935	0.079
21	0.538	2.975	NA	NA	3.934	4.391	0.303
22	7.163	8.500	NA	NA	9.944	11.844	8.671
23	3.111	6.431	NA	NA	6.516	6.079	2.133
24	39.0	55.4	72.4	61.0	62.2	62.4	42.8
25	75.0	90.0	98.0	109.0	98.0	98.0	NA
26	NA	NA	NA	NA	NA	NA	NA
27	2.104	1.468	0.839	0.831	1.103	1.178	1.252
28	3.723	4.663	3.107	3.567	4.007	3.753	3.480
29	NA	NA	NA	NA	NA	NA	NA
30	24.188	20.656	15.063	14.025	17.675	17.450	19.175
31	47.500	32.750	18.225	19.800	25.625	27.175	27.950
32	30.8	25.2	27.6	30.6	26.8	26.6	25.5
33	2.181	2.521	2.712	2.375	2.632	4.087	3.436
34	NA	NA	NA	NA	NA	NA	NA
35	52.853	52.217	43.756	36.613	38.742	46.165	45.377
36	52.853	52.323	43.756	36.613	38.742	46.165	45.377
37	NA	52.495	NA	NA	NA	NA	NA
38	12.852	7.882	5.622	9.900	8.688	7.605	12.704
39	64.020	54.780	47.975	34.775	40.275	61.960	92.375
40	65.934	74.170	69.474	76.900	81.097	118.808	94.587
41	NA	NA	NA	NA	NA	NA	NA
42	8.5	1.2	2.2	7.8	4.9	7.6	27.0
43	5.400	1.900	3.300	6.111	4.000	8.600	20.625
44	0.339	0.505	NA	NA	0.683	0.756	0.088
45	0.715	1.525	NA	NA	0.898	1.343	0.204
46	38.638	22.288	NA	NA	27.169	18.073	26.913
47	1.715	2.823	NA	NA	1.999	2.569	0.896
48	0.470	0.737	1.742	2.394	1.172	1.533	0.739
49	0.078	0.132	0.326	0.349	0.283	0.384	0.127
50	15.385	29.062	59.541	76.549	45.176	59.121	28.725
51	1.346	1.987	4.548	4.367	2.751	2.670	1.435
52	0.243	0.426	0.869	0.635	0.647	0.799	0.326

Table 198: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (L=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available

TABLE 199
Measured parameters of correlation IDs in foxtail millet
accessions under low N conditions( set 2 parameters)
	Corr. ID
Line	1	2	3	4	5	6	7
Line-1	NA	NA	NA	NA	29.853	NA	NA
Line-2	2.030	59.677	1.974	0.894	20.461	464.773	1.377
Line-3	1.861	23.324	1.840	0.931	34.437	688.197	1.281
Line-4	1.599	35.999	1.198	0.922	29.746	516.068	1.864
Line-5	1.586	25.739	1.638	0.931	22.314	380.021	1.683
Line-6	1.971	33.810	1.229	0.936	23.019	484.900	1.609
Line-7	NA	NA	NA	NA	22.590	NA	NA
Line-8	2.260	22.593	1.910	0.946	20.658	493.501	1.733
Line-9	1.429	22.112	1.920	0.925	37.088	572.757	1.474
Line-10	1.759	25.388	1.711	0.862	25.387	517.928	1.200
Line-11	NA	NA	NA	NA	20.968	0.000	NA
Line-12	1.809	20.586	2.096	0.929	33.964	661.856	1.047
Line-13	NA	NA	NA	NA	34.850	NA	NA
Line-14	1.941	19.832	2.127	0.900	26.215	565.170	1.963

Table 199: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (L=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available

TABLE 200
Measured parameters of correlation IDs in additional foxtail
millet accessions under low N conditions (set 2 parameters)
	Corr. ID
Line	8	9	10	11	12	13
Line-1	NA	NA	NA	NA	NA	NA
Line-2	415.320	49.453	20.741	0.414	28.238	0.121
Line-3	640.958	47.239	22.651	0.729	29.551	0.104
Line-4	475.705	40.363	25.730	0.737	20.639	0.100
Line-5	353.866	26.155	26.368	0.853	22.450	0.100
Line-6	453.769	31.131	21.260	0.739	20.204	0.087
Line-7	NA	NA	NA	NA	NA	NA
Line-8	466.836	26.665	18.842	0.775	22.138	0.073
Line-9	529.913	42.844	28.928	0.866	25.048	0.115
Line-10	446.456	71.472	23.919	0.355	31.807	0.164
Line-11	NA	NA	NA	NA	NA	NA
Line-12	614.571	47.285	23.217	0.718	35.765	0.120
Line-13	NA	NA	NA	NA	NA	NA
Line-14	508.793	56.377	21.670	0.465	20.076	0.097

Table 200: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (L=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available

TABLE 201
Correlation between the expression level of selected genes of some embodiments of
the invention in various tissues and the phenotypic performance under normal
conditions across Foxtail millet varieties (set 1)
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY3	0.84	3.73E−02	8	48	LBY3	0.75	8.91E−02	8	51
LBY3	0.78	7.00E−02	8	50	LBY3	0.80	5.75E−02	8	24
LBY3	0.73	1.73E−02	3	48	LBY3	0.77	9.58E−03	3	24
LBY3	0.82	2.33E−02	5	47	LBY3	0.71	7.23E−02	5	45
LBY3	0.84	8.92E−03	11	23	LBY3	0.78	2.28E−02	11	47
LBY3	0.79	6.88E−03	11	6	LBY3	0.90	2.37E−03	11	20
LBY3	0.72	1.83E−02	11	7	LBY3	0.79	1.95E−02	11	21
LBY3	0.72	1.96E−02	1	49	LBY3	0.74	3.77E−02	12	21
LBY55	0.73	9.96E−02	8	8	LBY55	0.73	2.42E−02	4	11
LBY55	0.73	2.68E−02	4	8	LBY55	0.82	7.35E−03	4	5
LBY55	0.72	1.93E−02	3	27	LBY55	0.97	4.76E−06	3	16
LBY55	0.77	4.41E−02	3	35	LBY55	0.72	2.00E−02	3	31
LBY55	0.78	7.24E−03	3	17	LBY55	0.71	3.28E−02	2	9
LBY55	0.91	4.85E−03	2	23	LBY55	0.91	4.07E−03	2	47
LBY55	0.77	1.53E−02	2	6	LBY55	0.91	7.45E−04	2	11
LBY55	0.85	3.49E−03	2	13	LBY55	0.92	5.08E−04	2	8
LBY55	0.76	4.63E−02	2	45	LBY55	0.90	6.21E−03	2	20
LBY55	0.73	2.62E−02	2	7	LBY55	0.81	2.66E−02	2	21
LBY55	0.90	9.19E−04	2	5	LBY55	0.72	6.67E−02	5	23
LBY55	0.81	2.59E−02	5	47	LBY55	0.70	7.82E−02	5	45
LBY55	0.71	7.21E−02	5	20	LBY55	0.71	2.18E−02	11	13
LBY55	0.88	6.75E−04	1	9	LBY55	0.92	1.74E−04	1	6
LBY55	0.76	1.06E−02	1	11	LBY55	0.94	3.96E−05	1	13
LBY55	0.74	2.29E−02	1	20	LBY55	0.74	1.42E−02	1	7
LBY55	0.71	2.14E−02	12	9	LBY56	0.72	1.03E−01	8	3
LBY56	0.70	7.84E−02	2	22	LBY57	0.86	3.10E−03	2	4
LBY57	0.77	1.46E−02	2	3	LBY57	0.82	6.39E−03	2	2
LBY57	0.78	7.47E−03	1	43	LBY57	0.75	1.16E−02	1	14
LBY57	0.71	2.02E−02	1	10	LBY57	0.79	7.08E−03	1	4
LBY57	0.77	9.58E−03	1	42	LBY57	0.74	2.21E−02	9	52
LBY58	0.72	2.87E−02	9	43	LBY58	0.74	2.31E−02	9	3
LBY58	0.74	2.38E−02	9	17	LBY58	0.71	3.05E−02	9	2
LBY58	0.71	7.29E−02	12	35	LBY59	0.76	1.76E−02	4	4
LBY59	0.78	1.27E−02	4	38	LBY59	0.75	1.24E−02	3	9
LBY59	0.79	6.15E−03	3	12	LBY59	0.88	1.93E−03	2	9
LBY59	0.85	3.59E−03	2	6	LBY59	0.76	1.65E−02	2	11
LBY59	0.88	1.69E−03	2	13	LBY59	0.71	3.28E−02	2	28
LBY59	0.72	2.93E−02	2	12	LBY59	0.75	2.11E−02	2	7
LBY59	0.71	3.33E−02	2	5	LBY59	0.80	3.23E−02	5	47
LBY59	0.77	9.22E−03	11	9	LBY59	0.81	1.55E−02	11	23
LBY59	0.75	3.10E−02	11	47	LBY59	0.94	4.06E−05	11	6
LBY59	0.85	2.05E−03	11	11	LBY59	0.85	1.96E−03	11	13
LBY59	0.71	2.12E−02	11	8	LBY59	0.89	2.83E−03	11	20
LBY59	0.91	2.83E−04	11	7	LBY59	0.76	2.99E−02	11	21
LBY59	0.71	2.05E−02	11	5	LBY59	0.74	5.97E−02	1	35
LBY59	0.71	2.25E−02	1	24	LBY59	0.72	2.84E−02	1	22
LBY59	0.83	2.19E−02	9	44	LBY59	0.93	2.79E−03	9	23
LBY59	0.70	7.94E−02	9	47	LBY59	0.90	8.22E−04	9	48
LBY59	0.89	1.14E−03	9	51	LBY59	0.91	7.74E−04	9	50
LBY59	0.90	9.10E−04	9	24	LBY59	0.87	1.08E−02	9	22
LBY59	0.87	1.12E−02	9	20	LBY59	0.84	4.16E−03	9	49
LBY59	0.88	1.59E−03	9	52	LBY59	0.98	1.71E−04	9	21
LBY59	0.79	7.13E−03	12	48	LBY59	0.83	3.15E−03	12	50
LBY59	0.76	1.01E−02	12	24	LBY59	0.71	4.66E−02	12	22
LBY59	0.82	3.55E−03	12	49	LBY59	0.87	2.08E−03	12	52
LBY61	0.71	1.13E−01	8	14	LBY61	0.76	8.09E−02	8	4
LBY61	0.72	1.05E−01	8	2	LBY61	0.74	2.15E−02	4	48
LBY61	0.76	1.63E−02	4	50	LBY61	0.74	5.52E−02	4	22
LBY61	0.88	1.63E−03	4	49	LBY61	0.76	1.72E−02	4	52
LBY61	0.95	9.10E−05	5	43	LBY61	0.77	1.59E−02	5	10
LBY61	0.87	2.40E−03	5	4	LBY61	0.76	1.73E−02	5	2
LBY61	0.76	1.70E−02	5	42	LBY61	0.74	2.22E−02	1	44
LBY61	0.77	1.43E−02	1	46	LBY61	0.81	7.96E−03	9	43
LBY61	0.75	1.89E−02	12	52	LBY62	0.81	4.83E−02	8	16
LBY62	0.89	1.64E−02	8	17	LBY62	0.80	9.44E−03	2	27
LBY62	0.79	1.07E−02	2	31	LBY62	0.89	1.31E−03	2	17
LBY62	0.91	4.15E−03	2	46	LBY62	0.79	1.09E−02	2	30
LBY62	0.71	3.17E−02	5	14	LBY62	0.74	2.35E−02	5	38
LBY62	0.82	6.65E−03	9	9	LBY62	0.80	9.39E−03	9	6
LBY62	0.81	7.64E−03	9	11	LBY62	0.80	9.08E−03	9	13
LBY62	0.71	7.50E−02	9	45	LBY62	0.73	6.48E−02	9	46
LBY62	0.74	2.39E−02	9	30	LBY62	0.76	1.65E−02	9	12
LBY62	0.72	2.89E−02	9	7	LBY62	0.79	6.02E−03	12	27
LBY62	0.78	7.72E−03	12	31	LBY62	0.82	3.35E−03	12	30
LBY63	0.83	3.28E−03	3	43	LBY63	0.88	8.69E−04	3	10
LBY63	0.84	2.23E−03	3	42	LBY63	0.96	4.26E−05	2	27
LBY63	0.95	9.51E−05	2	31	LBY63	0.72	2.85E−02	2	17
LBY63	0.92	3.28E−03	2	46	LBY63	0.94	1.50E−04	2	30
LBY63	0.71	2.05E−02	11	43	LBY63	0.74	1.51E−02	11	10
LBY63	0.73	1.69E−02	11	40	LBY63	0.97	6.14E−06	12	43
LBY63	0.82	3.88E−03	12	14	LBY63	0.88	8.45E−04	12	10
LBY63	0.76	1.06E−02	12	4	LBY63	0.93	1.07E−04	12	42
LBY64	0.79	6.17E−02	8	32	LBY64	0.74	9.41E−02	8	39
LBY64	0.74	2.37E−02	2	50	LBY64	0.75	1.92E−02	2	24
LBY64	0.77	4.39E−02	2	22	LBY64	0.80	1.76E−02	11	23
LBY64	0.74	3.61E−02	11	47	LBY64	0.92	1.88E−04	11	48
LBY64	0.92	1.68E−04	11	51	LBY64	0.92	1.59E−04	11	50
LBY64	0.93	1.16E−04	11	24	LBY64	0.81	1.51E−02	11	22
LBY64	0.79	2.03E−02	11	20	LBY64	0.84	2.15E−03	11	49
LBY64	0.92	5.13E−04	11	52	LBY64	0.85	8.20E−03	11	21
LBY64	0.79	6.68E−03	1	48	LBY64	0.73	6.24E−02	1	35
LBY64	0.76	1.10E−02	1	51	LBY64	0.76	1.07E−02	1	50
LBY64	0.80	4.99E−03	1	24	LBY64	0.90	8.35E−04	1	22
LBY64	0.71	2.13E−02	1	49	LBY64	0.77	1.45E−02	1	52
LBY64	0.87	1.05E−03	12	12	LBY65	0.74	9.52E−02	8	17
LBY65	0.75	2.03E−02	4	17	LBY65	0.73	1.57E−02	3	27
LBY65	0.82	3.91E−03	3	16	LBY65	0.73	1.59E−02	3	31
LBY65	0.80	5.03E−03	3	28	LBY65	0.74	1.35E−02	3	17
LBY65	0.75	1.25E−02	3	30	LBY65	0.75	1.20E−02	3	39
LBY65	0.73	1.65E−02	3	12	LBY65	0.71	3.20E−02	2	51
LBY65	0.78	3.94E−02	5	23	LBY65	0.73	6.46E−02	5	47
LBY65	0.71	7.61E−02	5	21	LBY65	0.80	5.88E−03	11	9
LBY65	0.90	2.36E−03	11	23	LBY65	0.86	5.75E−03	11	47
LBY65	0.74	1.35E−02	11	6	LBY65	0.74	1.47E−02	11	11
LBY65	0.85	1.73E−03	11	13	LBY65	0.79	6.21E−03	11	8
LBY65	0.90	2.38E−03	11	20	LBY65	0.80	5.05E−03	11	12
LBY65	0.84	8.98E−03	11	21	LBY65	0.87	1.21E−03	1	48
LBY65	0.79	3.62E−02	1	35	LBY65	0.83	3.16E−03	1	51
LBY65	0.81	4.37E−03	1	50	LBY65	0.86	1.37E−03	1	24
LBY65	0.76	1.87E−02	1	22	LBY65	0.71	2.15E−02	1	49
LBY65	0.79	1.07E−02	1	52	LBY65	0.81	7.55E−03	9	32
LBY65	0.77	8.85E−03	12	50	LBY65	0.73	1.64E−02	12	24
LBY65	0.72	4.26E−02	12	22	LBY65	0.83	3.08E−03	12	49
LBY65	0.88	1.71E−03	12	52	LBY66	0.83	2.77E−03	3	43
LBY66	0.75	1.31E−02	3	10	LBY66	0.84	2.12E−03	3	42
LBY66	0.78	1.23E−02	2	27	LBY66	0.78	1.32E−02	2	31
LBY66	0.73	2.62E−02	2	10	LBY66	0.72	2.99E−02	2	30
LBY66	0.78	7.27E−03	12	43	LBY66	0.73	1.56E−02	12	42
LBY67	0.79	5.99E−02	8	9	LBY67	0.73	1.01E−01	8	6
LBY67	0.80	5.62E−02	8	11	LBY67	0.91	1.08E−02	8	13
LBY67	0.91	1.10E−02	8	8	LBY67	0.83	4.23E−02	8	5
LBY67	0.87	1.14E−02	4	44	LBY67	0.78	3.91E−02	4	23
LBY67	0.73	6.42E−02	4	47	LBY67	0.85	3.27E−02	4	35
LBY67	0.80	2.94E−02	4	45	LBY67	0.72	6.75E−02	4	20
LBY67	0.72	3.00E−02	4	32	LBY67	0.87	1.07E−02	4	21
LBY67	0.83	3.14E−03	3	43	LBY67	0.71	2.21E−02	3	10
LBY67	0.86	1.54E−03	3	4	LBY67	0.72	1.99E−02	3	38
LBY67	0.78	7.47E−03	3	2	LBY67	0.71	2.07E−02	3	42
LBY67	0.72	2.90E−02	2	1	LBY67	0.86	1.32E−02	2	44
LBY67	0.71	7.51E−02	2	47	LBY67	0.74	2.33E−02	2	27
LBY67	0.86	2.83E−03	2	48	LBY67	0.73	2.47E−02	2	16
LBY67	0.78	1.40E−02	2	51	LBY67	0.73	2.49E−02	2	31
LBY67	0.72	2.77E−02	2	10	LBY67	0.93	3.14E−04	2	50
LBY67	0.88	1.60E−03	2	24	LBY67	0.83	5.81E−03	2	4
LBY67	0.92	3.58E−03	2	45	LBY67	0.72	2.84E−02	2	17
LBY67	0.85	1.51E−02	2	22	LBY67	0.73	2.70E−02	2	2
LBY67	0.72	2.78E−02	2	30	LBY67	0.91	6.89E−04	2	49
LBY67	0.87	4.79E−03	2	52	LBY67	0.77	4.30E−02	5	46
LBY67	0.80	9.60E−03	5	30	LBY67	0.79	7.05E−03	11	9
LBY67	0.74	1.44E−02	11	6	LBY67	0.82	3.74E−03	11	13
LBY67	0.77	1.62E−02	1	22	LBY67	0.80	1.02E−02	9	16
LBY67	0.78	8.29E−03	12	50	LBY67	0.82	1.24E−02	12	22
LBY67	0.77	9.80E−03	12	49	LBY67	0.70	2.28E−02	12	39
LBY67	0.81	7.58E−03	12	52	LBY68	0.70	7.69E−02	4	21
LBY68	0.89	1.20E−03	3	23	LBY68	0.76	1.80E−02	3	47
LBY68	0.76	1.10E−02	3	48	LBY68	0.74	1.36E−02	3	51
LBY68	0.75	1.29E−02	3	50	LBY68	0.84	2.19E−03	3	24
LBY68	0.80	1.02E−02	3	22	LBY68	0.88	1.79E−03	3	20
LBY68	0.83	5.22E−03	3	52	LBY68	0.83	5.77E−03	3	21
LBY68	0.77	4.13E−02	2	22	LBY68	0.78	3.79E−02	5	44
LBY68	0.91	4.32E−03	5	23	LBY68	0.80	2.94E−02	5	47
LBY68	0.72	6.76E−02	5	45	LBY68	0.78	3.65E−02	5	22
LBY68	0.89	8.00E−03	5	20	LBY68	0.90	6.38E−03	5	21
LBY68	0.97	3.84E−04	9	44	LBY68	0.95	1.05E−03	9	23
LBY68	0.93	2.06E−03	9	47	LBY68	0.71	3.26E−02	9	13
LBY68	0.91	4.54E−03	9	45	LBY68	0.97	4.03E−04	9	20
LBY68	0.87	1.06E−02	9	21	LBY68	0.72	1.99E−02	12	48
LBY68	0.70	2.31E−02	12	51	LBY68	0.74	1.43E−02	12	50
LBY68	0.76	1.09E−02	12	24	LBY68	0.78	7.36E−03	12	49
LBY68	0.84	4.97E−03	12	52	LBY69	0.70	1.19E−01	8	9
LBY69	0.72	1.05E−01	8	11	LBY69	0.72	1.07E−01	8	16
LBY69	0.84	3.86E−02	8	8	LBY69	0.72	2.74E−02	4	9
LBY69	0.88	1.81E−03	4	27	LBY69	0.75	2.07E−02	4	11
LBY69	0.81	8.13E−03	4	33	LBY69	0.87	2.28E−03	4	31
LBY69	0.83	6.04E−03	4	40	LBY69	0.73	2.42E−02	4	8
LBY69	0.71	3.23E−02	4	28	LBY69	0.78	1.33E−02	4	17
LBY69	0.91	7.07E−04	4	30	LBY69	0.86	3.20E−03	4	5
LBY69	0.86	1.60E−03	3	27	LBY69	0.85	1.64E−03	3	31
LBY69	0.80	5.33E−03	3	30	LBY69	0.72	1.97E−02	3	12
LBY69	0.85	3.86E−03	2	9	LBY69	0.75	5.23E−02	2	23
LBY69	0.90	5.30E−03	2	47	LBY69	0.93	2.29E−04	2	6
LBY69	0.84	4.14E−03	2	27	LBY69	0.93	3.41E−04	2	11
LBY69	0.92	3.77E−04	2	13	LBY69	0.78	1.33E−02	2	16
LBY69	0.83	5.48E−03	2	31	LBY69	0.95	1.10E−04	2	8
LBY69	0.71	7.41E−02	2	45	LBY69	0.86	2.82E−03	2	17
LBY69	0.81	2.67E−02	2	46	LBY69	0.85	1.58E−02	2	20
LBY69	0.92	4.79E−04	2	30	LBY69	0.84	4.72E−03	2	12
LBY69	0.83	5.50E−03	2	7	LBY69	0.78	1.23E−02	2	5
LBY69	0.76	1.74E−02	5	9	LBY69	0.81	2.58E−02	5	23
LBY69	0.80	1.01E−02	5	11	LBY69	0.75	1.94E−02	5	13
LBY69	0.73	2.57E−02	5	51	LBY69	0.86	2.64E−03	5	8
LBY69	0.70	3.51E−02	5	50	LBY69	0.78	1.41E−02	5	24
LBY69	0.76	4.64E−02	5	20	LBY69	0.76	1.73E−02	5	49
LBY69	0.74	2.18E−02	5	52	LBY69	0.81	2.88E−02	5	21
LBY69	0.75	2.10E−02	5	5	LBY69	0.90	3.86E−04	11	9
LBY69	0.87	1.16E−03	11	6	LBY69	0.81	4.52E−03	11	11
LBY69	0.96	6.44E−06	11	13	LBY69	0.79	6.49E−03	11	8
LBY69	0.77	2.67E−02	11	46	LBY69	0.71	4.94E−02	11	20
LBY69	0.71	2.13E−02	11	5	LBY69	0.79	6.03E−03	1	9
LBY69	0.71	2.27E−02	1	6	LBY69	0.71	2.05E−02	1	11
LBY69	0.77	8.71E−03	1	13	LBY69	0.87	9.51E−04	1	16
LBY69	0.81	8.59E−03	1	45	LBY69	0.83	5.26E−03	9	9
LBY69	0.74	2.24E−02	9	6	LBY69	0.70	3.57E−02	9	48
LBY69	0.84	4.35E−03	9	11	LBY69	0.80	9.94E−03	9	13
LBY69	0.84	4.67E−03	9	8	LBY69	0.72	2.85E−02	9	50
LBY69	0.86	1.33E−02	9	22	LBY69	0.72	2.82E−02	9	12
LBY69	0.76	1.81E−02	9	52	LBY69	0.78	1.41E−02	9	5
LBY69	0.76	1.10E−02	12	9	LBY69	0.72	1.83E−02	12	33
LBY69	0.71	2.19E−02	12	40	LBY69	0.75	1.31E−02	12	17
LBY69	0.72	1.96E−02	12	5	LBY70	0.85	3.02E−02	8	33
LBY70	0.87	2.39E−02	8	10	LBY70	0.79	6.29E−02	8	40
LBY70	0.80	5.80E−02	4	35	LBY70	0.78	3.68E−02	4	22
LBY70	0.71	2.18E−02	3	27	LBY70	0.71	2.04E−02	3	31
LBY70	0.91	5.68E−04	5	43	LBY70	0.72	2.79E−02	5	27
LBY70	0.72	2.77E−02	5	31	LBY70	0.84	4.47E−03	5	10
LBY70	0.76	1.75E−02	5	42	LBY70	0.72	1.80E−02	11	3
LBY70	0.78	7.88E−03	1	48	LBY70	0.77	9.11E−03	1	51
LBY70	0.71	2.28E−02	1	50	LBY70	0.85	1.86E−03	1	24
LBY70	0.78	1.22E−02	1	22	LBY70	0.84	4.91E−03	9	43
LBY70	0.71	3.09E−02	9	14	LBY70	0.83	5.74E−03	9	10
LBY70	0.87	2.53E−03	9	42	LBY71	0.80	3.15E−02	4	22
LBY71	0.76	1.15E−02	3	38	LBY71	0.72	6.69E−02	2	22
LBY71	0.80	2.90E−02	5	23	LBY71	0.80	9.52E−03	5	24
LBY71	0.77	4.21E−02	5	21	LBY71	0.80	5.86E−03	11	48
LBY71	0.77	9.35E−03	11	51	LBY71	0.77	8.69E−03	11	50
LBY71	0.81	4.45E−03	11	24	LBY71	0.82	3.59E−03	11	49
LBY71	0.83	5.19E−03	11	52	LBY71	0.78	3.73E−02	1	35
LBY71	0.77	9.76E−03	1	24	LBY71	0.81	8.76E−03	1	22
LBY71	0.71	2.07E−02	1	49	LBY71	0.76	1.71E−02	9	48
LBY71	0.84	4.74E−03	9	51	LBY71	0.73	2.61E−02	9	50
LBY71	0.89	1.15E−03	9	24	LBY71	0.72	2.77E−02	9	49
LBY71	0.76	1.05E−02	12	33	LBY72	0.71	1.15E−01	8	3
LBY72	0.85	3.94E−03	4	17	LBY72	0.77	8.67E−03	3	27
LBY72	0.78	8.28E−03	3	31	LBY72	0.77	2.66E−02	2	52
LBY72	0.71	3.25E−02	5	16	LBY72	0.79	3.33E−02	5	46
LBY72	0.76	1.80E−02	1	23	LBY72	0.82	7.28E−03	1	47
LBY72	0.73	1.63E−02	1	8	LBY72	0.78	1.37E−02	1	45
LBY72	0.79	1.06E−02	1	22	LBY72	0.70	3.41E−02	1	20
LBY72	0.73	2.65E−02	1	21	LBY72	0.75	1.93E−02	9	9
LBY72	0.74	2.37E−02	9	14	LBY72	0.77	4.37E−02	9	46
LBY72	0.71	3.18E−02	9	12	LBY72	0.73	1.67E−02	12	43
LBY72	0.74	1.54E−02	12	14	LBY72	0.87	1.07E−03	12	10
LBY72	0.73	1.59E−02	12	4	LBY72	0.73	1.65E−02	12	3
LBY72	0.74	1.48E−02	12	2	LBY72	0.85	2.07E−03	12	42
LBY73	0.74	2.31E−02	4	6	LBY73	0.73	2.43E−02	4	13
LBY73	0.76	1.68E−02	4	12	LBY73	0.73	2.58E−02	1	44
LBY73	0.78	3.82E−02	9	46	LBY74	0.84	3.58E−02	8	16
LBY74	0.71	1.18E−01	8	8	LBY74	0.74	5.51E−02	4	44
LBY74	0.78	3.77E−02	4	23	LBY74	0.84	1.94E−02	4	21
LBY74	0.73	1.59E−02	11	48	LBY74	0.74	1.49E−02	11	51
LBY74	0.76	1.06E−02	11	50	LBY74	0.82	3.50E−03	11	49
LBY74	0.86	3.19E−03	11	52	LBY74	0.72	1.84E−02	1	30
LBY74	0.82	2.28E−02	9	46	LBY74	0.80	9.62E−03	12	52
LBY75	0.82	4.41E−02	8	32	LBY75	0.79	6.40E−02	8	39
LBY75	0.75	1.20E−02	3	48	LBY75	0.71	2.10E−02	3	31
LBY75	0.70	2.40E−02	3	10	LBY75	0.80	4.96E−03	3	50
LBY75	0.85	1.66E−03	3	17	LBY75	0.74	2.36E−02	3	22
LBY75	0.80	5.52E−03	3	49	LBY75	0.70	3.54E−02	3	52
LBY75	0.77	4.27E−02	2	44	LBY75	0.87	1.01E−02	2	47
LBY75	0.75	2.07E−02	2	48	LBY75	0.77	1.55E−02	2	51
LBY75	0.74	2.16E−02	2	50	LBY75	0.75	2.02E−02	2	24
LBY75	0.89	6.94E−03	2	45	LBY75	0.76	1.67E−02	2	49
LBY75	0.74	3.57E−02	2	52	LBY75	0.74	5.48E−02	2	21
LBY75	0.85	1.55E−02	5	23	LBY75	0.86	1.24E−02	5	47
LBY75	0.77	1.49E−02	5	48	LBY75	0.75	2.12E−02	5	51
LBY75	0.74	2.30E−02	5	50	LBY75	0.89	1.45E−03	5	24
LBY75	0.73	6.52E−02	5	45	LBY75	0.84	1.69E−02	5	20
LBY75	0.83	2.13E−02	5	21	LBY75	0.79	6.86E−03	11	48
LBY75	0.75	1.18E−02	11	51	LBY75	0.72	1.86E−02	11	50
LBY75	0.87	1.08E−03	11	24	LBY75	0.88	8.07E−04	1	48
LBY75	0.80	5.97E−03	1	51	LBY75	0.84	2.29E−03	1	50
LBY75	0.83	2.68E−03	1	24	LBY75	0.86	3.10E−03	1	22
LBY75	0.89	6.43E−04	1	49	LBY75	0.87	2.26E−03	1	52
LBY75	0.75	1.21E−02	12	48	LBY75	0.77	9.16E−03	12	50
LBY75	0.91	1.79E−03	12	22	LBY75	0.79	6.42E−03	12	49
LBY75	0.71	3.10E−02	12	52	LBY76	0.89	1.67E−02	8	43
LBY76	0.73	9.68E−02	8	14	LBY76	0.72	1.03E−01	8	33
LBY76	0.88	2.05E−02	8	10	LBY76	0.74	9.54E−02	8	38
LBY76	0.87	2.39E−02	8	42	LBY76	0.72	6.91E−02	4	23
LBY76	0.77	4.32E−02	4	47	LBY76	0.94	1.97E−04	4	48
LBY76	0.94	1.97E−04	4	51	LBY76	0.90	1.04E−03	4	50
LBY76	0.88	1.57E−03	4	24	LBY76	0.80	2.94E−02	4	20
LBY76	0.78	1.32E−02	4	49	LBY76	0.77	1.47E−02	4	52
LBY76	0.75	5.11E−02	4	21	LBY76	0.72	2.90E−02	2	9
LBY76	0.81	8.22E−03	2	6	LBY76	0.74	2.23E−02	2	50
LBY76	0.75	4.99E−02	2	20	LBY76	0.89	3.24E−03	2	52
LBY76	0.82	6.30E−03	5	27	LBY76	0.82	6.36E−03	5	31
LBY76	0.71	3.14E−02	5	4	LBY76	0.84	4.46E−03	5	38
LBY76	0.72	6.92E−02	5	46	LBY76	0.74	2.14E−02	5	30
LBY76	0.74	1.46E−02	11	6	LBY76	0.76	1.00E−02	11	48
LBY76	0.75	1.27E−02	11	13	LBY76	0.76	1.07E−02	11	50
LBY76	0.82	3.55E−03	11	24	LBY76	0.85	7.49E−03	11	22
LBY76	0.77	9.67E−03	11	49	LBY76	0.74	2.22E−02	11	52
LBY76	0.82	6.76E−03	1	44	LBY76	0.81	8.52E−03	1	23
LBY76	0.88	1.77E−03	1	47	LBY76	0.87	1.14E−03	1	6
LBY76	0.75	1.16E−02	1	11	LBY76	0.78	7.80E−03	1	13
LBY76	0.81	4.50E−03	1	8	LBY76	0.89	1.12E−03	1	45
LBY76	0.81	8.64E−03	1	20	LBY76	0.72	1.92E−02	1	7
LBY76	0.80	1.04E−02	1	21	LBY76	0.71	7.37E−02	9	46
LBY76	0.75	3.35E−02	12	23	LBY76	0.83	3.29E−03	12	6
LBY76	0.84	9.60E−03	12	20	LBY76	0.71	3.14E−02	12	52
LBY77	0.74	1.52E−02	3	17	LBY77	0.77	1.53E−02	2	9
LBY77	0.75	2.11E−02	2	6	LBY77	0.74	2.38E−02	2	11
LBY77	0.75	2.00E−02	2	13	LBY77	0.71	3.27E−02	2	7
LBY77	0.71	3.20E−02	5	51	LBY77	0.92	1.35E−04	11	48
LBY77	0.85	1.82E−03	11	51	LBY77	0.93	1.19E−04	11	50
LBY77	0.84	2.58E−03	11	24	LBY77	0.90	2.13E−03	11	22
LBY77	0.92	1.31E−04	11	49	LBY77	0.88	1.68E−03	11	52
LBY77	0.91	2.62E−04	1	48	LBY77	0.78	3.67E−02	1	35
LBY77	0.86	1.47E−03	1	51	LBY77	0.89	5.99E−04	1	50
LBY77	0.88	7.44E−04	1	24	LBY77	0.83	5.50E−03	1	22
LBY77	0.94	3.89E−05	1	49	LBY77	0.92	5.06E−04	1	52
LBY78	0.74	2.23E−02	4	17	LBY78	0.71	3.06E−02	4	49
LBY78	0.81	4.61E−03	3	27	LBY78	0.81	4.33E−03	3	16
LBY78	0.81	4.70E−03	3	31	LBY78	0.71	3.09E−02	3	46
LBY78	0.83	2.89E−03	3	30	LBY78	0.81	7.61E−03	2	27
LBY78	0.79	1.06E−02	2	31	LBY78	0.70	3.50E−02	2	17
LBY78	0.71	7.19E−02	2	46	LBY78	0.82	7.22E−03	2	30
LBY78	0.84	1.82E−02	5	47	LBY78	0.71	3.21E−02	5	24
LBY78	0.70	7.90E−02	5	45	LBY78	0.72	6.79E−02	5	20
LBY78	0.77	8.85E−03	1	9	LBY78	0.74	1.54E−02	1	10
LBY78	0.76	1.01E−02	1	17	LBY78	0.76	2.94E−02	12	47
LBY78	0.89	4.71E−04	12	6	LBY78	0.78	7.82E−03	12	11
LBY78	0.74	1.52E−02	12	13	LBY78	0.76	1.07E−02	12	17
LBY78	0.82	1.19E−02	12	20	LBY78	0.72	1.82E−02	12	12
LBY78	0.91	2.33E−04	12	7	LBY79	0.74	8.99E−02	8	8
LBY79	0.74	1.42E−02	3	2	LBY79	0.73	1.58E−02	11	51
LBY79	0.72	1.77E−02	11	50	LBY79	0.78	7.82E−03	11	49
LBY79	0.88	1.52E−03	11	52	LBY79	0.82	6.29E−03	9	48
LBY79	0.81	8.59E−03	9	51	LBY79	0.85	3.93E−03	9	50
LBY79	0.74	5.96E−02	9	22	LBY79	0.81	8.64E−03	9	49
LBY79	0.86	2.92E−03	9	52	LBY79	0.82	3.69E−03	12	48
LBY79	0.95	8.70E−04	12	35	LBY79	0.84	2.13E−03	12	51
LBY79	0.82	3.91E−03	12	50	LBY79	0.73	1.62E−02	12	24
LBY79	0.78	7.51E−03	12	49	LBY79	0.88	1.72E−03	12	52
LBY80	0.75	8.69E−02	8	17	LBY80	0.75	2.08E−02	4	9
LBY80	0.85	3.88E−03	4	6	LBY80	0.70	3.42E−02	4	33
LBY80	0.74	2.33E−02	4	13	LBY80	0.71	3.15E−02	4	39
LBY80	0.77	1.56E−02	4	7	LBY80	0.72	1.97E−02	3	9
LBY80	0.89	1.16E−03	2	27	LBY80	0.90	9.11E−04	2	31
LBY80	0.84	4.99E−03	2	30	LBY80	0.82	2.34E−02	5	47
LBY80	0.77	1.56E−02	5	6	LBY80	0.80	9.43E−03	5	11
LBY80	0.77	1.55E−02	5	13	LBY80	0.79	1.05E−02	5	8
LBY80	0.81	2.78E−02	5	45	LBY80	0.73	6.24E−02	5	20
LBY80	0.76	1.70E−02	5	7	LBY80	0.71	2.17E−02	11	9
LBY80	0.79	7.12E−03	11	6	LBY80	0.72	1.84E−02	11	13
LBY80	0.73	4.14E−02	11	20	LBY80	0.82	3.91E−03	1	9
LBY80	0.84	2.50E−03	1	6	LBY80	0.80	5.06E−03	1	13
LBY80	0.76	1.79E−02	9	9	LBY80	0.78	3.87E−02	9	47
LBY80	0.79	1.09E−02	9	6	LBY80	0.74	2.18E−02	9	11
LBY80	0.82	6.85E−03	9	13	LBY80	0.74	2.21E−02	9	8
LBY80	0.84	1.75E−02	9	45	LBY80	0.72	6.77E−02	9	20
LBY80	0.78	7.68E−03	12	9	LBY80	0.81	4.58E−03	12	6
LBY80	0.72	1.98E−02	12	13	LBY81	0.72	1.07E−01	8	17
LBY81	0.70	2.33E−02	3	30	LBY81	0.81	4.41E−03	3	12
LBY81	0.78	1.39E−02	5	24	LBY81	0.79	6.81E−03	11	9
LBY81	0.80	1.67E−02	11	23	LBY81	0.75	3.18E−02	11	47
LBY81	0.81	4.56E−03	11	6	LBY81	0.78	7.36E−03	11	11
LBY81	0.87	1.21E−03	11	13	LBY81	0.74	1.47E−02	11	8
LBY81	0.89	3.27E−03	11	20	LBY81	0.77	2.59E−02	11	21
LBY81	0.75	2.00E−02	1	47	LBY81	0.78	7.48E−03	1	11
LBY81	0.78	7.95E−03	1	13	LBY81	0.83	3.05E−03	1	8
LBY81	0.76	1.71E−02	1	20	LBY81	0.75	1.32E−02	12	50
LBY81	0.73	3.99E−02	12	22	LBY81	0.76	1.06E−02	12	49
LBY81	0.82	6.75E−03	12	52	LBY82	0.87	2.27E−02	8	6
LBY82	0.72	1.06E−01	8	3	LBY82	0.74	5.98E−02	4	47
LBY82	0.73	6.22E−02	4	45	LBY82	0.81	4.92E−03	3	1
LBY82	0.74	2.40E−02	3	44	LBY82	0.73	1.65E−02	3	16
LBY82	0.78	1.36E−02	3	45	LBY82	0.72	2.01E−02	3	5
LBY82	0.72	2.80E−02	5	11	LBY82	0.70	7.92E−02	5	46
LBY82	0.74	2.16E−02	5	12	LBY82	0.78	1.27E−02	11	52
LBY82	0.72	7.03E−02	9	46	LBY82	0.81	4.63E−03	12	9
LBY82	0.80	1.83E−02	12	23	LBY82	0.94	5.54E−05	12	6
LBY82	0.70	2.38E−02	12	11	LBY82	0.86	1.45E−03	12	13
LBY82	0.73	4.12E−02	12	22	LBY82	0.88	3.58E−03	12	20
LBY82	0.80	5.94E−03	12	7	LBY82	0.75	3.30E−02	12	21
LBY83	0.83	3.11E−03	3	16	LBY83	0.76	4.79E−02	3	35
LBY83	0.75	5.36E−02	5	47	LBY83	0.77	9.07E−03	11	43
LBY83	0.90	4.49E−04	11	10	LBY83	0.72	1.83E−02	11	42
LBY84	0.73	9.91E−02	8	4	LBY84	0.82	3.70E−03	3	43
LBY84	0.76	1.04E−02	3	14	LBY84	0.70	2.31E−02	3	10
LBY84	0.82	3.68E−03	3	42	LBY84	0.73	2.61E−02	5	10
LBY84	0.86	1.25E−02	5	46	LBY84	0.73	6.06E−02	11	35
LBY84	0.84	4.39E−03	1	44	LBY84	0.70	3.52E−02	1	23
LBY84	0.82	7.04E−03	1	47	LBY84	0.71	2.21E−02	1	11
LBY84	0.83	5.49E−03	1	45	LBY84	0.72	2.89E−02	12	52
LBY85	0.90	1.02E−03	2	14	LBY85	0.73	2.71E−02	2	30
LBY85	0.77	4.26E−02	5	23	LBY85	0.81	2.86E−02	5	47
LBY85	0.72	2.86E−02	5	51	LBY85	0.80	9.11E−03	5	24
LBY85	0.73	6.43E−02	5	20	LBY85	0.70	2.34E−02	11	50
LBY85	0.77	8.66E−03	11	24	LBY85	0.70	5.13E−02	11	22
LBY85	0.75	1.18E−02	1	48	LBY85	0.75	1.18E−02	1	50
LBY85	0.79	6.18E−03	1	24	LBY85	0.80	1.02E−02	1	22
LBY85	0.87	1.09E−03	1	49	LBY85	0.83	5.34E−03	1	52
LBY85	0.84	1.80E−02	9	44	LBY85	0.78	3.95E−02	9	23
LBY85	0.88	8.24E−03	9	47	LBY85	0.71	3.33E−02	9	50
LBY85	0.82	2.25E−02	9	45	LBY85	0.85	1.55E−02	9	20
LBY85	0.78	1.39E−02	9	52	LBY85	0.88	7.82E−04	12	48
LBY85	0.85	1.87E−03	12	51	LBY85	0.93	1.17E−04	12	50
LBY85	0.80	5.42E−03	12	24	LBY85	0.86	6.59E−03	12	22
LBY85	0.92	1.73E−04	12	49	LBY85	0.95	8.82E−05	12	52
LBY86	0.73	9.84E−02	8	1	LBY86	0.77	7.44E−02	8	4
LBY86	0.92	1.02E−02	8	3	LBY86	0.87	2.48E−02	8	2
LBY86	0.71	1.11E−01	8	39	LBY86	0.73	1.00E−01	8	7
LBY86	0.91	6.76E−04	3	52	LBY86	0.79	1.86E−02	2	52
LBY86	0.90	8.00E−04	5	43	LBY86	0.93	2.79E−04	5	10
LBY86	0.71	3.29E−02	5	3	LBY86	0.87	2.16E−03	5	42
LBY86	0.76	1.12E−02	11	27	LBY86	0.76	1.13E−02	11	31
LBY86	0.74	1.42E−02	11	30	LBY86	0.80	5.80E−03	1	48
LBY86	0.83	3.11E−03	1	50	LBY86	0.88	7.92E−04	1	24
LBY86	0.89	1.37E−03	1	22	LBY86	0.86	1.33E−03	1	49
LBY86	0.82	7.34E−03	1	52	LBY87	0.71	1.10E−01	8	6
LBY87	0.70	3.44E−02	4	17	LBY87	0.75	2.09E−02	4	52
LBY87	0.73	1.62E−02	3	27	LBY87	0.74	1.54E−02	3	31
LBY87	0.77	9.18E−03	3	30	LBY87	0.92	1.50E−04	11	48
LBY87	0.74	5.62E−02	11	35	LBY87	0.90	3.73E−04	11	51
LBY87	0.93	1.01E−04	11	50	LBY87	0.83	3.00E−03	11	24
LBY87	0.89	3.38E−03	11	22	LBY87	0.96	8.57E−06	11	49
LBY87	0.95	8.94E−05	11	52	LBY87	0.70	2.41E−02	12	9
LBY87	0.80	5.26E−03	12	33	LBY87	0.71	2.06E−02	12	13
LBY88	0.98	3.85E−04	8	8	LBY88	0.79	6.65E−03	3	51
LBY88	0.74	5.73E−02	2	23	LBY88	0.72	6.89E−02	2	21
LBY88	0.86	3.30E−03	5	24	LBY88	0.73	1.58E−02	1	24
LBY88	0.79	1.05E−02	1	22	LBY88	0.72	2.98E−02	9	48
LBY88	0.73	2.42E−02	9	50	LBY88	0.86	1.30E−02	9	22
LBY88	0.70	3.47E−02	9	49	LBY88	0.79	1.13E−02	9	52
LBY88	0.77	9.62E−03	12	48	LBY88	0.73	1.55E−02	12	51
LBY88	0.81	4.14E−03	12	50	LBY88	0.74	1.46E−02	12	24
LBY88	0.76	1.09E−02	12	49	LBY88	0.86	2.89E−03	12	52
LBY89	0.73	9.62E−02	8	8	LBY89	0.72	1.09E−01	8	52
LBY89	0.75	1.87E−02	3	44	LBY89	0.71	3.07E−02	3	47
LBY89	0.80	5.72E−03	3	16	LBY89	0.82	2.43E−02	3	35
LBY89	0.82	6.22E−03	3	45	LBY89	0.80	3.19E−02	5	47
LBY89	0.83	2.88E−03	11	10	LBY89	0.71	2.02E−02	11	42
LBY89	0.74	2.39E−02	12	52	LBY90	0.75	8.86E−02	8	51
LBY90	0.75	8.38E−02	8	50	LBY90	0.70	1.19E−01	8	24
LBY90	0.83	3.92E−02	8	49	LBY90	0.90	1.44E−02	8	52
LBY90	0.80	5.53E−03	3	48	LBY90	0.74	0.44E−02	3	51
LBY90	0.72	3.04E−02	3	22	LBY90	0.74	2.23E−02	2	50
LBY90	0.75	1.95E−02	2	24	LBY90	0.87	1.16E−02	2	22
LBY90	0.85	3.44E−03	2	49	LBY90	0.77	2.52E−02	9	52
LBY90	0.72	1.88E−02	11	48	LBY90	0.74	1.42E−02	11	51
LBY90	0.74	1.51E−02	11	50	LBY90	0.76	1.00E−02	11	49
LBY90	0.81	8.45E−03	11	52	LBY90	0.72	1.77E−02	1	48
LBY90	0.71	2.24E−02	1	50	LBY90	0.79	6.17E−03	1	24
LBY90	0.73	2.68E−02	1	22	LBY90	0.82	3.49E−03	1	49
LBY90	0.71	3.24E−02	1	52	LBY90	0.75	1.21E−02	12	48
LBY90	0.78	3.73E−02	12	35	LBY90	0.83	3.17E−03	12	51
LBY90	0.77	8.63E−03	12	50	LBY90	0.75	1.28E−02	12	49
LBY90	0.82	6.30E−03	12	52	LBY90	0.71	5.04E−02	12	21
LBY91	0.72	1.10E−01	8	48	LBY91	0.81	2.84E−02	4	44
LBY91	0.70	3.55E−02	4	48	LBY91	0.72	1.09E−01	4	35
LBY91	0.82	7.23E−03	4	51	LBY91	0.88	9.41E−03	4	45
LBY91	0.73	2.68E−02	4	52	LBY91	0.72	2.95E−02	9	43
LBY91	0.93	2.47E−04	9	10	LBY91	0.91	7.70E−04	9	42
LBY91	0.70	5.27E−02	12	22	LBY91	0.75	1.32E−02	12	49
LBY92	0.72	1.09E−01	8	8	LBY92	0.76	1.80E−02	4	16
LBY92	0.75	8.55E−02	4	35	LBY92	0.82	1.23E−02	11	23
LBY92	0.73	3.85E−02	11	47	LBY92	0.88	8.74E−04	11	13
LBY92	0.71	2.28E−02	11	8	LBY92	0.91	1.46E−03	11	20
LBY92	0.74	3.43E−02	11	21	LBY92	0.80	8.92E−03	1	22
LBY92	0.76	1.15E−02	12	50	LBY92	0.72	4.37E−02	12	20
LBY92	0.76	1.12E−02	12	49	LBY92	0.92	4.14E−04	12	52
LGN52	0.76	7.80E−02	8	14	LGN52	0.71	1.12E−01	8	49
LGN52	0.72	1.06E−01	8	52	LGN52	0.71	1.15E−01	8	5
LGN52	0.87	1.04E−03	3	43	LGN52	0.75	1.32E−02	3	10
LGN52	0.85	1.84E−03	3	42	LGN52	0.97	2.18E−05	2	27
LGN52	0.96	4.90E−05	2	31	LGN52	0.74	2.27E−02	2	17
LGN52	0.87	1.11E−02	2	46	LGN52	0.93	2.74E−04	2	30
LGN52	0.88	7.74E−04	11	10	LGN52	0.79	6.14E−03	11	42
LGN52	0.72	2.71E−02	9	52	LGN52	0.84	2.11E−03	12	43
LGN52	0.77	9.66E−03	12	14	LGN52	0.82	3.33E−03	12	10
LGN52	0.85	1.92E−03	12	4	LGN52	0.70	2.28E−02	12	38
LGN52	0.75	3.14E−02	12	46	LGN52	0.73	1.74E−02	12	2
LGN52	0.83	3.16E−03	12	42	LGN60	0.87	9.92E−03	4	44
LGN60	0.71	7.55E−02	4	23	LGN60	0.90	6.09E−03	4	47
LGN60	0.71	3.16E−02	4	11	LGN60	0.74	2.32E−02	4	13
LGN60	0.77	1.44E−02	4	8	LGN60	0.96	5.57E−04	4	45
LGN60	0.73	2.47E−02	2	48	LGN60	0.71	3.33E−02	2	50
LGN60	0.81	8.79E−03	2	24	LGN60	0.89	7.27E−03	2	22
LGN60	0.80	1.01E−02	2	49	LGN60	0.76	4.87E−02	5	44
LGN60	0.86	1.23E−02	5	23	LGN60	0.85	1.50E−02	5	20
LGN60	0.93	2.40E−03	5	21	LGN60	0.81	4.19E−03	12	48
LGN60	0.83	2.92E−03	12	51	LGN60	0.87	9.49E−04	12	50
LGN60	0.78	8.33E−03	12	24	LGN60	0.78	2.11E−02	12	20
LGN60	0.85	1.74E−03	12	49	LGN60	0.92	4.26E−04	12	52

Table 201. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 191. “Exp. Set”—Expression set specified in Table 189. “R”=Pearson correlation coefficient: “P”=p value

TABLE 202
Correlation between the expression level of selected genes of some embodiments of
the invention in various tissues and the phenotypic performance under normal
conditions (set 2 parameters) across Foxtail millet varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY3	0.72	4.40E−02	3	12	LBY3	0.71	7.31E−02	2	7
LBY3	0.72	6.53E−02	2	11	LBY3	0.75	3.25E−02	5	2
LBY3	0.71	4.66E−02	5	12	LBY3	0.84	8.66E−03	5	8
LBY3	0.82	1.31E−02	5	6	LBY3	0.79	6.88E−03	11	5
LBY3	0.79	6.88E−03	11	4	LBY3	0.75	3.33E−02	11	11
LBY3	0.71	4.86E−02	1	12	LBY3	0.81	1.37E−02	1	13
LBY3	0.81	1.44E−02	1	3	LBY55	0.77	1.53E−02	2	5
LBY55	0.77	1.53E−02	2	4	LBY55	0.86	6.15E−03	11	8
LBY55	0.87	5.42E−03	11	6	LBY55	0.92	1.74E−04	1	5
LBY55	0.85	7.39E−03	1	8	LBY55	0.92	1.74E−04	1	4
LBY55	0.83	1.08E−02	1	6	LBY55	0.73	2.42E−02	12	8
LBY56	0.80	1.04E−02	4	13	LBY56	0.74	3.43E−02	3	13
LBY56	0.83	1.13E−02	1	3	LBY57	0.79	1.16E−02	4	7
LBY57	0.79	1.99E−02	5	2	LBY57	0.81	1.56E−02	1	7
LBY58	0.79	1.85E−02	9	7	LBY59	0.83	5.65E−03	4	3
LBY59	0.85	3.59E−03	2	5	LBY59	0.79	3.44E−02	2	8
LBY59	0.85	3.59E−03	2	4	LBY59	0.76	4.57E−02	9	6
LBY59	0.86	5.64E−03	5	2	LBY59	0.94	4.06E−05	11	5
LBY59	0.72	4.31E−02	11	10	LBY59	0.74	3.74E−02	11	8
LBY59	0.94	4.06E−05	11	4	LBY59	0.82	1.34E−02	11	11
LBY59	0.73	3.78E−02	1	12	LBY59	0.75	3.10E−02	1	13
LBY59	0.92	1.11E−03	9	12	LBY59	0.85	6.87E−03	9	13
LBY59	0.79	1.14E−02	12	12	LBY61	0.75	2.04E−02	4	12
LBY61	0.87	2.43E−03	4	13	LBY61	0.72	4.34E−02	3	3
LBY61	0.86	1.33E−02	2	3	LBY61	0.80	1.75E−02	5	7
LBY61	0.77	2.62E−02	5	3	LBY61	0.72	4.40E−02	1	2
LBY61	0.85	7.86E−03	9	3	LBY62	0.76	4.58E−02	2	7
LBY62	0.72	6.99E−02	2	11	LBY62	0.79	1.86E−02	5	3
LBY62	0.80	9.39E−03	9	5	LBY62	0.72	4.47E−02	9	8
LBY62	0.80	9.39E−03	9	4	LBY62	0.74	3.65E−02	9	11
LBY62	0.71	3.18E−02	12	11	LBY63	0.84	8.26E−03	3	9
LBY63	0.77	2.70E−02	3	7	LBY63	0.85	1.62E−02	2	7
LBY63	0.76	4.58E−02	2	11	LBY63	0.71	3.06E−02	12	7
LBY64	0.79	1.20E−02	4	9	LBY64	0.88	4.43E−03	11	12
LBY64	0.87	4.55E−03	11	13	LBY64	0.74	3.48E−02	1	12
LBY64	0.76	2.71E−02	1	13	LBY65	0.77	1.52E−02	4	9
LBY65	0.83	1.03E−02	3	11	LBY65	0.89	7.62E−03	2	9
LBY65	0.71	4.68E−02	5	12	LBY65	0.74	1.35E−02	11	5
LBY65	0.80	1.77E−02	11	8	LBY65	0.74	1.35E−02	11	4
LBY65	0.78	2.26E−02	11	6	LBY65	0.74	3.63E−02	1	12
LBY65	0.79	2.09E−02	1	13	LBY65	0.76	3.03E−02	9	2
LBY65	0.84	4.26E−03	12	12	LBY65	0.74	2.32E−02	12	6
LBY66	0.81	1.51E−02	3	9	LBY66	0.73	2.67E−02	12	9
LBY67	0.73	1.01E−01	8	4	LBY67	0.73	1.01E−01	8	5
LBY67	0.83	2.01E−02	2	9	LBY67	0.74	5.91E−02	2	7
LBY67	0.90	5.37E−03	2	12	LBY67	0.77	4.30E−02	2	13
LBY67	0.72	4.43E−02	11	2	LBY67	0.74	1.44E−02	11	5
LBY67	0.92	1.22E−03	11	8	LBY67	0.74	1.44E−02	11	4
LBY67	0.87	4.63E−03	11	6	LBY67	0.88	3.98E−03	11	11
LBY67	0.73	3.88E−02	9	1	LBY67	0.71	3.39E−02	12	8
LBY67	0.77	1.57E−02	12	6	LBY68	0.80	1.75E−02	3	12
LBY68	0.81	1.50E−02	3	13	LBY68	0.88	3.48E−03	1	3
LBY68	0.80	1.76E−02	9	8	LBY68	0.76	2.94E−02	9	6
LBY68	0.80	1.02E−02	12	12	LBY69	0.84	4.48E−03	4	7
LBY69	0.73	2.48E−02	4	11	LBY69	0.77	2.62E−02	3	11
LBY69	0.93	2.29E−04	2	5	LBY69	0.72	6.80E−02	2	7
LBY69	0.78	4.03E−02	2	8	LBY69	0.93	2.29E−04	2	4
LBY69	0.78	3.78E−02	2	6	LBY69	0.88	9.02E−03	2	11
LBY69	0.73	3.91E−02	5	2	LBY69	0.70	5.18E−02	5	7
LBY69	0.77	2.47E−02	5	12	LBY69	0.71	4.96E−02	5	13
LBY69	0.87	1.16E−03	11	5	LBY69	0.81	1.40E−02	11	8
LBY69	0.87	1.16E−03	11	4	LBY69	0.82	1.18E−02	11	6
LBY69	0.71	2.27E−02	1	5	LBY69	0.71	2.27E−02	1	4
LBY69	0.74	2.24E−02	9	5	LBY69	0.74	2.24E−02	9	4
LBY69	0.73	2.67E−02	12	7	LBY69	0.73	2.53E−02	12	8
LBY69	0.76	1.74E−02	12	6	LBY70	0.82	7.19E−03	4	9
LBY70	0.80	3.22E−02	2	3	LBY70	0.75	3.14E−02	5	7
LBY70	0.75	3.09E−02	5	3	LBY70	0.72	4.20E−02	11	7
LBY70	0.84	9.05E−03	1	13	LBY70	0.85	7.23E−03	9	3
LBY70	0.71	3.19E−02	12	11	LBY71	0.88	1.61E−03	4	9
LBY71	0.76	4.59E−02	2	13	LBY71	0.77	2.43E−02	5	2
LBY71	0.74	3.64E−02	5	12	LBY71	0.85	8.13E−03	11	1
LBY71	0.84	8.57E−03	11	12	LBY71	0.72	4.53E−02	11	13
LBY71	0.82	1.30E−02	1	12	LBY71	0.90	2.32E−03	1	13
LBY71	0.86	5.68E−03	9	1	LBY71	0.80	1.67E−02	9	2
LBY71	0.94	5.81E−04	9	12	LBY71	0.79	2.00E−02	9	13
LBY72	0.74	2.22E−02	4	7	LBY72	0.76	4.77E−02	2	1
LBY72	0.93	2.07E−03	2	9	LBY72	0.80	1.66E−02	11	1
LBY72	0.75	3.04E−02	1	9	LBY72	0.78	2.14E−02	1	2
LBY72	0.84	8.33E−03	1	13	LBY72	0.92	5.32E−04	12	7
LBY73	0.74	2.31E−02	4	5	LBY73	0.74	2.31E−02	4	4
LBY73	0.82	7.07E−03	4	11	LBY73	0.71	4.93E−02	11	10
LBY74	0.72	4.56E−02	3	1	LBY74	0.87	1.01E−02	2	11
LBY74	0.88	3.57E−03	11	1	LBY74	0.71	4.77E−02	11	12
LBY74	0.71	4.88E−02	1	13	LBY74	0.83	6.18E−03	12	1
LBY75	0.77	1.61E−02	4	9	LBY75	0.86	6.52E−03	3	7
LBY75	0.78	2.37E−02	3	13	LBY75	0.72	7.08E−02	2	9
LBY75	0.89	7.22E−03	2	12	LBY75	0.72	7.07E−02	2	8
LBY75	0.95	9.63E−04	2	13	LBY75	0.71	7.09E−02	2	6
LBY75	0.76	2.72E−02	5	12	LBY75	0.77	2.51E−02	5	13
LBY75	0.80	1.60E−02	11	12	LBY75	0.84	9.42E−03	11	13
LBY75	0.85	8.21E−03	1	12	LBY75	0.98	2.12E−05	1	13
LBY75	0.70	5.27E−02	9	8	LBY75	0.75	3.16E−02	9	6
LBY75	0.81	7.91E−03	12	13	LBY76	0.74	2.27E−02	4	1
LBY76	0.74	2.19E−02	4	9	LBY76	0.79	1.16E−02	4	13
LBY76	0.71	4.85E−02	3	7	LBY76	0.81	8.22E−03	2	5
LBY76	0.76	4.71E−02	2	8	LBY76	0.81	8.22E−03	2	4
LBY76	0.78	3.90E−02	2	11	LBY76	0.74	1.46E−02	11	5
LBY76	0.88	4.28E−03	11	12	LBY76	0.77	2.61E−02	11	8
LBY76	0.74	1.46E−02	11	4	LBY76	0.89	3.18E−03	11	13
LBY76	0.74	3.42E−02	11	6	LBY76	0.76	2.80E−02	1	2
LBY76	0.87	1.14E−03	1	5	LBY76	0.75	3.18E−02	1	8
LBY76	0.87	1.14E−03	1	4	LBY76	0.72	4.58E−02	1	6
LBY76	0.83	3.29E−03	12	5	LBY76	0.79	1.20E−02	12	8
LBY76	0.83	3.29E−03	12	4	LBY76	0.81	8.56E−03	12	6
LBY76	0.76	1.73E−02	12	11	LBY77	0.75	2.11E−02	2	5
LBY77	0.75	5.07E−02	2	8	LBY77	0.75	2.11E−02	2	4
LBY77	0.71	7.38E−02	2	6	LBY77	0.71	4.76E−02	5	1
LBY77	0.88	3.89E−03	5	2	LBY77	0.70	5.13E−02	11	1
LBY77	0.90	2.22E−03	11	9	LBY77	0.90	2.58E−03	11	12
LBY77	0.94	5.05E−04	11	13	LBY77	0.75	3.20E−02	1	1
LBY77	0.85	7.58E−03	1	12	LBY77	0.95	2.89E−04	1	13
LBY77	0.93	7.90E−04	9	2	LBY78	0.73	2.42E−02	4	7
LBY78	0.75	3.29E−02	3	2	LBY78	0.80	1.79E−02	5	2
LBY78	0.71	5.06E−02	5	6	LBY78	0.85	8.10E−03	1	3
LBY78	0.88	4.01E−03	9	2	LBY78	0.89	4.71E−04	12	5
LBY78	0.89	4.71E−04	12	4	LBY78	0.78	1.29E−02	12	11
LBY79	0.77	1.60E−02	4	2	LBY79	0.82	1.23E−02	5	1
LBY79	0.85	8.24E−03	11	1	LBY79	0.77	2.44E−02	9	1
LBY79	0.74	3.62E−02	9	9	LBY79	0.79	1.21E−02	12	1
LBY80	0.85	3.88E−03	4	5	LBY80	0.76	1.86E−02	4	8
LBY80	0.85	3.88E−03	4	4	LBY80	0.71	3.14E−02	4	6
LBY80	0.87	5.07E−03	3	8	LBY80	0.83	1.09E−02	3	6
LBY80	0.78	2.17E−02	3	11	LBY80	0.76	4.76E−02	2	7
LBY80	0.92	3.07E−03	2	11	LBY80	0.77	1.56E−02	5	5
LBY80	0.79	2.01E−02	5	8	LBY80	0.77	1.56E−02	5	4
LBY80	0.76	2.91E−02	5	6	LBY80	0.79	7.12E−03	11	5
LBY80	0.84	8.54E−03	11	8	LBY80	0.79	7.12E−03	11	4
LBY80	0.81	1.42E−02	11	6	LBY80	0.84	2.50E−03	1	5
LBY80	0.88	3.87E−03	1	8	LBY80	0.84	2.50E−03	1	4
LBY80	0.82	1.28E−02	1	6	LBY80	0.79	1.09E−02	9	5
LBY80	0.92	1.14E−03	9	8	LBY80	0.79	1.09E−02	9	4
LBY80	0.92	1.06E−03	9	6	LBY80	0.81	4.58E−03	12	5
LBY80	0.87	2.44E−03	12	8	LBY80	0.81	4.58E−03	12	4
LBY80	0.81	8.59E−03	12	6	LBY80	0.70	3.54E−02	12	11
LBY81	0.86	6.60E−03	3	11	LBY81	0.72	7.08E−02	2	8
LBY81	0.76	4.75E−02	2	6	LBY81	0.81	1.43E−02	5	2
LBY81	0.81	4.56E−03	11	5	LBY81	0.90	2.28E−03	11	8
LBY81	0.81	4.56E−03	11	4	LBY81	0.88	3.88E−03	11	6
LBY81	0.80	1.64E−02	1	8	LBY81	0.81	1.51E−02	1	6
LBY81	0.88	3.92E−03	9	2	LBY81	0.73	2.67E−02	12	6
LBY82	0.87	2.27E−02	8	4	LBY82	0.87	2.27E−02	8	5
LBY82	0.82	6.80E−03	4	2	LBY82	0.83	1.03E−02	3	2
LBY82	0.73	3.97E−02	5	11	LBY82	0.94	5.54E−05	12	5
LBY82	0.71	3.24E−02	12	10	LBY81	0.83	5.42E−03	12	8
LBY82	0.94	5.54E−05	12	4	LBY82	0.77	1.49E−02	12	6
LBY82	0.72	2.86E−02	12	11	LBY83	0.78	3.93E−02	9	3
LBY83	0.82	1.21E−02	1	3	LBY85	0.74	2.24E−02	4	9
LBY85	0.84	8.66E−03	3	1	LBY85	0.87	5.42E−03	5	2
LBY85	0.72	4.26E−02	5	12	LBY85	0.80	1.78E−02	11	2
LBY85	0.85	6.82E−03	1	12	LBY85	0.87	5.25E−03	1	13
LBY85	0.74	3.68E−02	9	2	LBY85	0.75	3.20E−02	9	12
LBY85	0.82	1.36E−02	9	8	LBY85	0.83	9.95E−03	9	6
LBY85	0.89	1.43E−03	12	1	LBY85	0.75	1.95E−02	12	12
LBY85	0.71	3.32E−02	12	13	LBY86	0.74	3.74E−02	3	3
LBY86	0.74	5.58E−02	2	1	LBY86	0.74	3.63E−02	5	7
LBY86	0.87	5.51E−03	5	3	LBY86	0.88	3.68E−03	1	12
LBY86	0.90	2.30E−03	1	13	LBY86	0.71	5.05E−02	9	7
LBY87	0.71	1.10E−01	8	4	LBY87	0.71	1.10E−01	8	5
LBY87	0.72	2.90E−02	4	9	LBY87	0.71	4.80E−02	3	7
LBY87	0.91	1.53E−03	11	1	LBY87	0.80	1.62E−02	11	12
LBY87	0.81	1.42E−02	11	13	LBY87	0.77	2.57E−02	1	3
LBY87	0.74	2.29E−02	12	6	LBY88	0.71	7.53E−02	2	9
LBY88	0.70	7.75E−02	2	2	LBY88	0.84	8.90E−03	5	12
LBY88	0.73	4.04E−02	5	13	LBY88	0.89	3.33E−03	1	12
LBY88	0.98	2.40E−05	1	13	LBY88	0.77	2.48E−02	9	12
LBY88	0.74	2.14E−02	12	1	LBY88	0.73	2.61E−02	12	12
LBY88	0.80	9.13E−03	12	8	LBY88	0.78	1.23E−02	12	6
LBY89	0.84	4.69E−03	4	2	LBY89	0.90	6.38E−03	2	3
LBY89	0.71	4.85E−02	5	2	LBY89	0.77	2.45E−02	5	8
LBY89	0.74	3.67E−02	5	6	LBY89	0.86	5.94E−03	11	7
LBY89	0.74	2.37E−02	12	6	LBY90	0.87	1.15E−02	2	12
LBY90	0.80	2.95E−02	2	13	LBY90	0.84	8.27E−03	11	1
LBY90	0.82	1.17E−02	1	12	LBY90	0.89	2.92E−03	1	13
LBY90	0.87	2.12E−03	12	1	LBY91	0.77	1.47E−02	4	1
LBY91	0.71	3.12E−02	4	2	LBY91	0.90	2.17E−03	3	8
LBY91	0.87	4.73E−03	3	6	LBY91	0.73	4.07E−02	3	11
LBY91	0.77	2.41E−02	9	3	LBY91	0.73	2.52E−02	12	12
LBY91	0.79	1.08E−02	12	13	LBY92	0.78	1.35E−02	4	2
LBY92	0.93	9.85E−04	11	8	LBY92	0.93	7.84E−04	11	6
LBY92	0.84	9.48E−03	1	13	LBY92	0.71	3.31E−02	12	12
LGN52	0.84	8.85E−03	3	9	LGN52	0.88	8.70E−03	2	7
LGN52	0.80	3.09E−02	2	11	LGN52	0.88	3.56E−03	11	7
LGN52	0.74	2.34E−02	12	7	LGN60	0.76	1.69E−02	4	8
LGN60	0.72	2.93E−02	4	6	LGN60	0.91	4.99E−03	2	12
LGN60	0.95	1.17E−03	2	13	LGN60	0.73	3.81E−02	5	13
LGN60	0.71	4.72E−02	11	2	LGN60	0.81	8.73E−03	12	1
LGN60	0.75	2.08E−02	12	12

Table 202. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 192. “Exp. Set”—Expression set specified in Table 189. “R”=Pearson correlation coefficient; “P”=p value

TABLE 203
Correlation between the expression level of selected genes of some
embodiments of the invention in various tissues and the phenotypic performance
under low N conditions (set 1 parameters) across Foxtail millet varieties
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY3	0.83	2.89E−03	3	51	LBY3	0.73	6.38E−02	3	25
LBY3	0.71	3.09E−02	8	6	LBY3	0.91	4.57E−03	8	22
LBY3	0.82	3.76E−03	1	48	LBY3	0.81	4.89E−03	1	51
LBY3	0.81	4.48E−03	1	50	LBY3	0.87	1.17E−03	1	24
LBY3	0.86	1.45E−03	1	49	LBY3	0.77	8.76E−03	1	52
LBY3	0.79	3.29E−02	1	25	LBY3	0.74	3.44E−02	4	22
LBY3	0.93	1.25E−04	9	32	LBY55	0.81	4.93E−03	3	1
LBY55	0.73	1.59E−02	3	14	LBY55	0.77	9.93E−03	3	16
LBY55	0.71	2.10E−02	3	5	LBY55	0.74	9.49E−02	8	25
LBY55	0.72	1.90E−02	1	9	LBY55	0.77	1.58E−02	1	47
LBY55	0.71	3.17E−02	1	45	LBY55	0.85	3.67E−03	1	20
LBY55	0.70	2.33E−02	1	5	LBY55	0.78	7.20E−03	9	14
LBY55	0.75	1.27E−02	9	16	LBY55	0.84	5.01E−03	9	45
LBY55	0.76	1.02E−02	2	9	LBY55	0.75	1.94E−02	2	23
LBY55	0.73	1.57E−02	2	13	LBY55	0.73	2.71E−02	2	20
LBY55	0.71	2.03E−02	2	12	LBY55	0.71	3.26E−02	2	21
LBY56	0.76	1.03E−02	3	43	LBY56	0.79	6.68E−03	3	10
LBY57	0.71	2.05E−02	3	16	LBY57	0.75	1.24E−02	1	1
LBY57	0.74	1.37E−02	1	3	LBY57	0.70	2.30E−02	1	2
LBY57	0.77	8.86E−03	4	43	LBY57	0.71	2.02E−02	4	42
LBY57	0.77	8.55E−03	9	16	LBY57	0.70	3.45E−02	9	45
LBY57	0.71	2.16E−02	9	32	LBY58	0.72	1.06E−01	8	25
LBY58	0.85	1.98E−03	4	48	LBY58	0.87	1.22E−03	4	51
LBY58	0.78	7.21E−03	4	50	LBY58	0.73	1.61E−02	4	24
LBY58	0.71	2.12E−02	4	49	LBY58	0.72	1.94E−02	4	52
LBY59	0.75	1.21E−02	1	24	LBY59	0.77	1.46E−02	1	22
LBY59	0.74	1.51E−02	1	49	LBY59	0.74	5.74E−02	1	25
LBY59	0.77	2.64E−02	4	22	LBY59	0.70	2.34E−02	9	14
LBY59	0.83	5.55E−03	9	47	LBY59	0.71	2.13E−02	9	16
LBY59	0.82	6.21E−03	9	45	LBY59	0.73	1.61E−02	9	17
LBY59	0.75	1.98E−02	9	20	LBY59	0.77	9.82E−03	2	6
LBY59	0.85	4.03E−03	2	22	LBY59	0.78	7.99E−03	2	7
LBY61	0.73	1.69E−02	1	11	LBY61	0.73	2.71E−02	1	22
LBY61	0.73	1.57E−02	9	10	LBY61	0.73	2.69E−02	9	46
LBY62	0.75	1.31E−02	3	28	LBY62	0.74	1.46E−02	2	1
LBY62	0.73	2.47E−02	2	44	LBY62	0.81	8.53E−03	2	23
LBY62	0.93	3.13E−04	2	47	LBY62	0.82	3.58E−03	2	28
LBY62	0.90	8.36E−04	2	45	LBY62	0.89	1.45E−03	2	20
LBY62	0.74	1.43E−02	2	7	LBY62	0.71	3.26E−02	2	21
LBY63	0.82	6.91E−03	3	22	LBY63	0.72	1.81E−02	1	43
LBY63	0.73	1.75E−02	1	10	LBY63	0.74	1.47E−02	1	39
LBY63	0.96	1.60E−05	9	43	LBY63	0.94	5.89E−05	9	10
LBY63	0.92	1.59E−04	9	42	LBY63	0.87	1.19E−03	2	43
LBY63	0.93	1.10E−04	2	10	LBY63	0.81	4.29E−03	2	38
LBY63	0.83	3.11E−03	2	42	LBY64	0.72	1.83E−02	3	36
LBY64	0.72	1.94E−02	3	35	LBY64	0.78	7.63E−03	3	39
LBY64	0.73	1.77E−02	3	5	LBY64	0.71	3.16E−02	8	50
LBY64	0.76	4.64E−02	8	22	LBY64	0.94	4.72E−03	8	25
LBY64	0.71	3.23E−02	1	44	LBY64	0.73	2.60E−02	1	23
LBY64	0.79	6.08E−03	1	48	LBY64	0.76	1.02E−02	1	51
LBY64	0.73	1.59E−02	1	50	LBY64	0.89	4.87E−04	1	24
LBY64	0.74	2.33E−02	1	21	LBY64	0.85	1.46E−02	1	25
LBY64	0.70	3.55E−02	9	47	LBY64	0.71	3.04E−02	9	45
LBY65	0.77	8.96E−03	3	1	LBY65	0.81	7.46E−03	3	44
LBY65	0.72	2.75E−02	3	23	LBY65	0.80	1.00E−02	3	47
LBY65	0.77	8.73E−03	3	16	LBY65	0.77	1.62E−02	3	45
LBY65	0.72	1.81E−02	3	5	LBY65	0.73	2.59E−02	8	9
LBY65	0.74	2.19E−02	8	6	LBY65	0.79	1.17E−02	8	7
LBY65	0.70	3.42E−02	1	44	LBY65	0.70	3.42E−02	1	23
LBY65	0.88	8.53E−04	1	48	LBY65	0.77	8.48E−03	1	33
LBY65	0.76	1.01E−02	1	51	LBY65	0.78	7.15E−03	1	40
LBY65	0.86	1.43E−03	1	50	LBY65	0.90	4.28E−04	1	24
LBY65	0.70	2.32E−02	1	17	LBY65	0.78	7.94E−03	1	49
LBY65	0.80	5.26E−03	1	52	LBY65	0.73	2.69E−02	1	21
LBY65	0.86	1.41E−02	1	25	LBY65	0.72	2.72E−02	9	44
LBY65	0.78	8.19E−03	9	14	LBY65	0.78	1.39E−02	9	47
LBY65	0.84	2.58E−03	9	16	LBY65	0.85	3.36E−03	9	45
LBY65	0.84	2.56E−03	9	17	LBY66	0.74	1.52E−02	9	10
LBY66	0.80	5.20E−03	2	43	LBY66	0.91	2.26E−04	2	10
LBY66	0.84	2.13E−03	2	42	LBY67	0.77	9.53E−03	3	43
LBY67	0.84	2.29E−03	3	33	LBY67	0.78	7.68E−03	3	40
LBY67	0.78	7.45E−03	3	4	LBY67	0.75	1.27E−02	3	3
LBY67	0.84	2.25E−03	3	39	LBY67	0.88	9.86E−03	8	44
LBY67	0.93	2.68E−03	8	23	LBY67	0.89	6.49E−03	8	47
LBY67	0.76	1.64E−02	8	8	LBY67	0.95	1.11E−03	8	45
LBY67	0.95	1.22E3−03	8	20	LBY67	0.71	3.19E−02	8	7
LBY67	0.93	2.83E−03	8	21	LBY67	0.71	4.76E−02	4	44
LBY67	0.79	2.05E−02	4	47	LBY67	0.72	1.94E−02	4	27
LBY67	0.72	1.91E−02	4	31	LBY67	0.77	2.62E−02	4	45
LBY67	0.71	3.15E−02	9	44	LBY67	0.83	2.93E−03	9	14
LBY67	0.76	1.64E−02	9	47	LBY67	0.73	1.64E−02	9	27
LBY67	0.80	5.54E−03	9	16	LBY67	0.73	1.56E−02	9	31
LBY67	0.90	1.05E−03	9	45	LBY67	0.75	1.24E−02	9	17
LBY67	0.72	1.91E−02	9	30	LBY67	0.73	1.56E−02	2	24
LBY67	0.74	1.49E−02	2	52	LBY68	0.73	1.58E−02	3	1
LBY68	0.75	1.23E−02	3	48	LBY68	0.82	6.71E−03	8	28
LBY68	0.71	3.04E−02	9	23	LBY68	0.72	2.75E−02	9	47
LBY68	0.77	8.75E−03	9	48	LBY68	0.77	8.78E−03	9	51
LBY68	0.75	1.19E−02	9	50	LBY68	0.82	3.60E−03	9	24
LBY68	0.77	9.09E−03	9	49	LBY68	0.72	1.85E−02	9	52
LBY68	0.70	3.40E−02	9	21	LBY69	0.74	1.38E−02	3	43
LBY69	0.71	2.24E−02	3	10	LBY69	0.70	2.40E−02	3	42
LBY69	0.78	1.31E−02	8	43	LBY69	0.75	2.04E−02	8	10
LBY69	0.78	3.72E−02	8	22	LBY69	0.86	3.10E−03	8	5
LBY69	0.80	9.24E−03	1	45	LBY69	0.75	1.22E−02	1	5
LBY69	0.87	1.13E−03	4	36	LBY69	0.87	1.14E−03	4	35
LBY69	0.75	1.17E−02	4	17	LBY69	0.82	3.67E−03	9	14
LBY69	0.75	1.98E−02	9	47	LBY69	0.83	3.16E−03	9	16
LBY69	0.88	1.92E−03	9	45	LBY69	0.85	1.93E−03	9	17
LBY70	0.73	2.46E−02	1	22	LBY70	0.73	1.60E−02	4	43
LBY70	0.72	1.84E−02	4	10	LBY70	0.72	1.99E−02	4	42
LBY70	0.80	9.47E−03	2	23	LBY70	0.77	9.35E−03	2	24
LBY70	0.74	2.30E−02	2	20	LBY70	0.75	1.26E−02	2	12
LBY70	0.78	1.30E−02	2	21	LBY71	0.93	1.02E−04	3	32
LBY71	0.92	3.36E−03	8	22	LBY71	0.80	1.02E−02	1	22
LBY71	0.74	1.37E−02	1	49	LBY71	0.72	1.91E−02	9	16
LBY71	0.72	1.79E−02	9	17	LBY71	0.75	2.01E−02	2	22
LBY72	0.73	1.56E−02	3	28	LBY72	0.73	2.57E−02	1	22
LBY72	0.74	1.53E−02	9	43	LBY72	0.84	2.37E−03	9	10
LBY72	0.78	7.44E−03	9	42	LBY72	0.74	1.35E−02	2	50
LBY72	0.77	8.87E−03	2	24	LBY72	0.79	6.39E−03	2	49
LBY72	0.82	3.75E−03	2	52	LBY72	0.71	7.31E−02	2	25
LBY73	0.86	1.43E−03	4	27	LBY73	0.86	1.50E−03	4	31
LBY73	0.72	1.97E−02	4	38	LBY73	0.83	1.09E−02	4	46
LBY73	0.80	5.04E−03	4	30	LBY73	0.74	2.38E−02	9	46
LBY73	0.71	2.16E−02	2	52	LBY74	0.70	2.34E−02	3	36
LBY74	0.70	2.36E−02	3	35	LBY74	0.77	9.50E−03	3	28
LBY74	0.71	2.14E−02	3	30	LBY74	0.74	2.39E−02	8	9
LBY74	0.89	7.55E−03	8	44	LBY74	0.92	3.56E−03	8	23
LBY74	0.84	4.50E−03	8	14	LBY74	0.88	9.49E−03	8	47
LBY74	0.73	2.52E−02	8	11	LBY74	0.77	1.63E−02	8	51
LBY74	0.82	7.40E−03	8	8	LBY74	0.93	2.10E−03	8	45
LBY74	0.95	9.01E−04	8	20	LBY74	0.95	1.19E−03	8	21
LBY74	0.74	9.13E−02	8	25	LBY74	0.75	1.95E−02	9	44
LBY74	0.83	2.78E−03	9	48	LBY74	0.85	1.70E−03	9	51
LBY74	0.80	5.29E−03	9	50	LBY74	0.73	1.63E−02	9	24
LBY74	0.79	6.81E−03	9	49	LBY74	0.87	1.14E−03	9	52
LBY74	0.73	2.71E−02	9	21	LBY75	0.73	1.68E−02	3	33
LBY75	0.73	1.56E−02	3	40	LBY75	0.71	3.35E−02	8	24
LBY75	0.75	8.74E−02	8	25	LBY75	0.78	7.55E−03	1	48
LBY75	0.80	5.96E−03	1	50	LBY75	0.80	5.46E−03	1	24
LBY75	0.77	1.49E−02	1	22	LBY75	0.86	1.36E−03	1	49
LBY75	0.75	1.19E−02	1	52	LBY75	0.73	6.26E−02	1	25
LBY75	0.75	1.22E−02	4	1	LBY75	0.74	3.56E−02	4	44
LBY75	0.73	4.11E−02	4	23	LBY75	0.81	1.57E−02	4	21
LBY75	0.71	2.02E−02	9	14	LBY75	0.72	1.91E−02	9	16
LBY75	0.74	2.18E−02	9	45	LBY75	0.74	1.50E−02	9	17
LBY75	0.81	4.11E−03	2	43	LBY75	0.84	2.30E−03	2	10
LBY75	0.73	1.64E−02	2	42	LBY76	0.85	1.42E−02	8	44
LBY76	0.77	4.48E−02	8	23	LBY76	0.86	1.37E−02	8	47
LBY76	0.81	7.68E−03	8	48	LBY76	0.75	2.02E−02	8	51
LBY76	0.73	2.47E−02	8	28	LBY76	0.80	9.70E−03	8	50
LBY76	0.76	1.71E−02	8	24	LBY76	0.81	2.81E−02	8	45
LBY76	0.74	5.95E−02	8	20	LBY76	0.85	3.81E−03	8	49
LBY76	0.74	2.17E−02	8	32	LBY76	0.86	3.16E−03	8	52
LBY76	0.76	7.77E−02	8	25	LBY76	0.78	7.80E−03	1	6
LBY76	0.78	7.17E−03	1	11	LBY76	0.71	2.13E−02	1	13
LBY76	0.77	8.91E−03	1	24	LBY76	0.86	1.37E−03	1	7
LBY76	0.71	3.22E−02	1	21	LBY76	0.76	4.55E−02	1	25
LBY76	0.79	6.17E−03	9	27	LBY76	0.79	6.74E−03	9	31
LBY76	0.72	2.98E−02	9	46	LBY76	0.71	2.07E−02	9	30
LBY76	0.71	2.09E−02	2	9	LBY76	0.71	2.28E−02	2	28
LBY77	0.83	3.05E−03	3	3	LBY77	0.77	8.99E−03	3	2
LBY77	0.94	1.72E−03	3	25	LBY77	0.78	1.29E−02	8	14
LBY77	0.76	1.73E−02	8	48	LBY77	0.81	8.72E−03	8	50
LBY77	0.73	2.52E−02	8	49	LBY77	0.79	6.21E−02	8	25
LBY77	0.79	7.10E−03	1	49	LBY77	0.76	4.58E−02	1	25
LBY77	0.74	1.41E−02	4	48	LBY77	0.79	6.96E−03	4	50
LBY77	0.75	1.24E−02	4	49	LBY77	0.79	6.28E−03	4	52
LBY77	0.86	1.29E−02	4	25	LBY77	0.73	6.10E−02	9	25
LBY77	0.83	3.22E−03	2	43	LBY77	0.88	7.92E−04	2	10
LBY77	0.75	1.28E−02	2	42	LBY78	0.75	1.96E−02	8	43
LBY78	0.79	1.12E−02	8	10	LBY78	0.80	1.02E−02	8	4
LBY78	0.71	3.08E−02	8	3	LBY78	0.70	7.93E−02	8	22
LBY78	0.74	2.26E−02	8	2	LBY78	0.78	1.41E−02	8	42
LBY78	0.70	3.54E−02	8	39	LBY78	0.71	3.30E−02	8	12
LBY78	0.73	1.55E−02	1	51	LBY78	0.76	1.10E−02	1	52
LBY78	0.71	2.21E−02	4	14	LBY78	0.72	1.90E−02	2	27
LBY78	0.71	2.10E−02	2	31	LBY78	0.75	1.33E−02	2	38
LBY79	0.72	2.00E−02	9	48	LBY79	0.82	3.53E−03	9	51
LBY79	0.72	1.85E−02	9	24	LBY80	0.70	3.57E−02	8	31
LBY80	0.80	9.50E−03	8	4	LBY80	0.88	1.77E−03	8	38
LBY80	0.71	3.37E−02	8	30	LBY80	0.76	1.84E−02	8	39
LBY80	0.81	4.73E−03	1	28	LBY80	0.73	4.17E−02	4	47
LBY80	0.76	1.01E−02	4	36	LBY80	0.76	1.06E−02	4	35
LBY80	0.80	1.61E−02	4	45	LBY80	0.79	2.07E−02	4	20
LBY80	0.79	1.14E−02	9	47	LBY80	0.73	1.72E−02	9	28
LBY80	0.70	3.53E−02	9	45	LBY80	0.74	2.32E−02	9	20
LBY80	0.73	1.62E−02	2	27	LBY80	0.74	1.41E−02	2	31
LBY80	0.71	2.21E−02	2	38	LBY81	0.74	1.44E−02	3	1
LBY81	0.85	1.99E−03	3	3	LBY81	0.79	6.20E−03	3	2
LBY81	0.72	1.82E−02	3	5	LBY81	0.85	3.95E−03	8	1
LBY81	0.78	1.33E−02	8	3	LBY81	0.71	7.11E−02	8	45
LBY81	0.72	6.56E−02	8	20	LBY81	0.73	2.51E−02	8	2
LBY81	0.96	5.97E−05	8	5	LBY81	0.71	3.07E−02	1	44
LBY81	0.86	1.35E−03	1	48	LBY81	0.75	1.22E−02	1	51
LBY81	0.89	6.41E−04	1	50	LBY81	0.85	1.71E−03	1	24
LBY81	0.92	1.93E−04	1	49	LBY81	0.86	1.27E−03	1	52
LBY81	0.80	9.31E−03	1	21	LBY81	0.92	3.00E−03	1	25
LBY81	0.72	4.56E−02	4	22	LBY81	0.71	2.17E−02	9	14
LBY81	0.81	8.02E−03	9	47	LBY81	0.76	1.13E−02	9	51
LBY81	0.85	3.75E−03	9	45	LBY81	0.71	3.24E−02	9	20
LBY81	0.72	2.79E−02	2	22	LBY82	0.73	1.61E−02	3	16
LBY82	0.75	1.87E−02	8	33	LBY82	0.71	3.12E−02	8	39
LBY82	0.71	1.12E−01	8	25	LBY82	0.86	3.05E−03	9	44
LBY82	0.71	3.24E−02	9	23	LBY82	0.78	1.36E−02	9	21
LBY83	0.71	2.08E−02	3	1	LBY83	0.75	1.17E−02	3	16
LBY83	0.70	2.33E−02	3	17	LBY83	0.73	1.61E−02	1	13
LBY83	0.78	7.17E−03	1	12	LBY83	0.72	1.86E−02	2	32
LBY84	0.98	5.65E−05	8	44	LBY84	1.00	3.12E−06	8	23
LBY84	0.82	6.85E−03	8	14	LBY84	0.99	2.72E−05	8	47
LBY84	0.79	1.13E−02	8	48	LBY84	0.86	2.92E−03	8	51
LBY84	0.72	2.75E−02	8	8	LBY84	0.75	1.92E−02	8	50
LBY84	0.75	1.97E−02	8	24	LBY84	0.97	2.07E−04	8	45
LBY84	0.98	1.17E−04	8	20	LBY84	0.76	1.66E−02	8	49
LBY84	0.80	9.56E−03	8	52	LBY84	0.98	1.15E−04	8	21
LBY84	0.76	8.00E−02	8	25	LBY84	0.73	1.70E−02	1	1
LBY84	0.80	9.09E−03	1	44	LBY84	0.81	8.51E−03	1	23
LBY84	0.88	8.82E−04	1	14	LBY84	0.84	4.89E−03	1	47
LBY84	0.89	1.41E−03	1	45	LBY84	0.87	2.52E−03	1	20
LBY84	0.77	1.60E−02	1	21	LBY84	0.89	5.76E−04	1	5
LBY84	0.81	4.85E−03	9	36	LBY84	0.75	1.23E−02	9	27
LBY84	0.81	4.35E−03	9	35	LBY84	0.75	1.30E−02	9	31
LBY84	0.74	1.45E−02	9	30	LBY84	0.77	8.62E−03	2	12
LBY85	0.80	4.96E−03	3	48	LBY85	0.79	6.11E−03	3	50
LBY85	0.71	2.13E−02	3	49	LBY85	0.80	1.01E−02	1	22
LBY85	0.80	5.09E−03	1	49	LBY85	0.71	2.10E−02	9	48
LBY85	0.72	1.97E−02	9	51	LBY85	0.85	2.05E−03	2	43
LBY85	0.81	4.66E−03	2	10	LBY85	0.80	5.98E−03	2	42
LBY86	0.78	1.29E−028	8	12	LBY86	0.82	3.94E−03	1	48
LBY86	0.76	1.06E−02	1	51	LBY86	0.77	9.06E−03	1	50
LBY86	0.77	8.69E−03	1	24	LBY86	0.76	1.79E−02	1	22
LBY86	0.74	1.43E−02	1	52	LBY86	0.79	6.62E−03	4	14
LBY86	0.71	3.24E−02	2	44	LBY86	0.73	2.66E−02	2	23
LBY86	0.75	1.33E−02	2	48	LBY86	0.70	2.36E−02	2	51
LBY86	0.74	1.41E−02	2	50	LBY86	0.88	8.94E−04	2	24
LBY86	0.76	1.01E−02	2	49	LBY86	0.78	1.28E−02	2	21
LBY86	0.83	2.09E−02	2	25	LBY87	0.75	1.88E−02	8	9
LBY87	0.72	2.99E−02	8	13	LBY87	0.74	2.33E−02	8	12
LBY87	0.92	9.52E−03	8	25	LBY87	0.75	1.23E−02	9	48
LBY87	0.81	4.17E−03	9	51	LBY87	0.81	4.34E−03	2	48
LBY87	0.72	1.88E−02	2	51	LBY87	0.84	2.20E−03	2	50
LBY87	0.80	5.95E−03	2	24	LBY87	0.91	2.35E−04	2	49
LBY87	0.75	1.27E−02	2	12	LBY87	0.91	2.28E−04	2	52
LBY87	0.73	6.04E−02	2	25	LBY88	0.80	2.97E−02	8	22
LBY88	0.81	4.53E−03	1	48	LBY88	0.73	1.65E−02	1	51
LBY88	0.79	6.62E−03	1	50	LBY88	0.88	8.79E−04	1	24
LBY88	0.78	1.39E−02	1	22	LBY88	0.78	7.49E−03	1	49
LBY88	0.77	4.12E−02	1	25	LBY88	0.81	1.55E−02	4	22
LBY88	0.71	2.24E−02	9	14	LBY88	0.76	1.86E−02	9	47
LBY88	0.79	6.47E−03	9	16	LBY88	0.80	1.01E−02	9	45
LBY88	0.79	6.43E−03	9	17	LBY88	0.8	9.21E−03	2	22
LBY89	0.93	8.71E−05	3	16	LBY89	0.71	2.14E−02	3	35
LBY89	0.76	1.77E−02	3	45	LBY89	0.87	1.11E−03	3	17
LBY89	0.85	4.08E−03	8	43	LBY89	0.73	2.69E−02	8	10
LBY89	0.76	1.66E−02	8	42	LBY89	0.78	1.39E−02	8	39
LBY89	0.75	1.25E−02	4	11	LBY89	0.72	1.87E−02	4	51
LBY89	0.71	2.08E−02	4	8	LBY89	0.70	2.34E−02	9	51
LBY90	0.88	9.52E−03	8	44	LBY90	0.94	1.85E−03	8	23
LBY90	0.88	8.72E−03	8	47	LBY90	0.89	1.44E−03	8	48
LBY90	0.88	1.69E−03	8	51	LBY90	0.89	1.14E−03	8	50
LBY90	0.81	8.21E−03	8	24	LBY90	0.92	3.33E−03	8	45
LBY90	0.95	9.06E−04	8	20	LBY90	0.93	3.19E−04	8	49
LBY90	0.94	1.54E−04	8	52	LBY90	0.96	4.86E−04	8	21
LBY90	0.76	8.17E−02	8	25	LBY90	0.72	1.80E−02	1	48
LBY90	0.76	1.14E−02	1	50	LBY90	0.77	9.07E−03	1	24
LBY90	0.83	5.22E−03	1	22	LBY90	0.83	3.12E−03	1	49
LBY90	0.71	2.19E−02	1	52	LBY90	0.74	5.78E−02	1	25
LBY90	0.74	2.37E−02	9	23	LBY90	0.93	3.04E−04	9	47
LBY90	0.78	8.23E−03	9	48	LBY90	0.79	6.01E−03	9	51
LBY90	0.73	1.55E−02	9	50	LBY90	0.70	2.39E−02	9	24
LBY90	0.93	2.64E−04	9	45	LBY90	0.92	3.93E−04	9	20
LBY90	0.78	7.96E−03	9	52	LBY90	0.75	1.20E−02	2	24
LBY91	0.81	8.47E−03	8	49	LBY91	0.82	6.37E−03	8	52
LBY91	0.81	4.45E−03	4	14	LBY91	0.71	2.08E−02	4	51
LBY91	0.80	1.77E−02	4	20	LBY91	0.76	1.10E−02	4	52
LBY92	0.79	3.43E−02	8	44	LBY92	0.73	6.23E −02	8	47
LBY92	0.75	1.89E−02	8	17	LBY92	0.72	7.07E−02	8	20
LBY92	0.72	6.98E−02	8	21	LBY92	0.74	1.46E−02	1	9
LBY92	0.75	2.06E−02	1	44	LBY92	0.77	1.51E−02	1	23
LBY92	0.85	1.94E−03	1	14	LBY92	0.74	2.17E−02	1	47
LBY92	0.71	2.17E−02	1	11	LBY92	0.71	2.24E−02	1	13
LBY92	0.77	8.82E−03	1	8	LBY92	0.84	4.31E−03	1	45
LBY92	0.79	1.05E−02	1	20	LBY92	0.77	1.59E−02	1	21
LGN52	0.71	3.36E−02	3	22	LGN52	0.74	2.37E−02	8	42
LGN52	0.82	3.30E−03	4	4	LGN52	0.71	2.14E−02	4	2
LGN52	0.93	8.45E−05	9	43	LGN52	0.95	1.88E−05	9	10
LGN52	0.92	1.41E−04	9	42	LGN52	0.78	8.25E−03	2	43
LGN52	0.88	8.36E−04	2	10	LGN52	0.89	6.05E−04	2	38
LGN52	0.80	5.49E−03	2	42	LGN52	0.78	7.42E−03	2	39
LGN60	0.79	1.22E−02	3	23	LGN60	0.71	3.28E−02	3	20
LGN60	0.74	2.20E−02	3	21	LGN60	0.76	1.73E−02	8	51
LGN60	0.77	1.62E−02	9	23	LGN60	0.86	3.30E−03	9	47
LGN60	0.81	4.48E−03	9	48	LGN60	0.82	3.84E−03	9	51
LGN60	0.78	7.99E−03	9	50	LGN60	0.76	1.03E−02	9	24
LGN60	0.70	3.50E−02	9	45	LGN60	0.83	5.71E−03	9	20
LGN60	0.75	1.19E−02	9	49	LGN60	0.82	3.71E−03	9	52
LGN60	0.76	9.98E−03	2	14	LGN60	0.82	7.09E−03	2	47
LGN60	0.74	1.43E−02	2	48	LGN60	0.80	5.04E−03	2	51
LGN60	0.76	1.11E−02	2	8	LGN60	0.80	5.05E−03	2	50
LGN60	0.79	1.10E−02	2	45	LGN60	0.71	3.13E−02	2	20
LGN60	0.82	3.78E−03	2	49	LGN60	0.82	3.70E−03	2	52

Table 203. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 191. “Exp. Set”—Expression set specified in Table 190. “R”=Pearson correlation coefficient: “P”=p value

TABLE 204
Correlation between the expression level of selected genes of some embodiments of the invention in various
tissues and the phenotypic performance under low N conditions (set 2 parameters) across Foxtail millet varieties
				Corr.					Corr.
Gene		P	Exp.	Set	Gene		P	Exp.	Set
Name	R	value	set	ID	Name	R	value	set	ID
LBY3	0.71	3.09E−02	8	5	LBY3	0.82	1.21E−02	8	8
LBY3	0.81	1.41E−02	8	6	LBY3	0.95	1.07E−04	1	12
LBY3	0.84	5.04E−03	1	10	LBY3	0.72	2.84E−02	1	13
LBY56	0.84	4.77E−03	1	10	LBY56	0.72	1.81E−02	4	9
LBY58	0.75	3.04E−02	8	12	LBY58	0.71	4.96E−02	8	8
LBY58	0.74	3.48E−02	8	6	LBY58	0.71	3.21E−02	9	2
LBY58	0.74	1.50E−02	4	9	LBY58	0.75	1.23E−02	4	13
LBY59	0.71	4.99E−02	8	8	LBY59	0.72	4.43E−02	8	6
LBY59	0.93	2.52E−04	1	12	LBY59	0.71	3.26E−02	1	8
LBY59	0.72	2.81E−02	1	6	LBY59	0.77	9.82E−03	2	5
LBY59	0.83	6.17E−03	2	8	LBY59	0.76	1.81E−02	2	6
LBY61	0.70	3.52E−02	3	4	LBY61	0.79	1.15E−02	3	11
LBY61	0.71	3.27E−02	9	2	LBY61	0.80	9.43E−03	1	8
LBY61	0.82	7.19E−03	1	6	LBY62	0.82	1.29E−02	8	11
LBY62	0.80	8.90E−03	1	7	LBY62	0.72	2.87E−02	2	10
LBY62	0.89	1.49E−03	2	11	LBY63	0.84	4.15E−03	3	9
LBY63	0.85	3.85E−03	2	7	LBY64	0.82	1.29E−02	8	9
LBY64	0.85	3.53E−03	1	12	LBY65	0.86	3.02E−03	3	4
LBY65	0.86	2.93E−03	3	11	LBY65	0.74	2.19E−02	8	5
LBY65	0.75	3.24E−02	8	10	LBY65	0.82	1.36E−02	8	8
LBY65	0.78	2.35E−02	8	6	LBY65	0.70	3.42E−02	1	9
LBY65	0.79	1.13E−02	1	12	LBY65	0.73	2.43E−02	1	13
LBY65	0.70	3.55E−02	2	3	LBY66	0.74	2.34E−02	9	2
LBY66	0.74	2.16E−02	1	1	LBY66	0.81	7.64E−03	2	7
LBY67	0.72	4.48E−02	8	12	LBY67	0.87	2.07E−03	9	13
LBY67	0.90	8.08E−04	2	2	LBY67	0.81	8.28E−03	2	13
LBY68	0.72	2.93E−02	3	9	LBY68	0.78	1.23E−02	9	12
LBY68	0.80	1.02E−02	9	13	LBY68	0.70	3.57E−02	1	10
LBY68	0.90	4.40E−04	4	2	LBY69	0.73	2.57E−02	3	7
LBY69	0.76	2.86E−02	8	7	LBY69	0.83	1.16E−02	8	8
LBY69	0.73	3.88E−02	8	6	LBY69	0.73	1.69E−02	4	7
LBY69	0.72	2.91E−02	2	7	LBY70	0.77	1.61E−02	3	4
LBY70	0.75	1.87E−02	3	11	LBY70	0.76	1.73E−02	9	9
LBY70	0.71	3.19E−02	2	12	LBY70	0.73	2.45E−02	2	10
LBY70	0.79	1.05E−02	2	13	LBY71	0.97	6.55E−05	8	8
LBY71	0.97	7.48E−05	8	6	LBY71	0.90	1.10E−03	1	12
LBY71	0.76	1.68E−02	1	8	LBY71	0.78	1.28E−02	1	6
LBY71	0.76	1.15E−02	4	2	LBY71	0.84	4.55E−03	2	8
LBY71	0.81	8.40E−03	2	6	LBY72	0.75	1.17E−02	4	7
LBY72	0.71	3.07E−02	2	12	LBY72	0.84	4.96E−03	2	13
LBY73	0.85	3.91E−03	3	11	LBY73	0.74	2.33E−02	9	2
LBY73	0.72	2.92E−02	2	13	LBY74	0.85	3.61E−03	3	11
LBY74	0.80	1.61E−02	8	9	LBY74	0.75	3.38E−02	8	12
LBY74	0.87	5.33E−03	8	13	LBY74	0.72	2.93E−02	9	9
LBY74	0.87	2.23E−03	9	13	LBY74	0.76	1.07E−02	4	10
LBY74	0.71	3.21E−02	2	2	LBY75	0.81	1.45E−02	8	12
LBY75	0.70	3.55E−02	1	1	LBY75	0.97	1.22E−05	1	12
LBY75	0.73	2.60E−02	1	8	LBY75	0.75	2.08E−02	1	6
LBY76	0.75	1.88E−02	3	11	LBY76	0.77	2.52E−02	8	4
LBY76	0.81	1.58E−02	8	13	LBY76	0.78	7.80E−03	1	5
LBY76	0.73	2.69E−02	1	12	LBY76	0.75	2.00E−02	1	8
LBY76	0.78	1.24E−02	1	6	LBY77	0.85	3.56E−03	3	9
LBY77	0.88	3.55E−03	8	9	LBY77	0.81	1.57E−02	8	13
LBY77	0.87	2.01E−03	9	9	LBY77	0.86	2.64E−03	1	12
LBY77	0.86	1.23E−03	4	9	LBY77	0.71	2.12E−02	4	13
LBY78	0.72	4.21E−02	8	7	LBY78	0.77	1.47E−02	1	7
LBY78	0.80	1.02E−02	1	13	LBY78	0.80	9.29E−03	2	7
LBY79	0.70	3.53E−02	3	1	LBY79	0.71	4.80E−02	8	9
LBY79	0.85	3.47E−03	9	13	LBY80	0.70	5.21E−02	8	7
LBY80	0.95	3.98E−04	8	4	LBY80	0.88	4.33E−03	8	11
LBY80	0.77	1.59E−02	1	11	LBY80	0.74	2.21E−02	2	4
LBY81	0.80	8.89E−03	9	13	LBY81	0.93	2.26E−04	1	12
LBY81	0.72	2.91E−02	1	13	LBY81	0.79	1.05E−02	2	8
LBY81	0.73	2.68E−02	2	6	LBY82	0.78	1.23E−02	3	4
LBY83	0.78	1.22E−02	1	10	LBY84	0.70	3.41E−02	3	11
LBY84	0.80	1.77E−02	8	12	LBY84	0.85	7.91E−03	8	13
LBY85	0.78	1.23E−02	3	9	LBY85	0.79	1.17E−02	3	2
LBY85	0.86	6.72E−03	8	2	LBY85	0.84	4.30E−03	9	9
LBY85	0.74	2.17E−02	9	13	LBY85	0.92	4.75E−04	1	12
LBY85	0.71	3.32E−02	1	8	LBY85	0.73	2.57E−02	1	6
LBY85	0.82	3.74E−03	4	2	LBY85	0.72	2.95E−02	2	8
LBY86	0.77	1.47E−02	9	9	LBY86	0.81	8.12E−03	9	13
LBY86	0.74	2.17E−02	1	9	LBY86	0.79	1.21E−02	1	13
LBY86	0.95	7.11E−05	2	12	LBY87	0.70	3.48E−02	3	11
LBY87	0.74	2.17E−02	2	12	LBY87	0.86	3.03E−03	2	13
LBY88	0.77	2.66E−02	8	12	LBY88	0.92	3.90E−04	1	12
LBY88	0.74	2.19E−02	1	8	LBY88	0.76	1.64E−02	1	6
LBY88	0.78	1.23E−02	2	8	LBY88	0.77	1.56E−02	2	6
LBY90	0.77	2.41E−02	8	9	LBY90	0.74	3.65E−02	8	12
LBY90	0.93	8.11E−04	8	13	LBY90	0.70	3.40E−02	9	9
LBY90	0.86	3.25E−03	9	13	LBY90	0.96	3.50E−05	1	12
LBY90	0.72	2.93E−02	1	8	LBY90	0.75	1.99E−02	1	6
LBY90	0.75	2.08E−02	2	13	LBY91	0.71	2.19E−02	4	9
LBY91	0.79	6.64E−03	4	13	LBY92	0.73	2.43E−02	1	9
LBY92	0.83	6.13E−03	1	13	LGN52	0.79	1.21E−02	3	9
LGN52	0.79	1.92E−02	8	7	LGN52	0.74	2.21E−02	9	7
LGN52	0.91	5.97E−04	2	7	LGN60	0.71	3.22E−02	3	13
LGN60	0.88	1.87E−03	9	13	LGN60	0.83	5.65E−03	2	9
LGN60	0.76	1.81E−02	13	13

Table 204. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 192. “Exp. Set”—Expression set specified in Table 190. “R”=Pearson correlation coefficient; “P”=p value.

Example 22

Production of Foxtail Millet Transcriptome and High Throughput Correlation Analysis with Yield Related Parameters Measured in Fields Using 65K Foxtail Millet Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a Foxtail millet oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 65,000 Foxtail millet genes and transcripts. In order to define correlations between the levels of RNA expression with yield components or vigor related parameters, various plant characteristics of 51 different Foxtail millet inbreds were analyzed. Among them, 49 inbreds encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

51 Foxtail millet varieties were grown in 4 repetitive plots, in field. Briefly, the growing protocol was as follows:

Regular growth conditions: foxtail millet plants were grown in the field using commercial fertilization and irrigation protocols, which include 202 m³ water per dunam (1000 square meters) per entire growth period and fertilization of 12 units of URAN® 32% (Nitrogen Fertilizer Solution; PCS Sales, Northbrook. Ill., USA) (normal growth conditions).

Analyzed Foxtail millet tissues—49 selected Foxtail millet inbreds were sampled. Tissues [leaf, panicle and peduncle] representing different plant characteristics, from plants growing under normal conditions were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 205 below.

TABLE 205
Foxtail millet transcriptome expression sets in field experiment
Expression Set                   Set ID
Panicle grown under normal conditions, flowering 1
stage
Leaf grown under normal conditions, seedling stage 2
Peduncle grown under normal conditions, flowering 3
stage

Table 205: Provided are the foxtail transcriptome expression sets. Peduncle=stem below the panicle.

Foxtail millet yield components and vigor related parameters assessment—Plants were phenotyped as shown in Table 206 below. Some of the following parameters were collected using digital imaging system:

1000 grain (seed) weight (gr)—was calculated using Formula XIV above.

1000 grain weight filling rate (gr./day)—was calculated based on Formula XXXVI above.

Average heads dry weight per plant at heading (gr.)—At the process of the growing period heads of 3 plants per plot were collected (heading stage). Heads were weighted after oven dry (dry weight), and the weight was divided by the number of plants.

Average internode length (cm)—Plant heights of 4 plants per plot were measured at harvest and divided by plant number. The average plant height was divided by the average number of nodes.

Average main tiller leaves dry weight per plant at heading (gr.)—At heading stage, main tiller leaves were collected from 3 plants per plot and dried in an oven to obtain the leaves dry weight. The obtained leaves dry weight was divided by the number of plants.

Average seedling dry weight (gr)—At seedling stage, shoot material of 4 plants per plot (without roots) was collected and dried in an oven to obtain the dry weight. The obtained values were divided by the number of plants.

Average shoot dry weight (gr)—During the vegetative growing period, shoot material of 3 plants per plot (without roots) was collected and dried in an oven to obtain the dry weight. The obtained values were divided by the number of plants.

Average total dry matter per plant at harvest (kg)—Average total dry matter per plant was calculated as follows: average head weight per plant at harvest+average vegetative dry weight per plant at harvest.

Average total dry matter per plant at heading (gr)—Average total dry matter per plant was calculated as follows: average head weight per plant at heading+average vegetative dry weight per plant at heading.

Average vegetative dry weight per plant at harvest (kg)—At the end of the growing period all vegetative material (excluding roots and heads) were collected and weighted after oven dry (dry weight). The biomass was then divided by the total number of square meters. To obtain the biomass per plant the biomass per square meter was divided by the number of plants per square meter.

Average vegetative dry weight per plant at heading (gr)—At the heading stage, all vegetative material (excluding roots) were collected and weighted after (dry weight) oven dry. The biomass per plant was calculated by dividing total biomass by the number of plants.

Calculated grains per dunam (number)—Calculated by dividing grains yield per dunam by average grain weight.

Dry matter partitioning (ratio)—Dry matter partitioning was calculated based on Formula XXXV.

Grain area (cm²)—At the end of the growing period the grains were separated from the head. A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Grain fill duration (num)—Duration of grain filling period was calculated by subtracting the number of days to flowering from the number of days to maturity.

Grain length (cm)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths (longest axis) was measured from those images and was divided by the number of grains.

Grain width (cm)—At the end of the growing period the grains were separated from the ear. A sample of ˜200 grains were weighted, photographed and images were processed using the below described image processing system. The sum of grain width (longest axis) was measured from those images and was divided by the number of grains.

Grains yield per dunam (kg)—At the end of the growing period heads were collected (harvest stage). Heads were separately threshed and grains were weighted (grain yield). Grains yield per dunam was calculated by multiplying grain yield per m² by 1000 (dunam is 1000 m²).

Grains yield per head (gr.)—At the end of the experiment all heads were collected. 6 main heads from 6 plants per plot were separately threshed and grains were weighted. The average grain weight per head was calculated by dividing the total grain weight of the 6 heads by the number of heads.

Grains yield per plant (gr.)—At the end of the experiment all plants were collected. All heads from 6 plants per plot were separately threshed and grains were weighted. The average grain weight per plant was calculated by dividing the total grain weight of the 6 plants by the number of plants.

Harvest index (number)—was calculated based on Formula XV above.

Head area (cm²)—At the end of the growing period 6 main heads from 6 plants per plot were photographed and images were processed using the below described image processing system. The head area was measured from those images and was divided by the number of heads.

Head length (cm)—At the end of the growing period 6 heads from 6 plants per plot were photographed and images were processed using the below described image processing system. The head length (longest axis) was measured from those images and was divided by the number of heads.

Head width (cm)—At the end of the growing period 6 main heads of 6 plants per plot were photographed and images were processed using the below described image processing system. The head width (longest axis) was measured from those images and was divided by the number of heads.

Heads per plant (number)—At the end of the growing period total number of 6 plants heads per plot was counted and divided by the number of plants.

Leaves area per plant at heading (cm)—Total green leaves area per plant at heading. Leaf area of 3 plants was measured separately using a leaf area-meter. The obtained leaf area was divided by 3 to obtain leaf area per plant.

Leaves dry weight at heading (gr.)—Leaves dry weight was measured at heading stage by collecting all leaves material of 3 plants per plot and weighting it after oven dry (dry weight).

Leaves num at heading (number)—Plants were characterized for leaf number during the heading stage. Plants were measured for their leaf number by separately counting all green leaves of 3 plants per plot.

Leaves temperature_1 (° Celsius)—Leaf temperature was measured using Fluke IR thermometer 568 device. Measurements were done on opened flag leaf.

Lower stem width at heading (mm)—At heading stage lower stem internodes from 3 plants were separated from the plant and their diameter was measured using a caliber.

Main heads dry weight at harvest (gr.)—At the end of the growing period (harvest stage) main heads of 6 plants per plot were collected and weighted after oven dry (dry weight).

Main heads grains number (number)—At the end of the growing period (harvest stage) all plants were collected. Main heads from 6 plants per plot were threshed and grains were counted.

Main heads grains yield (gr.)—At the end of the growing period (harvest stage) all plants were collected. Main heads from 6 plants per plot were threshed and grains were weighted.

Main stem dry weight at harvest (gr.)—At the end of the experiment all plants were collected. Main stems from 6 plants per plot were separated from the rest of the plants, oven dried and weighted to obtain their dry weight.

Nodes number (number)—Nodes number was counted in main culm in 6 plants at heading stage.

Number days to flag leaf senescence (number)—the number of days from sowing till 50% of the plot arrives to flag leaf senescence (above half of the leaves are yellow).

Number days to heading (number)—the number of days from sowing till 50% of the plot arrives to heading.

Number days to tan (number)—the number of days from sowing till 50% of the plot arrives to tan.

Peduncle thickness per plant at heading (mm)—Peduncle thickness was obtained at heading stage by measuring the diameter of main culm just above auricles of flag leaf.

Plant height (cm)—Plants were measured for their height at harvest stage using a measuring tape. Height was measured from ground level to the point below the head.

Plant weight growth (gr./day)—Plant weight growth was calculated based on Formula VII above.

SPAD at grain filling (SPAD unit)—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at grain filling stage. SPAD meter readings were done on fully developed leaves of 4 plants per plot by performing three measurements per leaf per plant.

SPAD at vegetative stage (SPAD unit)—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at vegetative stage. SPAD meter readings were done on fully developed leaves of 4 plants per plot by performing three measurements per leaf per plant.

Specific leaf area at heading (cm²/gr.)—was calculated according to Formula XXXVII above.

Tillering per plant at heading (number)—Tillers of 3 plants per plot were counted at heading stage and divided by the number of plants.

Vegetative dry weight at flowering/water until flowering (gr./lit)—was calculated according to Formula XXXVIII above.

Vegetative dry weight (kg)—At the end of the growing period all vegetative material (excluding roots and heads) were collected and weighted after oven dry. The weight of plants is per one meter.

Yield filling rate (gr./day)—was calculated according to Formula XXXIX above.

Yield per dunam/water until tan (kg/ml)—was calculated according to Formula XXXX above.

Yield per plant/water until tan (gr/ml)—was calculated according to Formula XXXXI above.

Data parameters collected are summarized in Table 206, herein below.

TABLE 206
Foxtail millet correlated parameters under normal conditions (vectors)
Correlated parameter with        Correlation ID
1000 grain weight [gr.]          1
1000 grain weight filling rate [gr./day] 2
Average Heads DW per plant (HD) [gr.] 3
Average Seedling DW [gr.]        4
Average Shoot DW_[gr.]           5
Average Total dry matter per plant (H) [kg] 6
Average r Total dry matter per plant (HD) [gr.] 7
Average Vegetative DW per plant (H) [kg] 8
Average Vegetative DW per plant (HD) [gr.] 9
Average internode length [cm]    10
Average main Stem DW (H) [gr.]   11
Average main tiller Leaves DW per plant (HD) [gr.] 12
CV (Grain area) [%]              13
CV (Grain length) [%]            14
CV (Grain width) [%]             15
Calculated Grains per dunam [number] 16
Dry matter partitioning [ratio]  17
Field Head Width [cm]            18
Grain area [cm2]                 19
Grain fill duration [days]       20
Grain length [cm]                21
Grain width [cm]                 22
Grains Yield per dunam [kg]      23
Grains Yield per plant [gr.]     24
Grains yield per Head [gr.]      25
Harvest index [number]           26
Head Area [cm2]                  27
Head Width [cm]                  28
Heads per plant [number]         29
Leaves DW (HD) [gr.]             30
Leaves area per plant (HD) [cm2] 31
Leaves num (HD) [number]         32
Leaves temperature [Celsius]     33
Lower Stem width (HD) [mm]       34
Main Heads DW (H) [gr,]          35
Main heads Grains num [number]   36
Main heads Grains yield [gr.]    37
Nodes num [number]               38
Num days Flag leaf senescence [number] 39
Num days to Heading [number]     40
Num days to Tan [number]         41
Peduncle thickness per plant (HD) [mm] 42
Plant height [cm]                43
Plant weight growth [gr./day]    44
SPAD (GF) [SPAD unit]            45
SPAD_(veg) [SPAD unit]           46
Specific leaf area (HD) [cm2gr.] 47
Tillering per plant (HD) [num]   48
VDW (F)/water until heading [gr./lit] 49
Vegetative DW [kg]               50
Yield filling rate [gr./day]     51
Yield per dunam/water until tan [kg/ml] 52
Yield per plant/water until tan [gr./ml] 53
Main Stem DW (H) [gr.]           54

Table 206. Provided are the Foxtail millet correlated parameters (vectors). “gr.”=grams; “kg”=kilograms; “SPAD”=chlorophyll levels; “DW”=Plant Dry weight; “GF”=grain filling growth stage; “F”=flowering stage; “H”=harvest stage; “hd”=heading growth stage; “Avr”—average; “num”—number; “cm”—centimeter; “veg”=vegetative stage. VDW”=vegetative dry weight; “TDM”=Total dry matter; “lit”—liter: “CV”=coefficient of variation (%).

Experimental Results

51 different Foxtail millet inbreds were grown and characterized for different parameters (Table 206). 49 lines were selected for expression analysis. The average for each of the measured parameter was calculated using the JMP software (Tables 207-211) and a subsequent correlation analysis was performed (Table 212). Results were then integrated to the database.

TABLE 207
Measured parameters in Foxtail millet accessions under normal conditions
L/
Corr.
ID	1	2	3	4	5	6	7	8	9
L-1	3.208	0.134	10.147	0.511	7.660	0.130	51.761	0.064	41.614
L-2	2.154	0.061	33.467	0.252	6.325	0.095	99.808	0.044	66.342
L-3	2.677	0.096	7.593	0.553	7.712	0.147	56.331	0.065	48.738
L-4	3.932	0.109	5.847	0.730	6.713	0.140	49.564	0.068	43.718
L-5	3.584	0.112	4.278	0.487	5.842	0.069	37.041	0.034	32.762
L-6	3.087	0.094	10.188	0.456	7.750	0.132	56.967	0.057	46.779
L-7	3.103	0.069	7.784	0.478	9.359	0.117	69.368	0.066	61.584
L-8	3.297	0.094	2.448	0.548	5.723	0.088	55.047	0.056	52.598
L-9	2.738	0.098	6.027	0.463	6.472	0.090	41.753	0.045	35.727
L-10	2.775	0.099	6.747	0.361	8.378	0.083	50.306	0.043	43.559
L-11	3.116	0.068	8.867	0.553	10.585	0.114	47.990	0.046	39.123
L-12	3.444	0.073	6.311	0.465	5.718	0.159	52.453	0.076	46.142
L-13	2.914	0.050	2.819	0.559	11.420	0.075	22.454	0.038	19.635
L-14	3.103	0.108	8.452	0.344	6.838	0.091	94.874	0.061	86.423
L-15	3.530	0.091	3.936	0.534	7.591	0.078	35.256	0.037	31.321
L-16	3.576	0.069	3.200	0.597	12.147	0.093	26.559	0.050	23.359
L-17	2.837	0.092	7.730	0.670	8.237	0.070	39.558	0.026	31.829
L-18	3.139	0.059	2.683	0.521	7.299	0.119	25.120	0.059	22.437
L-19	3.255	0.128	6.551	0.347	6.683	0.095	33.126	0.046	26.575
L-20	2.751	0.098	4.975	0.346	8.865	0.118	34.057	0.067	29.082
L-21	2.753	0.089	6.103	0.558	9.557	0.097	29.286	0.050	23.183
L-22	2.909	0.107	4.842	0.434	8.093	0.094	31.300	0.045	26.458
L-23	2.358	0.076	1.658	0.269	5.851	0.054	9.614	0.026	11.161
L-24	2.715	0.097	4.715	0.448	6.207	0.079	25.785	0.033	21.070
L-25	4.374	0.169	7.418	0.364	5.400	0.080	30.032	0.031	22.614
L-26	3.464	0.123	9.505	0.442	3.918	0.080	37.617	0.029	28.113
L-27	2.190	0.084	3.478	0.470	6.974	0.105	50.380	0.065	46.903
L-28	3.081	0.135	6.490	0.460	4.592	0.099	53.233	0.046	46.743
L-29	2.250	0.091	6.998	0.317	4.893	0.107	63.263	0.056	56.265
L-30	2.205	0.114	4.700	0.245	3.628	0.070	31.946	0.045	27.246
L-31	4.027	0.130	2.821	0.371	5.728	0.053	15.271	0.019	12.450
L-32	3.141	0.081	6.290	0.589	6.377	0.093	59.825	0.048	53.535
L-33	3.008	0.120	5.783	0.497	7.686	0.092	72.317	0.060	66.535
L-34	3.633	0.137	6.710	0.499	6.853	0.117	50.777	0.070	44.067
L-35	NA	NA	4.130	0.307	4.770	0.097	58.229	0.071	54.099
L-36	3.400	0.138	6.720	0.588	7.298	0.094	83.265	0.055	76.545
L-37	2.582	0.098	4.713	0.516	6.683	0.068	70.256	0.044	65.543
L-38	2.758	0.086	6.511	0.520	9.272	0.079	101.692	0.056	95.181
L-39	3.662	0.115	8.973	0.400	8.886	0.098	73.627	0.051	64.654
L-40	2.869	0.098	7.036	0.440	8.166	0.065	66.610	0.044	59.574
L-41	3.202	0.121	10.416	0.513	7.105	0.068	104.128	0.044	93.712
L-42	2.773	0.087	6.421	0.469	7.333	0.125	90.612	0.077	84.191
L-43	3.644	0.074	3.959	0.516	9.263	0.176	50.238	0.093	46.279
L-44	3.179	0.064	4.466	0.573	6.958	0.080	74.387	0.047	69.921
L-45	2.809	0.104	1.668	0.441	5.720	0.082	22.522	0.035	20.854
L-46	2.729	0.097	3.372	0.521	9.980	0.069	20.338	0.035	16.967
L-47	3.070	0.088	1.187	0.553	7.092	0.086	16.061	0.045	14.873
L-48	2.937	0.109	7.150	0.450	5.181	0.059	33.797	0.033	26.647
L-49	3.180	0.091	1.593	0.443	7.718	0.104	34.323	0.056	32.730

Table 207: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 208
Additional measured parameters in Foxtail millet accessions under normal growth conditions
L/
Corr.
ID	10	11	12	13	14	15	16	17	18	19	20
L-1	12.686	10.313	2.612	6.099	5.497	3.996	1676.9	60.631	19.032	0.0375	24.0
L-2	10.142	6.468	1.459	7.378	5.309	5.237	944.0	64.283	19.270	0.0219	35.3
L-3	14.277	12.260	2.910	7.292	6.030	5.838	1495.9	102.784	20.593	0.0252	28.0
L-4	11.986	22.069	4.932	11.818	7.687	7.170	1952.9	79.206	29.108	0.0310	36.0
L-5	10.970	26.449	6.151	12.920	8.473	8.127	1051.3	52.837	29.004	0.0296	32.0
L-6	12.081	11.044	2.928	8.158	5.198	6.360	1471.2	97.580	26.820	0.0281	32.8
L-7	12.542	1.960	0.500	10.456	7.250	7.683	1132.8	41.680	12.018	0.0271	45.0
L-8	12.779	7.057	2.227	7.155	4.667	5.252	1232.5	29.373	11.824	0.0273	35.5
L-9	11.794	4.539	1.179	7.347	5.689	5.327	1097.0	60.904	10.365	0.0266	28.0
L-10	12.770	5.456	1.493	6.250	4.725	5.464	1224.3	54.117	12.463	0.0271	28.0
L-11	14.431	3.253	0.719	11.091	6.955	6.691	1342.0	113.742	17.098	0.0257	46.0
L-12	15.967	2.693	0.491	8.547	7.227	6.783	1095.1	129.888	11.823	0.0303	47.0
L-13	14.503	2.828	0.600	8.529	7.111	5.815	963.1	70.391	10.306	0.0267	58.0
L-14	10.829	7.429	2.678	6.738	4.610	5.097	954.9	24.402	11.778	0.0261	29.0
L-15	11.397	2.635	0.879	7.872	6.023	5.222	1459.9	55.647	11.313	0.0319	39.0
L-16	12.088	2.557	0.681	10.377	8.299	6.394	1586.6	58.556	11.380	0.0288	52.0
L-17	11.851	2.519	0.730	11.656	8.375	7.661	1501.1	120.670	14.759	0.0266	31.0
L-18	17.928	2.130	0.560	10.740	6.469	7.048	1220.2	63.720	11.093	0.0273	53.0
L-19	12.491	29.343	5.763	12.832	7.121	7.363	928.7	95.491	36.429	0.0263	25.5
L-20	18.281	9.465	1.446	6.630	4.511	5.548	1363.7	53.204	14.307	0.0260	28.0
L-21	16.102	2.888	0.708	9.456	7.235	6.494	1013.7	69.628	10.331	0.0271	31.0
L-22	14.445	5.864	1.264	8.847	6.039	6.308	1308.4	71.324	13.965	0.0309	28.0
L-23	12.405	8.522	1.943	10.122	6.608	6.866	427.6	84.873	23.511	0.0185	31.0
L-24	16.231	3.538	1.139	10.357	8.790	6.070	1178.7	82.008	12.619	0.0307	28.0
L-25	13.090	13.257	3.074	11.382	10.248	6.698	1557.6	139.907	18.695	0.0308	25.5
L-26	11.367	23.084	3.792	11.089	7.902	6.726	1437.5	107.836	29.608	0.0278	28.0
L-27	10.137	53.191	10.500	8.302	5.860	5.570	829.7	32.839	35.452	0.0213	26.8
L-28	10.028	35.971	11.395	9.475	7.126	6.094	1738.0	70.807	41.648	0.0311	23.5
L-29	11.946	24.312	6.000	9.794	8.685	6.039	1031.5	55.269	33.265	0.0259	25.0
L-30	13.794	27.705	4.963	10.768	10.660	6.234	512.5	26.243	24.077	0.0219	19.5
L-31	11.515	19.933	3.584	10.860	6.947	7.328	1152.6	131.172	37.533	0.0316	31.0
L-32	10.170	2.835	0.334	9.703	6.649	7.077	869.5	47.609	9.805	0.0274	39.0
L-33	12.299	9.160	2.562	6.851	4.151	5.376	1056.1	28.044	10.692	0.0249	25.0
L-34	13.188	18.293	4.159	6.499	4.080	5.029	1446.5	45.362	21.174	0.0289	26.5
L-35	13.397	12.865	3.533	11.012	7.230	7.830	NA	23.629	18.504	0.0268	25.0
L-36	12.106	7.624	2.618	5.630	3.872	5.478	1388.6	36.807	12.702	0.0284	25.0
L-37	11.304	11.766	3.044	8.134	5.961	5.237	728.2	26.055	14.503	0.0252	26.5
L-38	12.956	9.730	2.748	6.636	4.359	5.278	606.9	22.285	13.497	0.0245	32.0
L-39	14.395	11.080	3.336	6.835	4.235	5.355	1634.5	60.632	15.688	0.0309	32.0
L-40	13.946	7.363	2.500	7.240	4.473	5.792	800.2	21.278	11.303	0.0249	30.0
L-41	16.451	8.469	2.743	6.352	4.335	5.221	821.0	29.561	15.190	0.0272	26.5
L-42	12.541	13.742	2.530	8.685	6.595	6.130	1207.6	40.569	16.800	0.0265	32.0
L-43	13.992	1.373	0.299	10.376	8.012	6.776	1487.7	92.060	9.488	0.0304	49.0
L-44	13.289	2.455	0.782	9.823	7.672	6.309	1281.2	42.087	11.558	0.0318	50.0
L-45	12.215	14.230	2.470	10.054	6.377	6.540	863.5	116.960	28.215	0.0220	27.0
L-46	13.746	4.615	1.008	6.990	6.278	5.642	981.7	53.445	13.281	0.0358	28.0
L-47	12.590	2.400	0.633	11.093	8.332	6.284	1059.8	61.182	11.226	0.0303	35.0
L-48	16.000	21.536	3.817	7.312	5.589	4.878	655.0	55.139	22.766	0.0242	27.0
L-49	13.929	1.940	0.693	11.206	8.514	6.269	1229.0	66.595	10.489	0.0271	35.0

Table 208: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 209
Additional measured parameters in Foxtail millet accessions under normal growth conditions
L/
Corr.
ID	21	22	23	24	25	26	27	28	29	30	31
L-1	0.2470	0.1936	523.448	52.326	6.423	0.406	45.904	1.902	7.935	7.835	465.7
L-2	0.2109	0.1486	436.940	35.126	3.468	0.372	40.258	2.166	10.327	4.378	193.4
L-3	0.2288	0.1585	560.843	61.498	7.077	0.419	35.816	2.618	8.655	8.730	543.0
L-4	0.2404	0.1838	491.668	51.859	10.845	0.363	55.857	2.730	4.821	14.796	726.2
L-5	0.2418	0.1799	296.573	23.980	15.033	0.319	39.621	2.886	1.734	18.454	742.8
L-6	0.2338	0.1719	478.080	59.256	8.795	0.442	57.119	2.730	6.929	8.785	522.8
L-7	0.2437	0.1617	357.615	31.052	0.710	0.268	11.506	1.265	45.779	1.501	82.8
L-8	0.2446	0.1608	373.488	24.845	2.316	0.278	23.955	1.292	11.107	6.680	321.5
L-9	0.2494	0.1540	403.167	35.211	1.801	0.391	19.008	1.298	19.469	3.538	221.6
L-10	0.2514	0.1550	440.728	31.820	2.091	0.385	22.942	1.374	15.442	4.479	301.9
L-11	0.2248	0.1637	423.047	50.574	1.548	0.436	14.462	1.948	44.151	2.157	177.5
L-12	0.2716	0.1650	318.777	57.406	0.558	0.352	12.210	1.321	100.117	1.474	105.0
L-13	0.2439	0.1597	330.000	28.963	1.262	0.389	13.395	1.193	33.200	1.799	163.2
L-14	0.2368	0.1596	306.945	21.188	2.029	0.235	24.485	1.427	10.610	8.035	431.6
L-15	0.2665	0.1743	412.848	29.392	0.907	0.369	15.126	1.359	32.856	2.637	177.7
L-16	0.2499	0.1691	444.183	35.353	0.868	0.378	15.290	1.281	40.880	2.044	190.0
L-17	0.2425	0.1587	510.250	37.182	1.327	0.534	14.334	1.500	27.810	2.191	202.3
L-18	0.2499	0.1583	389.653	41.484	0.713	0.343	13.613	1.335	46.577	1.681	136.7
L-19	0.2185	0.1711	286.170	35.081	13.319	0.371	65.767	3.107	3.317	17.289	648.0
L-20	0.2331	0.1609	494.023	42.095	2.721	0.355	25.215	1.642	15.483	4.339	240.5
L-21	0.2604	0.1508	369.768	36.300	0.591	0.370	10.086	1.307	71.952	2.123	147.9
L-22	0.2442	0.1674	449.293	37.191	1.281	0.398	18.308	1.630	30.340	3.791	286.9
L-23	0.1829	0.1436	181.893	17.860	1.239	0.369	42.599	2.116	17.236	5.830	357.0
L-24	0.2518	0.1643	433.943	33.982	0.931	0.430	15.019	1.440	36.918	3.416	287.1
L-25	0.2569	0.1790	324.913	36.954	11.493	0.461	49.775	2.064	3.233	9.222	396.5
L-26	0.2226	0.1780	421.437	38.561	17.576	0.484	60.261	2.541	2.232	11.375	459.2
L-27	0.1948	0.1499	381.280	30.666	13.922	0.251	80.493	2.628	2.347	31.500	1184.3
L-28	0.2291	0.1826	516.873	40.226	21.574	0.405	91.859	4.606	2.064	34.185	1417.5
L-29	0.2167	0.1657	458.375	40.534	9.844	0.321	56.953	2.893	4.071	18.000	771.6
L-30	0.2209	0.1598	229.610	16.337	7.564	0.228	54.685	2.479	2.120	14.888	505.8
L-31	0.2387	0.1877	286.395	26.549	19.153	0.503	84.473	3.176	1.439	8.073	593.5
L-32	0.2413	0.1642	277.078	24.807	0.274	0.268	6.454	1.372	90.586	1.002	68.4
L-33	0.2238	0.1587	351.175	24.234	2.841	0.263	20.919	1.305	8.580	7.685	434.5
L-34	0.2459	0.1680	399.380	35.310	6.138	0.303	46.721	2.212	5.775	12.478	589.5
L-35	0.2482	0.1581	217.370	19.085	3.016	0.196	34.087	1.717	6.456	10.600	463.4
L-36	0.2475	0.1651	408.020	28.705	2.276	0.305	23.952	1.320	12.720	7.855	415.1
L-37	0.2294	0.1585	275.790	17.510	2.132	0.265	36.224	1.853	8.146	9.133	442.1
L-38	0.2254	0.1573	219.835	15.830	1.535	0.206	31.321	1.676	10.755	8.243	460.7
L-39	0.2565	0.1715	442.417	37.021	5.071	0.372	37.722	1.690	7.337	10.008	529.8
L-40	0.2363	0.1527	279.125	16.235	2.136	0.247	29.251	1.524	7.727	7.500	320.8
L-41	0.2431	0.1619	254.648	18.083	1.925	0.266	29.508	1.560	9.393	8.228	349.8
L-42	0.2319	0.1649	432.950	36.965	2.230	0.294	29.121	1.873	15.957	7.590	366.1
L-43	0.2535	0.1735	407.965	58.985	0.364	0.332	7.714	1.141	123.564	0.896	73.7
L-44	0.2631	0.1691	407.297	27.890	0.712	0.315	14.875	1.406	41.222	2.084	160.9
L-45	0.1989	0.1563	308.283	35.358	8.497	0.431	51.224	2.990	4.233	7.410	470.8
L-46	0.2578	0.1771	359.710	25.460	0.723	0.373	12.674	1.492	38.671	3.023	255.1
L-47	0.2512	0.1621	345.240	30.750	0.476	0.357	10.189	1.344	64.453	1.900	169.8
L-48	0.2157	0.1609	223.693	20.025	4.673	0.326	46.936	2.144	4.279	11.450	525.3
L-49	0.2416	0.1634	386.343	35.518	0.669	0.361	15.213	1.284	54.655	2.080	204.6

Table 209: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 210
Additional measured parameters in Foxtail millet accessions under normal growth conditions
L/
Corr.
ID	32	33	34	35	36	37	38
L-1	10.167	35.346	6.212	89.800	21808	69.938	10.208
L-2	8.333	34.194	5.268	60.278	23393	50.248	11.278
L-3	9.500	34.783	6.399	97.153	31815	83.283	8.917
L-4	11.417	34.140	7.169	142.260	27993	108.443	12.375
L-5	10.083	34.019	7.164	132.088	31003	111.863	11.500
L-6	11.500	35.904	5.592	100.283	25379	80.673	10.667
L-7	6.917	33.910	2.338	15.723	3051	10.450	7.000
L-8	11.000	33.469	5.303	28.830	7161	23.435	10.875
L-9	9.083	33.577	3.978	29.715	9195	25.053	9.625
L-10	8.667	34.346	4.298	33.580	10390	28.743	9.167
L-11	5.667	33.310	3.834	29.700	6830	21.315	6.250
L-12	5.111	34.939	2.419	12.540	2858	9.567	5.000
L-13	5.083	33.229	3.491	16.488	4767	13.643	5.750
L-14	11.417	33.375	5.554	27.015	6622	20.438	12.375
L-15	8.500	34.779	3.556	21.528	4829	16.873	8.083
L-16	6 .750	33.577	3.465	17.920	4062	14.260	6.913
L-17	6.000	34.521	3.798	29.255	7386	20.890	7.478
L-18	5.583	33.352	3.108	17.700	4644	14.143	5.208
L-19	10.889	35.702	8.488	164.405	39491	126.260	10.542
L-20	8.917	36.081	5.109	36.920	11175	30.363	8.833
L-21	6.500	36.331	3.382	15.525	4550	12.288	6.667
L-22	7.000	34.096	4.139	43.960	11884	35.613	7 .542
L-23	9.333	37.794	5.143	74.270	25745	61.475	8.083
L-24	7.417	33.710	4.044	32.258	10116	26.915	6.500
L-25	8.417	35.383	6.398	118.615	22554	96.977	8.083
L-26	10.333	33.544	6.353	183.995	45768	153.405	10.917
L-27	13.333	34.252	9.559	205.330	72811	148.725	16.250
L-28	13.583	35.631	9.078	297.645	79336	240.727	12.125
L-29	12.417	34.608	7.847	111.153	39953	89.588	12.833
L-30	9.250	37.969	7.537	84.168	30461	64.960	11.167
L-31	10.667	35.627	5.907	212.663	42852	172.618	10.458
L-32	6.500	35.527	2.685	7.305	1916	5.963	7.208
L-33	10.667	32.798	5.477	27.695	7487	22.548	11.833
L-34	11.167	35.050	6.534	67.398	15024	54.450	12.000
L-35	12.917	33.967	5.899	37.395	15482	28.640	12.000
L-36	11.083	33.675	5.436	30.835	7112	24.018	11.500
L-37	12.833	35.694	4.868	36.010	11390	29.410	12.250
L-38	10.667	34.590	5.763	30.610	8318	22.915	10.875
L-39	9.833	34.421	6.426	59.638	13586	49.848	10.333
L-40	10.333	33.773	5.662	25.743	6967	19.830	10.667
L-41	10.250	34.317	6.289	28.155	6920	22.085	9.625
L-42	9.833	34.573	5.321	67.483	20024	50.003	12.333
L-43	5.250	34.356	2.686	7.388	1589	5.618	6.667
L-44	5.667	33.465	3.166	17.748	4360	13.555	6.875
L-45	8.750	37.452	6.546	99.460	28950	81.203	9.250
L-46	7.500	35.338	4.528	29.748	8930	24.443	7.792
L-47	6.750	34.892	3.188	11.615	2977	8.810	7.375
L-48	10.167	35.425	7.607	96.310	28133	82.633	9.875
L-49	6.000	32.788	3.748	17.885	4690	14.583	6.292
			L/	Additional measured parameters in Foxtail
			Corr.	millet accessions under normal growth conditions
			ID	39	40	41	42
			L-1	87.000	37.8	61.0	2.970
			L-2	87.750	43.8	79.0	2.078
			L-3	83.667	40.0	68.0	2.589
			L-4	86.667	47.0	83.0	3.971
			L-5	81.333	47.0	79.0	4.913
			L-6	89.333	46.3	79.0	3.916
			L-7	87.000	41.0	86.0	1.525
			L-8	83.500	50.5	86.0	2.313
			L-9	76.000	40.0	68.0	2.226
			L-10	70.000	40.0	68.0	2.944
			L-11	85.000	33.0	79.0	3.059
			L-12	94.333	39.0	86.0	1.701
			L-13	91.000	33.0	91.0	2.690
			L-14	79.000	54.8	83.0	1.861
			L-15	79.250	40.0	79.0	1.906
			L-16	88.333	33.0	86.0	2.865
			L-17	81.667	33.0	64.0	2.984
			L-18	91.000	33.0	86.0	2.526
			L-19	70.000	38.5	64.0	4.219
			L-20	74.667	40.0	68.0	2.264
			L-21	85.333	33.0	64.0	2.252
			L-22	70.000	33.0	61.0	2.510
			L-23	78.000	33.0	64.0	2.289
			L-24	82.333	33.0	61.0	2.910
			L-25	70.000	38.5	64.0	3.405
			L-26	78.333	39.3	68.0	4.377
			L-27	86.667	52.3	79.0	4.740
			L-28	96.000	55.5	79.0	3.959
			L-29	80.000	53.3	79.0	3.215
			L-30	81.333	52.5	72.0	2.460
			L-31	78.000	37.0	68.0	5.002
			L-32	96.000	47.0	86.0	1.530
			L-33	81.333	53.3	79.0	2.278
			L-34	81.333	52.5	79.0	2.883
			L-35	83.667	53.3	79.0	2.219
			L-36	79.000	53.3	79.0	1.995
			L-37	75.750	52.5	79.0	2.519
			L-38	85.750	54.0	86.0	2.693
			L-39	79.000	47.0	79.0	2.719
			L-40	83.500	49.0	79.0	2.089
			L-41	82.667	52.5	79.0	2.383
			L-42	81.333	47.0	79.0	1.879
			L-43	92.667	37.0	86.0	1.114
			L-44	91.000	41.0	91.0	2.841
			L-45	75.750	37.0	64.0	2.644
			L-46	73.500	33.0	61.0	1.944
			L-47	92.667	33.0	68.0	1.508
			L-48	70.000	37.0	64.0	3.365
			L-49	82.333	33.0	68.0	1.535

Table 210: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 211
Additional measured parameters in Foxtail millet accessions under normal growth conditions
L/
Corr.
ID	43	44	45	46	46	47	48	49
L-1	128.958	1.573	61.935	48.331	48.331	178.139	7.583	0.491
L-2	109.277	1.677	53.240	43.752	43.752	132.587	10.333	0.567
L-3	125.646	1.852	59.635	45.810	45.810	186.288	9.250	0.487
L-4	147.621	1.317	62.080	51.204	51.204	147.933	3.750	0.319
L-5	126.171	0.981	60.254	51.054	51.054	121.133	2.250	0.239
L-6	127.190	1.397	65.681	48.802	48.802	179.088	6.583	0.357
L-7	86.450	1.845	57.424	47.806	47.806	167.304	20.667	0.588
L-8	138.625	1.608	46.640	49.923	49.923	144.454	13.667	0.335
L-9	112.875	1.350	46.440	41.715	41.715	189.283	15.833	0.357
L-10	116.771	1.650	42.698	42.912	42.912	225.039	16.250	0.436
L-11	88.729	1.928	57.308	48.588	48.588	246.888	21.750	0.543
L-12	78.717	1.765	61.122	45.067	45.067	215.861	35.222	0.510
L-13	81.875	0.954	54.270	44.900	44.900	270.627	16.500	0.273
L-14	134.546	1.739	45.058	46.185	46.185	162.870	13.750	0.476
L-15	91.300	1.163	53.465	49.672	49.672	204.193	16.667	0.313
L-16	82.761	1.138	56.990	47.027	47.027	279.201	15.000	0.297
L-17	82.835	1.558	48.423	44.356	44.356	277.408	18.250	0.442
L-18	90.954	1.096	61.010	48.983	48.983	246.853	16.583	0.312
L-19	129.383	0.978	63.658	49.510	49.510	125.254	1.167	0.296
L-20	159.542	1.078	64.058	48.517	48.517	166.770	9.000	0.291
L-21	105.783	1.131	57.615	49.127	49.127	211.221	15.083	0.322
L-22	107.063	1.301	53.504	45.627	45.627	227.911	13.917	0.384
L-23	97.808	0.635	58.092	50.992	50.992	203.990	5.250	0.129
L-24	102.479	1.031	53.400	45.177	45.177	251.631	11.000	0.293
L-25	104.246	0.844	64.658	51.258	51.258	130.619	2.000	0.257
L-26	123.167	1.067	61.858	50.104	50.104	119.749	3.167	0.291
L-27	164.167	1.169	51.271	50.649	50.649	111.567	1.417	0.282
L-28	120.870	1.168	59.071	47.508	47.508	124.662	1.583	0.252
L-29	152.421	1.434	45.519	47.983	47.983	128.734	3.667	0.334
L-30	153.063	0.683	45.221	49.431	49.431	102.055	1.417	0.166
L-31	118.438	0.604	67.892	51.856	51.856	165.763	1.333	0.152
L-32	72.504	1.632	60.747	43.388	43.388	207.114	26.667	0.391
L-33	144.917	1.679	44.081	47.810	47.810	152.324	9.833	0.384
L-34	157.854	1.095	55.485	45.529	45.529	141.685	4.083	0.269
L-35	160.021	1.378	46.251	45.260	45.260	131.123	6.417	0.313
L-36	138.813	1.943	46.836	46.131	46.131	158.832	11.583	0.447
L-37	137.308	2.012	40.937	45.190	45.190	143.926	11.417	0.393
L-38	136.265	2.065	43.448	44.017	44.017	169.880	14.583	0.538
L-39	148.475	1.969	37.781	44.381	44.381	161.392	8.167	0.489
L-40	147.958	1.494	42.473	44.954	44.954	127.309	9.250	0.437
L-41	157.513	2.397	46.823	47.042	47.042	125.253	13.750	0.567
L-42	154.208	2.146	44.696	44.742	44.742	144.574	13.500	0.615
L-43	90.950	1.742	57.319	44.931	44.931	246.502	31.667	0.564
L-44	88.750	2.476	60.113	50.192	50.192	212.864	36.167	0.668
L-45	110.617	1.165	65.658	52.279	52.279	191.657	5.250	0.254
L-46	106.083	0.758	56.935	43.960	43.960	254.498	6.917	0.236
L-47	90.854	0.830	55.525	47.365	47.365	292.024	11.417	0.207
L-48	157.133	1.001	61.688	48.563	48.563	138.388	2.250	0.325
L-49	85.788	1.819	54.054	47.442	47.442	295.635	23.417	0.457
			Additional measured parameters in Foxtail millet
			accessions under normal growth conditions
			L/
			Corr. ID	50	51	52	53	54
			L-1	0.622	21.437	2.412	0.241	61.875
			L-2	0.544	12.445	1.844	0.148	38.808
			L-3	0.595	20.030	2.366	0.259	73.563
			L-4	0.652	13.657	2.075	0.219	132.413
			L-5	0.453	9.268	1.251	0.101	158.695
			L-6	0.474	14.578	2.017	0.250	66.263
			L-7	0.762	8.015	1.509	0.131	11.760
			L-8	0.845	10.653	1.576	0.105	42.343
			L-9	0.584	14.399	1.701	0.149	27.233
			L-10	0.601	15.740	1.860	0.134	32.738
			L-11	0.465	9.197	1.785	0.213	19.515
			L-12	0.428	6.817	1.345	0.242	16.160
			L-13	0.435	5.690	1.392	0.122	16.970
			L-14	0.869	10.673	1.295	0.089	44.573
			L-15	0.529	10.586	1.742	0.124	15.813
			L-16	0.633	8.540	1.874	0.149	14.768
			L-17	0.360	16.460	2.153	0.157	14.250
			L-18	0.655	7.352	1.644	0.175	12.780
			L-19	0.373	11.352	1.207	0.148	176.060
			L-20	0.782	17.644	2.084	0.178	56.788
			L-21	0.510	11.928	1.560	0.153	17.325
			L-22	0.532	16.777	2.070	0.171	35.183
			L-23	0.245	4.514	0.767	0.075	51.133
			L-24	0.434	15.498	2.000	0.157	21.228
			L-25	0.268	12.684	1.371	0.156	79.543
			L-26	0.352	15.209	1.778	0.163	138.503
			L-27	0.933	14.478	1.609	0.129	319.148
			L-28	0.579	22.470	2.181	0.170	215.828
			L-29	0.758	18.513	1.934	0.171	145.873
			L-30	0.637	12.112	0.969	0.069	166.228
			L-31	0.204	9.239	1.208	0.112	119.595
			L-32	0.536	7.105	1.169	0.105	17.010
			L-33	0.874	14.082	1.482	0.102	54.960
			L-34	0.797	15.179	1.685	0.149	109.758
			L-35	0.824	8.860	0.917	0.081	77.188
			L-36	0.787	16.885	1.722	0.121	45.743
			L-37	0.654	10.592	1.164	0.074	70.598
			L-38	0.751	6.870	0.928	0.067	58.378
			L-39	0.626	14.667	1.867	0.156	66.483
			L-40	0.763	9.530	1.178	0.069	44.175
			L-41	0.611	9.726	1.074	0.076	50.813
			L-42	0.901	13.530	1.827	0.156	82.453
			L-43	0.662	8.326	1.721	0.249	8.235
			L-44	0.725	7.986	1.719	0.118	14.728
			L-45	0.307	11.418	1.301	0.149	85.383
			L-46	0.483	12.847	1.658	0.117	27.690
			L-47	0.507	9.864	1.457	0.130	14.400
			L-48	0.396	8.285	0.944	0.084	129.215
			L-49	0.580	10.577	1.630	0.150	11.638

Table 211: Provided are the values of each of the parameters (as described above) measured in Foxtail millet accessions (“L”=Line) under normal conditions. Growth conditions are specified in the experimental procedure section.

TABLE 212
Correlation between the expression level of selected genes of some
embodiments of the invention in various tissues and the phenotypic
performance under normal conditions across Foxtail millet accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY69	0.72	1.07E−08	3	25	LBY69	0.74	2.07E−09	3	28
LBY69	0.76	5.41E−10	3	37	LBY69	0.72	6.18E−09	3	36
LBY69	0.73	4.40E−09	3	18	LBY69	0.75	1.07E−09	3	35
LBY80	0.73	5.10E−09	3	25	LBY80	0.76	4.12E−10	3	37
LBY80	0.75	1.01E−09	3	35	LGN52	0.71	1.56E−08	3	29

Table 212. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 206. “Exp. Set”—Expression set specified in Table 205. “R”=Pearson correlation coefficient: “P”=p value.

Example 23

Production of Wheat Transcriptome and High Throughput Correlation Analysis with Yield Related Parameters Using 62K Wheat Oligonucleotide Micro-Arrays

In order to produce a high throughput correlation analysis between plant phenotype and gene expression level, the present inventors utilized a wheat oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 50,000 wheat genes and transcripts.

Correlation of Wheat Lines Grown Under Regular Growth Conditions

Experimental Procedures

185 spring wheat lines were grown in 5 replicate plots in the field. Wheat seeds were sown and plants were grown under commercial fertilization and irrigation protocols (normal growth conditions) which include 150 m³ applied water and 400 m³ by rainfall per dunam (1000 square meters) per entire growth period and fertilization of 15 units of URAN® 21% (Nitrogen Fertilizer Solution; PCS Sales, Northbrook. Ill. USA).

In order to define correlations between the levels of RNA expression with yield components or vigor related parameters, phenotypic performance of the 185 different wheat lines was characterized and analyzed at various developmental stages. Twenty six selected lines, encompassing a wide range of the observed variation were sampled for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Analyzed Wheat tissues—Three types of plant tissues [flag leaf, inflorescence and peduncle] from plants grown under Normal conditions were sampled and RNA was extracted as described above. Micro-array expression information from each tissue type has received a Set ID as summarized in Table 213 below.

TABLE 213
Wheat transcriptome expression sets under normal growth conditions
Expression Set                   Set ID
Flag leaf at heading stage under normal growth conditions 1
Inflorescence at heading stage under normal growth conditions 2
peduncle at heading stage under normal growth conditions 3

Table 213: Provided are the wheat transcriptome expression sets. Flag leaf=Full expanded upper leaf at heading; inflorescence=spike before flowering at full head emergence; peduncle=upper stem internode between the flag leaf and spike.

Wheat yield components and vigor related parameters assessment

The collected data parameters were as follows:

% Canopy coverage (F)—percent Canopy coverage at flowering stage. The % Canopy coverage is calculated using Formula XXXII (above).

1000 seed weight [gr.]—was calculated based on Formula XIV (above).

Average spike weight (H) [gr.]—The biomass and spikes of each plot was separated. Spikes dry weight at harvest was divided by the number of spikes or by the number of plants.

Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours.

Average tiller DW (H) [gr.]—Average Stem Dry Matter at harvest.

Average vegetative DWper plant (H) [gr.]—Vegetative dry weight per plant at harvest.

Fertile spikelets [number]—Number of fertile spikelets per spike. Count the bottom sterile spikelets in a sample from harvested spikes and deduce from number of spikelets per spike (with the unfertile spikes).

Fertile spikelets ratio [value]—Measure by imaging, the number of fertile and sterile spikelets per spike in 20 spikes randomly selected from the plot. Calculate the ratio between fertile spikelets to total number of spikelets×100 (sum of fertile and sterile spikelets).

Field Spike length (H) [cm]—Measure spike length per plant excluding the awns. at harvest.

Grain fill duration [number]—Defined by view. Calculate the number of days from anthesis in 50% of the plot to physiological maturity in 50% of the plot.

Grains per spike [number]—The total number of grains from 20 spikes per plot that were manually threshed was counted. The average grains per spike was calculated by dividing the total grain number by the number of spikes.

Grains per spikelet [number]—Number of grains per spike divided by the number of fertile spikelets per spike. Measure by imaging the number of fertile spikelets in 20 randomly selected spikes and calculate an average per spike.

Grains yield per micro plots [Kg]—Grain weight per micro plots.

Grains yield per spike [gr.]—Total grain weight per spike from 20 spikes per plot. The total grain weight per spike was calculated by dividing the grain weight of 20 spikes by the number of spikes.

Harvest index [ratio]—was calculated based on Formula XVIII (above).

Number days to anthesis [number]—Calculated as the number of days from sowing till 50% of the plots reach anthesis.

Number days to maturity [number]—Calculated as the number of days from sowing till 50% of the plots reach maturity.

Number days to tan [number]—Calculated as the number of days from sowing till 50% of the plot arrive to grain maturation.

PAR_LAI (F)—Photosynthetically Active Radiation (PAR) at flowering.

Peduncle length (F) [cm]—Length of upper internode from the last node to the spike base at flowering. Calculate the average peduncle length per 10-15 plants randomly distributed within a pre-defined 0.5 m² of a plot.

Peduncle width (F) [mm]—Upper node width at flowering. Calculate the average upper nodes width, measured just above the flag leaf auricles per 10-15 plants randomly distributed within a pre-defined 0.5 m² of a plot.

Peduncle volume (F) [Float value]=

Peduncle length*(peduncle thickness/2)²*π.

Spikelets per spike [number]—Number of spikelets per spike (with the unfertile spikes). Measured by imaging, the number of spikelets per spike in 20 spikes randomly selected from the plot.

Spikes per plant (H) [number]—Number of spikes per plant at harvest. Calculate Number of spikes per unit area/Number of plants per plot.

Spikes weight per plant (FC) [gr.]—Spikes weight per plant at flowering complete. Spikes weight from 10 plants/number of plants.

Stem length (F) [cm]—Main Stem length at flowering. Measures the length of Main Stem from ground to end of elongation (without the spike).

Stem width (F) [mm]—Stem width at flowering. Measures on the stem beneath the peduncle.

Test weight (mechanical harvest) [Kg/hectoliter]—Volume weight of seeds.

Tillering (F) [number]—Count the number of tillers per plant from 6-10 plants randomly distributed in a plot, at flowering stage.

Tillering (H) [number]—Number of tillers at harvest.

Total dry matter (FC) [gr.]—was calculated based on Formula XXI.

Total Plant Biomass (H) [gr.]—Vegetative dry weight+Spikes dry weight.

Vegetative DW per plant (F) [gr.]—Plant weight after drying (excluding the spikes) at flowering stage.

Total N content of grain per plant [gr.]—N content of grain*Grains yield per plant.

NDRE 1 [Float value]—Normalized difference Red-Edge TP-1 (time point). Calculated as (NIR−Red edge)/(NIR+Red edge). (“NIR”—Near InfraRed)

NDRE 2 [Float value]—Normalized difference Red-Edge TP-2. Calculated as (Nir−Red edge)/(Nir+Red edge).

NDVI 1 [Float value]—Normalized Difference Vegetation Index TP-1. Calculated as (Nir−Red edge)/(Nir+Red edge).

NDVI 2[Float value]—Normalized Difference Vegetation Index TP-2. Calculated as (Nir−Red edge)/(Nir+Red edge).

RUE [ratio]—total dry matter produced per intercepted PAR. Spikes weight per plant+Vegetative DW per plant at flowering/% Canopy coverage.

The following parameters were collected using digital imaging system:

Grain Area [cm²]—A sample of ˜200 grains were weight, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Grain Length and Grain width [cm]—A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths and width (longest axis) was measured from those images and was divided by the number of grains.

Grain Perimeter [cm]—A sample of ˜200 grains were weight, photographed and images were processed using the below described image processing system. The sum of grain perimeter was measured from those images and was divided by the number of grains.

Spike area [cm²]—At the end of the growing period 5 ‘spikes’ were photographed and images were processed using the below described image processing system. The ‘spike’ area was measured from those images and was divided by the number of ‘spikes’.

Spike length [cm]—Measure by imaging spikes length excluding awns, per 30 randomly selected spikes within a pre-defined 0.5 m² of a plot.

Spike max width [cm]—Measure by imaging the max width of 10-15 spikes randomly distributed within a pre-defined 0.5 m² of a plot. Measurements were carried out at the middle of the spike.

Spike width [cm]—Measure by imaging the width of 10-15 spikes randomly distributed within a pre-defined 0.5 m² of a plot. Measurements were carried out at the middle of the spike.

N use efficiency [ratio]—was calculated based on Formula LI (above).

Yield per spike filling rate [gr/day]—was calculated based on Formula LX (above).

Yield per micro plots filling rate [gr/day]—was calculated based on Formula LXI (above).

Grains yield per hectare [ton/ha]—was calculated based on Formula LXII (above).

Total NUtE [ratio]—was calculated based on Formula LIII (above).

The image processing system consisted of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37, Java based image processing software, which was developed at the U.S. National Institutes of Health and is freely available on the internet at rsbweb (dot) nih (dot) gov/. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, image processing output data for seed area and seed length was saved to text files and analyzed using the JMP statistical analysis software (SAS institute).

Data parameters collected are summarized in Table 214, herein below

TABLE 214
Wheat correlated parameters (vectors)
Correlated parameter with        Correlation ID
% Canopy coverage (F) [%]        1
1000 grain weight [gr. ]         2
Avr Spikes DW per plant (H) [gr.] 3
Avr Vegetative DW per plant (H) [gr.] 4
Avr spike weight (H) [gr.]       5
Avr tiller DW (H) [gr.]          6
Fertile spikelets [number]       7
Fertile spikelets ratio [value]  8
Field Spike length (H) [cm]      9
Grain Perimeter [cm]             10
Grain area [cm2]                 11
Grain fill duration [number]     12
Grain length [cm]                13
Grain width [cm]                 14
Grains per spike [number]        15
Grains per spikelet [number]     16
Grains yield per hectare [ton/ha] 17
Grains yield per micro plots [kg] 18
Grains yield per spike [gr.]     19
Harvest index [ratio]            20
N content of grain (harvest) [gr.] 21
N use efficiency [ratio]         22
NDRE_1 [Float value]             23
NDRE_2 [Float value]             24
NDVI_1 [Float value]             25
NDVI_2 [Float value]             26
Num days to anthesis [number]    27
Num days to maturity [number]    28
Num days to tan [number]         29
PAR_LAI (F) [μmol−2 S−1]         30
Peduncle length (F) [cm]         31
Peduncle width (F) [mm]          32
RUE [ratio]                      33
Spike Area [cm2]                 34
Spike length [cm]                35
Spike max width [cm]             36
Spike width [cm]                 37
Spikelets per spike [number]     38
Spikes dry weight per plant (F) [gr] 39
Spikes per plant (H) [number]    40
Stem length (F) [cm]             41
Stem width (F) [mm]              42
Test weight (mechanical harvest) [kg/hectoliter] 43
Tittering (F) [number]           44
Tittering (H) [number]           45
Total N content of grain per plant [gr.] 46
Total N utilization efficiency [ratio] 47
Total Plant Biomass (H) [gr.]    48
Total dry matter (F) [gr.]       49
Vegetative DW per plant (F) [gr.] 50
Yield per micro plots filling rate [ratio] 51
Yield per spike filling rate [gr./day] 52
Peduncle volume (F) [Float value] 53

Table 214. Provided are the wheat correlated parameters. “TP”=time point; “DW”=dry weight; “FW”=fresh weight; “Low N”=Low Nitrogen; “Relative water content [percent]; “num”=number. “gr.”=grams; “cm”=centimeter; “Avr”=average; “RGR”=relative growth rate; “BPE”=biomass production efficiency; “NHI”=Nitrogen harvest index; “NupE”=nitrogen uptake efficiency; “NutE”=nitrogen utilization efficiency; “SPAD”=chlorophyll levels; “F”=flowering stage; “H”=harvest stage; “N”=nitrogen; “gr”=gram: “cm”=centimeter; “kg”=kilogram; “FC”=flowering completed; “RUE=radiation use efficiency; “NDVI”=normalized Difference Vegetation Index; “NDRE”=normalized Difference Red-Edge index.

Experimental Results

185 different wheat lines were grown and characterized for different parameters. Tissues for expression analysis were sampled from a subset of 26 lines. The correlated parameters are described in Table 214 above. The average for each of the measured parameter was calculated using the JMP software (Tables 215-217) and a subsequent correlation analysis was performed (Table 218). Results were then integrated to the database.

TABLE 215
Measured parameters in Wheat accessions under normal conditions
Line/	Line-	Line-	Line-	Line-	Line-	Line-	Line-	Line-	Line-
Corr. ID	4	8	23	27	31	36	40	60	63
1	92.15	67.65	64.37	73.02	96.17	59.83	87.75	92.76	92.93
2	39.771	38.337	42.139	41.724	48.413	39.471	41.237	41.290	44.576
3	3.476	2.069	4.998	6.599	5.636	3.925	4.471	4.684	5.777
4	5.872	3.010	4.063	4.548	3.516	7.846	6.721	3.866	3.609
5	1.606	1.118	1.802	2.142	2.645	1.296	2.082	2.229	2.766
6	1.986	1.346	1.235	1.355	1.472	2.315	2.281	1.375	1.636
7	16.05	14.92	15.58	15.95	16.64	15.87	17.25	17.98	17.16
8	88.46	88.07	86.26	88.96	86.97	90.10	88.22	89.52	87.05
9	8.904	6.704	8.551	7.925	10.461	8.830	10.122	9.492	9.700
10	1.703	1.678	1.740	1.733	1.837	1.677	1.676	1.756	1.789
11	0.183	0.178	0.186	0.189	0.211	0.173	0.178	0.190	0.202
12	365.63	388.60	304.75	337.75	437.30	432.70	383.67	426.10	304.75
13	0.6602	0.6526	0.6888	0.6713	0.7084	0.6621	0.6502	0.6961	0.7020
14	0.3682	0.3586	0.3601	0.3712	0.3855	0.3482	0.3643	0.3679	0.3825
15	29.10	24.76	32.16	37.42	43.25	24.12	32.46	42.80	46.27
16	1.814	1.649	2.066	2.356	2.610	1.529	1.883	2.383	2.695
17	6.585	4.538	8.242	9.747	11.851	5.633	5.943	7.969	12.367
18	5.663	3.903	7.088	8.383	10.192	4.844	5.111	6.853	10.636
19	1.124	0.887	1.322	1.516	1.951	0.933	1.311	1.689	2.029
20	0.2767	0.3339	0.4755	0.4356	0.4874	0.2530	0.2893	0.4480	0.4769
21	2.490	1.865	1.890	1.990	1.755	2.240	2.120	1.810	1.535
22	38.74	21.35	48.48	57.34	69.71	33.13	34.96	28.13	72.75
23	0.1337	0.1393	0.1280	0.1190	0.1212	0.1440	0.1471	0.1248	0.1290
24	0.2303	0.2285	0.2040	0.2330	0.1845	0.2358	0.2028	0.2115	0.1938
25	0.3278	0.3290	0.2976	0.3033	0.2890	0.3625	0.3562	0.2961	0.3040
26	0.609	0.601	0.540	0.616	0.455	0.645	0.525	0.558	0.507
27	128.0	120.8	128.0	127.8	116.6	137.6	129.3	117.2	128.0
28	176.0	163.0	167.3	168.3	163.0	177.8	175.7	164.6	169.0
29	160.8	153.2	157.8	158.3	153.6	172.0	163.7	153.2	157.0
30	4.578	2.445	2.256	2.494	5.783	1.881	2.866	5.262	3.732
31	38.87	36.37	38.03	39.54	34.51	38.34	49.04	38.29	35.90
32	2.438	3.123	2.677	2.684	3.046	2.204	2.662	3.094	2.728
33	0.0867	0.1030	0.1010	0.1381	0.0678	0.1876	0.1473	0.0791	0.0895
34	8.468	5.672	7.719	9.832	11.667	6.813	7.304	9.525	NA
35	9.503	6.564	8.222	8.203	11.055	8.094	9.407	9.927	NA
36	1.262	1.227	1.319	1.714	1.572	1.183	1.079	1.454	NA
37	1.030	1.006	1.086	1.417	1.259	0.965	0.899	1.159	NA
38	18.14	16.92	18.07	17.90	19.11	17.67	19.56	20.10	19.71
39	1.094	1.021	0.960	3.740	1.270	1.178	1.599	1.285	2.131
40	2.277	1.911	3.256	3.183	2.293	3.187	2.632	2.200	2.200
41	122.17	98.02	92.50	94.13	74.77	126.10	135.63	96.97	85.68
42	3.667	4.483	3.714	4.033	4.886	3.423	3.639	4.214	4.059
43	68.97	84.59	80.96	85.61	84.28	75.23	81.60	85.27	79.70
44	3.268	2.507	3.018	2.622	2.988	3.083	4.029	2.997	2.707
45	3.113	2.587	3.633	3.383	2.467	3.983	3.840	2.980	2.333
46	63.4	42.5	79.3	78.9	73.2	58.5	70.1	76.4	57.7
47	130.7	116.3	106.1	107.2	102.6	131.8	127.6	113.1	123.1
48	9.348	4.938	9.060	11.148	9.153	11.771	10.778	8.550	9.386
49	7.993	6.791	5.907	9.199	6.525	10.775	12.870	7.317	8.329
50	6.899	5.770	4.947	5.459	5.255	9.495	11.271	6.033	6.199
51	0.188	0.141	0.291	0.355	0.321	0.169	0.173	0.225	0.424
52	0.0333	0.0273	0.0450	0.0594	0.0528	0.0281	0.0387	0.0469	0.0681
53	18.92	28.23	21.62	22.47	25.26	14.66	27.86	28.93	21.01

Table 215. Provided are the values of each of the parameters (as described above) measured in wheat accessions (“L”=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Corr.”—correlation.

TABLE 216
Measured parameters in additional Wheat accessions under normal growth conditions
Line/	Line-	Line-	Line-	Line-	Line-	Line-	Line-	Line-	Line-
Corr. ID	68	74	75	87	100	107	118	129	134
1	75.68	92.96	61.62	64.40	72.70	84.76	63.27	55.16	83.90
2	43.695	39.709	40.901	38.616	40.864	31.194	40.414	39.068	42.290
3	5.031	5.355	3.845	2.995	5.111	3.821	6.104	3.987	6.352
4	5.649	3.329	5.380	6.082	9.563	8.829	5.997	6.744	4.466
5	2.857	3.171	1.695	1.708	2.424	1.551	2.650	1.935	3.494
6	2.749	1.671	1.830	2.397	3.048	2.271	2.091	2.305	1.940
7	19.01	20.09	16.13	17.64	17.45	18.73	18.41	17.08	17.96
8	90.50	93.37	85.94	94.89	88.16	94.68	91.23	88.62	87.16
9	9.988	9.644	7.432	9.172	9.408	10.700	10.892	9.541	10.586
10	1.704	1.762	1.684	1.691	1.712	1.619	1.651	1.657	1.816
11	0.185	0.189	0.179	0.172	0.173	0.149	0.174	0.165	0.194
12	336.75	377.75	358.92	344.25	366.85	371.83	358.45	432.70	282.88
13	0.6603	0.7007	0.6577	0.6766	0.6847	0.6636	0.6405	0.6580	0.7336
14	0.3765	0.3584	0.3610	0.3383	0.3370	0.2990	0.3697	0.3390	0.3556
15	45.48	62.53	32.83	33.96	33.97	25.57	41.96	26.68	51.20
16	2.397	3.139	2.051	1.925	1.945	1.532	2.286	1.559	2.843
17	9.560	11.600	6.977	5.830	5.707	5.474	8.463	6.100	9.665
18	8.222	9.976	6.000	5.014	4.908	4.708	7.278	5.246	8.312
19	1.970	2.391	1.293	1.278	1.358	0.795	1.628	1.028	2.127
20	0.3769	0.4967	0.3767	0.2567	0.2390	0.1958	0.3424	0.2352	0.4410
21	2.215	1.310	2.040	2.135	2.440	2.210	1.885	2.430	1.840
22	56.24	68.24	32.83	34.30	33.57	31.60	49.78	35.88	56.85
23	0.1353	0.1190	0.1270	0.1307	0.1490	0.1378	0.0935	0.1290	0.1350
24	0.2166	0.2036	0.2165	0.2475	0.2540	0.2825	0.2476	0.2400	0.2597
25	0.3233	0.2670	0.2850	0.3103	0.3930	0.3490	0.2140	0.3045	0.3290
26	0.570	0.533	0.568	0.664	0.674	0.737	0.647	0.602	0.685
27	140.0	128.0	124.0	137.0	139.4	148.5	137.4	137.6	131.0
28	177.0	170.5	166.8	175.8	182.8	182.3	179.4	183.4	173.0
29	168.0	162.5	154.6	167.0	169.4	175.3	167.8	172.0	158.8
30	2.944	4.297	2.149	1.823	3.274	2.910	2.425	1.771	4.201
31	41.05	30.85	38.67	41.78	42.23	39.78	31.46	36.07	32.98
32	2.931	3.054	2.459	2.615	2.740	2.586	2.590	2.597	2.455
33	0.1566	0.0629	0.1843	0.1326	0.1810	0.1536	0.1131	0.1521	0.0821
34	8.406	11.662	7.542	7.321	7.937	8.695	11.244	6.241	12.124
35	9.114	12.104	8.485	9.126	8.853	9.911	9.883	7.662	10.187
36	1.342	1.446	1.292	1.123	1.204	1.193	1.612	1.123	1.707
37	1.092	1.128	1.078	0.910	1.044	0.995	1.329	0.941	1.446
38	21.00	21.49	18.80	18.59	19.91	19.87	20.25	19.58	20.62
39	3.530	1.520	1.175	1.177	2.271	1.975	1.906	1.085	1.480
40	2.053	1.827	2.707	1.693	2.573	3.183	2.572	2.463	2.300
41	104.53	77.26	119.44	133.29	136.31	124.29	106.89	123.76	83.26
42	4.375	4.878	3.689	4.135	4.017	3.696	4.130	3.981	3.220
43	76.16	77.76	84.07	75.85	75.44	78.44	75.38	77.36	77.09
44	2.600	1.933	3.333	2.500	3.031	4.150	2.450	2.433	1.867
45	2.233	2.133	3.160	2.717	3.667	4.250	3.296	3.697	3.367
46	98.5	52.6	63.0	42.7	70.5	61.5	82.4	57.6	65.4
47	98.3	147.7	116.0	164.8	155.0	163.8	399.1	138.2	127.3
48	10.681	8.683	9.225	9.077	14.673	12.650	12.101	10.731	10.818
49	11.396	5.760	8.000	7.719	12.699	12.645	6.994	7.724	5.553
50	7.866	4.240	6.825	6.542	10.428	10.670	5.088	6.639	4.073
51	0.353	0.336	0.219	0.196	0.196	0.208	0.280	0.183	0.379
52	0.0703	0.0712	0.0432	0.0430	0.0477	0.0355	0.0536	0.0312	0.0643
53	27.89	22.60	18.83	22.35	24.96	21.18	16.82	19.28	17.89

Table 216. Provided are the values of each of the parameters (as described above) measured in wheat accessions (“L”=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Corr.”—correlation.

TABLE 217
Measured parameters in additional Wheat accessions under normal growth conditions
Line/	Line-	Line-	Line-	Line-	Line-	Line-	Line-
Corr. ID	142	146	159	161	171	173	175
1	70.33	63.51	67.99	75.95	96.46	71.12	96.07
2	46.396	42.314	44.476	38.053	48.044	40.010	47.328
3	3.146	2.415	6.405	3.645	5.909	2.868	7.029
4	6.269	5.358	7.858	6.615	3.719	5.067	4.978
5	1.642	1.409	1.903	2.028	2.711	1.610	2.717
6	2.088	1.928	2.053	2.684	1.597	2.120	1.802
7	16.47	17.19	16.36	18.22	17.62	19.14	18.24
8	91.88	91.74	90.74	81.02	87.83	92.35	88.92
9	8.424	9.980	8.948	9.723	9.692	10.215	9.076
10	1.759	1.720	1.831	1.695	1.807	1.725	1.795
11	0.188	0.176	0.197	0.174	0.207	0.176	0.201
12	343.44	372.65	302.20	405.05	448.50	300.35	363.42
13	0.6980	0.6916	0.7357	0.6742	0.7052	0.6941	0.7000
14	0.3641	0.3440	0.3544	0.3408	0.3885	0.3362	0.3769
15	27.08	25.35	31.68	30.54	44.63	25.54	44.88
16	1.661	1.475	1.936	1.671	2.552	1.288	2.460
17	6.142	5.479	5.979	6.777	11.488	5.758	12.033
18	5.282	4.712	5.142	5.828	9.880	4.952	10.348
19	1.223	1.057	1.381	1.160	2.033	0.933	2.045
20	0.2601	0.2741	0.3992	0.2621	0.5019	0.2647	0.4684
21	1.805	2.115	1.925	2.215	1.635	2.305	1.510
22	36.13	32.23	35.17	39.87	67.58	33.87	70.78
23	0.1370	0.1468	0.1250	0.1357	0.1246	0.1388	0.1260
24	0.2593	0.2080	0.2068	0.2422	0.1990	0.2590	0.2328
25	0.3190	0.3710	0.3007	0.3333	0.2940	0.3490	0.3037
26	0.691	0.623	0.544	0.641	0.507	0.665	0.620
27	141.8	137.0	127.8	140.0	116.0	140.6	127.8
28	179.8	178.6	170.2	177.0	163.0	178.6	168.3
29	169.3	168.6	154.2	171.6	154.0	166.6	161.3
30	2.868	2.049	2.733	2.805	5.937	3.020	3.390
31	37.36	42.74	39.01	45.06	39.34	40.03	40.06
32	2.573	2.660	2.511	2.943	2.888	2.213	2.754
33	0.1448	0.1287	0.1513	0.1309	0.0486	0.2053	0.1241
34	6.766	7.258	8.234	6.678	10.681	8.093	12.476
35	7.829	9.208	9.678	8.045	9.827	10.472	9.948
36	1.199	1.116	1.208	1.166	1.638	1.056	1.794
37	1.001	0.908	1.024	0.965	1.310	0.879	1.476
38	18.01	18.74	18.04	22.43	20.04	20.66	20.53
39	2.661	1.506	1.733	1.309	1.393	2.584	2.477
40	1.960	2.007	4.116	2.273	2.373	2.319	2.733
41	128.30	129.54	113.05	139.09	90.72	125.02	104.32
42	3.895	4.048	3.815	4.269	4.503	3.397	4.140
43	76.60	78.30	79.30	81.19	86.38	80.25	86.04
44	2.760	2.833	4.225	2.533	2.650	4.595	3.295
45	3.133	3.332	4.673	2.678	2.520	3.344	2.867
46	40.3	37.0	120.9	46.0	84.4	77.5	68.6
47	145.8	147.9	113.7	179.3	116.7	123.5	131.4
48	9.415	7.773	14.263	10.260	9.628	7.935	12.007
49	10.805	7.806	9.949	9.531	6.707	14.149	11.903
50	8.144	6.300	8.216	8.222	5.450	11.565	9.426
51	0.231	0.173	0.226	0.222	0.302	0.226	0.355
52	0.0438	0.0334	0.0530	0.0387	0.0535	0.0360	0.0591
53	19.45	23.79	19.30	30.97	26.02	15.83	23.90
				Measured parameters in additional Wheat
				accessions under normal growth conditions
				Line/	Line-	Line-	Line-
				Corr. ID	178	179	183
				1	95.73	74.63	80.19
				2	43.489	48.337	47.431
				3	6.195	5.470	5.555
				4	4.934	5.262	4.407
				5	2.618	3.048	2.920
				6	1.842	2.313	2.088
				7	17.72	19.36	19.12
				8	90.62	92.28	87.19
				9	9.020	10.747	10.952
				10	1.708	1.892	1.808
				11	0.187	0.212	0.203
				12	343.75	197.70	356.45
				13	0.6593	0.7570	0.7098
				14	0.3751	0.3700	0.3786
				15	47.67	49.18	45.87
				16	2.687	2.543	2.397
				17	11.226	10.802	11.160
				18	9.654	9.290	9.598
				19	1.985	2.328	2.129
				20	0.4472	0.4419	0.4382
				21	1.715	2.010	1.725
				22	66.03	63.54	65.65
				23	0.1203	0.1268	0.1278
				24	0.2133	0.2056	0.2010
				25	0.2845	0.3033	0.3068
				26	0.553	0.516	0.520
				27	128.0	140.0	131.0
				28	170.0	171.7	174.6
				29	160.2	159.7	163.4
				30	5.554	2.884	2.583
				31	NA	42.71	38.47
				32	NA	3.265	3.067
				33	NA	0.166	0.077
				34	11.403	11.778	12.753
				35	8.604	10.918	11.104
				36	1.869	1.595	1.714
				37	1.579	1.280	1.365
				38	19.55	21.01	21.96
				39	NA	4.889	2.085
				40	2.490	2.167	2.040
				41	NA	110.38	99.82
				42	NA	4.561	4.313
				43	86.76	85.32	86.96
				44	NA	2.322	2.117
				45	2.723	2.507	2.413
				46	84.2	101.5	74.2
				47	118.0	96.1	116.9
				48	11.129	10.277	9.961
				49	NA	11.791	5.647
				50	NA	6.902	3.562
				51	0.349	0.573	0.348
				52	0.0616	0.1226	0.0664
				53	NA	35.87	28.40

Table 217. Provided are the values of each of the parameters (as described above) measured in wheat accessions (“L”=Line). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Corr.”—correlation.

TABLE 218
Correlation between the expression level of selected genes of some embodiments of the invention
in various tissues and the phenotypic performance under normal across wheat accessions
				Corr.					Corr.
Gene		P	Exp.	Set	Gene		P	Exp.	Set
Name	R	value	set	ID	Name	R	value	set	ID
LBY214	0.78	1.24E−04	3	47	LBY215	0.77	2.07E−04	3	47
LBY222	0.71	1.14E−04	2	2	LBY222	0.77	1.14E−05	2	18
LBY222	0.75	2.42E−05	2	22	LBY222	0.77	1.14E−05	2	17
LBY222	0.70	1.78E−04	2	34	LBY222	0.72	7.19E−05	2	11
LBY225	0.74	4.90E−04	3	20	LBY228	0.72	7.17E−04	3	2
LBY228	0.83	2.45E−05	3	52	LBY228	0.74	4.20E−04	3	19
LBY228	0.76	2.38E−04	3	11	LBY228	0.71	1.04E−03	3	10
LBY228	0.74	4.64E−04	3	51	LBY231	0.71	8.99E−04	3	26
LBY231	0.73	6.60E−04	3	24

Table 218. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 214. “Exp. Set”—Expression set specified in Table 213. “R”=Pearson correlation coefficient; “P”=p value.

Example 24

Production of Wheat Transcriptome and High Throughput Correlation Analysis Using 60K Wheat Oligonucleotide Micro-Array

In order to produce a high throughput correlation analysis comparing between plant phenotype and gene expression level, the present inventors utilized a Wheat oligonucleotide micro-array, produced by Agilent Technologies [chem. (dot) agilent (dot) com/Scripts/PDS (dot) asp?1Page=50879]. The array oligonucleotide represents about 60K Wheat genes and transcripts. In order to define correlations between the levels of RNA expression and yield or vigor related parameters, various plant characteristics of 14 different Wheat accessions were analyzed. Among them, 10 accessions encompassing the observed variance were selected for RNA expression analysis. The correlation between the RNA levels and the characterized parameters was analyzed using Pearson correlation test [davidmlane (dot) com/hyperstat/A34739 (dot) html].

Experimental Procedures

14 Wheat accessions in 5 repetitive blocks, each containing 8 plants per pot were grown at net house. Three different treatments were applied: plants were regularly fertilized and watered during plant growth until harvesting under normal conditions [as recommended for commercial growth, plants were irrigated 2-3 times a week, and fertilization was given in the first 1.5 months of the growth period], under low Nitrogen (70% percent less Nitrogen) or under drought stress (cycles of drought and re-irrigating were conducted throughout the whole experiment, overall 40% less water were given in the drought treatment).

Analyzed Wheat tissues—Five tissues at different developmental stages [leaf, stem, root tip and adventitious root, flower], representing different plant characteristics, were sampled and RNA was extracted as described above. Each micro-array expression information tissue type has received a Set ID as summarized in Table 219 below.

TABLE 219
Wheat transcriptome expression sets under normal conditions
                                 Set
Expression Set                   ID
Adv root, grown under Normal conditions, first tillering stage 1
Basal lemma, grown under Normal conditions, grain filling, stage 2
Basal spike, grown under Normal conditions, flowering stage 3
Basal spike, grown under Normal conditions, grain filling stage 4
Leaf, grown under Normal conditions, flowering stage 5
Leaf, grown under Normal conditions, grain filling stage 6
Root tip, grown under Normal conditions, first tillering stage 7
Stem grown under Normal conditions, flowering stage 8
Stem, grown under Normal conditions, grain filling stage 9

Table 219. Provided are the wheat transcriptome expression sets under normal conditions.

TABLE 220
Wheat transcriptome expression sets under low N conditions
Expression Set                   Set ID
Adv root, grown under Low N conditions, first tillering stage 1
Basal spike, grown under Low N conditions, flowering stage 2
Basal spike, grown under Low N conditions, grain filling stage 3
Leaf, grown under Low N conditions, flowering stage 4
Leaf, grown under Low N conditions, grain filling stage 5
Root tip, grown under Low N conditions, first tillering stage 6
Stem, grown under Low N conditions, flowering stage 7
Stem grown under Low N conditions, grain filling stage 8

Table 220. Provided are the wheat transcriptome expression sets under low N conditions.

TABLE 221
Wheat transcriptome expression sets low N vs. normal conditions
                                 Set
Expression Set                   ID
Adv root; grown under Low N vs. normal conditions, first tillering 1
stage
Basal spike; grown under Low N vs. normal conditions, flowering 2
stage
Basal spike; grown under Low N vs. normal conditions, grain 3
filling stage
Leaf; grown under Low N vs. normal conditions, flowering stage 4
Leaf; grown under Low N vs. normal conditions, grain filling stage 5
Root tip; grown under Low N vs. normal conditions, first tillering 6
stage
Stem; grown under Low N vs. normal conditions, flowering stage 7
Stem; grown under Low N vs. normal conditions, grain filling stage 8

Table 221. Provided are the wheat transcriptome expression sets at low N versus (vs.) normal conditions.

Wheat yield components and vigor related parameters assessment—Plants were phenotyped on a daily basis following the parameters listed in Tables 222-223 below. Harvest was conducted while all the spikes were dry. All material was oven dried and the seeds were threshed manually from the spikes prior to measurement of the seed characteristics (weight and size) using scanning and image analysis. The image analysis system included a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.37 (Java based image processing program, which was developed at the U.S. National Institutes of Health and freely available on the internet [rsbweb (dot) nih (dot) gov/]. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Grain yield (gr.)—At the end of the experiment all spikes of the pots were collected. The total grains from all spikes that were manually threshed were weighted. The grain yield was calculated by per plot or per plant.

Spike length and width analysis—At the end of the experiment the length and width of five chosen spikes per plant were measured using measuring tape excluding the awns.

Spike number analysis—The spikes per plant were counted.

Plant height—Each of the plants was measured for its height using measuring tape. Height was measured from ground level to top of the longest spike excluding awns at two time points at the Vegetative growth (30 days after sowing) and at harvest.

Spike weight—The biomass and spikes weight of each plot was separated, measured and divided by the number of plants.

Dry weight—total weight of the vegetative portion above ground (excluding roots) after drying at 70° C. in oven for 48 hours at two time points at the Vegetative growth (30 days after sowing) and at harvest.

Spikelet per spike—number of spikelets per spike was counted.

Root/Shoot Ratio—The Root/Shoot Ratio is calculated using Formula XXII described above.

Total No. of tillers—all tillers were counted per plot at two time points at the Vegetative growth (30 days after sowing) and at harvest.

Node number—number of nodes in the main stem.

Percent of reproductive tillers—was calculated based on Formula XXVI (above).

SPAD—Chlorophyll content was determined using a Minolta SPAD 502 chlorophyll meter and measurement was performed at time of flowering. SPAD meter readings were done on young fully developed leaf. Three measurements per leaf were taken per plot.

Root FW (gr.), root length (cm) and No. of lateral roots—3 plants per plot were selected for measurement of root weight, root length and for counting the number of lateral roots formed.

Shoot FW (fresh weight)—weight of 3 plants per plot were recorded at different time-points.

Average Grain Area (cm²)—At the end of the growing period the grains were separated from the spike. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The grain area was measured from those images and was divided by the number of grains.

Average Grain Length and width (cm)—At the end of the growing period the grains were separated from the spike. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain lengths or width (longest axis) was measured from those images and was divided by the number of grains.

Average Grain perimeter (cm)—At the end of the growing period the grains were separated from the spike. A sample of ˜200 grains was weighted, photographed and images were processed using the below described image processing system. The sum of grain perimeter was measured from those images and was divided by the number of grains.

Heading date—the day in which booting stage was observed was recorded and number of days from sowing to heading was calculated.

Relative water content—Relative water content (RWC) is calculated according to Formula I.

Tiller abortion rate (hd to F)—difference between tiller number at heading and tiller number at flowering divided by tiller number at heading.

Tiller abortion rate—difference between tiller number at harvest and tiller number at flowering divided by tiller number at flowering.

Grain N (H)—% N content of dry matter in the grain at harvest.

Head N (GF)—% N content of dry matter in the head at grain filling.

Total shoot N—calculated as the % N content multiplied by the weight of plant shoot.

Total grain N—calculated as the % N content multiplied by the weight of plant grain yield.

NUE [kg/kg] (N use efficiency)—was calculated based on Formula LI.

NUpE [kg/kg] (N uptake efficiency)—was calculated based on Formula LII.

Grain NUtE (N utilization efficiency)—was calculated based on Formula LV.

Total NUtE—was calculated based on Formula LIII.

Stem Volume—was calculated based on Formula L.

Stem density—was calculated based on Formula LIV.

NHI (N harvest index)—was calculated based on Formula LVI.

BPE (Biomass production efficiency)—was calculated based on Formula LVII.

Grain fill duration—the difference between number of days to maturity and number of days to flowering.

Harvest Index (for Wheat)—The harvest index was calculated using Formula XVIII described above.

Growth rate: the growth rate (GR) of Plant Height (Formula III described above), SPAD (Formula IV described above) and number of tillers (Formula V described above) were calculated with the indicated Formulas.

Specific N absorption—N absorbed per root biomass.

Specific root length—root biomass per root length.

Ratio low N/Normal: Represents ratio for the specified parameter of LowN condition results divided by Normal conditions results (maintenance of phenotype under LowN in comparison to normal conditions).

Data parameters collected are summarized in Tables 222-223, herein below.

TABLE 222
Wheat correlated parameters under normal and
low N conditions (vectors)
Correlation set                  Correlation ID
1000 grain weight [gr.]          1
Avr spike DW (SS) [gr.]          2
Avr spike DW (flowering) [gr.]   3
Avr spike weight (harvest) [gr.] 4
BPE [ratio]                      5
Fertile spikelets ratio [ratio]  6
Grain area [mm2]                 7
Grain fill duration [days]       8
Grains per plant [number]        9
Grains per spike [number]        10
Grains per spikelet [number]     11
Grains weight per plant [gr.]    12
Grains weight per spike [gr.]    13
Harvest index                    14
Leaf Area [cm2]                  15
Leaf Average Width [cm]          16
Leaf Length [cm]                 17
Leaf Perimeter [cm]              18
Leaves num at tillering [number] 19
Leaves num flowering [number]    20
N use efficiency [ratio]         21
NHI [ratio]                      22
Node Num [number]                23
Num days Heading [days]          24
Num days to anthesis [days]      25
NupE [ratio]                     26
Peduncle length [cm]             27
Peduncle thickness [mm]          28
Plant height [cm]                29
RWC [%]                          30
Root length [cm]                 31
Roots DW [gr.]                   32
SPAD early-mid grain filling [SPAD units] 33
SPAD flowering [SPAD units]      34
SPAD mid-late grain filling [SPAD] 35
Seminal roots [number]           36
Shoot C/N [ratio]                37
Shoot DW [gr.]                   18
Shoot/Root [ratio]               39
Spike Area [cm2]                 40
Spike Perimeter [cm]             41
Spike length [cm]                42
Spike width [cm]                 43
Spikelets per spike [number]     44
Tiller abortion rate [ratio]     45
Tillering (Flowering) [number]   46
Tillering (Heading) [number]     47
Tillering (Tillering) [number]   48
Total dry matter [gr]            49
Total Leaf Area [cm2]            50
Vegetative DW (Harvest) [gr.]    51
field awns length [cm]           57
Grain C/N [ratio]                53
grain NUtE [ratio]               54
grain protein [%]                55
peduncle volume [cm3]            56
specific N absorption [mg/gr.]   57
specific root length [gr./cm]    58
tiller abortion rate (hd to F)   59
total NUtE [ratio]               60
total grain N [mg]               61
total shoot N [mg]               62

Table 222. Provided are the wheat correlated parameters. “TP”=time point: “DW”=dry weight; “FW”=fresh weight; “Low N”=Low Nitrogen; “Relative water content [percent]; “num”=number. “gr.”=grams; “cm”=centimeter; “Avr”=average; “RGR”=relative growth rate; “BPE”=biomass production efficiency; “NHI”=Nitrogen harvest index; “NupE”=nitrogen uptake efficiency; “NutE”=nitrogen utilization efficiency; “SPAD”=chlorophyll levels; “F”=flowering stage; “h”=heading stage; “N”=nitrogen.

TABLE 223
Wheat correlated parameters under low N conditions vs. normal (vectors)
Correlated parameter with        Correlation ID
1000 grain weight [gr.]          1
BPE [ratio]                      2
Fertile spikelets ratio [ratio]  3
Grain area [mm2]                 4
Grain fill duration [days]       5
Grains per spike [number]        6
Grains per spikelet [number]     7
Grains weight per spike [gr.]    8
N use efficiency [ratio]         9
NHI [ratio]                      10
NupE [ratio]                     11
Peduncle thickness [mm]          12
Root length [cm]                 13
SPAD early-mid grain filling [SPAD unit] 14
SPAD flowering [SPAD unit]       15
Seminal roots [number]           16
Shoot C/N [ratio]                17
Spikelets per spike [number]     18
Tiller abortion rate [ratio]     19
Grain C/N ratio                  20
Grain NUtE [ratio]               21
Grain protein [%]                22
Peduncle volume [cm3]            23
Specific N absorption [mg/gr]    24
Specific root length [gr./cm]    25
Tiller abortion rate (hd to F) [ratio] 26
Total NUtE [ratio]               27
Total grain N [mg]               28
Total shoot N [mg]               29

Table 223. Provided are the wheat correlated parameters. “TP”=time point; “DW”=dry weight; “FW”=fresh weight; “Low N”=Low Nitrogen; “Relative water content [percent]; “num”=number. “gr.”=grams; “cm”=centimeter; “Avr”=average; “RGR”=relative growth rate; “BPE”=biomass production efficiency; “NHI”=Nitrogen harvest index; “NupE”=nitrogen uptake efficiency; “NutE”=nitrogen utilization efficiency: “SPAD”=chlorophyll levels; “F”=flowering stage; “h”=heading stage; “N”=nitrogen.

Experimental Results

Fourteen different Wheat accessions were grown and characterized for different parameters as described above. Tables 222-223 describe the wheat correlated parameters. The average for each of the measured parameters was calculated using the JMP software and values are summarized in Tables 224-229 below. Subsequent correlation analysis between the various transcriptome sets and the average parameters was conducted (Tables 230-232). Follow, results were integrated to the database.

TABLE 224
Measured parameters of correlation IDs in
wheat accessions under normal conditions
Line/
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	24.81	19.31	11.63	29.68	9.24	21.05	22.14
2	1.515	0.838	1.489	2.643	1.230	1.445	0.665
3	5.669	0.275	0.312	4.283	0.364	0.236	NA
4	1.356	0.893	1.414	2.510	1.014	1.565	0.506
5	0.581	0.364	0.338	0.466	0.370	0.611	NA
6	74.09	73.31	81.68	88.72	NA	75.72	NA
7	0.199	0.165	0.153	0.184	0.170	0.191	0.137
8	27.89	31.43	NA	30.02	NA	27.75	NA
9	94.23	68.65	122.44	123.90	151.23	105.13	16.30
10	19.69	13.29	22.77	37.16	21.52	19.41	5.98
11	2.166	1.264	2.186	2.932	NA	1.641	NA
12	4.536	2.749	3.756	5.934	4.316	4.862	0.476
13	0.950	0.531	0.696	1.739	0.590	0.897	0.133
14	0.483	0.317	0.276	0.490	0.257	0.345	0.046
15	13.80	19.54	NA	22.46	NA	21.61	NA
16	0.858	0.916	NA	1.262	NA	1.054	NA
17	19.65	26.79	NA	22.03	NA	25.53	NA
18	41.46	53.77	NA	48.92	NA	53.08	NA
19	6.60	5.60	6.20	6.60	5.80	5.60	6.40
20	18.00	13.00	22.50	11.50	20.75	18.50	NA
21	0.045	0.027	0.038	0.059	0.043	0.049	0.005
22	0.481	0.306	0.242	0.433	0.260	0.448	NA
23	4.00	4.43	4.50	4.94	4.27	4.56	NA
24	60.22	69.88	85.25	61.78	83.00	65.78	105.00
25	69.11	73.00	85.25	69.56	86.38	71.25	105.00
26	2.50	2.49	4.26	3.59	4.70	3.33	NA
27	27.28	30.39	21.21	30.71	26.15	34.07	NA
28	2.61	2.72	3.53	3.31	3.22	3.07	NA
29	45.59	63.41	69.33	62.91	68.03	79.43	NA
30	76.29	NA	82.03	76.11	NA	67.30	NA
31	31.10	16.20	28.10	34.06	37.84	26.88	31.98
32	0.89	0.07	0.20	1.01	0.36	0.50	0.63
33	37.33	28.34	NA	38.71	NA	46.47	NA
34	38.75	31.09	43.30	40.29	45.54	44.93	NA
35	35.97	NA	NA	37.21	NA	NA	NA
36	11.20	6.00	8.00	11.00	7.80	7.80	10.20
37	72.05	68.35	74.91	61.34	86.58	121.52	NA
38	0.641	0.250	0.457	0.557	0.429	0.369	0.580
39	0.724	3.466	2.301	0.552	1.180	0.740	0.920
40	9.52	6.27	8.42	11.73	7.03	6.51	8.96
41	22.34	15.81	22.47	20.86	26.69	20.43	30.39
42	8.48	6.51	9.54	8.14	10.29	8.51	13.41
43	1.39	1.18	1.12	1.68	0.83	1.02	0.89
44	16.24	17.22	19.40	16.93	NA	17.42	NA
45	19.58	−10.00	32.58	−2.31	46.10	41.28	NA
46	6.00	4.75	7.75	3.25	13.13	9.75	NA
47	4.00	5.89	7.00	4.24	11.25	6.86	2.80
48	2.60	1.80	3.40	2.00	3.40	2.40	2.80
49	75.26	62.94	109.09	94.88	128.46	112.16	72.40
50	227.54	111.47	NA	176.24	NA	549.02	NA
51	23.35	28.68	57.53	30.57	70.98	52.25	61.70
52	6.46	8.45	6.33	6.56	NA	1.20	NA
53	15.38	14.73	14.86	15.39	14.46	13.33	NA
54	0.04	0.02	0.01	0.03	0.01	0.03	NA
55	15.12	15.79	15.61	14.94	16.13	17.49	NA
56	1.46	1.76	2.08	2.64	2.13	2.51	NA
57	146.26	2391.37	1626.16	201.95	956.25	367.62	NA
58	0.03	0.00	0.01	0.03	0.01	0.02	0.02
59	−50.00	19.42	−10.71	23.31	−16.67	−42.19	NA
60	0.301	0.253	0.256	0.264	0.274	0.337	NA
61	120.32	76.17	102.85	155.55	122.14	149.13	0.00
62	129.59	172.80	322.79	203.44	347.42	183.50	0.00

Table 224. Provided are the values of each of the parameters (as described above) measured in wheat accessions (Lines). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Corr.”—correlation.

TABLE 225
Measured parameters correlation IDs in additional
wheat accessions under normal conditions
Line/
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14
1	15.08	13.61	20.71	33.52	16.66	12.74	13.43
2	1.593	1.670	1.962	2.894	1.642	0.618	0.419
3	0.266	0.279	0.473	9.111	5.109	NA	NA
4	1.416	1.480	2.056	2.458	1.158	0.440	0.359
5	0.581	0.271	0.556	0.831	0.759	NA	NA
6	83.70	87.05	78.99	86.83	75.82	NA	NA
7	0.204	0.174	0.183	0.195	0.172	0.115	0.112
8	32.84	NA	29.20	27.10	26.48	NA	NA
9	106.83	103.09	141.63	139.23	85.38	13.10	18.57
10	20.00	23.41	30.03	34.00	18.49	5.07	6.60
11	1.828	1.934	2.303	2.803	2.283	NA	NA
12	5.294	4.111	6.007	6.907	3.589	0.396	2.531
13	0.962	0.926	1.260	1.686	0.777	0.091	0.772
14	0.406	0.326	0.423	0.480	0.451	0.033	0.175
15	25.44	23.31	20.79	16.25	13.46	NA	NA
16	1.169	1.116	1.187	1.012	0.828	NA	NA
17	27.80	25.91	21.67	19.98	19.81	NA	NA
18	58.95	54.29	46.10	42.25	40.93	NA	NA
19	5.40	5.40	5.20	6.00	6.20	5.00	5.00
20	11.00	23.75	19.00	12.50	18.75	NA	NA
21	0.053	0.041	0.060	0.069	0.036	NA	NA
22	0.472	0.229	0.403	0.542	0.536	NA	NA
23	4.21	4.57	4.94	4.69	3.94	NA	NA
24	68.75	74.29	68.75	58.89	57.11	106.25	77.00
25	71.88	78.00	72.38	67.33	68.67	105.00	NA
26	3.78	4.78	3.51	3.04	1.81	NA	NA
27	29.78	25.44	27.41	28.13	21.53	NA	NA
28	3.06	3.75	3.51	3.02	1.92	NA	NA
29	61.86	62.33	59.18	55.23	44.72	NA	NA
30	73.33	NA	70.94	80.72	74.88	NA	NA
31	23.42	36.02	38.88	37.20	33.00	22.38	34.60
32	0.11	0.16	0.52	1.04	0.54	0.27	0.25
33	38.62	35.80	45.58	46.95	35.32	NA	NA
34	38.98	36.10	46.43	42.89	34.15	NA	NA
35	NA	NA	NA	46.27	35.81	NA	NA
36	6.00	6.20	8.20	10.80	7.60	6.60	7.80
37	95.65	54.23	88.39	110.33	103.07	NA	NA
38	0.339	0.447	0.461	0.520	0.427	0.331	0.386
39	3.116	2.755	0.891	0.498	0.785	1.238	1.532
40	9.88	9.43	10.33	12.38	9.53	7.33	8.14
41	20.81	20.89	21.34	22.76	18.72	22.74	27.02
42	8.11	8.25	8.57	9.13	7.46	9.69	11.24
43	1.50	1.43	1.55	1.64	1.52	1.03	0.92
44	16.22	17.25	18.84	19.56	16.93	NA	NA
45	−25.88	34.26	27.41	1.18	25.60	NA	NA
46	4.25	6.75	6.75	4.25	6.25	NA	NA
47	5.32	5.81	4.57	3.19	3.43	1.80	2.80
48	2.20	1.60	1.80	1.60	2.00	1.80	2.80
49	100.76	100.02	116.56	115.89	63.75	71.40	109.78
50	431.85	231.67	188.34	186.23	269.35	NA	NA
51	39.99	47.89	44.82	37.47	20.86	63.48	102.17
52	8.57	7.47	7.41	6.17	5.30	NA	NA
53	13.99	15.33	17.26	17.11	15.05	NA	NA
54	0.03	0.01	0.03	0.05	0.04	NA	NA
55	16.67	15.14	13.42	13.60	15.44	NA	NA
56	2.19	2.11	2.65	2.02	0.62	NA	NA
57	1596.15	2272.98	404.96	133.54	154.31	NA	NA
58	0.00	0.00	0.01	0.03	0.02	NA	NA
59	20.05	−16.08	−47.66	−33.21	−82.29	NA	NA
60	0.307	0.209	0.332	0.381	0.352	NA	NA
61	154.79	109.19	141.44	164.82	97.18	NA	NA
62	173.47	368.56	209.50	139.48	83.97	NA	NA

Table 225. Provided are the values of each of the parameters (as described above) measured in wheat accessions (Lines). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Corr.”—correlation.

TABLE 226
Measured parameters of correlation IDs in wheat accessions under low N conditions
Line/
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	14.16	25.17	14.38	31.87	16.45	17.73	18.58
2	3.13	2.01	3.00	5.55	1.32	3.31	0.83
3	0.286	0.329	0.304	0.502	0.228	0.319	NA
4	1.364	0.993	1.758	2.656	1.116	1.452	0.790
5	0.918	0.930	0.740	1.005	0.675	0.887	NA
6	71.78	67.63	90.51	86.83	85.63	86.29	90.18
7	0.177	0.164	0.137	0.175	0.154	0.181	0.121
8	27.54	31.57	27.11	33.14	22.43	33.75	NA
9	78.65	67.44	95.73	71.48	81.53	70.10	23.67
10	25.30	20.12	39.44	43.83	21.07	24.53	8.38
11	2.69	1.73	2.94	3.57	1.93	2.45	0.69
12	3.43	2.50	2.98	3.29	2.54	2.93	1.26
13	1.062	0.746	1.220	2.021	0.641	0.970	0.402
14	0.506	0.410	0.380	0.503	0.268	0.376	0.092
15	15.28	20.23	NA	11.13	NA	15.37	NA
16	0.939	1.010	NA	0.802	NA	0.903	NA
17	20.01	24.79	NA	16.84	NA	21.17	NA
18	43.99	53.54	NA	35.89	NA	43.81	NA
19	6.40	6.40	6.80	6.00	6.00	6.20	5.00
20	NA	NA	NA	NA	6.25	NA	NA
21	0.137	0.100	0.119	0.132	0.102	0.117	0.051
22	0.544	0.490	0.416	0.657	0.282	0.558	NA
23	4.125	4.077	4.438	4.750	3.938	3.813	NA
24	57.56	67.11	76.22	61.33	80.63	65.11	109.00
25	68.89	73.00	77.89	68.00	82.57	71.25	105.00
26	5.03	3.92	6.22	6.07	7.61	5.99	0.00
27	75.91	39.58	44.70	32.31	20.79	43.84	NA
28	2.45	2.85	3.54	3.59	2.88	3.42	NA
29	47.48	81.12	85.36	61.31	62.29	94.38	NA
30	78.08	75.04	84.41	84.12	NA	82.70	NA
31	34.60	33.36	33.10	32.00	38.60	41.90	36.90
32	0.777	0.629	0.284	1.100	0.477	0.682	0.608
33	41.11	26.03	NA	38.94	NA	38.05	NA
34	40.38	32.17	38.19	42.45	37.49	42.30	NA
35	33.10	NA	NA	32.57	NA	NA	NA
36	11.20	8.00	10.00	9.60	7.00	8.80	8.20
37	137.82	165.87	187.00	144.70	183.80	182.45	NA
38	0.448	0.482	0.637	0.511	0.387	0.552	0.478
39	0.577	0.766	2.242	0.465	0.812	0.810	0.786
40	8.05	5.90	7.31	11.08	8.29	7.38	9.73
41	18.48	15.54	19.57	19.84	23.88	20.11	32.44
42	7.32	6.31	8.17	7.87	10.05	8.70	14.36
43	1.285	1.103	1.128	1.514	1.034	1.067	0.916
44	16.20	16.29	17.49	16.44	17.97	16.49	20.62
45	17.33	36.36	46.11	33.00	51.94	53.20	NA
46	3.75	5.50	4.50	7.50	7.75	6.25	NA
47	4.14	4.22	4.29	3.00	6.05	5.29	2.40
48	1.80	2.60	4.20	1.60	3.20	2.80	2.40
49	52.66	46.55	67.18	52.36	92.33	58.79	89.95
50	201.42	190.89	NA	182.97	NA	148.36	NA
51	19.12	19.55	40.05	17.70	59.04	28.30	74.95
52	5.77	7.70	6.64	6.17	NA	NA	NA
53	26.65	22.91	23.37	24.05	32.57	23.51	NA
54	0.060	0.050	0.033	0.063	0.019	0.044	NA
55	8.60	9.96	9.81	9.58	7.09	9.80	NA
56	1.22	2.52	4.39	3.26	1.36	4.02	0.00
57	161.96	155.87	547.22	138.06	399.44	219.78	NA
58	0.022	0.019	0.009	0.034	0.012	0.016	NA
59	9.48	−30.26	−5.00	16.67	−28.15	−18.24	NA
60	0.419	0.475	0.432	0.345	0.485	0.392	NA
61	68.42	48.01	64.65	99.72	53.69	83.57	NA
62	57.37	50.04	90.78	52.09	136.69	66.27	NA

Table 226. Provided are the values of each of the parameters (as described above) measured in wheat accessions (Lines). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Cor.”—correlation.

TABLE 227
Measured parameters of correlation IDs in additional
wheat accessions under low N conditions
Line/
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14
1	15.41	9.52	24.18	25.37	13.45	21.45	15.71
2	2.96	3.21	5.22	5.01	2.98	1.14	0.84
3	0.371	0.339	0.697	0.575	0.266	NA	NA
4	1.457	1.516	2.603	2.500	1.262	1.085	0.711
5	0.809	0.806	0.541	0.888	0.761	NA	NA
6	78.66	79.08	80.66	80.58	75.68	83.34	81.51
7	0.191	0.161	0.166	0.169	0.159	0.134	0.121
8	31.43	31.93	31.14	30.37	27.98	NA	NA
9	57.70	74.75	83.60	81.60	73.13	67.66	24.52
10	19.91	24.84	46.51	40.93	22.11	22.96	7.78
11	1.85	2.29	3.58	3.62	2.26	2.02	0.63
12	2.77	2.63	3.27	3.41	2.75	1.50	0.92
13	0.932	0.879	1.819	1.672	0.832	0.506	0.198
14	0.386	0.326	0.420	0.464	0.451	0.165	0.142
15	13.37	18.07	14.65	16.78	12.92	NA	NA
16	0.806	0.976	0.945	0.934	0.922	NA	NA
17	19.79	22.14	19.60	22.26	18.02	NA	NA
18	41.85	46.51	45.20	46.58	38.43	NA	NA
19	5.60	5.40	6.00	6.00	6.00	5.80	5.40
20	NA	NA	NA	NA	NA	NA	NA
21	0.111	0.105	0.131	0.137	0.110	NA	NA
22	0.563	0.466	0.453	0.660	0.507	NA	NA
23	3.313	4.250	3.533	4.563	4.563	NA	NA
24	65.56	70.00	66.44	58.44	53.11	103.56	109.00
25	71.00	72.57	73.00	67.78	68.44	101.13	105.00
26	6.24	6.00	8.40	7.49	5.44	NA	NA
27	42.72	37.81	32.50	27.66	24.56	NA	NA
28	3.16	3.23	3.69	3.51	2.44	NA	NA
29	74.44	80.19	64.56	61.81	54.06	NA	NA
30	72.54	53.64	84.04	79.53	86.25	NA	NA
31	32.16	32.90	37.30	36.44	27.40	32.20	33.00
32	0.653	0.745	1.508	1.051	0.720	0.403	0.596
33	32.06	31.48	41.45	45.34	35.17	NA	NA
34	38.79	36.31	NA	45.14	34.60	NA	NA
35	NA	NA	NA	37.87	29.01	NA	NA
36	9.20	8.80	11.40	10.40	10.80	7.00	7.40
37	134.09	149.77	92.57	132.22	122.57	NA	NA
38	0.661	0.595	0.610	0.603	0.628	0.425	0.429
39	1.013	0.798	0.405	0.574	0.873	1.055	0.720
40	8.21	7.77	10.74	10.17	7.26	7.27	9.72
41	18.68	18.65	20.31	18.97	16.29	21.77	30.30
42	7.00	6.99	8.08	7.44	6.43	9.01	13.43
43	1.403	1.395	1.505	1.571	1.327	1.121	1.047
44	15.16	17.20	18.53	18.00	17.13	18.38	18.97
45	35.00	52.00	44.62	31.67	16.88	NA	NA
46	4.50	6.25	3.25	3.00	4.00	NA	NA
47	4.76	3.90	3.65	3.19	4.10	3.20	2.40
48	3.20	2.40	2.80	2.00	2.00	3.20	2.40
49	55.21	64.50	62.16	56.55	51.08	84.82	91.80
50	100.45	237.33	109.86	273.83	230.90	NA	NA
51	22.35	28.23	24.71	19.81	19.47	63.20	75.93
52	9.31	7.49	5.63	5.46	4.75	NA	NA
53	24.35	23.75	25.39	22.62	20.96	NA	NA
54	0.041	0.033	0.028	0.054	0.041	NA	NA
55	9.46	9.69	9.02	10.20	10.94	NA	NA
56	3.34	3.09	3.46	2.68	1.14	NA	NA
57	238.94	201.24	139.26	178.14	188.90	NA	NA
58	0.020	0.023	0.040	0.029	0.026	NA	NA
59	5.50	−60.06	10.96	5.97	2.33	NA	NA
60	0.354	0.430	0.296	0.302	0.376	NA	NA
61	87.82	69.89	95.05	123.62	68.89	NA	NA
62	68.21	80.06	114.89	63.65	67.08	NA	NA

Table 227. Provided are the values of each of the parameters (as described above) measured in wheat accessions (Lines). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Cor.”—correlation.

TABLE 228
Additional measured parameters of correlation IDs in
wheat accessions under low N vs. normal conditions (ratio)
Line/
Corr. ID	Line-1	Line-2	Line-3	Line-4	Line-5	Line-6	Line-7
1	0.57	1.30	1.24	1.07	1.78	0.84	0.84
2	1.580	2.555	2.190	2.155	1.827	1.451	NA
3	0.969	0.922	1.108	0.979	NA	1.140	NA
4	0.889	0.990	0.897	0.948	0.905	0.950	0.880
5	0.987	1.005	NA	1.104	NA	1.216	NA
6	1.28	1.51	1.73	1.18	0.98	1.26	1.40
7	1.24	1.37	1.34	1.22	NA	1.49	NA
8	1.12	1.41	1.75	1.16	1.09	1.08	3.03
9	3.026	3.634	3.170	2.217	2.354	2.408	10.621
10	1.130	1.601	1.721	1.516	1.084	1.244	NA
11	2.013	1.575	1.461	1.691	1.622	1.802	NA
12	0.939	1.049	1.001	1.084	0.895	1.114	NA
13	1.113	2.059	1.178	0.940	1.020	1.559	1.154
14	1.101	0.918	NA	1.006	NA	0.819	NA
15	1.042	1.035	0.882	1.054	0.823	0.941	NA
16	1.000	1.333	1.250	0.873	0.897	1.118	0.804
17	1.913	2.427	2.496	2.359	2.123	1.501	NA
18	0.997	0.946	0.901	0.971	NA	0.946	NA
19	0.885	−3.636	1.415	−14.300	1.127	1.289	NA
20	1.733	1.556	1.572	1.563	2.252	1.764	NA
21	1.709	3.138	2.818	2.165	1.496	1.667	NA
22	0.569	0.630	0.629	0.641	0.440	0.560	NA
23	0.838	1.432	2.113	1.236	0.636	1.598	NA
24	1.107	0.065	0.337	0.684	0.418	0.598	NA
25	0.788	4.227	1.215	1.162	1.286	0.876	NA
26	−0.190	−1.558	0.467	0.715	1.689	0.432	NA
27	1.390	1.878	1.686	1.305	1.773	1.164	NA
28	0.569	0.630	0.629	0.641	0.440	0.560	NA
29	0.443	0.290	0.281	0.256	0.393	0.361	NA

Table 228. Provided are the values of each of the parameters (as described above) measured in wheat accessions (Lines). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Cor.”—correlation.

TABLE 229
Additional measured parameters of correlation IDs in wheat
accessions under low N vs. normal conditions (ratio)
Line/
Corr. ID	Line-8	Line-9	Line-10	Line-11	Line-12	Line-13	Line-14
1	1.02	0.70	1.17	0.76	0.81	1.68	1.17
2	1.393	2.969	0.972	1.069	1.003	NA	NA
3	0.940	0.908	1.021	0.928	0.998	NA	NA
4	0.937	0.924	0.903	0.866	0.923	1.169	1.079
5	0.957	NA	1.067	1.121	1.057	NA	NA
6	1.00	1.06	1.55	1.20	1.20	4.52	1.18
7	1.01	1.19	1.55	1.29	0.99	NA	NA
8	0.97	0.95	1.44	0.99	1.07	5.54	0.26
9	2.097	2.559	2.179	1.977	3.070	NA	NA
10	1.194	2.039	1.123	1.219	0.944	NA	NA
11	1.901	1.255	2.393	2.462	3.002	NA	NA
12	1.031	0.992	1.050	1.162	1.269	NA	NA
13	1.373	0.913	0.959	0.980	0.830	1.439	0.954
14	0.830	0.879	0.909	0.966	0.996	NA	NA
15	0.995	1.006	NA	1.052	1.013	NA	NA
16	1.533	1.419	1.390	0.963	1.421	1.061	0.949
17	1.402	2.762	1.047	1.198	1.189	NA	NA
18	0.934	0.997	0.983	0.920	1.012	NA	NA
19	−1.352	1.518	1.628	26.917	0.659	NA	NA
20	1.741	1.550	1.471	1.322	1.393	NA	NA
21	1.333	2.945	0.993	1.083	0.961	NA	NA
22	0.567	0.640	0.672	0.750	0.709	NA	NA
23	1.526	1.464	1.308	1.329	1.836	NA	NA
24	0.150	0.089	0.344	1.334	1.224	NA	NA
25	4.376	5.031	3.037	1.028	1.593	NA	NA
26	0.274	3.734	−0.230	−0.180	−0.028	NA	NA
27	1.153	2.055	0.891	0.793	1.068	NA	NA
28	0.567	0.640	0.672	0.750	0.709	NA	NA
29	0.393	0.217	0.548	0.456	0.799	NA	NA

Table 229. Provided are the values of each of the parameters (as described above) measured in wheat accessions (Lines). Growth conditions are specified in the experimental procedure section. “NA”=not available. “Cor.”—correlation

TABLE 230
Correlation between the expression level of selected genes of some embodiments of the invention
in various tissues and the phenotypic performance under normal conditions across wheat accessions
Gene			Exp.	Corr.	Gene			Exp.	Corr.
Name	R	P value	set	Set ID	Name	R	P value	set	Set ID
LBY214	0.73	2.70E−02	3	18	LBY214	0.73	2.60E−02	3	17
LBY214	0.71	2.06E−02	1	47	LBY214	0.80	5.46E−03	1	29
LBY214	0.79	6.57E−03	1	51	LBY214	0.80	5.42E−02	5	37
LBY214	0.72	1.96E−02	6	36	LBY214	0.72	1.18E−02	8	54
LBY214	0.74	9.54E−03	8	5	LBY214	0.75	7.36E−03	8	60
LBY215	0.94	4.95E−04	2	16	LBY215	0.88	6.72E−04	2	12
LBY215	0.72	2.00E−02	2	14	LBY215	0.83	2.73E−03	2	56
LBY215	0.88	6.72E−04	2	21	LBY215	0.71	2.24E−02	2	43
LBY215	0.74	1.52E−02	2	40	LBY215	0.71	2.11E−02	2	2
LBY215	0.88	8.88E−04	2	61	LBY215	0.72	1.82E−02	2	7
LBY215	0.84	8.79E−03	2	50	LBY215	0.78	8.14E−03	2	13
LBY215	0.72	1.86E−02	2	4	LBY215	0.71	4.83E−02	7	15
LBY215	0.79	1.85E−02	7	18	LBY215	0.76	2.80E−02	7	17
LBY215	0.71	2.21E−02	7	55	LBY215	0.85	7.17E−03	7	50
LBY215	0.78	4.47E−03	3	1	LBY215	0.79	4.13E−03	3	32
LBY215	0.72	1.31E−02	3	12	LBY215	0.73	1.12E−02	3	14
LBY215	0.77	5.65E−03	3	58	LBY215	0.75	7.39E−03	3	3
LBY215	0.72	1.31E−02	3	21	LBY215	0.79	3.65E−03	3	43
LBY215	0.94	2.09E−05	3	40	LBY215	0.92	7.61E−05	3	2
LBY215	0.84	1.26E−03	3	36	LBY215	0.93	8.73E−05	3	11
LBY215	0.87	4.71E−04	3	13	LBY215	0.82	2.15E−03	3	4
LBY215	0.83	1.39E−03	3	10	LBY215	0.85	1.65E−03	1	46
LBY215	0.79	6.14E−03	1	24	LBY215	0.90	4.53E−04	1	47
LBY215	0.71	2.13E−02	1	29	LBY215	0.78	7.38E−03	1	25
LBY215	0.72	1.79E−02	1	41	LBY215	0.79	6.41E−03	1	42
LBY215	0.76	1.79E−02	1	50	LBY215	0.84	2.49E−03	1	49
LBY215	0.93	7.35E−05	1	51	LBY215	0.75	1.25E−02	4	32
LBY215	0.72	1.89E−02	4	14	LBY215	0.84	2.37E−03	4	58
LBY215	0.82	3.74E−03	4	22	LBY215	0.75	1.29E−02	4	7
LBY215	0.72	4.22E−02	4	50	LBY215	0.74	1.49E−02	9	37
LBY215	0.82	4.06E−03	9	12	LBY215	0.82	4.06E−03	9	21
LBY215	0.89	1.31E−03	9	33	LBY215	0.81	4.28E−03	9	61
LBY215	0.75	2.10E−02	9	50	LBY215	0.89	1.77E−02	5	1
LBY215	0.92	9.72E−03	5	32	LBY215	0.80	5.81E−02	5	14
LBY215	0.89	1.72E−02	5	6	LBY215	0.90	1.52E−02	5	58
LBY215	0.81	5.16E−02	5	3	LBY215	0.95	4.01E−03	5	43
LBY215	0.88	1.94E−02	5	40	LBY215	0.91	1.21E−02	5	2
LBY215	0.78	6.96E−02	5	61	LBY215	0.85	3.33E−02	5	36
LBY215	0.93	6.35E−03	5	11	LBY215	0.84	3.70E−02	5	13
LBY215	0.80	5.62E−02	5	4	LBY215	0.72	1.07E−01	5	19
LBY215	0.83	4.11E−02	5	10	LBY215	0.70	2.31E−02	6	37
LBY215	0.72	1.77E−02	6	55	LBY215	0.96	2.19E−04	6	50
LBY215	0.81	2.54E−03	8	1	LBY215	0.85	1.00E−03	8	32
LBY215	0.78	4.39E−03	8	12	LBY215	0.83	1.39E−03	8	14
LBY215	0.84	1.28E−03	8	58	LBY215	0.79	3.60E−03	8	3
LBY215	0.74	9.07E−03	8	54	LBY215	0.78	4.39E−03	8	21
LBY215	0.70	1.61E−02	8	43	LBY215	0.80	3.39E−03	8	40
LBY215	0.85	9.66E−04	8	2	LBY215	0.84	1.31E−03	8	36
LBY215	0.85	2.06E−03	8	11	LBY215	0.85	1.02E−03	8	13
LBY215	0.85	9.09E−04	8	4	LBY215	0.80	2.83E−03	8	10
LBY216	0.76	2.93E−02	2	50	LBY216	0.81	4.37E−03	7	36
LBY216	0.91	2.51E−04	4	62	LBY216	0.76	1.00E−02	4	24
LBY216	0.89	5.12E−04	4	26	LBY216	0.79	6.90E−03	4	25
LBY216	0.71	2.03E−02	4	20	LBY216	0.72	2.89E−02	9	15
LBY216	0.79	7.00E−03	9	29	LBY216	0.73	2.55E−02	9	18
LBY216	0.81	7.91E−03	9	50	LBY216	0.71	1.17E−01	5	3
LBY216	0.86	2.99E−02	5	48	LBY216	0.72	1.07E−01	5	22
LBY216	0.71	5.07E−02	6	50	LBY216	0.80	3.30E−03	8	24
LBY216	0.74	8.72E−03	8	25	LBY217	0.79	6.55E−03	2	27
LBY217	0.95	3.06E−05	4	62	LBY217	0.77	9.70E−03	4	24
LBY217	0.94	4.47E−05	4	26	LBY217	0.77	9.02E−03	4	25
LBY217	0.74	1.43E−02	4	51	LBY217	0.88	3.38E−04	8	62
LBY217	0.80	3.04E−03	8	26	LBY217	0.75	7.45E−03	8	25
LBY218	0.86	1.36E−02	2	30	LBY218	0.74	9.56E−03	3	32
LBY218	0.75	7.99E−03	3	14	LBY218	0.75	8.44E−03	3	58
LBY218	0.81	2.58E−03	3	3	LBY218	0.71	1.48E−02	3	54
LBY218	0.74	9.23E−03	3	19	LBY218	0.80	4.97E−03	1	1
LBY218	0.77	8.62E−03	1	32	LBY218	0.82	6.53E−03	1	6
LBY218	0.82	3.97E−03	1	58	LBY218	0.71	2.07E−02	1	3
LBY218	0.82	3.53E−03	1	2	LBY218	0.78	7.83E−03	1	36
LBY218	0.77	1.50E−02	1	11	LBY218	0.80	5.46E−03	1	13
LBY218	0.78	7.69E−03	1	4	LBY218	0.84	2.34E−03	1	19
LBY218	0.82	3.90E−03	1	10	LBY218	0.71	2.17E−02	9	55
LBY218	0.70	1.18E−01	5	32	LBY218	0.79	6.36E−02	5	14
LBY218	0.74	9.39E−02	5	58	LBY218	0.77	7.05E−02	5	3
LBY218	0.80	5.41E−02	5	22	LBY218	0.87	2.34E−02	5	19
LBY218	0.94	5.98E−04	6	50	LBY218	0.76	6.58E−03	8	1
LBY218	0.78	4.63E−03	8	32	LBY218	0.71	1.46E−02	8	14
LBY218	0.81	2.56E−03	8	58	LBY218	0.85	9.31E−04	8	3
LBY218	0.82	1.82E−03	8	54	LBY218	0.79	3.65E−03	8	22
LBY218	0.80	3.23E−03	8	5	LBY219	0.74	2.28E−02	2	44
LBY219	0.77	9.11E−03	7	38	LBY219	0.72	1.85E−02	7	36
LBY219	0.83	5.17E−03	7	11	LBY219	0.82	3.30E−03	7	19
LBY219	0.83	3.24E−03	1	14	LBY219	0.77	9.43E−03	1	54
LBY219	0.80	4.97E−03	1	43	LBY219	0.77	9.18E−03	1	40
LBY219	0.70	2.35E−02	1	5	LBY219	0.80	8.93E−03	1	11
LBY219	0.76	1.15E−02	9	48	LBY220	0.76	4.71E−02	7	30
LBY220	0.75	1.22E−02	1	1	LBY220	0.75	5.34E−02	1	30
LBY220	0.93	8.31E−05	1	14	LBY220	0.71	2.25E−02	1	3
LBY220	0.79	6.64E−03	1	54	LBY220	0.72	1.85E−02	1	22
LBY220	0.81	4.40E−03	1	53	LBY220	0.91	2.36E−04	1	43
LBY220	0.90	4.20E−04	1	40	LBY220	0.81	4.68E−03	1	2
LBY220	0.90	9.18E−04	1	11	LBY220	0.84	2.10E−03	1	13
LBY220	0.77	9.01E−03	1	4	LBY220	0.71	2.04E−02	1	10
LBY220	0.70	2.34E−02	4	39	LBY220	0.77	2.64E−02	9	30
LBY220	0.71	2.08E−02	9	24	LBY220	0.77	9.03E−03	9	48
LBY220	0.79	6.15E−03	9	25	LBY220	0.88	2.02E−02	5	46
LBY220	0.78	6.81E−02	5	31	LBY220	0.87	2.40E−02	5	48
LBY220	0.74	9.23E−02	5	34	LBY220	0.92	9.20E−03	5	20
LBY220	0.87	2.26E−02	5	45	LBY220	0.81	1.40E−02	6	15
LBY220	0.74	3.64E−02	6	16	LBY220	0.83	2.64E−03	6	56
LBY220	0.77	8.69E−03	6	29	LBY220	0.76	2.88E−02	6	33
LBY220	0.71	2.26E−02	6	49	LBY220	0.75	7.57E−03	8	37
LBY220	0.72	2.83E−02	8	50	LBY221	0.71	1.34E−02	3	3
LBY221	0.78	6.91E−02	5	48	LBY221	0.70	1.21E−01	5	50
LBY222	0.78	8.27E−03	2	27	LBY222	0.76	3.02E−02	2	50
LBY222	0.74	9.74E−03	3	1	LBY222	0.79	4.18E−03	3	32
LBY222	0.77	5.53E−03	3	58	LBY222	0.91	1.24E−04	3	3
LBY222	0.81	2.62E−03	3	54	LBY222	0.80	3.32E−03	3	5
LBY222	0.74	9.56E−03	3	60	LBY222	0.75	1.17E−02	1	24
LBY222	0.74	1.37E−02	1	47	LBY222	0.74	1.44E−02	1	25
LBY222	0.71	3.23E−02	1	33	LBY222	0.72	1.86E−02	1	42
LBY222	0.70	2.37E−02	1	51	LBY222	0.75	1.26E−02	4	55
LBY222	0.84	9.19E−03	4	50	LBY222	0.88	1.70E−03	9	50
LBY222	0.71	1.16E−01	5	14	LBY222	0.79	6.01E−02	5	58
LBY222	0.71	1.12E−01	5	3	LBY222	0.83	4.30E−02	5	48
LBY222	0.76	7.95E−02	5	38	LBY222	0.74	9.31E−02	5	36
LBY222	0.96	2.14E−03	5	19	LBY222	0.89	2.98E−03	6	50
LBY222	0.70	1.64E−02	8	1	LBY222	0.84	1.19E−03	8	32
LBY222	0.73	1.15E−02	8	14	LBY222	0.84	1.23E−03	8	58
LBY222	0.83	1.56E−03	8	3	LBY222	0.80	3.04E−03	8	38
LBY222	0.74	9.40E−03	8	2	LBY222	0.82	2.11E−03	8	36
LBY222	0.83	3.00E−03	8	11	LBY222	0.73	1.09E−02	8	13
LBY222	0.84	1.27E−03	8	19	LBY224	0.76	1.03E−02	2	14
LBY224	0.84	2.57E−03	2	54	LBY224	0.84	2.18E−03	2	22
LBY224	0.70	2.34E−02	2	61	LBY224	0.80	5.83E−03	2	7
LBY224	0.79	6.49E−03	2	5	LBY224	0.83	1.03E−02	2	50
LBY224	0.72	6.86E−02	7	30	LBY224	0.82	6.56E−03	7	11
LBY224	0.72	4.21E−02	3	30	LBY224	0.73	1.70E−02	1	32
LBY224	0.82	3.79E−03	1	14	LBY224	0.83	2.78E−03	1	3
LBY224	0.88	8.49E−04	1	54	LBY224	0.77	8.91E−03	1	22
LBY224	0.85	2.02E−03	1	43	LBY224	0.74	1.38E−02	1	40
LBY224	0.79	6.69E−03	1	2	LBY224	0.85	1.89E−03	1	5
LBY224	0.72	1.87E−02	1	60	LBY224	0.87	2.38E−03	1	11
LBY224	0.75	1.20E−02	1	13	LBY224	0.71	2.09E−02	1	10
LBY224	0.79	6.71E−03	9	28	LBY224	0.72	1.83E−02	9	56
LBY224	0.84	2.39E−03	9	34	LBY224	0.82	3.49E−03	9	9
LBY224	0.72	3.03E−02	9	33	LBY224	0.77	9.72E−03	9	49
LBY224	0.74	1.43E−02	9	23	LBY224	0.93	6.93E−03	5	1
LBY224	0.83	3.89E−02	5	32	LBY224	0.72	1.09E−01	5	12
LBY224	0.70	1.19E−01	5	14	LBY224	0.88	2.01E−02	5	6
LBY224	0.77	7.12E−02	5	58	LBY224	0.84	3.57E−02	5	3
LBY224	0.71	1.15E−01	5	54	LBY224	0.72	1.09E−01	5	21
LBY224	0.80	5.69E−02	5	43	LBY224	0.84	3.48E−02	5	40
LBY224	0.91	1.27E−02	5	2	LBY224	0.77	7.40E−02	5	61
LBY224	0.72	1.05E−01	5	36	LBY224	0.84	3.62E−02	5	11
LBY224	0.84	3.82E−02	5	13	LBY224	0.77	7.08E−02	5	4
LBY224	0.75	8.35E−02	5	10	LBY224	0.83	2.65E−03	6	53
LBY225	0.72	1.96E−02	7	53	LBY225	0.79	1.17E−02	7	44
LBY225	0.80	2.88E−03	3	31	LBY225	0.78	4.51E−03	3	53
LBY225	0.89	5.46E−04	4	62	LBY225	0.77	2.49E−02	4	15
LBY225	0.81	4.33E−03	4	24	LBY225	0.72	6.72E−02	4	8
LBY225	0.82	4.01E−03	4	26	LBY225	0.73	1.70E−02	4	57
LBY225	0.78	7.51E−03	4	25	LBY225	0.72	1.99E−02	4	51
LBY225	0.78	6.53E−02	5	3	LBY225	0.79	6.36E−02	5	54
LBY225	0.86	2.84E−02	5	22	LBY225	0.76	8.01E−02	5	5
LBY225	0.82	4.68E−02	5	50	LBY225	0.92	8.98E−03	5	19
LBY225	0.83	1.60E−03	8	62	LBY225	0.75	7.43E−03	8	26
LBY225	0.72	1.23E−02	8	25	LBY225	0.71	1.52E−02	8	20
LBY227	0.71	4.85E−02	2	50	LBY227	0.84	1.38E−03	3	3
LBY227	0.76	7.06E−03	3	54	LBY227	0.70	1.63E−02	3	5
LBY227	0.78	8.25E−03	1	46	LBY227	0.81	4.76E−03	1	48
LBY227	0.80	5.58E−03	9	55	LBY227	0.96	4.82E−05	9	50
LBY227	0.74	9.25E−02	5	3	LBY227	0.75	8.41E−02	5	54
LBY227	0.81	5.23E−02	5	22	LBY227	0.71	2.17E−02	6	55
LBY227	0.92	1.09E−03	6	50	LBY227	0.71	1.34E−02	8	32
LBY227	0.88	2.96E−04	8	3	LBY227	0.84	1.12E−03	8	54
LBY227	0.72	1.17E−02	8	22	LBY227	0.83	1.60E−03	8	5
LBY227	0.74	9.40E−03	8	60	LBY228	0.71	1.53E−02	3	5
LBY228	0.83	1.10E−02	4	50	LBY228	0.75	1.26E−02	9	46
LBY230	0.79	6.04E−03	2	31	LBY230	0.75	2.11E−02	7	44
LBY230	0.75	8.50E−03	3	57	LBY230	0.91	2.31E−04	1	46
LBY230	0.72	1.92E−02	1	47	LBY230	0.71	2.04E−02	1	20
LBY230	0.77	8.94E−03	1	45	LBY230	0.78	7.98E−03	4	28
LBY230	0.76	1.09E−02	4	62	LBY230	0.72	1.83E−02	4	24
LBY230	0.72	4.36E−02	4	16	LBY230	0.79	6.28E−03	4	26
LBY230	0.71	2.07E−02	4	49	LBY230	0.73	1.57E−02	4	51
LBY230	0.73	1.03E−01	5	53	LBY230	0.74	9.19E−02	5	33
LBY230	0.82	4.60E−02	5	7	LBY230	0.72	1.08E−01	5	60
LBY230	0.80	5.76E−02	5	41	LBY230	0.83	4.22E−02	5	42
LBY230	0.73	1.65E−02	6	32	LBY230	0.76	1.01E−02	6	58
LBY230	0.75	1.21E−02	6	36	LBY231	0.87	1.20E−03	7	19
LBY231	0.73	1.13E−02	3	29	LBY231	0.78	1.35E−02	3	50
LBY231	0.77	1.42E−02	1	11	LBY231	0.83	2.95E−03	9	61
LBY231	0.77	9.13E−03	9	7	LBY231	0.79	6.21E−02	5	62
LBY231	0.74	9.49E−02	5	15	LBY231	0.98	6.52E−04	5	24
LBY231	0.81	5.18E−02	5	47	LBY231	0.79	6.02E−02	5	8
LBY231	0.78	6.82E−02	5	29	LBY231	0.77	7.36E−02	5	18
LBY231	0.90	1.35E−02	5	25	LBY231	0.75	8.43E−02	5	17
LBY231	0.90	1.39E−02	5	52	LBY231	0.92	4.28E−04	6	44
LBY231	0.75	8.36E−03	8	24	LBY231	0.71	1.45E−02	8	25
LGN1	0.73	1.64E−02	7	40	LGN1	0.78	7.33E−03	7	2
LGN1	0.82	7.07E−03	7	11	LGN1	0.70	2.33E−02	7	10
LGN1	0.72	1.90E−02	1	2	LGN1	0.83	5.45E−03	1	11
LGN1	0.72	1.89E−02	1	13	LGN1	0.82	3.70E−03	1	10
LGN1	0.80	5.93E−03	4	37	LGN1	0.77	8.63E−03	4	54
LGN1	0.80	5.20E−03	4	22	LGN1	0.86	1.59E−03	4	5
LGN1	0.80	5.26E−03	4	60	LGN1	0.71	4.70E−02	4	50
LGN1	0.75	8.63E−02	5	28	LGN1	0.82	4.40E−02	5	62
LGN1	0.87	2.57E−02	5	15	LGN1	0.83	4.12E−02	5	24
LGN1	0.87	2.60E−02	5	16	LGN1	0.76	7.94E−02	5	8
LGN1	0.76	7.64E−02	5	56	LGN1	0.91	1.13E−02	5	29
LGN1	0.76	7.73E−02	5	26	LGN1	0.81	4.85E−02	5	18
LGN1	0.74	9.17E−02	5	25	LGN1	0.75	8.79E−02	5	17
LGN1	0.75	8.86E−02	5	52	LGN1	0.76	7.83E−02	5	23
LGN1	0.85	1.44E−02	6	8	LGN1	0.77	1.46E−02	6	44

Table 230. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 222. “Exp. Set”—Expression set specified in Table 219. “R”=Pearson correlation coefficient; “P”=p value.

TABLE 231
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under low N conditions across
wheat accessions
				Corr.					Corr.
Gene Name	R	P value	Exp. set	Set ID	Gene Name	R	P value	Exp. set	Set ID
LBY214	0.73	1.12E−02	2	5	LBY214	0.72	2.99E−02	2	50
LBY214	0.75	5.45E−02	3	19	LBY214	0.70	2.32E−02	5	34
LBY214	0.72	1.32E−02	8	43	LBY214	0.81	2.45E−03	8	7
LBY214	0.77	8.48E−03	7	55	LBY214	0.72	1.07E−01	4	1
LBY214	0.79	6.03E−02	4	22	LBY214	0.74	9.32E−02	4	50
LBY214	0.79	5.96E−02	4	23	LBY214	0.76	6.33E−03	1	22
LBY214	0.76	6.78E−03	1	7	LBY215	0.75	7.41E−03	5	22
LBY215	0.71	1.54E−02	8	61	LBY215	0.73	1.75E−02	7	43
LBY215	0.85	3.35E−02	4	30	LBY215	0.71	1.11E−01	4	57
LBY215	0.74	9.00E−02	4	55	LBY215	0.70	1.21E−01	4	39
LBY215	0.71	3.14E−02	1	18	LBY216	0.81	2.79E−02	3	32
LBY216	0.72	6.81E−02	3	58	LBY216	0.76	4.76E−02	3	3
LBY216	0.70	7.69E−02	3	10	LBY216	0.72	1.91E−02	7	48
LBY216	0.81	1.59E−02	7	52	LBY216	0.70	1.20E−01	4	55
LBY216	0.82	2.01E−03	6	46	LBY216	0.73	1.07E−02	6	37
LBY216	0.75	7.38E−03	6	47	LBY216	0.75	7.61E−03	6	31
LBY216	0.74	8.59E−03	6	42	LBY216	0.74	9.35E−03	6	51
LBY217	0.78	3.69E−02	3	24	LBY217	0.94	1.58E−03	3	31
LBY217	0.72	6.83E−02	3	53	LBY217	0.80	3.24E−02	3	45
LBY217	0.82	2.48E−02	3	41	LBY217	0.78	3.98E−02	3	42
LBY217	0.72	6.99E−02	3	49	LBY217	0.76	7.15E−03	5	47
LBY217	0.70	2.32E−02	7	62	LBY217	0.76	1.09E−02	7	26
LBY217	0.71	1.38E−02	6	24	LBY217	0.72	1.17E−02	6	75
LBY218	0.74	9.74E−03	2	14	LBY218	0.72	1.16E−02	2	54
LBY218	0.76	1.64E−02	2	50	LBY218	0.92	7.40E−05	2	23
LBY218	0.75	8.22E−03	8	57	LBY218	0.90	1.54E−04	8	39
LBY218	0.71	1.16E−01	4	12	LBY218	0.92	1.05E−02	4	14
LBY218	0.78	6.54E−02	4	54	LBY218	0.84	3.85E−02	4	22
LBY218	0.71	1.16E−01	4	21	LBY218	0.74	9.53E−02	4	7
LBY218	0.72	1.04E−01	4	5	LBY218	0.82	4.73E−02	4	23
LBY218	0.81	2.56E−03	1	14	LBY2I8	0.77	5.67E−03	1	54
LBY218	0.70	1.63E−02	6	54	LBY218	0.89	1.41E−03	6	50
LBY219	0.77	5.37E−03	2	62	LBY219	0.74	8.97E−03	2	24
LBY219	0.72	1.33E−02	2	6	LBY219	0.75	7.98E−03	2	45
LBY219	0.84	1.13E−03	2	41	LBY219	0.84	1.11E−03	2	42
LBY219	0.71	1.35E−02	2	49	LBY219	0.74	8.75E−03	2	51
LBY219	0.70	7.86E−02	3	47	LBY219	0.88	9.63E−03	3	57
LBY219	0.70	7.97E−02	3	49	LBY219	0.80	3.05E−02	3	19
LBY219	0.74	5.97E−02	3	51	LBY219	0.84	1.14E−03	8	19
LBY219	0.89	1.68E−02	4	55	LBY219	0.75	7.56E−03	1	14
LBY219	0.73	1.07E−02	1	2	LBY219	0.74	9.63E−03	1	36
LBY219	0.74	9.16E−03	6	8	LBY219	0.82	1.98E−03	6	26
LBY219	0.73	1.09E−02	6	2	LBY220	0.76	1.86E−02	2	15
LBY220	0.71	1.43E−02	2	48	LBY220	0.72	1.17E−02	2	57
LBY220	0.75	1.96E−02	2	18	LBY220	0.75	7.50E−03	2	9
LBY220	0.79	1.15E−02	2	17	LBY220	0.89	2.26E−04	2	39
LBY220	0.73	9.85E−02	3	16	LBY220	0.75	8.50E−02	3	18
LBY220	0.71	1.50E−02	5	62	LBY220	0.80	2.87E−03	5	32
LBY220	0.77	5.72E−03	5	58	LBY220	0.78	4.95E−03	5	3
LBY220	0.75	7.98E−03	5	40	LBY220	0.77	5.42E−03	5	9
LBY220	0.70	1.61E−02	5	2	LBY220	0.77	5.94E−03	5	13
LBY220	0.74	8.98E−03	5	4	LBY220	0.73	1.12E−02	5	10
LBY220	0.74	2.40E−02	8	16	LBY220	0.71	1.41E−02	8	39
LBY220	0.75	3.16E−02	7	16	LBY220	0.78	8.16E−03	7	48
LBY220	0.78	8.05E−03	7	57	LBY220	0.87	1.23E−03	7	39
LBY220	0.76	8.01E−02	4	12	LBY220	0.76	8.01E−02	4	21
LBY220	0.79	6.29E−02	4	9	LBY220	0.85	3.03E−02	4	33
LBY220	0.73	9.78E−02	4	36	LBY220	0.76	6.54E−03	1	3
LBY220	0.72	1.33E−02	1	38	LBY220	0.72	1.28E−02	1	36
LBY220	0.71	3.15E−02	6	52	LBY221	0.76	1.66E−02	2	50
LBY221	0.73	1.00E−01	3	16	LBY221	0.74	9.31E−02	3	52
LBY221	0.77	1.60E−02	5	15	LBY221	0.79	1.10E−02	5	16
LBY221	0.84	3.55E−02	4	12	LBY221	0.74	9.17E−02	4	31
LBY221	0.92	9.15E−03	4	53	LBY221	0.84	3.55E−02	4	21
LBY221	0.83	4.17E−02	4	7	LBY221	0.74	9.60E−02	4	41
LBY221	0.74	8.93E−02	4	42	LBY221	0.74	8.78E−03	1	7
LBY222	0.75	8.45E−03	2	14	LBY222	0.70	1.65E−02	2	54
LBY222	0.77	5.36E−03	2	22	LBY222	0.80	5.59E−02	3	50
LBY222	0.70	7.85E−02	3	23	LBY222	0.71	1.13E−01	4	37
LBY222	0.83	4.29E−02	4	54	LBY222	0.97	9.79E−04	4	22
LBY222	0.83	4.28E−02	4	5	LBY222	0.76	7.99E−02	4	50
LBY222	0.93	6.33E−03	4	23	LBY222	0.85	3.82E−03	1	15
LBY222	0.72	2.93E−02	1	18	LBY222	0.84	4.94E−03	1	17
LBY222	0.83	6.02E−03	1	50	LBY222	0.82	6.45E−03	6	33
LBY222	0.70	1.57E−02	6	45	LBY222	0.80	2.81E−03	6	41
LBY222	0.84	1.34E−03	6	42	LBY222	0.78	4.98E−03	6	49
LBY222	0.71	1.47E−02	6	51	LBY224	0.87	1.05E−02	3	46
LBY224	0.77	4.40E−02	3	37	LBY224	0.75	5.31E−02	3	74
LBY224	0.93	2.37E−03	3	47	LBY224	0.94	1.71E−03	3	57
LBY224	0.84	1.73E−02	3	53	LBY224	0.83	2.16E−02	3	25
LBY224	0.72	6.85E−02	3	60	LBY224	0.73	6.25E−02	3	42
LBY224	0.85	1.47E−02	3	49	LBY224	0.91	4.12E−03	3	51
LBY224	0.81	2.68E−03	8	28	LBY224	0.75	7.86E−03	8	6
LBY224	0.74	9.32E−03	8	13	LBY224	0.71	1.52E−02	8	4
LBY224	0.84	1.17E−03	8	10	LBY224	0.71	2.27E−02	7	57
LBY224	0.81	4.82E−02	4	14	LBY224	0.86	2.79E−02	4	57
LBY224	0.73	9.62E−02	4	36	LBY224	0.77	7.54E−02	4	59
LBY224	0.74	9.92E−03	1	14	LBY224	0.72	1.25E−02	1	36
LBY225	0.76	6.91E−03	2	28	LBY225	0.72	1.32E−02	2	8
LBY225	0.74	8.83E−03	2	45	LBY225	0.77	5.15E−03	2	41
LBY225	0.73	6.37E−02	3	45	LBY225	0.82	1.81E−03	5	56
LBY225	0.74	8.75E−03	5	27	LBY225	0.73	1.09E−02	5	10
LBY225	0.81	4.65E−03	7	32	LBY225	0.82	3.55E−03	7	12
LBY225	0.77	9.29E−03	7	3	LBY225	0.85	4.10E−03	7	34
LBY225	0.82	3.55E−03	7	21	LBY225	0.93	7.80E−04	7	33
LBY225	0.82	3.62E−03	7	2	LBY225	0.74	1.45E−02	7	61
LBY225	0.85	1.77E−03	7	11	LBY225	0.74	1.40E−02	7	13
LBY225	0.75	1.29E−02	7	4	LBY225	0.70	2.38E−02	7	10
LBY225	0.78	6.57E−02	4	14	LBY225	0.78	6.60E−02	4	54
LBY225	0.97	1.16E−03	4	22	LBY225	0.73	9.98E−02	4	50
LBY225	0.87	2.28E−02	4	23	LBY225	0.82	2.08E−03	6	42
LBY227	0.72	2.74E−02	2	50	LBY227	0.77	5.57E−03	2	23
LBY227	0.77	4.38E−02	3	14	LBY227	0.78	3.93E−02	3	54
LBY227	0.72	7.04E−02	3	55	LBY227	0.76	6.91E−03	5	39
LBY227	0.72	1.07E−01	4	57	LBY227	0.77	7.06E−02	4	50
LBY227	0.79	5.99E−02	4	23	LBY227	0.79	3.97E−03	1	54
LBY227	0.74	9.50E−03	1	22	LBY227	0.77	5.20E−03	1	5
LBY230	0.86	1.27E−02	3	1	LBY230	0.72	6.83E−02	3	32
LBY230	0.77	4.32E−02	3	3	LBY230	0.70	1.54E−02	8	32
LBY230	0.72	1.22E−02	8	58	LBY230	0.72	1.21E−02	8	3
LBY230	0.71	1.39E−02	8	40	LBY230	0.77	5.39E−03	8	2
LBY230	0.84	1.19E−03	8	11	LBY230	0.87	5.05E−04	8	13
LBY230	0.81	2.52E−03	8	4	LBY230	0.87	4.87E−04	8	10
LBY230	0.85	7.36E−03	7	15	LBY230	0.71	5.03E−02	7	16
LBY230	0.83	1.02E−02	7	18	LBY230	0.83	1.15E−02	7	17
LBY230	0.89	6.17E−04	7	60	LBY230	0.70	3.54E−02	1	50
LBY230	0.74	8.60E−03	1	23	LBY231	0.72	1.26E−02	2	39
LBY231	0.72	1.25E−02	5	28	LBY231	0.86	7.90E−04	5	10
LBY231	0.78	4.79E−03	8	27	LBY231	0.81	5.10E−02	4	9
LBY231	0.95	3.52E−03	4	36	LBY231	0.70	1.19E−01	4	49
LBY231	0.72	1.31E−02	1	32	LBY231	0.72	1.32E−02	1	58
LBY231	0.78	4.54E−03	1	3	LBY231	0.80	3.00E−03	1	40
LBY231	0.85	8.93E−04	1	2	LBY231	0.86	7.08E−04	1	11
LBY231	0.92	5.09E−05	1	13	LBY231	0.89	2.60E−04	1	4
LBY231	0.91	1.13E−04	1	10	LBY231	0.83	1.47E−03	6	12
LBY231	0.83	1.47E−03	6	21	LBY231	0.86	7.26E−04	6	43
LBY231	0.82	7.06E−03	6	33	LBY231	0.78	4.28E−03	6	2
LBY231	0.82	1.94E−03	6	61	LBY231	0.77	5.29E−03	6	36
LBY231	0.77	5.60E−03	6	11	LBY231	0.72	1.33E−02	6	13
LBY231	0.74	8.92E−03	6	4	LGN1	0.77	4.50E−02	3	39
LGN1	0.82	1.80E−03	5	48	LGN1	0.87	4.53E−04	5	57
LGN1	0.74	9.56E−03	5	9	LGN1	0.88	3.77E−04	5	39
LGN1	0.74	9.20E−03	8	57	LGN1	0.80	2.86E−03	8	9
LGN1	0.72	1.22E−02	8	44	LGN1	0.75	1.21E−02	7	48
LGN1	0.79	6.71E−03	7	57	LGN1	0.90	3.51E−04	7	39
LGN1	0.95	3.79E−03	4	30	LGN1	0.84	3.81E−02	4	6
LGN1	0.73	9.62E−02	4	58	LGN1	0.89	1.64E−02	4	22
LGN1	0.77	7.10E−02	4	43	LGN1	0.73	1.03E−01	4	2
LGN1	0.79	5.96E−02	4	61	LGN1	0.76	8.00E−02	4	23
LGN1	0.75	7.80E−03	1	58

Table 231. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 222. “Exp. Set”—Expression set specified in Table 220. “R”=Pearson correlation coefficient; “P”=p value

TABLE 232
Correlation between the expression level of selected genes of some embodiments of the
invention in various tissues and the phenotypic performance under low N vs. normal (ratio)
conditions across wheat accessions
				Corr.					Corr.
Gene Name	R	P value	Exp. set	Set ID	Gene Name	R	P value	Exp. set	Set ID
LBY214	0.71	1.37E−02	2	9	LBY214	0.70	1.55E−02	2	2
LBY214	0.80	3.13E−03	2	21	LBY214	0.95	8.68E−04	3	9
LBY214	0.71	7.53E−02	3	4	LBY214	0.70	7.98E−02	3	13
LBY214	0.76	4.82E−02	3	8	LBY214	0.73	6.16E−02	3	6
LBY214	0.73	1.73E−02	7	12	LBY214	0.77	1.53E−02	6	14
LBY215	0.91	7.19E−04	2	14	LBY215	0.73	6.16E−02	3	11
LBY215	0.80	3.21E−02	3	29	LBY215	0.82	2.52E−02	3	12
LBY215	0.73	6.37E−02	3	23	LBY215	0.80	3.33E−03	8	29
LBY215	0.88	2.06E−02	4	11	LBY215	0.90	1.34E−02	4	29
LBY215	0.79	6.24E−02	4	12	LBY215	0.70	1.20E−01	4	23
LBY216	0.76	6.34E−03	2	29	LBY216	0.91	1.22E−02	3	7
LBY216	0.84	1.82E−02	3	8	LBY216	0.84	1.75E−02	3	6
LBY216	0.72	1.04E−01	4	11	LBY216	0.80	5.48E−02	4	29
LBY216	0.76	7.67E−02	4	12	LBY216	0.74	9.51E−02	4	73
LBY216	0.72	1.34E−02	1	6	LBY216	0.75	8.50E−03	6	20
LBY217	0.81	5.25E−02	3	7	LBY217	0.81	2.51E−03	6	1
LBY218	0.72	1.23E−02	2	24	LBY218	0.80	9.86E−03	2	14
LBY218	0.78	6.89E−02	3	14	LBY218	0.94	5.37E−03	3	18
LBY218	0.76	1.08E−02	7	12	LBY218	0.77	7.56E−02	4	24
LBY218	0.77	7.26E−02	4	14	LBY218	0.81	4.85E−03	1	15
LBY218	0.87	2.13E−03	1	14	LBY218	0.84	4.77E−03	6	14
LBY218	0.76	7.22E−03	6	19	LBY219	0.74	5.78E−02	3	13
LBY219	0.91	2.87E−04	5	18	LBY219	0.76	7.07E−03	8	9
LBY219	0.94	5.86E−03	4	12	LBY219	0.71	1.15E−01	4	28
LBY219	0.71	1.15E−01	4	22	LBY219	0.95	3.47E−03	4	23
LBY220	0.72	1.22E−02	2	8	LBY220	0.85	1.55E−02	3	13
LBY220	0.78	4.01E−02	3	8	LBY220	0.72	6.67E−02	3	6
LBY220	0.73	1.09E−02	8	9	LBY220	0.71	2.08E−02	7	9
LBY220	0.82	4.68E−02	4	24	LBY220	0.87	2.55E−02	4	19
LBY220	0.76	6.81E−03	1	6	LBY221	0.72	1.24E−02	2	24
LBY221	0.73	1.14E−02	2	19	LBY221	0.84	1.87E−02	3	9
LBY221	0.74	5.57E−02	3	17	LBY221	0.75	5.41E−02	3	2
LBY221	0.85	1.46E−02	3	21	LBY221	0.81	1.47E−02	6	5
LBY222	0.79	3.89E−03	2	11	LBY222	0.79	3.83E−03	2	24
LBY222	0.75	1.31E−02	2	15	LBY222	0.85	9.33E−04	2	12
LBY222	0.77	4.12E−02	3	26	LBY222	0.82	3.59E−03	7	24
LBY222	0.89	3.38E−03	7	14	LBY222	0.92	1.26E−03	6	5
LBY224	0.95	1.30E−03	3	20	LBY224	0.84	1.07E−03	5	10
LBY224	0.78	4.87E−03	5	2	LBY224	0.73	1.11E−02	8	8
LBY224	0.82	1.23E−02	7	14	LBY224	0.85	3.28E−02	4	11
LBY224	0.82	4.64E−02	4	29	LBY224	0.87	2.52E−02	4	24
LBY224	0.74	9.14E−02	4	12	LBY224	0.89	1.71E−02	4	14
LBY224	0.77	7.51E−02	4	26	LBY224	0.71	1.44E−02	1	11
LBY224	0.81	7.47E−03	1	14	LBY225	0.73	1.08E−02	2	19
LBY225	0.71	7.36E−02	3	26	LBY225	0.72	1.23E−02	5	10
LBY225	0.74	2.21E−02	7	7	LBY225	0.81	5.33E−02	4	5
LBY225	0.73	1.02E−02	1	23	LBY225	0.90	3.91E−04	6	3
LBY225	0.72	1.95E−02	6	7	LBY225	0.74	8.76E−03	6	8
LBY227	0.76	6.16E−03	2	24	LBY227	0.80	2.87E−03	2	12
LBY227	0.83	4.14E−02	3	15	LBY227	0.83	3.06E−03	7	12
LBY227	0.88	2.14E−02	4	24	LBY227	0.75	8.92E−02	4	12
LBY227	0.76	1.00E−02	3	15	LBY228	0.84	1.33E−03	8	13
LBY228	0.76	6.12E−03	6	4	LBY230	0.91	1.22E−02	3	7
LBY230	0.84	1.81E−02	3	8	LBY230	0.91	4.56E−03	3	6
LBY230	0.70	1.57E−02	5	13	LBY230	0.75	1.19E−02	7	27
LBY230	0.76	7.81E−02	4	14	LBY231	0.79	1.93E−02	2	5
LBY231	0.84	2.43E−03	2	3	LBY231	0.87	1.05E−02	3	13
LBY231	0.90	6.48E−03	3	8	LBY231	0.83	2.14E−02	3	6
LBY231	0.75	7.68E−03	5	8	LBY231	0.70	1.55E−02	5	6
LBY231	0.76	6.93E−03	8	8	LBY231	0.70	1.62E−02	8	21
LBY231	0.76	6.13E−03	8	6	LBY231	0.78	6.85E−02	4	11
LBY231	0.77	7.28E−02	4	29	LGN1	0.76	7.09E−03	2	8
LGN1	0.74	5.49E−02	3	29	LGN1	0.75	5.32E−02	3	12
LGN1	0.84	1.26E−03	5	8	LGN1	0.77	8.93E−03	7	8
LGN1	0.86	2.74E−02	4	5	LGN1	0.93	8.06E−03	4	3
LGN1	0.78	6.88E−02	4	26	LGN1	0.76	6.71E−03	6	13

Table 232. Provided are the correlations (R) between the genes expression levels in various tissues and the phenotypic performance. “Corr. ID”—correlation set ID according to the correlated parameters specified in Table 223. “Exp. Set”—Expression set specified in Table 221. “R”=Pearson correlation coefficient; “P”=p value.

Example 25

Gene Cloning and Generation of Binary Vectors for Plant Expression

To validate their role in improving yield, selected genes were over-expressed in plants, as follows.

Cloning Strategy

Selected genes from those presented in Examples 1-24 hereinabove were cloned into binary vectors for the generation of transgenic plants. For cloning, the full-length open reading frames (ORFs) were identified. EST clusters and in some cases mRNA sequences were analyzed to identify the entire open reading frame by comparing the results of several translation algorithms to known proteins from other plant species.

In order to clone the full-length cDNAs, reverse transcription (RT) followed by polymerase chain reaction (PCR; RT-PCR) was performed on total RNA extracted from leaves, roots or other plant tissues, growing under normal/limiting or stress conditions. Total RNA extraction, production of cDNA and PCR amplification was performed using standard protocols described elsewhere (Sambrook J., E. F. Fritsch, and T. Maniatis. 1989. Molecular Cloning. A Laboratory Manual, 2nd Ed. Cold Spring Harbor Laboratory Press, New York) which are well known to those skilled in the art. PCR products were purified using PCR purification kit (Qiagen).

Usually, 2 sets of primers were prepared for the amplification of each gene, via nested PCR (if required). Both sets of primers were used for amplification on a cDNA. In case no product was obtained, a nested PCR reaction was performed. Nested PCR was performed by amplification of the gene using external primers and then using the produced PCR product as a template for a second PCR reaction, where the internal set of primers were used. Alternatively, one or two of the internal primers were used for gene amplification, both in the first and the second PCR reactions (meaning only 2-3 primers are designed for a gene). To facilitate further cloning of the cDNAs, an 8-12 base pairs (bp) extension was added to the 5′ of each internal primer. The primer extension includes an endonuclease restriction site. The restriction sites were selected using two parameters: (a) the restriction site does not exist in the cDNA sequence; and (b) the restriction sites in the forward and reverse primers were designed such that the digested cDNA was inserted in the sense direction into the binary vector utilized for transformation.

PCR products were digested with the restriction endonucleases (New England BioLabs Inc) according to the sites designed in the primers. Each digested/undigested PCR product was inserted into a high copy vector pUC19 (New England BioLabs Inc], or into plasmids originating from this vector. In some cases the undigested PCR product was inserted into pCR-Blunt II-TOPO (Invitrogen) or into pJET1.2 (CloneJET PCR Cloning Kit, Thermo Scientific) or directly into the binary vector. The digested/undigested products and the linearized plasmid vector were ligated using T4 DNA ligase enzyme (Roche, Switzerland or other manufacturers). In cases where pCR-Blunt II-TOPO is used no T4 ligase is needed.

Sequencing of the inserted genes was performed, using the ABI 377 sequencer (Applied Biosystems). In some cases, after confirming the sequences of the cloned genes, the cloned cDNA was introduced into a modified pGI binary vector containing the At6669 promoter (e.g., pQFNc or pQsFN) and the NOS terminator (SEQ ID NO: 10665) via digestion with appropriate restriction endonucleases.

Several DNA sequences of the selected genes were synthesized by GeneArt (Life Technologies. Grand Island, N.Y., USA). Synthetic DNA was designed in silico. Suitable restriction enzymes sites were added to the cloned sequences at the 5′ end and at the 3′ end to enable later cloning into the desired binary vector.

Binary vectors—The pPI plasmid vector was constructed by inserting a synthetic poly-(A) signal sequence, originating from pGL3 basic plasmid vector (Promega, GenBank Accession No. U47295: nucleotides 4658-4811) into the HindIII restriction site of the binary vector pBI101.3 (Clontech. GenBank Accession No. U12640). pGI is similar to pPI, but the original gene in the backbone is GUS-Intron and not GUS.

The modified pGI vector (e.g., pQFN, pQFNc, pQYN_6669, pQNa_RP, pQFYN, pQXNc, pQ6sVN (FIG. 11) or pQsFN (FIG. 12)) is a modified version of the pGI vector in which the cassette is inverted between the left and right borders so the gene and its corresponding promoter are close to the right border and the NPTII gene is close to the left border.

At6669, the new Arabidopsis thaliana promoter sequence (SEQ ID NO: 10654) was inserted in the modified pGI binary vector, upstream to the cloned genes, followed by DNA ligation and binary plasmid extraction from positive E. coli colonies, as described above. Colonies were analyzed by PCR using the primers covering the insert which were designed to span the introduced promoter and gene. Positive plasmids were identified, isolated and sequenced.

In case of Brachypodium transformation, after confirming the sequences of the cloned genes, the cloned cDNAs were introduced into pQ6sVN (FIG. 11) containing 35S promoter (SEQ ID NO: 10666) and the NOS terminator (SEQ ID NO: 10665) via digestion with appropriate restriction endonucleases. The genes were cloned downstream to the 35S promoter and upstream to the NOS terminator. In the pQ6sVN vector the Hygromycin resistance gene cassette and the Bar_GA resistance gene cassette replaced the NPTII resistance gene cassette. pQ6sVN contains the 35S promoter (SEQ ID NO: 10666). Bar_GA resistance gene (SEQ ID NO: 11335) is an optimized sequence of the BAR gene for expression in Brachypodium plants (ordered from GeneArt).

Additionally or alternatively. Brachypodium transformation was performed using the pEBbVNi vector. pEBbVNi (FIG. 9A) is a modified version of pJJ2LB in which the Hygromycin resistance gene was replaced with the BAR gene which confers resistance to the BASTA herbicide [BAR gene coding sequence is provided in GenBank Accession No. JQ293091.1 (SEQ ID NO: 10667): further description is provided in Akama K. et al. “Efficient Agrobacterium-mediated transformation of Arabidopsis thaliana using the bar gene as selectable marker”, Plant Cell Rep. 1995, 14(7):450-4; Christiansen P, et al. “A rapid and efficient transformation protocol for the grass Brachypodium distachyon ”, Plant Cell Rep. 2005 Mar., 23(10-11):751-8. Epub 2004 Oct 19; and Pacurar DI. et al. “A high-throughput Agrobacterium-mediated transformation system for the grass model species Brachypodium distachyon L”. Transgenic Res. 2008 17(5):965-75; each of which is fully incorporated herein by reference in its entirety]. The pEBbVNi construct contains the 35S promoter (SEQ ID NO: 10666). pJJ2LB is a modified version of pCambia0305.2 (Cambia).

In case genomic DNA was cloned, the genes were amplified by direct PCR on genomic DNA extracted from leaf tissue using the DNAeasy kit (Qiagen Cat. No. 69104).

Selected genes cloned by the present inventors are provided in Table 233 below.

TABLE 233
Cloned genes
Gene			Primers used	Polynucleotide	Polypeptide
Name	High copy plasmid	Organism	SEQ ID NOs:	SEQ ID NO:	SEQ ID NO:
LBY100	pMA-T_LBY100_GA			388	634
LBY102	pMA-T_LBY102_GA			389	635
LBY103	pQFNc_LBY103	MAIZE Zea mays L.	11069, 10874,	390	636
			11006, 10847
LBY104	pUC19g_LBY104	MAIZE Zea mays L.	11093, 11191,	391	637
			11105, 11166
LBY105	pQFNc_LBY105	MAIZE Zea mays L.	11005, 10887,	392	638
			11119, 10808
LBY106_H3	pQFNc_LBY106_H3	MAIZE Zea mays L.	11003, 11160,	505	884
			11028, 11160
LBY107	pQFNc_LBY107	MAIZE Zea mays L.	11158, 10766,	393	640
			11158, 10814
LBY108	pQFNc_LBY108	MAIZE Zea mays L.	10774, 10707,	394	838
			10756, 10699
LBY109	pUC19c_LBY109	MAIZE Zea mays L.	11088, 10910,	395	642
			11019, 10859
LBY110	pQFNc_LBY110	MAIZE Zea mays L.	11120, 10788,	396	643
			11038, 10883
LBY111	pMA-RQ_LBY111_GA			397	644
LBY112	pQFNc_LBY112	MAIZE Zea mays L.	10949, 10935,	398	645
			10948, 10928
LBY113	TopoB_LBY113	MAIZE Zea mays L.	11091, 11162,	399	646
			11130, 11182
LBY114	pQFNc_LBY114	MAIZE Zea mays L.	10886, 10692,	400	647
			10899, 10693
LBY115	TopoB_LBY115	MAIZE Zea mays L.	11154, 10763,	401	648
			11154, 10763
LBY116	pUC19c_LBY116	MAIZE Zea mays L.	10991, 10809,	402	839
			11012, 10792
LBY117	pUC19g_LBY117	MAIZE Zea mays L.	10947, 10786,	403	650
			10946, 10902
LBY118	pQFNc_LBY118	MAIZE Zea mays L.	11017, 10755,	404	651
			11104, 10888
LBY119_H1	pQFNc_LBY119_H1		10671, 11197,	506	885
			10671, 11197
LBY120	pQFNc_LBY120	MAIZE Zea mays L.	11144, 10794,	405	840
			10974, 10912
LBY121	pQFNc_LBY121	MAIZE Zea mays L.	10959, 11185,	406	841
			10959, 11185
LBY122	pQFNc_LBY122	MAIZE Zea mays L.	11108, 10782,	407	842
			11110, 11216
LBY123	pQFNc_LBY123	MAIZE Zea mays L.	11106, 10870,	408	656
			11034, 10800
LBY125	pMA_LBY125_GA			409	657
LBY126	pQFNc_LBY126	MEDICAGO Medicaeo truncatula		410	658
LBY127	pQFNc_LBY127	MEDICAGO Medicago truncatula	11095, 11200,	411	843
			11139, 11193
LBY128	pMA-T_LBY128_GA			412	660
LBY129	pMA-RQ_LBY129_GA			413	661
LBY132	pMA-RQ_LBY132_GA			414	663
LBY133	pMA-T_LBY133_GA			415	664
LBY134	pMA-T_LBY134_GA			416	665
LBY135	pQFNc_LBY135	POTATO Solanum tuberosum	11082, 10789,	417	666
			11116, 10798
LBY136	pUC19c_LBY136	POTATO Solanum tuberosum	10812, 10932,	418	844
			10749, 10937
LBY137	pQFNc_LBY137	POTATO Solanum tuberosum	10856, 10712,	419	845
			10856, 10712
LBY138	pUC19c_LBY138	RICE Oryza sativa L.	11092, 10922,	420	669
			11092, 10833
LBY139	TopoB_LBY139	RICE Oryza sativa L.	10728, 11204,	421	846
			10728, 11165
LBY14	pQsFN_LBY14	SORGHUM Sorghum bicolor	10744, 11210,	551	—
			10744, 11210
LBY140	pQFNc_LBY140	RICE Oryza sativa L.	10956, 10821,	422	671
			10958, 10841
LBY141	pMA-RQ_LBY141_GA			423	672
LBY142	pMA-RQ_LBY142_GA			424	673
LBY143	pQFNc_LBY143	RICE Oryza sativa L.	10943, 10781,	425	674
			10942, 10840
LBY144	pQFNc_LBY144	RICE Oryza sativa L.	11129, 10915,	426	847
			11129, 10915
LBY145	pQFNc_LBY145	RICE Oryza sativa L.	11018, 10863,	427	676
			11018, 10863
LBY146	pUC19c_LBY146	RICE Oryza sativa L.	10729, 10931,	428	848
			10729, 10931
LBY148	pMA-RQ_LBY148_GA			429	679
LBY149	pUC19c_LBY149	SORGHUM Sorghum bicolor	11146, 10923,	430	680
			11146, 10923
LBY15	pMA-RQ_LBY15_GA			261	—
LBY150	pQFNc_LBY150	SORGHUM Sorghum bicolor	11014, 10801,	431	681
			11109, 10884
LBY151	pUC19_LBY151	SORGHUM Sorghum bicolor	11015, 10907,	432	682
			11015, 10907
LBY152	pMA-RQ_LBY152_GA			433	683
LBY153	TopoB_LBY153	SORGHUM Sorghum bicolor	10963, 11171,	434	684
			10963, 11171
LBY154	pQFNc_LBY154	SORGHUM Sorghum bicolor	11145, 10865,	435	685
			10998, 10764
LBY155	pQFNc_LBY155	SORGHUM Sorghum bicolor	11048, 11168,	436	849
			11048, 11168
LBY156	pUC19c_LBY156	SORGHUM Sorghum bicolor	10784, 10722,	437	850
			10860, 10682
LBY157	pMA-RQ_LBY157_GA			438	688
LBY158	pQFNc_LBY158	SORGHUM Sorghum bicolor	10968, 10836,	439	851
			11041, 10817
LBY159	pQFNc_LBY159	SORGHUM Sorghum bicoior	11086, 10845,	440	690
			11103, 10843
LBY16	pUC19c_LBY16	ARABIDOPSIS Arabidopsis thalia	11076, 10739,	311	552
			11076, 10894
LBY160	TopoB_LBY160	SORGHUM Sorghum bicolor	11022, 10740,	441	691
			11151, 10754
LBY161	pMA_LBY161_GA			442	692
LBY162	pUC19g_LBY162	SORGHUM Sorghum bicolor	10966, 11159,	443	693
			11090, 11181
LBY163	pQFNc_LBY163	SORGHUM Sorghum bicoior	11011, 11180,	444	694
			10973, 11177
LBY164	pQFNc_LBY164	SORGHUM Sorghum bicolor	11078, 10815,	445	852
			11078, 10815
LBY165	pQFNc_LBY165	SORGHUM Sorghum bicolor	11140, 10677,	446	853
			11155, 10672
LBY166	pQFNc_LBY166	SORGHUM Sorghum bicolor	11125, 10878,	447	697
			11135, 10881
LBY167	pQFNc_LBY167	SORGHUM Sorghum bicolor	10675, 10708,	448	698
			10873, 10695
LBY17	pQFNc_LBY17	ARABIDOPSIS Arabidopsis thalia	10993, 10775,	312	553
			10982, 10743
LBY170	pMK-RQ_LBY170_GA			449	700
LBY171	pMK-RQ_LBY171_GA			450	701
LBY173	pQFNc_LBY173	SORGHUM Sorghum bicolor	10737, 10711,	451	702
			10891, 10716
LBY174	pUC19g_LBY174	SORGHUM Sorghum bicolor	10960, 11188,	452	703
			10952, 11196
LBY175	pQFNc_LBY175	SORGHUM Sorghum bicolor	10994, 10791,	453	704
			11150, 10918
LBY176	pMA-RQ_LBY176_GA			454	705
LBY177	pUC19g_LBY177	SORGHUM Sorghum bicolor	10941, 10877,	455	706
			10953, 10924
LBY178	pMK-RQ_LBY178_GA			456	707
LBY179	pQFNc_LBY179	SORGHUM Sorghum bicolor	11133, 10741,	457	708
			11133, 10895
LBY18	pMA-RQ_LBY18_GA			313	554
LBY180	TopoB_LBY180	SORGHUM Sorghum bicolor	10853, 10685,	458	854
			10919, 10718
LBY181	TopoB_LBY181	SORGHUM Sorghum bicolor	10730, 11199,	459	855
			10730, 11199
LBY182	pQFNc_LBY182	SORGHUM Sorghum bicolor	11064, 10686,	460	856
			11064, 10691
LBY183	pMA-RQ_LBY183_GA			461	712
LBY184	pQFNc_LBY184	SORGHUM Sorghum bicolor	10978, 10871,	462	713
			10976, 10835
LBY185	pQFNc_LBY185	SORGHUM Sorghum bicolor	11035, 10898,	463	857
			11100, 10868
LBY186	pQFNc_LBY186	SORGHUM Sorghum bicolor	11127, 10851,	464	715
			10986, 10772
LBY187	pUC19_LBY187	SORGHUM Sorghum bicolor	10736, 10734,	465	858
			10736, 10735
LBY188	pQFNc_LBY188	SORGHUM Sorghum bicolor	11148, 10760,	466	717
			10996, 10795
LBY190	pQFNc_LBY190	SORGHUM Sorghum bicolor	11023, 10778,	467	719
			11117, 10866
LBY191	pMA-RQ_LBY191_GA			468	720
LBY192	pQsFN_LBY192	SORGHUM Sorghum bicolor	10731, 11183,	469	859
			10727, 11205
LBY193	pQFNc_LBY193	SOYBEAN Glycine max	11004, 10769,	470	860
			11025, 10785
LBY194	pMA-RQ_LBY194_GA			471	723
LBY195	pQFNc_LBY195	SOYBEAN Glycine max	10925, 10717,	472	861
			10925, 10717
LBY196	pMA_LBY196_GA			473	725
LBY197	pUC19c_LBY197	SUNFLOWER Helianthus annuus	10689, 10938,	474	726
			10689, 10934
LBY199	pUC19g_LBY199	SUNFLOWER Helianthus annuus	11067, 11172,	475	862
			11067, 11174
LBY20	TopoB_LBY20	BARLEY Hordeum vulgare L.	11149, 11163,	314	817
			11063, 11173
LBY200	pQFNc_LBY200	SUNFLOWER Helianthus annuus	11045, 10779,	476	863
			11056, 10857
LBY201	TopoB_LBY201	SUNFLOWER Helianthus annuus	10981, 10669,	477	864
			11049, 10670
LBY202	pQFNc_LBY202	SUNFLOWER Helianthus annuus	11032, 10767,	478	865
			11032, 10767
LBY203	pQFNc_LBY203	SUNFLOWER Helianthus annuus	10725, 11178,	479	866
			10725, 11178
LBY204	pUC19c_LBY204	SUNFLOWER Helianthus annuus	10706, 10930,	480	732
			10688, 10936
LBY205	pQFNc_LBY205	SUNFLOWER Helianthus annuus	11083, 10897,	481	867
			11097, 10838
LBY206	pQFNc_LBY206	SUNFLOWER Helianthus annuus	11062, 11195,	482	868
			11047, 11176
LBY207	pQFNc_LBY207	SUNFLOWER Helianthus annuus	10987, 10816,	483	869
			11059, 10820
LBY208	pQFNc_LBY208	SUNFLOWER Helianthus annuus	11157, 10804,	484	736
			11157, 10804
LBY209	pUC19g_LBY209	SUNFLOWER Helianthus annuus	10969, 10964,	485	870
			11153, 10962
LBY21	pQFNc_LBY21	BARLEY Hordeum vulgare L.	11114, 10780,	315	557
			11053, 10810
LBY210	pQFNc_LBY210	SUNFLOWER Helianthus annuus	11123, 11192,	486	871
			11050, 11192
LBY211	pQFNc_LBY211	SUNFLOWER Helianthus annuus	10698, 11209,	487	872
			10700, 11208
LBY212	pQFNc_LBY212	TOMATO Lycopersicum ND	11111, 10751,	488	873
			11099, 10849
LBY213	pQFNc_LBY213	TOMATO Lycopersicum ND	11033, 10752,	489	874
			10967, 10837
LBY214	pQFNc_LBY214	WHEAT Triticum aestivum L.		490	742
LBY216	pQFNc_LBY216	WHEAT Triticum aestivum L.	10957, 10783,	491	875
			10951, 10892
LBY217	pQFNc_LBY217	WHEAT Triticum aestivum L.	11152, 11170,	492	876
			11079, 11167
LBY218	pQFNc_LBY218	WHEAT Triticum aestivum L.	10869, 10694,	493	877
			10862, 10696
LBY219_H9	pMA-			507	761
	RQ_LBY219_H9_GA
LBY22	pQFNc_LBY22	BARLEY Hordeum vulgare L.	10989, 10745,	316	558
			10984, 10876
LBY220	pMA-RQ_LBY220_GA			494	748
LBY221	pMA-RQ_LBY221_GA			495	749
LBY222	TopoB_LBY222	WHEAT Triticum aestivum L.	10970, 11161,	496	878
			10970, 11187
LBY224	TopoB_LBY224	WHEAT Triticum aestivum L.	10733, 10732,	497	751
			10726, 11206
LBY225	pUC19c_LBY225	WHEAT Triticum aestivum L.	10747, 10724,	498	879
			10747, 10724
LBY227	pQFNc_LBY227	WHEAT Triticum aestivum L.	11112, 10855,	499	753
			10990, 10822
LBY228	pUC19c_LBY228	WHEAT Triticum aestivum L.	11115, 10858,	500	880
			11046, 10819
LBY23	pQFNc_LBY23	BARLEY Hordeum vulgare L.	10961, 10823,	317	559
			10944, 10824
LBY230	pQFNc_LBY230	WHEAT Triticum aestivum L.	11075, 10742,	501	881
			11042, 10844
LBY231	TopoB_LBY231	WHEAT Triticum aestivum L.	11072, 10906,	502	882
			11072, 10906
LBY232	pQsFN_LBY232	WHEAT Triticum aestivum L.	11128, 11215,	503	883
			11128, 11215
LBY233	pQFNc_LBY233	MAIZE Zea mays L.	11118, 10827,	504	758
			11089, 10830
LBY24	pQFNc_LBY24	BARLEY Hordeum vulgare L.	11147, 11194,	318	818
			11057, 11189
LBY25	pQFNc_LBY25	BARLEY Hordeum vulgare L.	11094, 10738,	319	561
			11021, 10770
LBY26	pMK-RQ_LBY26_GA			320	562
LBY27_H4	pMA-			508	762
	RQ_LBY27_H4_GA
LBY28	pQFNc_LBY28	BARLEY Hordeum vulgare L.	11002, 10818,	321	819
			11002, 10828
LBY29	pUC19c_LBY29	BARLEY Hordeum vulgare L.	10850, 10679,	322	565
			10905, 10714
LBY3	pQFNc_LBY3	FOXTAIL Setaria italica	11058, 10758,	547	—
			11080, 10909
LBY30	pUC19_LBY30	BARLEY Hordeum vulgare L.	11000, 10880,	323	566
			11126, 10776
LBY31	pQFNc_LBY31	BARLEY Hordeum vulgare L.	11087, 10842,	324	820
			11087, 10829
LBY32	pMA-RQ_LBY32_GA			325	568
LBY33	pQFNc_LBY33	BEAN Phaseolus vulgaris	10889, 10719,	326	821
			10864, 10690
LBY34_H2	pMA-			509	763
	RQ_LBY34_H2_GA
LBY35	TopoB_LBY35	BEAN Phaseolus vulgaris	11141, 10903,	327	822
			10972, 10806
LBY36	pUC19c_LBY36	BEAN Phaseolus vulgaris	11142, 10867,	328	823
			11156, 10926
LBY37	pQFNc_LBY37	BRACHYPODIUM Brachypodiums	10997, 11184,	329	573
		dis	11024, 11201
LBY4	pQsFN_LBY4	COTTON Gossypium ND	11068, 10796,	548	—
			11068, 10796
LBY40	pMA-RQ_LBY40_GA			331	575
LBY41	pMA-RQ_LBY41_GA			332	576
LBY43	pQFNc_LBY43	CHLAMYDOMONAS	11055, 10761,	333	578
		Chlamydomonas re	11137, 10834
LBY44	pMK-RQ_LBY44_GA			334	579
LBY45	pQFNc_LBY45	COTTON Gossypium ND	11065, 10846,	335	580
			11065, 10846
LBY46	pQFNc_LBY46	COTTON Gossypium ND		336	824
LBY47	TopoB_LBY47	COTTON Gossypium ND	10713, 10927,	337	825
			10709, 10929
LBY48	pQFNc_LBY48	COTTON Gossypium ND	11026, 10904,	338	826
			11027, 10920
LBY49	pQFNc_LBY49	COTTON Gossypium ND	10759, 11207,	339	827
			10872, 11207
LBY5	pQFNc_LBY5	MAIZE Zea mays L.	11077, 11211,	549	—
			11124, 11211
LBY50	pUC19c_LBY50	COTTON Gossypium ND	11030, 10893,	340	828
			11043, 10748
LBY51	pQFNc_LBY51	COTTON Gossypium ND	11039, 10900,	341	586
			11143, 10762
LBY52	pQFNc_LBY52	COTTON Gossypium ND	11066, 11037,	342	829
			11066, 11037
LBY53	pQFNc_LBY53	COTTON Gossypium ND	10896, 10702,	343	830
			10896, 10702
LBY54	pUC19c_LBY54	COTTON Gossypium ND	11009, 10875,	344	589
			11085, 10875
LBY55	TopoB_LBY55	FOXTAIL Setaria italica	11102, 11213,	345	590
			11102, 11213
LBY56	pQFNc_LBY56	FOXTAIL Setaria italica	10807, 10720,	346	591
			10807, 10720
LBY57	pQFNc_LBY57	FOXTAIL Setaria italica	11098, 10753,	347	592
			11052, 10921
LBY58	pQFNc_LBY58	FOXTAIL Setaria italica	11113, 10746,	348	593
			10983, 10839
LBY59	pMA_LBY59_GA			349	594
LBY6	pQFNc_LBY6	MAIZE Zea mays L.	10799, 10680,	550	—
			10799, 10680
LBY61	pMA-RQ_LBY61_GA			350	595
LBY62	pQFNc_LBY62	FOXTAIL Setaria italica	10995, 10854,	351	596
			11096, 10831
LBY63	pUC19c_LBY63	FOXTAIL Setaria italica	11040, 10802,	352	597
			11040, 10885
LBY64	pQFNc_LBY64	FOXTAIL Setaria italica		353	598
LBY65	TopoB_LBY65	FOXTAIL Setaria italica	10965, 10703,	354	599
			10965, 10721
LBY66	pUC19c_LBY66	FOXTAIL Setaria italica	10975, 10710,	355	600
			10975, 10710
LBY68	pMA-RQ_LBY68_GA			356	602
LBY69	pQFNc_LBY69	FOXTAIL Setaria italica	11081, 11198,	357	831
			11131, 11179
LBY70	pQFNc_LBY70	FOXTAIL Setaria italica	11132, 10674,	358	604
			10999, 10676
LBY71	pUC19c_LBY71	FOXTAIL Setaria italica	11107, 11212,	359	605
			11054, 11214
LBY72	pQFNc_LBY72	FOXTAIL Setaria italica	11044, 10765,	360	832
			11044, 10765
LBY73	pQFNc_LBY73	FOXTAIL Setaria italica	10861, 10723,	361	607
			10879, 10697
LBY74	pQFNc_LBY74	FOXTAIL Setaria italica	11029, 11202,	362	833
			11031, 11169
LBY75	TopoB_LBY75	FOXTAIL Setaria italica	11074, 11186,	363	609
			10988, 11203
LBY76	TopoB_LBY76	FOXTAIL Setaria italica	11007, 10917,	364	610
			11101, 10901
LBY77	pQFNc_LBY77	FOXTAIL Setaria italica	11061, 10787,	365	611
			11136, 10757
LBY78	TopoB_LBY78	FOXTAIL Setaria italica	10992, 10797,	366	612
			11020, 10826
LBY79	pQFNc_LBY79	FOXTAIL Setaria italica	10971, 10908,	367	613
			10971, 10908
LBY80	pQFNc_LBY80	FOXTAIL Setaria italica	11084, 10890,	368	614
			11051, 10793
LBY81	pQFNc_LBY81	FOXTAIL Setaria italica	10805, 10933,	369	615
			10805, 10939
LBY82	pQFNc_LBY82	FOXTAIL Setaria italica	11010, 10955,	370	616
			10985, 10954
LBY83	pMA-RQ_LBY83_GA			371	617
LBY84	pQFNc_LBY84	FOXTAIL Setaria italica	11008, 10882,	372	618
			11013, 10825
LBY85	pQFNc_LBY85	FOXTAIL Setaria italica	11071, 10914,	373	619
			11071, 10914
LBY86	pMA-RQ_LBY86_GA			374	620
LBY87	TopoB_LBY87	FOXTAIL Setaria italica	11070, 10803,	375	621
			11134, 10852
LBY88	pQFNc_LBY88	FOXTAIL Setaria italica	10768, 10704,	376	622
			10811, 10681
LBY89	pUC19_LBY89	FOXTAIL Setaria italica	10980, 10773,	377	623
			10980, 10773
LBY90	pQFNc_LBY90	FOXTAIL Setaria italica	11016, 10848,	378	624
			11073, 10832
LBY91	TopoB_LBY91	FOXTAIL Setaria italica	10945, 10750,	379	625
			10945, 10750
LBY92	pQFNc_LBY92	FOXTAIL Setaria italica	10668, 10683,	380	626
			10678, 10701
LBY93	pQFNc_LBY93	COTTON Gossypium ND	11001, 11164,	381	834
			10979, 11175
LBY94	TopoB_LBY94	COTTON Gossypium ND	10977, 10940,	382	835
			11036, 10950
LBY95	pQFNc_LBY95	COTTON Gossypium ND	11138, 10673,	383	836
			11138, 10673
LBY96	pUC19_LBY96	COTTON Gossypium ND	11060, 10790,	384	630
			11060, 10913
LBY97	pQFNc_LBY97	COTTON Gossypium ND	10916, 10705,	385	837
			10911, 10687
LBY98	pMA-T_LBY98_GA			386	632
LBY99	pMA-RQ_LBY99_GA			387	633
LGN1	pQFNc_LGN1	WHEAT Triticum aestivum L.	11291, 11313,	510	764
			11292, 11309
LGN13	pUCsFN_LGN13	RICE Oryza sativa L.	11270, 11333,	518	772
			11270, 11333
LGN14	pUC19c_LGN14	RICE Oryza sativa L.	11254, 11218,	519	773
			11256, 11219
LGN17	pUCsFN_LGN17	MAIZE Zea mays L.	11279, 11315,	520	886
			11282, 11331
LGN18	pUCsFN_LGN18	MAIZE Zea mays L.	11321, 11252,	521	887
			11322, 11253
LGN2	pUCsFN_LGN2	SOYBEAN Glycine max	11303, 11245,	511	765
			11304, 11236
LGN20	pUCsFN_LGN20	MAIZE Zea mays L.	11295, 11314,	522	888
			11295, 11311
LGN23	pUCsFN_LGN23	MAIZE Zea mays L.	11275, 11246,	523	777
			11275, 11246
LGN24	pUCsFN_LGN24	MAIZE Zea mays L.	11294, 11324,	524	889
			11294, 11324
LGN26	pUCsFN_LGN26	MAIZE Zea mays L.	11306, 11310,	525	779
			11271, 11307
LGN3	pUCsFN_LGN3	SORGHUM Sorghum bicolor	11278, 11230,	512	766
			11278, 11227
LGN33	pUCsFN_LGN33	MAIZE Zea mays L.	11247, 11327,	526	780
			11247, 11327
LGN34	TopoB_LGN34	MAIZE Zea mays L.	11284, 11228,	527	890
			11299, 11221
LGN35	pUC19c_LGN35	MAIZE Zea mays L.	11318, 11249,	528	782
			11318, 11249
LGN36	pUCsFN_LGN36	MAIZE Zea mays L.	11281, 11261,	529	783
			11281, 11261
LGN39	pQFNc_LGN39	MAIZE Zea mays L.	11264, 11250,	530	891
			11264, 11250
LGN4	pUC19c_LGN4	SORGHUM Sorghum bicolor	11268, 11222,	513	767
			11273, 11232
LGN40	pUCsFN_LGN40	COTTON Gossypium hirsutum	11267, 11239,	531	785
			11305, 11243
LGN41	pUCsFN_LGN41	BRACHYPODIUM Brachypodiumsdis	11269, 11244,	532	786
			11283, 11329
LGN42	pQsFN_LGN42	BARLEY Hordeum vulgare L.	11280, 11229,	533	787
			11301, 11226
LGN43	pUCsFN_LGN43	BARLEY Hordeum vulgare L.	11274, 11237,	534	788
			11277, 11231
LGN44	pUCsFN_LGN44	BARLEY Hordeum vulgare L.	11276, 11326,	535	789
			11286, 11334
LGN45	pUCsFN_LGN45	BARLEY Hordeum vulgare L.	11265, 11332,	536	892
			11265, 11332
LGN46	TopoB_LGN46	BARLEY Hordeum vulgare L.	11298, 11312,	537	791
			11287, 11308
LGN47	TopoB_LGN47	BARLEY Hordeum vulgare L.	11242, 11330,	538	893
			11242, 11330
LGN48	pUC19c_LGN48	BARLEY Hordeum vulgare L.	11289, 11225,	539	793
			11296, 11328
LGN49	pQFNc_LGN49	MAIZE Zea mays L.	11240, 11257,	540	894
			11235, 11248
LGN5	pQFNc_LGN5	SORGHUM Sorghum bicolor	11317, 11259,	514	768
			11317, 11259
LGN52	pQsFN_LGN52	FOXTAIL Setaria italica	11293, 11234,	541	795
			11293, 11234
LGN54	pQFNc_LGN54	SORGHUM Sorghum bicolor	11288, 11238,	542	796
			11288, 11238
LGN57	pQFNc_LGN57	SORGHUM Sorghum bicolor	11266, 11258,	543	895
			11272, 11260
LGN6	pUCsFN_LGN6	SORGHUM Sorghum bicolor	11262, 11220,	515	769
			11263, 11217
LGN60	pUC19c_LGN60	FOXTAIL Setaria italica	11323, 11325,	544	798
			11323, 11325
LGN61	pUCsFN_LGN61	MAIZE Zea mays L.	11290, 11223,	545	896
			11297, 11224
LGN62_H2	TopoB_LGN62_H2	Foxtail millet	11320, 11285,	546	897
			11320, 11285
LGN7	pUC19c_LGN7	SORGHUM Sorghum bicolor	11316, 11255,	516	770
			11319, 11251
LGN9	pUCsFN_LGN9	RICE Oryza sativa L.	11300, 11241,	517	771
			11302, 11233
LBY39	—			330	574

Table 233: Provided are the gene names, cluster names, organisms from which they were derived, and polynucleotide and polypeptide sequence identifiers of selected genes of some embodiments of the invention. “GA”—Gene Art (synthetically prepared gene sequence).

Example 26

Transforming Agrobacterium Tumefaciens Cells with Binary Vectors Harboring Putative Genes

Each of the binary vectors described in Example 25 above were used to transform Agrobacterium cells. Two additional binary constructs, having only the At6669 or the 35S promoter, or no additional promoter were used as negative controls.

The binary vectors were introduced to Agrobacterium tumefaciens GV301 or LB4404 (for Arabidopsis) or AGL1 (for Brachypodium) competent cells (about 10⁹ cells/mL) by electroporation. The electroporation was performed using a MicroPulser electroporator (Biorad), 0.2 cm cuvettes (Biorad) and EC-2 electroporation program (Biorad). The treated cells were cultured in LB liquid medium at 28° C. for 3 hours, then plated over LB agar supplemented with gentamycin (for Arabidopsis; 50 mg/L; for Agrobacterium strains GV301) or streptomycin (for Arabidopsis; 300 mg/L; for Agrobacterium strain LB4404); or with Carbenicillin (for Brachypodium; 50 mg/L) and kanamycin (for Arabidopsis and Brachypodium; 50 mg/L) at 28° C. for 48 hours. Agrobacterium colonies, which were developed on the selective media, were further analyzed by PCR using the primers designed to span the inserted sequence in the pPI plasmid. The resulting PCR products were isolated and sequenced to verify that the correct polynucleotide sequences of the invention are properly introduced to the Agrobacterium cells.

Example 27

Producing Transgenic Arabidopsis Plants Expressing Selected Genes According to Some Embodiments of the Invention

Materials and Experimental Methods

Plant transformation—The Arabidopsis thaliana var Columbia (T₀ plants) were transformed according to the Floral Dip procedure [Clough S J, Bent A F. (1998) Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant J. 16(6): 735-43; and Desfeux C. Clough S J, Bent A F. (2000) Female reproductive tissues were the primary targets of Agrobacterium-mediated transformation by the Arabidopsis floral-dip method. Plant Physiol. 123(3): 895-904] with minor modifications. Briefly. Arabidopsis thaliana Columbia (Col0) T₀ plants were sown in 250 ml pots filled with wet peat-based growth mix. The pots were covered with aluminum foil and a plastic dome, kept at 4° C. for 3-4 days, then uncovered and incubated in a growth chamber at 18-24° C. under 16/8 hours light/dark cycles. The T₀ plants were ready for transformation six days before anthesis.

Single colonies of Agrobacterium carrying the binary vectors harboring the yield genes were cultured in LB medium supplemented with kanamycin (50 mg/L) and gentamycin (50 mg/L). The cultures were incubated at 28° C. for 48 hours under vigorous shaking and centrifuged at 4000 rpm for 5 minutes. The pellets comprising Agrobacterium cells were resuspended in a transformation medium which contained half-strength (2.15 g/L) Murashige-Skoog (Duchefa); 0.044 μM benzylamino purine (Sigma); 112 μg/L B5 Gambourg vitamins (Sigma); 5% sucrose; and 0.2 ml/L Silwet L-77 (OSI Specialists, CT) in double-distilled water, at pH of 5.7.

Transformation of T₀ plants was performed by inverting each plant into an Agrobacterium suspension such that the above ground plant tissue was submerged for 3-5 seconds. Each inoculated T₀ plant was immediately placed in a plastic tray, then covered with clear plastic dome to maintain humidity and was kept in the dark at room temperature for 18 hours to facilitate infection and transformation. Transformed (transgenic) plants were then uncovered and transferred to a greenhouse for recovery and maturation. The transgenic T₀ plants were grown in the greenhouse for 3-5 weeks until siliques were brown and dry, then seeds were harvested from plants and kept at room temperature until sowing.

For generating T₁ and T₂ transgenic plants harboring the genes, seeds collected from transgenic T₀ plants were surface-sterilized by soaking in 70% ethanol for 1 minute, followed by soaking in 5% sodium hypochlorite and 0.05% triton for 5 minutes. The surface-sterilized seeds were thoroughly washed in sterile distilled water then placed on culture plates containing half-strength Murashig-Skoog (Duchefa); 2% sucrose; 0.8% plant agar; 50 mM kanamycin; and 200 mM carbenicylin (Duchefa). The culture plates were incubated at 4° C. for 48 hours then transferred to a growth room at 25° C. for an additional week of incubation. Vital T₁ Arabidopsis plants were transferred to a fresh culture plates for another week of incubation. Following incubation the T₁ plants were removed from culture plates and planted in growth mix contained in 250 ml pots. The transgenic plants were allowed to grow in a greenhouse to maturity. Seeds harvested from T₁ plants were cultured and grown to maturity as T₂ plants under the same conditions as used for culturing and growing the T₁ plants.

Example 28

Transformation of Brachypodium Distachyon Plants with the Polynucleotides of the Invention

Similar to the Arabidopsis model plant, Brachypodium distachyon has several features that recommend it as a model plant for functional genomic studies, especially in the grasses. Traits that make it an ideal model include its small genome (˜160 Mbp for a diploid genome and 355 Mbp for a polyploidy genome), small physical stature, a short lifecycle, and few growth requirements. Brachypodium is related to the major cereal grain species but is understood to be more closely related to the Triticeae (wheat, barley) than to the other cereals. Brachypodium, with its polyploidy accessions, can serve as an ideal model for these grains (whose genomics size and complexity is a major barrier to biotechnological improvement).

Brachypodium distachyon embryogenic calli were transformed using the procedure described by Vogel and Hill (2008) [High-efficiency Agrobacterium-mediated transformation of Brachypodium distachyon inbred line Bd21-3. Plant Cell Rep 27:471-478], Vain et al (2008) [Agrobacterium-mediated transformation of the temperate grass Brachypodium distachyon (genotypeBd21) for T-DNA insertional mutagenesis. Plant Biotechnology J 6: 236-245], and Vogel J. et al. (2006) [Agrobacterium mediated transformation and inbred line development in the model grass Brachypodium distachyon. Plant Cell Tiss Org. Cult. 85:199-211], each of which is fully incorporated herein by reference, with some minor modifications, which are briefly summarized hereinbelow.

Callus initiation—Immature spikes (about 2 months after seeding) were harvested at the very beginning of seeds filling. Spikes were then husked and surface sterilized with 3% NaClO containing 0.1% Tween 20, shaken on a gyratory shaker at low speed for 20 minutes. Following three rinses with sterile distilled water, embryos were excised under a dissecting microscope in a laminar flow hood using fine forceps.

Excised embryos (size ˜0.3 mm, bell shaped) were placed on callus induction medium (CIM) [LS salts (Linsmaier. E. M. & Skoog, F. 1965. Physiol. Plantarum 18. 100) and vitamins plus 3% sucrose, 6 mg/L CuSO₄, 2.5 mg/l 2,4-Dichlorophenoxyacetic Acid, pH 5.8 and 0.25% phytagel (Sigma)] scutellar side down, 100 embryos on a plate, and incubated at 28° C. in the dark. One week later, the embryonic calli is cleaned from emerging roots, shoots and somatic calli, and was subcultured onto fresh CIM medium. During culture, yellowish embryogenic callus (EC) appeared and were further selected (e.g., picked and transferred) for further incubation in the same conditions for additional 2 weeks. Twenty-five pieces of sub-cultured calli were then separately placed on 90× 15 mm petri plates, and incubated as before for three additional weeks.

Transformation—As described in Vogel and Hill (2008. Supra), Agrobacterium is scraped off 2-day-old MGL plates (plates with the MGL medium which contains: Tryptone 5 g/l, Yeast Extract 2.5 g/l, NaCl 5 g/l, D-Mannitol 5 g/l. MgSO₄*7H₂O 0.204 g/l. K₂HPO₄ 0.25 g/l, Glutamic Acid 1.2 g/l, Plant Agar 7.5 g/l) and resuspended in liquid MS medium supplemented with 200 μM acetosyringone to an optic density (OD) at 600 nm (OD₆₀₀) of 0.6. Once the desired OD was attained, 1 ml of 10% Synperonic PE/F68 (Sigma) per 100 ml of inoculation medium is added.

To begin inoculation, 300 callus pieces were placed in approximately 12 plates (25 callus pieces in each plate) and covered with the Agrobacterium suspension (8-8.5 ml). The callus was incubated in the Agrobacterium suspension for 15 minutes with occasional gentle rocking. After incubation, the Agrobacterium suspension was aspirated off and the calli are then transferred into co-cultivation plates, prepared by placing a sterile 7-cm diameter filter paper in an empty 90×15 mm petri plate. The calli pieces were then gently distributed on the filter paper. One co-cultivation plate was used for two starting callus plates (50 initial calli pieces). The co-cultivation plates were then sealed with parafilm and incubated at 22° C. in the dark for 3 days.

The callus pieces were then individually transferred onto CIM medium as described above, which is further supplemented with 200 mg/l Ticarcillin (to kill the Agrobacterium) and Bialaphos (5 mg/L) (for selection of the transformed resistant embryogenic calli sections), and incubated at 28° C. in the dark for 14 days.

The calli pieces were then transferred to shoot induction media (SIM; LS salts and vitamins plus 3% Maltose monohydrate) supplemented with 200 mg/l Ticarcillin, Bialaphos (5 mg/L), Indol-3-acetic acid (IAA) (0.25 mg/L), and 6-Benzylaminopurine (BAP) (1 mg/L), and are sub-cultured in light to the same media after 10 days (total of 20 days). At each sub-culture all the pieces from a single callus are kept together to maintain their independence and are incubated under the following conditions: lighting to a level of 60 1E m−2 s−1, a 16-h light, 8-h dark photoperiod and a constant 24° C. temperature. Plantlets emerged from the transformed calli.

When plantlets were large enough to handle without damage, they were transferred to plates containing the above mentioned shoot induction media (SIM) without Bialaphos. Each plantlet was considered as a different event. The plantlets grew axillary tillers and eventually became bushy. Each bush from the same plant (event ID) was then divided to tissue culture boxes (“Humus”) containing “rooting medium” [MS basal salts, 3% sucrose, 3 g/L phytagel, 2 mg/l α-Naphthalene Acetic Acid (NAA) and 1 mg/L IAA and Ticarcillin 200 mg/L, PH 5.8). All plants in a “Humus box” were different plants of the same transformation event.

When plantlets establish roots they were transplanted to soil and transferred to a greenhouse. To verify the transgenic status of plants containing the other constructs, T0 plants were subjected to PCR as previously described by Vogel et al. 2006 [Agrobacterium mediated transformation and inbred line development in the model grass Brachypodium distachyon. Plant Cell Tiss Org. Cult. 85:199-211].

Example 29

Evaluation of Transgenic Arabidopsis for Seed Yield and Plant Growth Rate Under Normal Conditions in Greenhouse Assays (GH-SM Assays)

Assay 1: Seed Yield, Plant Biomass and Plant Growth Rate in Greenhouse Conditions (Seed Maturation Assay).

Under Normal conditions—This assay follows seed yield production, the biomass formation and the rosette area growth of plants grown in the greenhouse at non-limiting nitrogen growth conditions. Transgenic Arabidopsis seeds were sown in agar media supplemented with ½ MS medium and a selection agent (Kanamycin). The T₂ transgenic seedlings were then transplanted to 1.7 trays filled with peat and perlite in a 1:2 ratio. The plant were grown under normal growth conditions which included irrigation of the trays with a solution containing 6 mM inorganic nitrogen in the form of KNO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄. 1.5 mM CaCl₂ and microelements. Under normal conditions the plants grow in a controlled environment in a closed transgenic greenhouse, temperature about 18-22° C., humidity around 70%. Irrigation was done by flooding with a water solution containing 6 mM N (nitrogen) (as described hereinabove), and flooding was repeated whenever water loss reached 50%. All plants were grown in the greenhouse until mature seeds. Seeds were harvested, extracted and weighted. The remaining plant biomass (the above ground tissue) was also harvested, and weighted immediately or following drying in oven at 50° C. for 24 hours.

Under drought conditions and standard growth conditions—This assay follows seed yield production, the biomass formation and the rosette area growth of plants grown in the greenhouse under drought conditions and under standard growth conditions. Transgenic Arabidopsis seeds were sown in phytogel media supplemented with ½ MS medium and a selection agent (Kanamycin). The T₂ transgenic seedlings were then transplanted to 1.7 trays filled with peat and perlite in a 1:2 ratio and tuff at the bottom of the tray and a net below the trays (in order to facilitate water drainage). Half of the plants were irrigated with tap water (standard growth conditions) when tray weight reached 50% of its field capacity. The other half of the plants were irrigated with tap water when tray weight reached 20% of its field capacity in order to induce drought stress. All plants were grown in the greenhouse until seeds maturation. Seeds were harvested, extracted and weighted. The remaining plant biomass (the above ground tissue) was also harvested, and weighted immediately or following drying in oven at 50° C. for 24 hours.

Under nitrogen limiting (low N) and standard (nitrogen non-limiting) conditions—This assay follows seed yield production, the biomass formation and the rosette area growth of plants grown in the greenhouse at limiting and non-limiting nitrogen growth conditions. Transgenic Arabidopsis seeds were sown in agar media supplemented with ½ MS medium and a selection agent (Kanamycin). The T₂ transgenic seedlings were then transplanted to 1.7 trays filled with peat and perlite in a 1:1 ratio. The trays were irrigated with a solution containing nitrogen limiting conditions, which were achieved by irrigating the plants with a solution containing 2.8 mM inorganic nitrogen in the form of KNO₃, supplemented with 1 mM KH₂PO₄, 1 mM MgSO₄, 1.5 mM CaCl₂ and microelements, while normal nitrogen levels were achieved by applying a solution of 5.5 mM inorganic nitrogen also in the form of KNO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄, 1.5 mM CaCl₂ and microelements. All plants were grown in the greenhouse until mature seeds. Seeds were harvested, extracted and weight. The remaining plant biomass (the above ground tissue) was also harvested, and weighted immediately or following drying in oven at 50° C. for 24 hours.

Each construct was validated at its T₂ generation. Transgenic plants transformed with a construct conformed by an empty vector carrying a promoter and the selectable marker were used as control [The promoters which were used are described in Example 25 above, e.g., the At6669 promoter (SEQ ID NO: 10654) or the 35S promoter (SEQ ID NO: 10650]

The plants were analyzed for their overall size, growth rate, flowering, seed yield, 1,000-seed weight, dry matter and harvest index (HI— seed yield/dry matter). Transgenic plants performance was compared to control plants grown in parallel under the same (e.g., identical) conditions. Mock-transgenic plants expressing the uidA reporter gene (GUS-Intron) or with no gene at all, under the same promoter were used as controls.

The experiment was planned in nested randomized plot distribution. For each gene of the invention three to five independent transformation events were analyzed from each construct.

Digital imaging—A laboratory image acquisition system, which consists of a digital reflex camera (Canon EOS 300D) attached with a 55 mm focal length lens (Canon EF-S series), mounted on a reproduction device (Kaiser RS), which includes 4 light units (4×150 Watts light bulb) was used for capturing images of plant samples.

The image capturing process was repeated every 2 days starting from day 1 after transplanting till day 15. Same camera, placed in a custom made iron mount, was used for capturing images of larger plants sawn in white tubs in an environmental controlled greenhouse. The tubs were square shape include 1.7 liter trays. During the capture process, the tubs were placed beneath the iron mount, while avoiding direct sun light and casting of shadows.

An image analysis system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.39 [Java based image processing program which was developed at the U.S. National Institutes of Health and freely available on the internet at/rsbweb (dot) nih (dot) gov/]. Images are captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Leaf analysis—Using the digital analysis leaves data was calculated, including leaf number, rosette area, rosette diameter, and leaf blade area.

Vegetative growth rate: the relative growth rate (RGR) of leaf number [Formula VIII (described above)], rosette area (Formula IX above), plot coverage (Formula XI above) and harvest index (Formula XV above) were calculated with the indicated formulas.

Seeds average weight—At the end of the experiment all seeds were collected. The seeds were scattered on a glass tray and a picture is taken. Using the digital analysis, the number of seeds in each sample was calculated.

Dry weight and seed yield—On about day 80 from sowing, the plants were harvested and left to dry at 30° C. in a drying chamber. The vegetative portion above ground was separated from the seeds. The total weight of the vegetative portion above ground and the seed weight of each plot were measured and divided by the number of plants.

Dry weight=total weight of the vegetative portion above ground (excluding roots) after drying at 30° C. in a drying chamber; Seed yield per plant=total seed weight per plant (gr.).

1000 seed weight (the weight of 1000 seeds) (gr.).

Oil percentage in seeds—At the end of the experiment all seeds from each plot were collected. Seeds from 3 plots were mixed grounded and then mounted onto the extraction chamber. 210 ml of n-Hexane (Cat No. 080951 Biolab Ltd.) were used as the solvent. The extraction was performed for 30 hours at medium heat 50° C. Once the extraction has ended the n-Hexane was evaporated using the evaporator at 35° C., and vacuum conditions. The process was repeated twice. The information gained from the Soxhlet extractor (Soxhlet, F. Die gewichtsanalytische Bestimmung des Milchfettes, Polytechnisches J. (Dingler's) 1879, 232, 461) is used to create a calibration curve for the Low Resonance NMR. The content of oil of all seed samples was determined using the Low Resonance NMR (MARAN Ultra-Oxford Instrument) and its MultiQuant software package.

Silique length analysis—On day 50 from sowing, 30 siliques from different plants in each plot were sampled in block A. The chosen siliques were green-yellow in color and were collected from the bottom parts of a grown plant's stem. A digital photograph was taken to determine silique's length.

Statistical analyses—To identify outperforming genes and constructs, results from the independent transformation events tested were analyzed separately. Data was analyzed using Student's t-test and results were considered significant if the p value was less than 0.1. The JMP statistics software package was used (Version 5.2.1. SAS Institute Inc., Cary, N.C., USA).

Tables 234-240 summarize the observed phenotypes of transgenic plants exogenously expressing the gene constructs using the seed maturation (GH-SM) assays under low nitrogen (Low N) conditions. The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value <0.1 was considered statistically significant.

TABLE 234
Genes showing improved plant performance at Low Nitrogen
growth conditions under regulation of At6669 promoter
		Dry Weight [mg]	Flowering	Inflorescence Emergence
			P-	%		P-	%		P-	%
Gene Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN5	88198.1	884.2	0.27	2	46.0	0.14	−2	38.5	0.20	−1
LGN5	88198.4	—	—	—	45.2	0.03	−3	38.2	0.04	−2
LGN5	88201.1	—	—	—	47.1	L	−1	38.9	L	−2
LGN5	88201.3	947.9	0.27	10	46.3	0.29	−3	38.9	0.27	−2
CONT.	—	864.8	—	—	46.7	—	—	38.9	—	—
LGN60	89175.1	—	—	—	47.4	0.10	−3	—	—	—
LGN60	89175.2	—	—	—	47.6	0.18	−2	—	—	—
LGN60	89176.1	—	—	—	47.5	0.12	−2	—	—	—
LGN60	89176.3	956.2	0.04	17	46.1	0.02	−5	38.4	0.03	−5
CONT.	—	818.1	—	—	48.7	—	—	40.3	—	—
LGN49	89079.3	—	—	—	47.4	0.26	−1	—	—	—
LGN49	89081.1	—	—	—	47.1	0.12	−2	39.0	0.29	−2
LGN49	89081.3	932.1	0.03	12	—	—	—	—	—	—
LGN49	89082.1	—	—	—	45.6	0.09	−5	38.2	0.08	−4
CONT.	—	828.8	—	—	47.0	—	—	39.8	—	—
LGN54	88208.2	955.9	0.16	5	—	—	—	—	—	—
CONT.	—	992.0	—	—	—	—	—	—	—	—
LGN2	89029.2	855.0	0.17	9	46.4	0.02	−3	—	—	—
LGN2	89032.1	847.1	0.10	8	—	—	—	—	—	—
CONT.	—	782.4	—	—	48.0	—	—	—	—	—
LGN5	88198.1	—	—	—	48.2	0.23	−1	40.2	0.23	−1
LGN5	88198.4	—	—	—	47.1	L	−3	39.8	0.05	−2
LGN5	88201.3	802.7	0.09	8	—	—	—	—	—	—
CONT.	—	793.1	—	—	48.8	—	—	40.4	—	—
LGN54	88206.1	—	—	—	47.3	0.27	−1	39.1	0.20	−2
CONT.	—	—	—	—	47.9	—	—	39.8	—	—
LGN36	89045.1	—	—	—	47.2	0.26	−3	—	—	—
LGN36	89047.1	590.4	0.13	9	—	—	—	—	—	—
CONT.	—	539.6	—	—	48.5	—	—	—	—	—
LGN24	89094.2	570.4	0.02	11	—	—	—	—	—	—
CONT.	—	513.8	—	—	—	—	—	—	—	—
NUE102	90004.1	—	—	—	—	—	—	38.0	0.23	−4
NUE102	90004.3	—	—	—	—	—	—	38.6	0.25	−3
NUE102	90005.2	—	—	—	—	—	—	38.3	0.25	−3
CONT.	—	—	—	—	—	—	—	39.7	—	—
LGN2	89029.2	—	—	—	43.3	0.02	−5	35.2	0.15	−5
LGN2	89032.3	—	—	—	44.9	0.19	−2	—	—	—
LGN2	89033.1	795.0	0.17	8	—	—	—	—	—	—
CONT.	—	738.8	—	—	45.7	—	—	37.1	—	—
NUE102	90004.3	849.6	0.25	5	—	—	—	—	—	—
CONT.	—	805.8	—	—	—	—	—	—	—	—
LGN26	89036.1	720.8	0.29	6	—	—	—	—	—	—
LGN26	89036.4	774.9	0.24	14	—	—	—	—	—	—
LGN26	89037.2	854.6	0.01	26	—	—	—	—	—	—
LGN26	89037.4	844.2	L	24	—	—	—	—	—	—
CONT.	—	680.3	—	—	—	—	—	—	—	—
LGN60	89174.2	—	—	—	—	—	—	39.9	0.15	−1
LGN60	89175.1	—	—	—	47.6	0.21	−2	39.9	0.14	−1
LGN60	89176.3	1000.7	0.09	20	46.7	0.03	−4	39.7	0.05	−2
CONT.	—	831.9	—	—	48.4	—	—	40.4	—	—
LGN26	89036.4	504.3	0.17	10	—	—	—	—	—	—
LGN26	89037.2	548.1	L	20	—	—	—	38.0	0.16	−3
L6N26	89037.3	514.6	0.06	13	—	—	—	—	—	—
CONT.	—	457.2	—	—	—	—	—	39.1	—	—
LGN49	89079.3	712.4	0.29	10	—	—	—	—	—	—
LGN49	89081.3	739.2	0.28	14	48.8	0.09	−4	40.7	0.21	−4
L6N49	89081.6	710.4	0.25	10	48.0	0.03	−5	40.2	0.12	−5
LGN49	89082.1	—	—	—	49.3	0.16	−3	41.3	0.23	−1
CONT.	—	647.8	—	—	50.8	—	—	42.2	—	—

Table 234. “CONT.”—Control; “Ave.”—Average: “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 235
Genes showing improved plant performance at Low Nitrogen growth conditions under
regulation of At6669 promoter
		Leaf Blade Area [cm2]	Leaf Number	Plot Coverage [cm2]
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN36	89044.1	0.482	0.02	10	10.0	L	4	27.0	0.13	10
LGN36	89047.1	0.461	0.08	5	—	—	—	—	—	—
CONT.	—	0.440	—	—	9.62	—	—	24.5	—	—
LGN5	88198.1	—	—	—	10.8	0.21	5	—	—	—
LGN5	88198.4	1.07	0.16	13	11.4	0.10	7	64.6	0.10	20
LGN5	88201.1	—	—	—	—	—	—	52.1	0.23
LGN5	88201.3	1.06	0.28	11	12.4	0.01	16	66.9	0.19	24
CONT.	—	0.949	—	—	10.7	—	—	54.0	—	—
LGN60	89174.2	—	—	—	10.4	0.07	3	—	—	—
LGN60	89175.2	—	—	—	10.4	0.13	3	46.8	0.24	9
LGN60	89176.1	0.879	0.09	10	—	—	—	48.6	0.13	13
LGN60	89176.3	0.938	0.01	18	10.7	0.04	4	53.0	0.02	23
CONT.	—	0.795	—	—	10.3	—	—	43.0	—	—
LGN49	89081.1	0.888	0.09	5	—	—	—	51.1	0.09	7
LGN49	89081.3	0.998	0.28	8	10.9	0.02	6	59.8	0.09	14
LGN49	89081.6	1.01	0.13	20	11.1	0.08	9	60.8	0.29	16
LGN49	89082.1	0.963	0.03	14	—	—	—	56.9	0.22	8
CONT.	—	0.925	—	—	10.2	—	—	52.5	—	—
LGN54	88207.3	—	—	—	10.7	0.22	6	—	—	—
CONT.	—	—	—	—	10.1	—	—	—	—	—
LGN2	89029.2	0.925	0.09	10	11.4	L	7	58.2	0.03	21
CONT.	—	0.838	—	—	10.6	—	—	48.2	—	—
LGN5	88198.4	1.06	L	22	10.8	0.20	5	61.3	L	26
LGN5	88201.3	—	—	—	10.7	0.19	6	—	—	—
LGN1	88203.2	0.932	0.24	8	—	—	—	—	—	—
CONT.	—	0.870	—	—	10.3	—	—	48.5	—	—
LGN24	89094.7	0.677	L	33	10.0	0.18	5	37.7	L	35
LGN24	89094.3	0.573	0.14	13	—	—	—	31.8	0.13	14
LGN24	89096.1	0.553	0.22	9	10.0	0.24	4	30.8	0.21	10
LGN24	89096.2	—	—	—	—	—	—	30.9	0.30	10
CONT.	—	0.509	—	—	9.59	—	—	28.0	—	—
LGN54	88207.3	—	—	—	10.4	0.20	2	55.3	0.27	6
CONT.	—	—	—	—	10.2	—	—	52.3	—	—
LGN36	89044.1	—	—	—	—	—	—	30.5	0.22	5
LGN36	89047.2	—	—	—	10.4	0.13	2	—	—	—
CONT.	—	—	—	—	10.2	—	—	29.2	—	—
LGN6	89169.2	—	—	—	10.9	0.04	6	—	—	—
LGN6	89170.1	—	—	—	11.0	0.05	6	—	—	—
LGN6	89171.4	—	—	—	10.8	0.06	5	—	—	—
CONT.	—	—	—	—	10.3	—	—	—	—	—
LGN24	89094.2	0.768	0.01	21	—	—	—	42.7	L	21
CONT.	—	0.634	—	—	—	—	—	35.4	—	—
NUE102	90003.5	—	—	—	—	—	—	34.5	0.10	6
NUE102	90004.1	0.690	0.11	15	—	—	—	38.6	0.07	19
CONT.	—	0.602	—	—	—	—	—	32.5	—	—
LGN2	89029.1	0.890	0.02	24	10.2	0.29	3	48.7	L	25
CONT.	—	0.717	—	—	9.84	—	—	38.9	—	—
LGN60	89175.7	—	—	—	10.3	0.01	4	51.7	0.28	12
LGN60	89176.3	0.924	L	9	10.6	0.06	6	53.6	0.10	13
CONT.	—	0.886	—	—	9.97	—	—	47.4	—	—
LGN26	89036.1	0.581	0.27	4	—	—	—	—	—	—
CONT.	—	0.557	—	—	—	—	—	—	—	—
LGN49	89081.3	0.886	0.29	6	—	—	—	49.1	0.27	9
LGN49	89081.6	0.970	0.06	16	—	—	—	53.5	0.06	19
CONT.	—	0.838	—	—	—	—	—	44.9	—	—

Table 235. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 236
Genes showing improved plant performance at Low Nitrogen growth conditions under
regulation of At6669 promoter
								RGR Of Rosette
		RGR Of Leaf Number	RGR Of Plot Coverage	Diameter
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN36	89044.1	0.664	0.21	12	3.00	0.16	9	0.192	0.30	3
CONT.	—	0.592	—	—	2.74	—	—	0.185	—	—
LGN5	88198.4	—	—	—	7.16	0.13	18	0.341	0.19	9
LGN5	88201.1	—	—	—	5.87	0.25	3	—	—	—
LGN5	88201.3	0.618	0.12	12	7.50	0.22	24	—	—	—
CONT.	—	0.551	—	—	6.05	—	—	0.322	—	—
LGN60	89174.2	0.641	L	16	—	—	—	—	—	—
LGN60	89175.2	0.596	0.13	8	5.30	0.30	9	—	—	—
LGN60	89176.1	—	—	—	5.56	0.13	14	0.314	0.21	9
LGN60	89176.3	—	—	—	5.77	0.06	18	—	—	—
CONT.	—	0.551	—	—	4.88	—	—	0.289	—	—
LGN49	89079.3	0.566	0.05	20	—	—	—	—	—	—
LGN49	89081.1	—	—	—	5.68	0.09	8	0.308	0.03	7
LGN49	89081.3	—	—	—	6.45	0.15	12	0.311	0.10	8
LGN49	89081.6	—	—	—	6.64	0.19	27	0.335	0.16	16
LGN49	89082.1	—	—	—	6.29	0.24	9	0.317	0.11	10
CONT.	—	0.471	—	—	5.76	—	—	0.310	—	—
LGN54	88206.1	0.619	0.12	21	—	—	—	—	—	—
LGN54	88207.3	0.637	0.11	25	—	—	—	—	—	—
CONT.	—	0.510	—	—	—	—	—	—	—	—
LGN2	89029.2	0.719	0.14	10	6.87	0.03	22	0.361	0.04	11
CONT.	—	0.652	—	—	5.65	—	—	0.325	—	—
LGN5	88198.4	—	—	—	6.99	0.01	28	0.354	0.02	14
LGN5	88203.2	—	—	—	—	—	—	0.339	0.07	9
CONT.	—	—	—	—	5.48	—	—	0.310	—	—
LGN24	89094.2	—	—	—	4.05	0.01	32	0.196	0.16	16
LGN24	89094.3	—	—	—	3.47	0.17	14	—	—	—
LGN24	89096.1	—	—	—	3.34	0.30	9	—	—	—
CONT.	—	—	—	—	3.06	—	—	0.169	—	—
LGN54	88206.4	0.577	0.08	8	—	—	—	—	—	—
LGN54	88207.3	0.579	0.21	8	—	—	—	—	—	—
LGN54	88208.2	0.632	0.08	17	—	—	—	—	—	—
CONT.	—	0.540	—	—	—	—	—	—	—	—
LGN36	89047.2	0.728	0.08	10	—	—	—	—	—	—
CONT.	—	0.662	—	—	—	—	—	—	—	—
LGN6	89169.7	0.659	0.07	18	—	—	—	—	—	—
LGN6	89170.1	0.681	L	22	—	—	—	—	—	—
LGN6	89171.4	0.682	0.11	22	—	—	—	—	—	—
LGN6	89173.1	0.646	0.24	15	—	—	—	—	—	—
CONT.	—	0.560	—	—	—	—	—	—	—	—
LGN24	89094.2	—	—	—	4.68	L	19	0.201	0.16	7
LGN24	89094.3	—	—	—	—	—	—	0.197	0.27	5
LGN24	89096.7	—	—	—	—	—	—	0.199	0.29	6
CONT.	—	—	—	—	3.93	—	—	0.188	—	—
NUE102	90003.5	—	—	—	4.68	0.25	5	—	—	—
NUE102	90004.1	—	—	—	5.29	0.11	18	0.341	0.30	4
CONT.	—	—	—	—	4.48	—	—	0.328	—	—
LGN2	89029.2	—	—	—	6.80	L	27	0.414	L	18
LGN2	89029.7	0.820	0.11	6	—	—	—	—	—	—
CONT.	—	0.774	—	—	5.34	—	—	0.352	—	—
LGN26	89037.4	0.707	0.29	7	—	—	—	—	—	—
CONT.	—	0.658	—	—	—	—	—	—	—	—
LGN60	89174.2	—	—	—	—	—	—	0.330	L	4
LGN60	89175.1	—	—	—	—	—	—	0.335	0.10	6
LGN60	89175.2	—	—	—	—	—	—	0.325	0.14	3
LGN60	89176.3	—	—	—	6.17	0.13	11	0.332	0.11	5
CONT.	—	—	—	—	5.54	—	—	0.324	—	—
LGN49	89081.3—	—	—	—	5.50	0.03	10	—	—	—
LGN49	89081.6	—	—	—	5.95	0.10	18	0.321	0.25	4
CONT.	—	—	—	—	5.06	—	—	0.312	—	—

Table 236. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value. L—p<0.01.

TABLE 237
Genes showing improved plant performance at Low Nitrogen growth conditions under
regulation of At6669 promoter
		Harvest Index	Rosette Area [cm2]	Rosette Diameter [cm]
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN36	89044.1	0.0942	0.19	30	3.38	0.13	10	3.01	0.24	4
LGN36	89047.1	0.0979	0.16	35	—	—	—	—	—	—
CONT.	—	0.0725	—	—	3.06	—	—	2.90	—	—
LGN5	88198.4	—	—	—	8.08	0.10	20	4.80	0.15	8
LGN5	88201.1	—	—	—	6.51	0.23	3	—	—	—
LGN5	88201.3	—	—	—	8.36	0.19	24	4.73	0.28	10
CONT.	—	—	—	—	6.75	—	—	4.44	—	—
LGN60	89174.2	0.241	0.17	9	—	—	—	—	—	—
LGN60	89175.1	0.252	0.21	8	—	—	—	—	—	—
LGN60	89175.2	—	—	—	5.85	0.24	9	—	—	—
LGN60	89176.1	—	—	—	6.07	0.13	13	4.27	0.11	8
LGN60	89176.3	—	—	—	6.62	0.02	23	4.38	0.04	10
CONT.	—	0.233	—	—	5.37	—	—	3.97	—	—
LGN49	89081.1	—	—	—	6.39	0.11	6	4.35	0.07	3
LGN49	89081.3	—	—	—	7.48	0.09	14	4.61	0.24	5
LGN49	89081.6	—	—	—	7.60	0.29	16	4.81	0.22	9
LGN49	89082.1	0.211	0.08	28	7.12	0.22	8	4.56	0.08	8
CONT.	—	0.164	—	—	6.56	—	—	4.41	—	—
LGN54	88206.1	0.188	L	48	—	—	—	—	—	—
LGN54	88207.3	0.162	0.16	27	—	—	—	—	—	—
CONT.	—	0.128	—	—	—	—	—	—	—	—
LGN2	89029.2	0.148	0.12	15	7.28	0.03	21	4.52	0.01	11
CONT.	—	0.129	—	—	6.03	—	—	4.09	—	—
LGN5	88198.4	—	—	—	7.66	L	26	4.82	L	14
LGN5	88203.2	—	—	—	6.29	0.22	7	4.54	0.07	8
CONT.	—	—	—	—	6.06	—	—	4.22	—	—
LGN24	89094.2	—	—	—	4.71	L	35	3.48	0.02	16
LGN24	89094.3	—	—	—	3.98	0.13	14	3.20	0.17	6
LGN24	89096.1	—	—	—	3.85	0.21	10	3.15	0.26	5
LGN24	89096.2	—	—	—	3.86	0.30	10	—	—	—
CONT.	—	—	—	—	3.50	—	—	3.01	—	—
LGN54	88206.4	0.306	0.06	15	—	—	—	—	—	—
LGN54	88207.2	0.317	L	19	—	—	—	—	—	—
LGN54	88207.3	0.291	0.13	9	6.91	0.27	6	—	—	—
LGN54	88208.2	0.297	0.20	12	—	—	—	—	—	—
CONT.	—	0.266	—	—	6.53	—	—	—	—	—
LGN36	89044.1	—	—	—	3.82	0.22	5	—	—	—
CONT.	—	—	—	—	3.65	—	—	—	—	—
LGN6	89170.1	0.176	0.25	17	—	—	—	—	—	—
CONT.	—	0.150	—	—	—	—	—	—	—	—
LGN24	89094.2	—	—	—	5.34	L	21	3.73	L	9
LGN24	89094.3	—	—	—	—	—	—	3.49	0.24	2
LGN24	89096.1	0.154	0.08	13	—	—	—	—	—	—
CONT.	—	0.136	—	—	4.42	—	—	3.41	—	—
NUE102	90003.5	—	—	—	4.32	0.10	6	—	—	—
NUE102	90004.1	0.212	0.22	24	4.82	0.07	19	3.88	0.03	10
CONT.	—	0.172	—	—	4.06	—	—	3.53	—	—
LGN2	89029.2	0.210	0.14	17	6.09	L	25	4.48	L	15
CONT.	—	0.179	—	—	4.86	—	—	3.88	—	—
LGN60	89174.2	0.315	0.26	16	—	—	—	—	—	—
LGN60	89175.1	—	—	—	—	—	—	4.38	0.03	3
LGN60	89175.2	—	—	—	6.46	0.28	12	4.45	0.25	5
LGN60	89176.3	—	—	—	6.70	0.10	13	4.47	0.12	5
CONT.	—	0.286	—	—	5.93	—	—	4.25	—	—
LGN49	89079.3	0.209	0.11	17	—	—	—	—	—	—
LGN49	89081.1	0.207	0.23	16	—	—	—	—	—	—
LGN49	89081.3	—	—	—	6.14	0.27	9	4.34	0.23	4
LGN49	89081.6	—	—	—	6.69	0.06	19	4.61	0.05	10
CONT.	—	0.179	—	—	5.61	—	—	4.19	—	—

Table 237. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 238
Genes showing improved plant performance at Low Nitrogen
growth conditions under regulation of At6669 promoter
			1000 Seed
		Seed Yield [mg]	Weight [mg]
Gene	Event		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN36	89044.1	62.9	0.19	36	—	—	—
LGN36	89047.2	59.7	0.26	29	—	—	—
CONT.	—	46.4	—	—	—	—	—
LGN5	88198.1	—	—	—	19.3	0.02	6
LGN5	88198.4	—	—	—	18.4	0.12	7
LGN5	88201.3	—	—	—	19.5	0.20	8
CONT.	—	—	—	—	18.2	—	—
LGN60	89174.2	—	—	—	17.4	0.26	4
LGN60	89175.1	213.2	0.03	12	18.3	0.02	10
LGN60	89175.2	—	—	—	18.8	0.13	13
LGN60	89176.3	—	—	—	22.3	L	34
CONT.	—	189.9	—	—	16.7	—	—
LGN49	89079.3	159.1	0.21	18	—	—	—
LGN49	89081.3	162.5	0.23	20	21.1	0.05	12
LGN49	89081.6	—	—	—	19.7	0.28	5
LGN49	89082.1	168.7	0.05	25	—	—	—
CONT.	—	135.0	—	—	18.8	—	—
LGN54	88206.1	160.7	0.08	27	—	—	—
CONT.	—	126.7	—	—	—	—	—
LGN2	89029.2	126.4	L	26	—	—	—
CONT.	—	100.5	—	—	—	—	—
LGN5	88198.1	—	—	—	21.0	L	8
LGN5	88201.3	—	—	—	21.5	0.03	11
CONT.	—	—	—	—	19.4	—	—
LGN24	89094.2	—	—	—	19.1	L	15
CONT.	—	—	—	—	16.5	—	—
LGN54	88206.1	—	—	—	20.9	0.18	3
CONT.	—	—	—	—	21.0	—	—
LGN6	89169.2	—	—	—	19.5	L	12
CONT.	—	—	—	—	17.4	—	—
LGN3	89069.5	—	—	—	15.9	0.19	7
LGN3	89072.3	—	—	—	16.0	0.19	8
LGN3	89072.4	—	—	—	15.5	0.09	4
LGN3	89073.1	—	—	—	16.6	0.11	12
CONT.	—	—	—	—	14.9	—	—
LGN24	89094.2	80.6	0.17	15	19.6	0.01	13
CONT.	—	70.2	—	—	17.3	—	—
NUE102	90004.1	158.1	0.20	22	—	—	—
CONT.	—	130.0	—	—	—	—	—
LGN2	89029.2	164.6	0.21	25	—	—	—
CONT.	—	131.9	—	—	—	—	—
LGN26	89037.3	—	—	—	18.7	L	12
CONT.	—	—	—	—	16.7	—	—
LGN60	89174.2	266.1	0.24	21	—	—	—
LGN60	89176.3	249.7	0.17	14	22.9	0.02	16
CONT.	—	237.7	—	—	19.6	—	—
LGN26	89036.1	—	—	—	17.1	0.13	2
LGN26	89037.3	—	—	—	18.2	0.02	9
CONT.	—	—	—	—	16.7	—	—
LGN49	89079.3	148.3	0.11	27	—	—	—
LGN49	89081.3	—	—	—	20.0	0.02	10
LGN49	89081.6	—	—	—	20.8	0.01	14
CONT.	—	117.0	—	—	18.3	—	—

Table 238. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 239
Genes showing improved plant performance at Low Nitrogen
growth conditions under regulation of At6669 promoter
	1000 Seed Weight [mg]
	Gene Name	Event #	Ave.	P-Val.	% Incr.
	LGN5	88198.1	19.3	0.02	6
	LGN5	88198.4	18.4	0.12	7
	LGN5	88201.3	19.5	0.20	8
	CONT.	—	18.2	—	—
	LGN60	89174.2	17.4	0.26	4
	LGN60	89175.1	18.3	0.02	10
	LGN60	89175.2	18.8	0.13	13
	LGN60	89176.3	22.3	L	34
	CONT.	—	16.7	—	—
	LGN49	89081.3	21.1	0.05	12
	LGN49	89081.6	19.7	0.28	5
	CONT.	—	18.8	—	—
	LGN5	88198.1	21.0	L	8
	LGN5	88201.3	21.5	0.03	11
	CONT.	—	19.4	—	—
	LGN24	89094.2	19.1	L	15
	CONT.	—	16.5	—	—
	LGN54	88206.1	20.9	0.18	3
	CONT.	—	21.0	—	—
	LGN6	89169.2	19.5	L	12
	CONT.	—	17.4	—	—
	LGN3	89069.5	15.9	0.19	7
	LGN3	89072.3	16.0	0.19	8
	LGN3	89072.4	15.5	0.09	4
	LGN3	89073.1	16.6	0.11	12
	CONT.	—	14.9	—	—
	LGN24	89094.2	19.6	0.01	13
	CONT.	—	17.3	—	—
	LGN26	89037.3	18.7	L	12
	CONT.	—	16.7	—	—
	LGN60	89176.3	22.9	0.02	16
	CONT.	—	19.6	—	—
	LGN26	89036.1	17.1	0.13	2
	LGN26	89037.3	18.2	0.02	9
	CONT.	—	16.7	—	—
	LGN49	89081.3	20.0	0.02	10
	LGN49	89081.6	20.8	0.01	14
	CONT.	—	18.3	—	—

Table 239. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 240
Genes showing improved plant performance at Low Nitrogen
growth conditions under regulation of At6669 promoter
	Harvest Index
	Gene Name	Event #	Ave.	P-Val.	% Incr.
	LGN36	89044.1	0.0942	0.19	30
	LGN36	89047.2	0.0979	0.16	35
	CONT.	—	0.0725	—	—
	LGN60	89174.2	0.241	0.17	9
	LGN60	89175.1	0.252	0.21	8
	CONT.	—	0.233	—	—
	LGN49	89082.1	0.211	0.08	28
	CONT.	—	0.164	—	—
	LGN54	88206.1	0.188	L	48
	LGN54	88207.3	0.162	0.16	27
	CONT.	—	0.128	—	—
	LGN2	89029.2	0.148	0.12	15
	CONT.	—	0.129	—	—
	LGN54	88206.4	0.306	0.06	15
	LGN54	88207.2	0.317	L	19
	LGN54	88207.3	0.291	0.13	9
	LGN54	88208.2	0.297	0.20	12
	CONT.	—	0.266	—	—
	LGN6	89170.1	0.176	0.25	17
	CONT.	—	0.150	—	—
	LGN24	89096.1	0.154	0.08	13
	CONT.	—	0.136	—	—
	NUE102	90004.1	0.212	0.22	24
	CONT.	—	0.172	—	—
	LGN2	89029.2	0.210	0.14	17
	CONT.	—	0.179	—	—
	LGN60	89174.2	0.315	0.26	16
	CONT.	—	0.286	—	—
	LGN49	89079.3	0.209	0.11	17
	LGN49	89081.1	0.207	0.23	16
	CONT.	—	0.179	—	—

Table 240. “CONT.”—Control; “Ave.”—Average: “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

Tables 241-247 summarize the observed phenotypes of transgenic plants exogenously expressing the gene constructs using the seed maturation (GH-SM) assays under normal conditions. The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value <0.1 was considered statistically significant.

TABLE 241
Genes showing improved plant performance at Normal growth conditions under
regulation of At6669 promoter
		Dry weight [mg]	Flowering	Inflorescence Emergence
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN36	89047.1	961.2	0.24	7	—	—	—	—	—	—
CONT.	—	900.1	—	—	—	—	—	—	—	—
LBY96	92428.4	1608.1	L	21	—	—	—	—	—	—
LBY87	92256.1	1412.5	0.08	6	—	—	—	—	—	—
LBY30	92324.4	1400.0	0.13	5	35.6	0.02	−4	28.2	0.11	−2
LBY225	91605.3	—	—	—	—	—	—	28.2	0.09	−2
LBY225	91607.3	—	—	—	—	—	—	28.4	0.25	−2
LBY225	91607.5	—	—	—	—	—	—	27.9	0.09	−3
LBY213	92030.2	1424.4	0.08	7	—	—	—	—	—	—
LBY213	92032.1	1378.8	0.27	4	—	—	—	—	—	—
LBY213	92032.4	1384.4	0.21	4	—	—	—	—	—	—
LBY212	92026.4	—	—	—	—	—	—	27.9	0.21	−3
LBY212	92028.3	1395.1	0.20	5	—	—	—	—	—	—
LBY202	92021.1	—	—	—	—	—	—	28.4	0.28	−2
LBY202	92022.3	1528.1	0.15	15	—	—	—	—	—	—
LBY319	91660.2	1409.4	0.08	6	—	—	—	27.7	0.28	−4
LBY319	91662.1	—	—	—	—	—	—	28.3	0.14	−2
LBY218	92396.1	—	—	—	—	—	—	28.3	0.18	−2
LBY174	92080.1	1435.6	0.14	8	—	—	—	—	—	—
LBY158	91649.1	—	—	—	35.9	0.04	−3	—	—	—
LBY154	92432.3	1569.4	0.07	18	—	—	—	—	—	—
LBY146	91590.2	—	—	—	35.0	L	−5	27.2	L	−6
LBY146	91590.4	—	—	—	—	—	—	27.9	0.03	−3
LBY146	91593.3	—	—	—	34.2	L	−7	27.6	0.21	−4
LBY146	91594.1	—	—	—	35.9	0.04	−3	—	—	—
LBY139	92241.2	—	—	—	—	—	—	28.2	0.11	−2
LBY135	92321.6	—	—	—	35.8	0.05	−3	28.1	0.06	−3
LBY135	92322.1	1497.5	0.13	13	35.6	0.02	−3	28.2	0.11	−2
LBY113	92234.1	—	—	—	36.0	0.05	−2	28.3	0.18	−2
LBY113	92234.2	1429.4	0.04	7	35.9	0.04	−3	—	—	—
LBY113	92234.5	—	—	—	35.7	0.02	−3	28.2	0.13	−2
CONT.	—	1331.1	—	—	36.9	—	—	28.9	—	—
LGN5	88198.1	—	—	—	45.1	L	−2	38.0	0.07	−1
LGN5	88198.4	—	—	—	44.8	L	−3	38.0	0.07	−1
LGN5	88201.3	—	—	—	—	—	—	38.0	0.07	−1
CONT.	—	—	—	—	45.1	—	—	38.1	—	—
LBY97	92034.3	—	—	—	29.8	0.23	−1	22.0	0.14	−2
LBY87	92255.1	—	—	—	29.3	0.14	−3	21.8	0.10	−3
LBY81	92009.1	—	—	—	28.9	0.30	−4	21.6	0.21	−4
LBY81	92013.1	—	—	—	30.0	0.29	−1	22.0	0.14	−2
LBY25	91335.3	—	—	—	29.1	0.24	−4	21.8	0.10	−3
LBY25	91338.2	—	—	—	29.6	0.01	−2	21.8	0.10	−3
LBY230	91667.1	—	—	—	30.0	0.29	−1	—	—	—
LBY230	91669.3	—	—	—	—	—	—	21.6	0.02	−4
LBY217	92359.2	—	—	—	29.3	0.14	−3	—	—	—
LBY217	92362.1	—	—	—	29.8	0.23	−1	—	—	—
LBY318	92075.2	—	—	—	28.8	0.02	−5	21.3	L	−5
LBY318	92076.1	—	—	—	29.8	0.23	−1	—	—	—
LBY318	92078.4	—	—	—	28.2	L	−7	21.2	L	−6
LBY316	91442.9	—	—	—	—	—	—	21.2	L	−6
LBY315	92321.6	—	—	—	—	—	—	21.5	0.24	−4
LBY315	92322.1	—	—	—	—	—	—	21.7	0.16	−4
LBY315	92323.1	—	—	—	30.0	0.29	−1	—	—	—
LBY120	91211.2	—	—	—	29.1	0.24	−4	21.8	0.10	−3
LBY118	91432.3	—	—	—	28.2	L	−7	21.4	0.03	−5
LBY117	91366.1	—	—	—	—	—	—	21.5	0.02	−5
LBY117	91366.3	—	—	—	26.5	L	−12	21.1	L	−6
LBY112	92051.1	—	—	—	28.1	L	−7	21.0	L	−7
LBY112	92051.3	—	—	—	28.3	L	−6	21.2	L	−6
LBY112	92053.2	—	—	—	—	—	—	21.7	0.16	−4
LBY112	92053.6	—	—	—	—	—	—	21.8	0.10	−3
LBY108	91422.2	—	—	—	29.8	0.23	−1	—	—	—
LBY108	91423.1	—	—	—	28.2	0.05	−7	21.1	L	−6
LBY310	91381.11	—	—	—	—	—	—	21.8	0.10	−3
LBY310	91381.6	—	—	—	28.7	0.08	−5	21.7	0.16	−4
LBY310	91381.9	—	—	—	28.1	0.11	−7	21.1	L	−6
CONT.	—	—	—	—	30.2	—	—	22.5	—	—
LBY79	92223.3	—	—	—	—	—	—	18.7	0.14	−4
LBY72	92764.1	—	—	—	25.2	0.14	−2	—	—	—
LBY72	92766.4	—	—	—	—	—	—	18.4	0.03	−6
LBY36	92526.1	—	—	—	23.9	0.14	−7	18.2	L	−7
LBY36	92526.2	—	—	—	—	—	—	19.0	0.10	−3
LBY32	92830.3	—	—	—	24.9	0.03	−3	18.3	L	−6
LBY32	92830.4	—	—	—	—	—	—	19.0	0.10	−3
LBY32	92832.1	—	—	—	—	—	—	18.8	0.08	−4
LBY30	92326.1	—	—	—	25.0	0.25	−2	18.4	0.03	−6
LBY233	92474.3	—	—	—	24.9	0.15	−3	—	—	—
LBY233	92477.1	—	—	—	24.6	0.04	−4	18.3	0.06	−6
LBY233	92477.2	—	—	—	24.7	0.11	−4	—	—	—
LBY233	92477.3	—	—	—	—	—	—	18.2	L	−7
LBY214	92760.3	—	—	—	25.2	0.12	−2	18.3	L	−6
LBY204	92827.1	—	—	—	—	—	—	18.6	0.01	−5
LBY204	92828.1	—	—	—	25.1	0.20	−2	—	—	—
LBY187	92810.1	—	—	—	—	—	—	18.5	L	−5
LBY187	92812.1	—	—	—	24.8	0.04	−3	18.4	0.03	−6
LBY187	92812.3	—	—	—	25.3	0.28	−1	—	—	—
LBY165	92678.1	—	—	—	25.3	0.20	−1	—	—	—
LBY165	92678.3	—	—	—	24.2	0.02	−5	18.3	0.06	−6
LBY137	92751.1	—	—	—	—	—	—	18.7	0.16	−4
LBY137	92752.1	—	—	—	25.0	0.11	−2	18.6	0.21	−5
LBY127	92748.2	—	—	—	24.6	0.15	−4	18.7	0.02	−4
LBY126	92834.3	—	—	—	—	—	—	19.0	0.10	−3
LBY107	92284.1	—	—	—	—	—	—	18.3	0.06	−6
CONT.	—	—	—	—	25.6	—	—	19.5	—	—
LGN60	89174.2	1195.7	0.12	8	—	—	—	—	—	—
LGN60	89175.2	—	—	—	46.7	0.24	−3	38.0	0.09	−4
LGN60	89176.1	—	—	—	—	—	—	38.4	0.18	−3
LGN60	89176.3	—	—	—	45.4	0.02	−6	38.0	0.09	−3
CONT.	—	1109.1	—	—	48.1	—	—	39.4	—	—
LGN49	89079.3	1069.2	0.16	7	—	—	—	—	—	—
LGN49	89081.3	1158.3	0.03	16	—	—	—	38.1	0.02	−2
LGN49	89081.6	1117.9	0.09	12	45.1	0.12	−3	38.0	0.02	−2
LGN49	89082.1	—	—	—	—	—	—	38.0	0.01	−2
CONT.	—	998.2	—	—	45.9	—	—	38.2	—	—
LGN2	89029.2	—	—	—	46.9	0.08	−3	—	—	—
LGN2	89032.3	1180.4	0.10	8	—	—	—	—	—	—
CONT.	—	1090.4	—	—	48.6	—	—	—	—	—
LGN5	88198.1	—	—	—	45.2	0.02	−4	—	—	—
LGN5	88198.4	—	—	—	44.6	L	−6	38.0	0.19	−0
LGN5	88201.3	—	—	—	46.3	0.25	−2	38.0	0.19	−0
CONT.	—	—	—	—	47.3	—	—	38.1	—	—
LGN54	88207.2	1233.8	0.12	14	—	—	—	—	—	—
CONT.	—	1082.6	—	—	—	—	—	—	—	—
LGN6	89169.2	—	—	—	—	—	—	33.9	0.29	−2
CONT.	—	—	—	—	—	—	—	34.7	—	—
LGN36	89044.1	1027.9	0.10	16	—	—	—	—	—	—
CONT.	—	889.6	—	—	—	—	—	—	—	—
LBY79	92221.2	—	—	—	24.8	0.19	−6	19.0	0.04	−2
LBY72	92765.1	—	—	—	25.2	0.01	−5	19.0	0.04	−2
LBY72	92766.2	—	—	—	25.0	0.10	−6	—	—	—
LBY72	92766.4	—	—	—	26.0	0.14	−2	—	—	—
LBY36	92526.1	—	—	—	—	—	—	19.1	0.08	−2
LBY32	92830.1	—	—	—	25.1	0.20	−5	19.0	0.04	−2
LBY32	92830.3	—	—	—	25.0	L	−6	19.0	0.04	−2
LBY32	92830.4	—	—	—	25.7	0.16	−3	19.1	0.08	−2
LBY32	92832.1	—	—	—	25.4	L	−4	19.0	0.04	−2
LBY32	92833.2	—	—	—	25.6	0.07	−3	19.1	0.08	−2
LBY26	92484.4	—	—	—	24.5	L	−8	19.0	0.04	−2
LBY26	92484.5	—	—	—	24.7	0.04	−7	19.1	0.08	−2
LBY233	92474.3	—	—	—	24.2	L	−9	19.0	0.04	−2
LBY233	92477.3	—	—	—	25.6	0.01	−3	—	—	—
LBY233	92478.3	—	—	—	25.2	0.04	−5	—	—	—
LBY214	92760.3	—	—	—	24.5	0.11	−7	19.0	0.04	−2
LBY214	92760.4	—	—	—	26.0	0.14	−2	—	—	—
LBY210	92845.2	—	—	—	25.2	0.01	−5	19.0	0.04	−2
LBY210	92845.4	—	—	—	24.8	L	−6	19.1	0.08	−2
LBY204	92826.1	—	—	—	—	—	—	19.0	0.04	−2
LBY204	92827.1	—	—	—	25.8	0.12	−3	—	—	—
LBY204	92828.1	—	—	—	25.2	0.25	−5	—	—	—
LBY204	92828.3	—	—	—	26.2	0.29	−1	—	—	—
LBY196	91300.1	—	—	—	25.6	0.07	−3	19.0	0.04	−2
LBY196	91303.2	—	—	—	25.0	L	−6	19.1	0.08	−2
LBY187	92810.1	—	—	—	26.0	0.09	−2	—	—	—
LBY187	92812.3	—	—	—	25.5	0.27	−4	—	—	—
LBY187	92813.2	—	—	—	25.4	0.17	−4	19.1	0.08	−2
LBY154	92432.3	—	—	—	25.8	0.02	−3	—	—	—
LBY154	92433.4	—	—	—	26.0	0.20	−2	—	—	—
LBY137	92751.1	—	—	—	25.5	0.27	−4	—	—	—
LBY137	92751.2	—	—	—	25.8	0.07	−2	—	—	—
LBY137	92751.5	—	—	—	25.1	0.20	−5	—	—	—
LBY126	92834.3	—	—	—	26.0	0.19	−2	—	—	—
LBY126	92837.2	—	—	—	26.1	0.14	−1	—	—	—
LBY126	92837.3	—	—	—	25.4	0.19	−4	—	—	—
LBY126	92837.4	—	—	—	26.1	0.18	−1	—	—	—
LBY126	92838.1	—	—	—	24.6	L	−7	19.0	0.04	−2
LBY120	91214.1	—	—	—	25.6	0.04	−3	—	—	—
LBY113	92234.2	—	—	—	26.1	0.20	−1	—	—	—
CONT.	—	—	—	—	26.5	—	—	19.4	—	—
LBY83	91332.2	—	—	—	47.2	0.11	−2	39.2	0.21	−2
LBY63	91325.2	1548.1	L	13	—	—	—	—	—	—
LBY51	90981.1	—	—	—	45.9	0.21	−5	37.6	L	−6
LBY51	90981.4	1431.2	0.21	4	—	—	—	—	—	—
LBY48	90967.3	1446.9	0.07	5	47.2	0.11	−2	—	—	—
LBY224	91528.4	—	—	—	—	—	—	39.2	0.21	−2
LBY224	91529.1	—	—	—	—	—	—	39.0	0.08	−2
LBY22	90962.4	1637.5	L	19	—	—	—	—	—	—
LBY196	91303.2	1430.0	0.28	4	—	—	—	—	—	—
LBY196	91304.2	1531.7	0.19	12	—	—	—	—	—	—
LBY818	91557.3	—	—	—	47.2	0.18	−3	—	—	—
LBY150	91644.3	—	—	—	—	—	—	39.0	0.08	−2
LBY134	91282.1	1711.3	L	25	46.0	0.11	−5	38.1	0.10	−5
LBY313	91138.1	1454.1	0.29	6	—	—	—	—	—	—
LBY132	91277.1	1473.8	0.23	7	—	—	—	—	—	—
LBY132	91279.3	—	—	—	46.7	0.03	−4	38.1	0.02	−5
LBY125	91273.3	—	—	—	47.3	0.10	−2	38.7	0.07	−3
LBY102	91262.1	1725.7	0.23	26	—	—	—	—	—	—
CONT.	—	1371.8	—	—	48.4	—	—	39.9	—	—
NUE102	90003.5	1100.4	0.12	15	—	—	—	—	—	—
NUE102	90004.1	—	—	—	44.5	0.26	−3	34.8	0.02	−10
CONT.	—	959.8	—	—	46.1	—	—	38.6	—	—
LGN24	89094.2	968.8	L	9	—	—	—	—	—	—
LGN24	89096.2	968.8	0.22	9	—	—	—	—	—	—
CONT.	—	891.6	—	—	—	—	—	—	—	—
LBY91	91634.2	1431.9	0.20	12	34.5	0.16	−6	—	—	—
LBY91	91634.3	—	—	—	35.5	0.04	−4	28.7	0.28	−2
LBY81	92009.1	—	—	—	35.5	0.04	−4	28.2	0.03	−4
LBY81	92013.1	—	—	—	—	—	—	28.6	0.13	−2
LBY81	92013.2	1333.8	0.14	4	35.7	0.11	−3	27.9	0.01	−5
LBY77	92061.2	—	—	—	—	—	—	28.6	0.30	−2
LBY77	92062.1	1360.6	0.04	6	35.5	0.04	−4	28.3	0.05	−3
LBY77	92063.6	1340.6	0.21	4	—	—	—	—	—	—
LBY54	92084.4	1389.4	0.28	8	—	—	—	—	—	—
LBY54	92087.3	—	—	—	—	—	—	28.5	0.09	−3
LBY49	92039.4	—	—	—	—	—	—	28.1	0.02	−4
LBY35	92123.1	—	—	—	—	—	—	28.8	0.30	−2
LBY29	91619.1	—	—	—	—	—	—	28.7	0.28	−2
LBY29	91619.2	—	—	—	35.8	0.10	−3	28.7	0.28	−2
LBY29	91619.2	—	—	—	35.2	0.02	−4	28.6	0.30	−2
LBY23	91396.3	1431.9	0.27	12	—	—	—	28.7	0.28	−2
LBY23	91397.2	—	—	—	—	—	—	28.6	0.30	−2
LBY23	91398.2	1523.8	L	19	—	—	—	—	—	—
LBY174	92079.8	1411.2	0.29	10	—	—	—	—	—	—
LBY158	91647.3	—	—	—	—	—	—	28.8	0.28	−2
LBY158	91649.1	1515.0	0.05	18	—	—	—	—	—	—
LBY146	91590.2	—	—	—	34.9	L	−5	27.3	0.15	−7
LBY146	91590.4	—	—	—	—	—	—	28.2	0.03	−4
LBY146	91593.3	1421.5	0.26	11	35.0	0.01	−5	26.9	0.13	−8
LBY138	92075.2	1474.4	L	15	—	—	—	—	—	—
LBY138	92076.1	—	—	—	—	—	—	28.6	0.30	−2
LBY117	91366.3	1451.2	0.26	13	33.5	L	−9	26.6	0.02	−9
LBY117	91367.1	1414.5	0.06	10	—	—	—	—	—	—
LBY117	91367.2	—	—	—	—	—	—	28.6	0.13	−2
LBY115	92073.1	—	—	—	35.8	0.10	−3	28.5	0.09	−3
LBY112	92053.6	1483.1	0.03	16	—	—	—	—	—	—
LBY108	91422.2	—	—	—	—	—	—	28.7	0.28	−2
LBY108	91423.1	—	—	—	34.7	L	−6	28.1	0.02	−4
LBY108	91423.4	—	—	—	—	—	—	28.3	0.10	−3
LBY108	91423.3	1372.5	0.25	7	—	—	—	—	—	—
LBY104	91269.5	1600.6	0.07	25	—	—	—	—	—	—
LBY103	91381.9	1390.0	0.27	8	—	—	—	28.8	0.30	−2
CONT.	—	1283.2	—	—	36.8	—	—	29.3	—	—
LGN2	89029.2	—	—	—	41.8	0.03	−5	32.9	0.02	−4
CONT.	—	—	—	—	44.0	—	—	34.3	—	—
LGN26	89037.4	1229.1	0.01	26	—	—	—	—	—	—
CONT.	—	973.8	—	—	—	—	—	—	—	—
NUE102	90005.2	—	—	—	46.6	0.18	−2	36.8	0.19	−3
CONT.	—	—	—	—	47.7	—	—	38.0	—	—
LGN60	89174.2	—	—	—	45.5	0.06	−2	38.2	0.11	−1
LGN60	89175.1	—	—	—	46.1	0.16	−3	38.0	L	−2
LGN60	89175.2	1125.7	0.21	8	46.5	0.19	−2	—	—	—
LGN60	89176.3	1192.9	0.05	14	45.1	0.01	−3	38.2	0.10	−1
CONT.	—	1044.1	—	—	46.5	—	—	38.3	—	—
LBY91	91630.1	—	—	—	36.5	0.29	−2	—	—	—
LBY91	91633.1	—	—	—	36.5	0.16	−2	—	—	—
LBY77	92062.1	—	—	—	36.6	0.23	−2	—	—	—
LBY54	92084.4	—	—	—	36.5	0.20	−2	—	—	—
LBY54	92086.1	—	—	—	36.4	0.11	−3	—	—	—
LBY35	92120.2	—	—	—	36.7	0.25	−2	—	—	—
LBY29	91617.1	—	—	—	35.9	0.27	−4	27.6	0.13	−5
LBY25	91335.2	—	—	—	—	—	—	28.6	0.23	−1
LBY230	91665.1	—	—	—	36.4	0.12	−3	—	—	—
LBY230	91667.2	—	—	—	36.6	0.20	−2	—	—	—
LBY230	91669.2	—	—	—	35.3	0.12	−6	—	—	—
LBY225	91605.3	—	—	—	35.8	0.03	−4	—	—	—
LBY225	91607.3	—	—	—	35.3	0.22	−6	—	—	—
LBY225	91607.5	—	—	—	35.5	0.06	−5	27.1	0.10	−6
LBY225	91607.6	—	—	—	36.0	0.12	−4	28.0	L	−3
LBY217	92363.1	—	—	—	36.5	0.20	−2	—	—	—
LBY213	92033.1	—	—	—	35.8	0.20	−4	—	—	—
LBY212	92024.3	—	—	—	36.2	0.10	−3	—	—	—
LBY202	92022.1	—	—	—	36.1	0.06	−3	—	—	—
LBY202	92022.2	—	—	—	36.6	0.20	−2	—	—	—
LBY319	91660.2	—	—	—	—	—	—	28.6	0.23	−1
LBY319	91664.5	—	—	—	36.6	0.21	−2	—	—	—
LBY218	92398.3	—	—	—	36.5	0.17	−2	—	—	—
LBY316	91442.9	—	—	—	36.5	0.15	−2	—	—	—
LBY118	91432.5	—	—	—	36.4	0.12	−3	—	—	—
LBY118	91432.5	—	—	—	36.4	0.12	−3	—	—	—
LBY118	91434.4	—	—	—	36.7	0.25	−2	—	—	—
CONT.	—	—	—	—	37.4	—	—	28.9	—	—
LGN49	89081.1	1065.0	0.09	8	—	—	—	—	—	—
LGN49	89081.3	1162.9	0.20	9	—	—	—	—	—	—
LGN49	89081.6	1095.8	0.05	11	—	—	—	—	—	—
CONT.	—	1065.3	—	—	—	—	—	—	—	—

Table 241. “CONT.”=Control; “Ave.”=Average; “% Incr.”=% increment; “p-val.”=p-value, L=p<0.01. It should be noted that a negative increment (in percentages) when found in flowering or inflorescence emergence indicates drought avoidance of the plant.

TABLE 242
Genes showing improved plant performance at Normal
growth conditions under regulation of At6669 promoter
		Leaf Blade Area [cm2]	Leaf Number	Plot Coverage [cm2]
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY30	92324.4	1.06	L	17	11.5	0.13	10	68.6	L	29
LBY30	92326.2	0.962	0.18	7	—	—	—	—	—	—
LBY225	91607.5	0.971	0.12	8	—	—	—	60.3	0.22	14
LBY225	91607.6	—	—	—	11.1	0.11	6	—	—	—
LBY193	91662.1	0.969	0.25	8	—	—	—	58.9	0.08	11
LBY174	92079.1	0.973	0.16	8	—	—	—	—	—	—
LBY158	91649.1	1.04	0.15	16	—	—	—	63.3	0.05	19
LBY146	91590.4	0.985	0.14	9	—	—	—	—	—	—
LBY139	92241.2	1.04	L	15	—	—	—	64.0	0.02	21
LBY135	92321.1	—	—	—	11.1	0.11	6	58.9	0.28	11
LBY135	92321.6	1.08	0.19	20	11.1	0.11	6	68.3	0.27	29
LBY113	92234.1	0.963	0.14	7	—	—	—	—	—	—
LBY113	92234.5	1.01	0.22	13	—	—	—	—	—	—
LBY113	92234.6	—	—	—	—	—	—	57.3	0.29	8
CONT.	—	0.900	—	—	10.4	—	—	53.0	—	—
LGN5	88198.1	1.00	0.05	9	—	—	—	—	—	—
LGN5	88198.4	1.08	0.09	7	11.8	0.02	6	65.2	0.07	10
LGN5	88201.3	1.07	0.09	16	12.2	0.18	9	69.2	0.15	17
CONT.	—	1.01	—	—	11.1	—	—	59.3	—	—
LBY97	92034.3	1.03	0.04	11	11.1	0.24	12	66.5	0.01	26
LBY97	92038.2	—	—	—	10.6	L	7	—	—	—
LBY87	92255.1	1.16	L	25	11.1	0.10	12	73.2	L	38
LBY87	92257.1	—	—	—	10.6	0.30	7	—	—	—
LBY81	92009.1	1.15	L	74	—	—	—	68.3	0.15	29
LBY55	92419.1	—	—	—	10.2	0.16	3	—	—	—
LBY25	91337.1	—	—	—	10.1	0.20	2	—	—	—
LBY230	91669.3	0.991	0.16	7	—	—	—	—	—	—
LBY217	92362.1	0.985	0.21	6	10.5	0.23	6	58.1	0.10	10
LBY138	92076.1	—	—	—	10.4	0.10	5	—	—	—
LBY138	92078.1	0.987	0.18	6	10.1	0.29	2	56.9	0.17	8
LBY138	92078.4	1.12	L	21	10.9	0.03	10	70.5	L	34
LBY136	91442.9	1.10	L	18	10.4	L	5	63.9	0.02	21
LBY135	92321.6	1.15	0.15	24	10.2	0.04	3	67.7	0.09	28
LBY120	91210.2	1.04	0.18	13	—	—	—	—	—	—
LBY120	91211.2	—	—	—	10.8	0.09	9	—	—	—
LBY118	91432.3	1.19	L	28	11.4	0.11	15	71.7	L	36
LBY118	91433.1	—	—	—	10.8	0.16	8	—	—	—
LBY118	91434.5	1.13	0.03	22	—	—	—	64.5	0.01	22
LBY117	91366 .3	—	—	—	10.6	0.14	7	58.9	0.20	11
LBY115	92073.5	1.07	0.01	16	10.6	L	7	64.3	0.03	22
LBY112	92051.1	1.29	L	39	11.4	0.15	15	79.1	0.09	50
LBY112	92051.3	1.08	L	16	11.4	0.01	15	67.9	L	29
LBY112	92053.2	—	—	—	10.2	0.16	3	—	—	—
LBY112	92053.6	1.10	L	19	—	—	—	62.5	0.04	18
LBY108	91422.2	—	—	—	10.1	0.19	2	—	—	—
LBY108	91423.1	—	—	—	10.1	0.29	2	57.2	0.15	8
LBY108	91423.4	1.27	L	37	11.2	0.27	14	78.0	0.10	48
LBY103	91381.11	1.03	0.05	12	—	—	—	—	—	—
LBY103	91381.3	0.994	0.14	7	10.1	0.29	2	59.4	0.08	13
LBY103	91381.6	1.07	0.29	15	—	—	—	—	—	—
LBY103	91381.9	1.08	L	16	11.4	0.15	15	69.8	L	32
CONT.	—	0.927	—	—	9.91	—	—	52.8	—	—
LBY96	92428.4	—	—	—	11.8	0.12	4	—	—	—
LBY79	92221.2	—	—	—	—	—	—	87.8	0.22	12
LBY72	92764.1	1.46	0.04	8	12.7	0.08	12	88.8	0.19	13
LBY72	92765.3	—	—	—	12.3	0.13	9	84.0	0.06	7
LBY72	92766.4	—	—	—	12.4	0.07	9	88.2	0.09	12
LBY36	92526.1	1.56	0.20	15	12.2	0.08	8	97.9	L	24
LBY32	92830.3	1.59	0.21	17	—	—	—	—	—	—
LBY30	92326.1	1.48	L	9	11.6	0.18	3	88.2	L	12
LBY233	92477.1	1.49	0.06	10	12.1	0.11	7	93.5	0.20	19
LBY233	92477.2	1.55	L	14	11.8	0.07	4	93.7	L	19
LBY214	92760.1	—	—	—	11.8	0.16	4	—	—	—
LBY214	92760.3	—	—	—	12.0	0.15	6	83.6	0.07	6
LBY214	92760.4	1.50	0.11	10	—	—	—	—	—	—
LBY210	92845.2	—	—	—	11.9	0.03	5	—	—	—
LBY210	92846.2	1.44	0.17	6	12.0	0.03	6	—	—	—
LBY204	92827.1	1.66	0.17	22	—	—	—	102.6	0.26	30
LBY204	92828.3	1.65	L	22	12.6	0.01	11	101.7	0.02	29
LBY165	92677.7	1.42	0.08	5	—	—	—	—	—	—
LBY165	92678.3	1.53	0.19	13	—	—	—	89.7	L	14
LBY137	92750.1	1.49	0.26	10	—	—	—	—	—	—
LBY137	92752.1	1.60	0.12	18	—	—	—	92.6	L	18
LBY126	92834.3	—	—	—	—	—	—	88.2	L	12
LBY126	92837.4	—	—	—	12.0	0.29	6	—	—	—
LBY126	92838.1	—	—	—	11.8	0.16	4	—	—	—
LBY110	91176.6	1.41	0.29	4	—	—	—	—	—	—
LBY110	91179.2	1.50	L	10	11.9	0.03	5	90.0	L	14
LBY107	92285.2	1.41	0.15	4	11.7	0.27	3	85.0	0.07	8
CONT.	—	1.36	—	—	11.3	—	—	78.6	—	—
LGN60	89175.1	0.844	0.09	7	10.2	0.25	1	49.5	0.02	15
LGN60	89175.2	0.869	0.18	10	—	—	—	50.0	0.12	16
LGN60	89176.1	0.834	0.14	6	—	—	—	46.7	0.12	8
LGN60	89176.3	0.896	0.07	13	10.8	0.12	5	55.1	0.04	28
CONT.	—	0.790	—	—	10.2	—	—	43.2	—	—
LGN49	89081.1	0.959	0.29	10	11.1	0.26	5	58.9	0.23	18
LGN49	89081.3	0.980	0.21	13	11.4	0.29	8	61.6	0.17	23
LGN49	89081.6	1.05	0.27	10	12.2	L	15	66.4	0.12	22
CONT.	—	0.953	—	—	10.6	—	—	54.4	—	—
LGN2	89029.2	1.04	0.22	5	11.8	0.02	7	68.1	0.04	13
CONT.	—	0.986	—	—	11.0	—	—	60.1	—	—
LGN5	88198.4	1.11	L	18	10.9	0.03	8	67.2	L	28
LGN5	88201.3	1.02	0.09	9	11.0	0.10	9	63.0	0.03	20
LGN5	88203.2	—	—	—	—	—	—	57.8	0.25	10
CONT.	—	0.935	—	—	10.1	—	—	52.4	—	—
LGN24	89094.2	0.967	L	26	10.4	0.24	5	58.2	L	26
CONT.	—	0.769	—	—	9.91	—	—	46.2	—	—
LGN6	89169.2	—	—	—	11.5	0.01	10	—	—	—
CONT.	—	—	—	—	10.5	—	—	—	—	—
LBY79	92221.3	—	—	—	11.9	0.17	5	87.7	0.29	15
LBY72	92764.1	1.64	L	27	12.2	0.25	7	97.2	0.10	27
LBY72	92765.1	1.67	L	30	—	—	—	102.8	0.15	34
LBY72	92766.4	1.44	0.06	12	11.8	0.20	4	88.3	0.09	15
LBY36	92526.1	1.40	L	8	—	—	—	85.6	0.22	12
LBY32	92830.1	1.56	L	21	12.1	0.20	6	98.1	0.11	28
LBY32	92830.3	1.48	L	15	11.8	0.26	4	93.1	0.09	22
LBY32	92832.1	1.39	0.24	8	—	—	—	85.4	0.10	12
LBY32	92833.2	1.42	0.05	10	—	—	—	—	—	—
LBY26	92484.4	1.67	0.10	29	12.2	0.03	8	102.0	0.04	33
LBY26	92484.5	1.37	0.07	7	—	—	—	81.0	0.01	6
LBY26	92488.1	1.41	0.20	10	—	—	—	86.4	0.02	13
LBY233	92477.1	1.35	0.01	5	12.0	0.17	6	81.4	0.30	6
LBY233	92478.3	—	—	—	12.2	0.15	7	—	—	—
LBY214	92760.1	1.44	0.11	11	—	—	—	90.0	0.01	18
LBY214	92760.3	1.47	0.27	14	—	—	—	—	—	—
LBY210	92845.2	1.47	0.17	14	—	—	—	—	—	—
LBY210	92845.4	1.43	0.14	11	—	—	—	82.8	L	8
LBY210	92846.2	1.41	0.03	10	—	—	—	80.4	0.20	5
LBY204	92826.1	—	—	—	12.1	0.10	6	—	—	—
LBY204	92827.1	—	—	—	—	—	—	86.5	L	13
LBY204	92828.1	1.41	0.03	10	—	—	—	—	—	—
LBY204	92828.3	—	—	—	—	—	—	85.2	0.27	11
LBY196	91303.2	1.60	0.02	24	—	—	—	100.2	0.21	31
LBY187	92809.2	1.49	0.27	16	12.7	0.01	12	92.5	0.20	21
LBY187	92812.3	1.42	0.19	10	12.2	0.28	8	88.2	0.23	15
LBY154	92432.1	—	—	—	11.8	0.20	4	—	—	—
LBY154	92432.3	—	—	—	12.1	0.10	6	—	—	—
LBY126	92837.3	1.37	0.17	7	—	—	—	82.6	0.17	8
LBY126	92837.4	—	—	—	12.6	0.02	11	79.9	0.11	4
LBY126	92838.1	—	—	—	12.5	0.01	10	83.6	0.23	9
LBY120	91210.2	1.34	0.24	4	—	—	—	77.9	0.29	2
LBY120	91214.1	—	—	—	12.5	0.01	10	84.8	0.24	11
LBY113	92234.2	—	—	—	11.8	0.26	4	—	—	—
LBY113	92235.2	1.33	L	3	—	—	—	—	—	—
LBY107	92284.3	1.38	0.28	7	—	—	—	—	—	—
CONT.	—	1.29	—	—	11.4	—	—	76.4	—	—
LBY83	91330.1	0.730	0.03	13	—	—	—	42.7	0.10	12
LBY83	91330.2	0.816	0.15	26	—	—	—	51.8	0.06	36
LBY83	91332.1	0.726	0.10	12	—	—	—	44.0	0.03	15
LBY83	91332.2	0.706	0.09	9	—	—	—	—	—	—
LBY63	91326.1	—	—	—	10.2	0.17	2	—	—	—
LBY51	90981.1	—	—	—	—	—	—	42.2	0.09	11
LBY48	90968.1	0.764	0.01	18	—	—	—	45.2	0.01	19
LBY48	90968.2	0.750	0.10	16	—	—	—	43.5	0.07	14
LBY224	91527.4	—	—	—	—	—	—	43.4	0.29	14
LBY224	91528.3	0.686	0.22	6	—	—	—	—	—	—
LBY224	91529.1	0.725	0.25	12	10.4	0.15	3	43.8	0.11	15
LBY22	90961.2	—	—	—	—	—	—	43.3	0.17	14
LBY22	90965.5	0.734	0.29	14	—	—	—	43.6	0.10	14
LBY196	91300.1	0.708	0.07	9	—	—	—	43.3	0.04	14
LBY196	91303.2	0.774	0.02	20	—	—	—	45.2	0.29	19
LBY150	91644.3	0.787	L	22	10.7	0.09	6	47.9	L	26
LBY133	91139.4	0.788	0.10	22	11.1	0.23	10	49.3	0.05	29
LBY132	91277.1	0.847	L	31	—	—	—	52.6	0.20	38
LBY132	91279.3	0.881	L	36	11.0	L	9	54.9	0.03	44
LBY125	91273.2	—	—	—	10.2	0.17	2	—	—	—
LBY125	91273.3	0.826	0.08	28	—	—	—	51.3	0.10	35
LBY102	91262.1	0.699	0.21	8	—	—	—	42.6	0.17	12
CONT.	—	0.647	—	—	10.0	—	—	38.1	—	—
NUE102	90003.5	0.824	0.05	11	—	—	—	49.1	0.15	15
NUE102	90004.1	0.785	0.21	6	—	—	—	47.2	0.27	11
CONT.	—	0.741	—	—	—	—	—	42.7	—	—
LGN24	89094.2	0.991	0.02	14	11 .0	0.14	5	64.8	0.04	19
LGN24	89094.3	0.922	0.18	6	11.1	0.10	7	60.2	0.16	11
LGN24	89096.2	—	—	—	11.0	0.19	5	—	—	—
CONT.	—	0.867	—	—	10.4	—	—	54.4	—	—
LBY91	91634.2	1.53	0.27	9	—	—	—	—	—	—
LBY91	91634.3	1.59	0.06	14	—	—	—	99.8	0.16	13
LBY81	92013.1	1.60	0.28	14	—	—	—	—	—	—
LBY81	92013.2	1.68	0.21	20	—	—	—	108.0	0.06	22
LBY77	92061.2	1.70	0.01	21	12.6	0.20	4	113.9	0.01	29
LBY77	92062.1	1.87	L	33	—	—	—	116.5	L	32
LBY49	92039.4	1.59	0.20	14	—	—	—	98.2	0.25	11
LBY35	92119.2	1.50	0.29	7	—	—	—	—	—	—
LBY35	92123.2	1.55	0.12	11	—	—	—	—	—	—
LBY29	91619.1	1.53	0.17	9	—	—	—	99.6	0.17	13
LBY29	91619.5	1.64	0.02	17	—	—	—	102.5	0.14	16
LBY23	91396.3	1.61	0.09	15	—	—	—	103.4	0.22	17
LBY23	91397.2	1.50	0.29	7	—	—	—	—	—	—
LBY23	91398.2	1.53	0.29	9	—	—	—	—	—	—
LBY174	92079.1	1.56	0.11	11	—	—	—	101.6	0.19	15
LBY174	92080.1	1.54	0.14	10	—	—	—	97.2	0.30	10
LBY158	91647.3	—	—	—	13.2	0.04	9	100.9	0.24	14
LBY158	91649.1	1.60	0.08	14	—	—	—	104.8	0.26	19
LBY146	91593.3	1.59	0.06	13	—	—	—	107.4	0.05	21
LBY138	92075.2	—	—	—	—	—	—	97.2	0.28	10
LBY138	92076.1	1.54	0.16	10	—	—	—	—	—	—
LBY117	91366.3	1.55	0.11	11	—	—	—	—	—	—
LBY115	92071.2	1.53	0.18	9	—	—	—	—	—	—
LBY115	92071.3	1.53	0.30	9	—	—	—	—	—	—
LBY115	92073.1	1.58	0.07	13	—	—	—	101.3	0.12	15
LBY112	92051.3	1.70	0.27	22	—	—	—	—	—	—
LBY108	91422.2	1.58	0.07	13	—	—	—	100.1	0.15	13
LBY108	91423.1	1.73	0.19	24	—	—	—	107.3	0.05	21
LBY104	91267.4	—	—	—	12.6	0.20	4	—	—	—
LBY104	91269.2	1.61	0.30	15	—	—	—	100.8	0.28	14
LBY103	91381.8	—	—	—	12.6	0.24	3	—	—	—
CONT.	—	1.40	—	—	12.1	—	—	88.4	—	—
LGN2	89029.2	1.05	L	31	11.0	0.05	13	67.7	L	46
LGN2	89032.3	0.891	0.06	11	—	—	—	—	—	—
CONT.	—	0.799	—	—	9.72	—	—	46.4	—	—
LGN26	89037.4	—	—	—	9.83	0.16	5	—	—	—
CONT.	—	—	—	—	9.38	—	—	—	—	—
LGN60	89175.2	0.923	0.23	6	10.5	0.04	4	52.7	0.05	8
LGN60	89176.3	0.999	0.01	15	11.0	L	9	60.3	0.08	11
CONT.	—	0.956	—	—	10.7	—	—	48.7	—	—
LBY77	92062.1	1.04	0.24	11	—	—	—	65.4	0.19	11
LBY54	92084.4	1.19	L	28	12.7	0.02	16	84.4	L	43
LBY54	92086.1	1.03	0.17	10	11.4	0.30	4	66.7	0.11	13
LBY29	91617.1	1.13	0.01	21	11.8	0.07	7	75.6	L	28
LBY29	91619.1	1.02	0.19	9	—	—	—	—	—	—
LBY25	91335.2	1.09	L	17	12.6	L	15	82.1	L	39
LBY230	91669.2	—	—	—	12.1	0.27	11	—	—	—
LBY23	91397.3	1.09	0.06	16	12.1	0.16	10	76.8	0.07	30
LBY225	91605.3	1.05	0.02	13	12.2	L	12	74.2	0.03	26
LBY225	91607.3	—	—	—	12.4	L	13	82.9	0.30	41
LBY225	91607.5	1.15	0.25	24	11.8	0.05	8	77.2	L	31
LBY217	92363.1	1.02	0.07	9	11.5	0.19	5	64.5	0.23	9
LBY213	92033.1	1.15	0.03	23	12.4	L	13	79.3	0.06	35
LBY212	92024.2	1.03	0.19	10	—	—	—	—	—	—
LBY212	92024.3	1.08	0.03	16	12.1	0.02	11	71.6	0.03	21
LBY202	92022.1	0.997	0.17	7	12.2	0.03	12	69.6	0.04	18
LBY182	92396.1	—	—	—	12.2	0.06	11	70.5	0.28	20
LBY136	91442.6	1.08	0.04	16	12.1	0.03	10	71.9	0.03	22
LBY136	91442.9	1.09	0.14	17	11.8	0.14	8	74.2	0.13	26
CONT.	—	0.933	—	—	11.0	—	—	59.0	—	—
LGN49	89081.3	—	—	—	10.6	0.13	8	—	—	—
LGN49	89081.6	1.05	0.27	12	10.7	0.12	9	61.2	0.08	19
CONT.	—	0.967	—	—	9.78	—	—	51.4	—	—

Table 242. “CONT.”=Control; “Ave.”=Average; “% Incr.”=% increment; “p-val.”=-p-value. L=p<0.01.

TABLE 243
Genes showing improved plant performance at Normal
growth conditions under regulation of At6669 promoter
		RGR Of Leaf				RGR Of Rosette
		Number	RGR Of Plot Coverage	Diameter
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN36	89046.1	—	—	—	—	—	—	0.279	0.23	6
CONT.	—	—	—	—	—	—	—	0.262	—	—
LBY30	92324.4	—	—	—	7.84	0.14	26	—	—	—
LBY158	91649.1	—	—	—	7.43	0.26	19	—	—	—
LBY139	92241.2	—	—	—	7.52	0.22	20	—	—	—
LBY135	92321.6	—	—	—	7.91	0.14	27	0.407	0.28	14
CONT.	—	—	—	—	6.24	—	—	0.357	—	—
LGN5	88198.4	—	—	—	7.27	0.06	9	0.376	L	9
LGN5	88201.3	—	—	—	7.60	0.24	14	—	—	—
CONT.	—	—	—	—	6.67	—	—	0.346	—	—
LBY97	92034.3	—	—	—	8.74	0.05	27	0.463	0.26	10
LBY87	92255.1	—	—	—	9.54	L	38	0.472	0.16	12
LBY81	92009.1	—	—	—	8.84	0.05	28	0.474	0.14	12
LBY138	92078.4	—	—	—	9.22	0.02	34	0.468	0.19	11
LBY136	91442.9	—	—	—	8.31	0.12	21	0.466	0.22	10
LBY135	92321.6	—	—	—	8.87	0.04	29	0.478	0.13	13
LBY135	92323.1	—	—	—	—	—	—	0.492	0.10	16
LBY118	91432.3	0.814	0.10	25	9.37	0.01	36	0.478	0.11	13
LBY118	91434.5	—	—	—	8.32	0.12	21	—	—	—
LBY115	92073.5	—	—	—	8.35	0.12	21	—	—	—
LBY112	92051.1	0.797	0.13	22	10.3	L	50	0.513	0.02	21
LBY112	92051.3	0.808	0.10	24	8.79	0.05	28	0.469	0.19	11
LBY112	92053.6	—	—	—	8.16	0.18	18	—	—	—
LBY108	91423.4	—	—	—	10.2	L	48	0.512	0.02	21
LBY103	91381.9	—	—	—	9.08	0.02	32	0.460	0.28	9
CONT.	—	0.651	—	—	6.89	—	—	0.423	—	—
LBY72	92766.4	—	—	—	—	—	—	0.485	0.28	6
LBY36	92526.1	—	—	—	9.97	0.05	24	0.513	0.03	12
LBY32	92830.3	—	—	—	9.26	0.22	15	0.510	0.04	11
LBY32	92833.2	—	—	—	9.30	0.20	16	0.508	0.09	11
LBY30	92326.1	—	—	—	9.06	0.29	13	0.497	0.13	9
LBY233	92477.1	—	—	—	9.56	0.12	19	0.497	0.12	8
LBY233	92477.2	—	—	—	9.47	0.16	18	0.510	0.05	11
LBY214	92760.3	—	—	—	—	—	—	0.485	0.29	6
LBY210	92846.2	0.700	0.13	14	—	—	—	—	—	—
LBY204	92827.1	—	—	—	10.6	0.02	32	0.522	0.02	14
LBY204	92828.1	—	—	—	—	—	—	0.491	0.18	7
LBY204	92828.3	—	—	—	10.2	0.04	27	0.499	0.10	9
LBY187	92809.2	—	—	—	9.65	0.12	20	0.494	0.24	8
LBY165	92678.3	—	—	—	9.09	0.27	13	0.493	0.16	8
LBY137	92752.1	—	—	—	9.58	0.11	19	0.504	0.07	10
LBY110	91177.3	—	—	—	9.19	0.26	15	0.502	0.12	10
LBY110	91179.2	—	—	—	9.10	0.27	13	0.495	0.16	8
CONT.	—	0.614	—	—	8.02	—	—	0.458	—	—
LGN60	89175.1	—	—	—	5.76	L	18	0.331	L	10
LGN60	89175.2	—	—	—	5.70	0.10	17	0.315	0.28	4
LGN60	89176.1	—	—	—	5.37	0.06	10	—	—	—
LGN60	89176.3	—	—	—	6.20	0.06	27	0.330	0.17	9
CONT.	—	—	—	—	4.89	—	—	0.302	—	—
LGN49	89079.3	0.553	0.13	8	—	—	—	—	—	—
LGN49	89081.1	—	—	—	6.49	0.19	20	0.325	0.18	6
LGN49	89081.3	—	—	—	6.74	0.19	24	—	—	—
LGN49	89081.6	0.619	0.14	28	7.32	0.14	24	0.369	0.20	15
CONT.	—	0.485	—	—	5.93	—	—	0.321	—	—
LGN54	88207.3	0.597	0.21	10	—	—	—	—	—	—
LGN54	88208.2	0.567	0.07	8	—	—	—	—	—	—
CONT.	—	0.542	—	—	—	—	—	—	—	—
LGN2	89029.2	0.709	0.25	8	7.96	0.03	13	0.407	L	10
CONT.	—	0.659	—	—	7.04	—	—	0.369	—	—
LGN5	88198.4	—	—	—	7.61	0.01	25	0.386	0.12	6
LGN5	88201.3	—	—	—	7.22	0.05	19	0.363	0.29	4
LGN5	88203.2	—	—	—	6.60	0.29	9	—	—	—
CONT.	—	—	—	—	6.07	—	—	0.365	—	—
LGN24	89094.2	—	—	—	6.80	0.02	26	0.328	0.03	14
LGN24	89096.1	—	—	—	—	—	—	0.311	0.10	8
CONT.	—	—	—	—	5.40	—	—	0.288	—	—
LGN54	88206.4	0.568	0.29	10	—	—	—	—	—	—
CONT.	—	0.514	—	—	—	—	—	—	—	—
LGN6	89170.1	0.686	0.27	6	—	—	—	—	—	—
CONT.	—	0.647	—	—	—	—	—	—	—	—
LBY79	92221.3	—	—	—	10.9	0.18	15	—	—	—
LBY72	92764.1	—	—	—	11.9	0.03	24	0.540	0.05	11
LBY72	92765.1	—	—	—	12.7	L	33	0.551	0.03	13
LBY72	92766.4	—	—	—	10.9	0.18	14	0.521	0.21	7
LBY32	92830.1	—	—	—	12.1	0.02	27	0.543	0.04	12
LBY32	92830.3	—	—	—	11.3	0.11	18	0.548	0.03	13
LBY26	92484.4	—	—	—	12.5	L	31	0.567	0.02	17
LBY26	92488.1	—	—	—	10.8	0.20	13	—	—	—
LBY233	92474.3	—	—	—	11.1	0.19	16	—	—	—
LBY233	92477.1	—	—	—	—	—	—	0.522	0.20	7
LBY233	92478.3	—	—	—	11.0	0.19	15	0.525	0.25	8
LBY214	92760.1	—	—	—	11.2	0.10	17	0.531	0.10	9
LBY214	92760.3	—	—	—	10.8	0.29	13	0.545	0.11	12
LBY214	92760.4	—	—	—	—	—	—	0.525	0.30	8
LBY210	92845.2	—	—	—	10.7	0.28	12	0.542	0.05	12
LBY210	92845.4	—	—	—	—	—	—	0.538	0.07	11
LBY204	92826.1	—	—	—	10.7	0.30	12	—	—	—
LBY204	92827.1	—	—	—	—	—	—	0.539	0.06	11
LBY204	92828.3	—	—	—	—	—	—	0.518	0.27	7
LBY196	91303.2	—	—	—	12.3	0.01	29	0.561	0.01	15
LBY187	92809.2	—	—	—	11.4	0.09	19	0.539	0.07	11
LBY187	92812.3	—	—	—	10.9	0.17	15	—	—	—
LBY154	92432.1	0.845	0.20	15	—	—	—	—	—	—
LBY137	92751.2	—	—	—	—	—	—	0.519	0.23	7
LBY120	91214.1	0.874	0.10	19	10.7	0.24	12	0.537	0.08	10
CONT.	—	0.736	—	—	9.54	—	—	0.486	—	—
LBY83	91330.2	—	—	—	5.41	0.05	35	0.342	0.14	22
LBY48	90968.1	—	—	—	4.74	0.27	19	—	—	—
LBY224	91529.2	0.635	0.20	15	—	—	—	—	—	—
LBY196	91303.2	—	—	—	4.73	0.28	19	—	—	—
LBY196	91304.2	0.656	0.10	19	—	—	—	—	—	—
LBY150	91644.3	0.667	0.06	21	4.94	0.18	24	0.331	0.23	18
LBY133	91139.4	0.648	0.12	17	5.16	0.10	29	—	—	—
LBY132	91277.1	—	—	—	5.38	0.05	35	—	—	—
LBY132	91279.3	0.648	0.13	17	5.77	0.01	45	0.346	0.11	24
LBY125	91273.3	—	—	—	5.31	0.06	33	—	—	—
CONT.	—	0.552	—	—	3.99	—	—	0.280	—	—
LGN3	89069.4	0.689	0.20	16	—	—	—	—	—	—
LGN3	89072.3	0.638	0.25	7	—	—	—	—	—	—
LGN3	89072.4	0.687	0.15	15	—	—	—	—	—	—
LGN3	89073.1	0.644	0.16	8	—	—	—	—	—	—
CONT.	—	0.596	—	—	—	—	—	—	—	—
NUE102	90003.5	—	—	—	6.78	0.12	16	—	—	—
NUE102	90004.1	—	—	—	6.56	0.21	12	—	—	—
NUE102	90005.2	0.769	0.10	15	—	—	—	—	—	—
CONT.	—	0.671	—	—	5.84	—	—	—	—	—
LGN24	89094.2	—	—	—	7.75	0.05	19	0.364	0.17	6
LGN24	89094.3	0.734	0.09	9	7.24	0.18	11	0.360	0.25	5
LGN24	89096.2	0.719	0.28	7	—	—	—	—	—	—
CONT.	—	0 .671	—	—	6.53	—	—	0.343	—	—
LBY77	92061.2	—	—	—	13.2	0.19	29	—	—	—
LBY77	92062.1	—	—	—	13.5	0.15	31	—	—	—
CONT.	—	—	—	—	10.3	—	—	—	—	—
LGN2	89029.2	—	—	—	9.37	L	46	0.469	0.13	7
CONT.	—	—	—	—	6.40	—	—	0.437	—	—
LGN26	89037.3	0.647	0.24	7	—	—	—	—	—	—
LGN26	89037.4	0.651	0.23	8	—	—	—	—	—	—
CONT.	—	0.602	—	—	—	—	—	—	—	—
NUE102	90005.2	0.810	0.07	1.7	—	—	—	—	—	—
CONT.	—	0.693	—	—	—	—	—	—	—	—
LGN60	89175.2	—	—	—	6.32	0.01	12	0.371	0.22	9
LGN60	89176.3	0.604	0.03	11	7.00	0.10	11	0.365	0.28	7
CONT.	—	0.635	—	—	6.31	—	—	0.351	—	—
LBY54	92084.4	—	—	—	10.1	0.01	42	0.445	0.16	16
LBY29	91617.1	—	—	—	9.20	0.06	30	0.434	0.24	13
LBY25	91335.2	—	—	—	9.80	0.02	38	0.440	0.18	15
LBY230	91669.2	—	—	—	8.98	0.11	27	0.443	0.19	15
LBY23	91397.3	—	—	—	9.27	0.06	31	0.456	0.10	19
LBY225	91605.3	—	—	—	8.94	0.11	26	—	—	—
LBY225	91607.3	—	—	—	10.0	0.02	41	0.441	0.23	15
LBY225	91607.5	—	—	—	9.34	0.05	32	—	—	—
LBY213	92033.1	0.756	0.18	26	9.55	0.03	35	0.442	0.18	15
LBY212	92024.3	—	—	—	8.56	0.19	21	—	—	—
LBY182	92396.1	—	—	—	8.48	0.23	20	—	—	—
LBY136	91442.6	—	—	—	8.71	0.15	23	—	—	—
LBY136	91442.9	—	—	—	9.06	0.09	28	—	—	—
CONT.	—	0.599	—	—	7.08	—	—	0.384	—	—
LGN49	89081.6	—	—	—	6.86	0.09	18	—	—	—
CONT.	—	—	—	—	5.80	—	—	—	—	—

Table 243. “CONT.”=Control; “Ave.”=Average; “% Incr.”=% increment; “p-val.”=p-value, L=p<0.01. RGR=relative growth rate.

TABLE 244
Genes showing improved plant performance at Normal
growth conditions under regulation of At6669 promoter
					Rosette Area	Rosette Diameter
		Harvest Index	[cm2]	[cm]
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY87	92256.1	0.237	0.20	14	—	—	—	—	—	—
LBY30	92324.4	—	—	—	8.58	L	29	5.05	L	10
LBY30	92326.2	—	—	—	—	—	—	4.91	0.06	7
LBY225	91605.3	0.241	0.06	16	—	—	—	—	—	—
LBY225	91607.3	0.245	0.05	18	—	—	—	—	—	—
LBY225	91607.5	—	—	—	7.54	0.22	14	4.71	0.29	3
LBY212	92026.4	0.246	0.29	19	—	—	—	—	—	—
LBY202	92022.1	0.224	0.29	8	—	—	—	—	—	—
LBY193	91660.2	0.254	0.06	23	—	—	—	—	—	—
LBY193	91662.1	0.229	0.30	10	7.36	0.08	11	4.90	0.15	7
LBY174	92079.1	—	—	—	—	—	—	4.72	0.20	3
LBY158	91648.1	—	—	—	—	—	—	4.82	0.17	5
LBY158	91649.1	—	—	—	7.92	0.05	19	5.09	0.03	11
LBY139	92241.2	—	—	—	8.00	0.02	21	5.03	L	10
LBY135	92321.1	—	—	—	7.36	0.28	11	—	—	—
LBY135	92321.6	—	—	—	8.54	0.27	29	5.15	0.28	13
LBY135	92322.1	0.243	0.05	17	—	—	—	—	—	—
LBY113	92234.1	—	—	—	—	—	—	4.74	0.22	4
LBY113	92234.6	—	—	—	7.17	0.29	8	—	—	—
CONT.	—	0.207	—	—	6.63	—	—	4.57	—	—
LGN5	88198.1	0.268	L	10	—	—	—	—	—	—
LGN5	88198.4	0.278	0.27	14	8.14	0.07	10	5.05	0.02	7
LGN5	88201.3	—	—	—	8.65	0.15	17	5.00	0.11	11
CONT.	—	0.260	—	—	7.41	—	—	4.74	—	—
LBY97	92034.3	—	—	—	8.31	0.01	26	4.94	0.07	9
LBY87	92255.1	—	—	—	9.14	L	38	5.26	L	16
LBY87	92256.1	—	—	—	—	—	—	4.80	0.08	6
LBY81	92009.1	—	—	—	8.54	0.15	29	5.19	L	14
LBY230	91669.3	—	—	—	—	—	—	4.68	0.20	3
LBY217	92362.1	—	—	—	7.26	0.10	10	4.74	0.21	4
LBY138	92078.1	—	—	—	7.11	0.17	8	4.75	0.08	5
LBY138	92078.4	—	—	—	8.82	L	34	5.10	0.03	13
LBY136	91442.6	—	—	—	—	—	—	4.75	0.09	5
LBY136	91442.8	—	—	—	—	—	—	4.71	0.12	4
LBY136	91442.9	—	—	—	7.98	0.02	21	5.00	L	10
LBY135	92321.1	—	—	—	—	—	—	4.66	0.29	3
LBY135	92321.6	—	—	—	8.46	0.09	28	5.10	0.09	12
LBY120	91210.2	—	—	—	—	—	—	4.85	0.10	7
LBY118	91432.3	—	—	—	8.96	L	36	5.14	0.02	13
LBY118	91434.5	—	—	—	8.06	0.01	22	5.02	L	11
LBY117	91366.3	—	—	—	7.36	0.20	11	—	—	—
LBY115	92073.3	—	—	—	—	—	—	4.72	0.15	4
LBY115	92073.5	—	—	—	8.04	0.03	22	5.09	L	12
LBY112	92051.1	—	—	—	9.89	0.09	50	5.57	0.11	23
LBY112	92051.3	—	—	—	8.49	L	29	5.10	L	12
LBY112	92053.6	—	—	—	7.82	0.04	18	4.85	0.02	7
LBY108	91423.1	—	—	—	7.15	0.15	8	4.89	0.01	8
LBY108	91423.4	—	—	—	9.75	0.10	48	5.52	0.01	22
LBY103	91381.11	—	—	—	—	—	—	4.82	0.16	6
LBY103	91381.3	—	—	—	7.43	0.08	13	4.84	0.02	7
LBY103	91381.9	—	—	—	8.72	L	32	5.14	L	13
CONT.	—	—	—	—	6.60	—	—	4.54	—	—
LBY79	92221.2	—	—	—	11.0	0.22	12	5.92	0.18	9
LBY72	92764.1	—	—	—	11.1	0.19	13	5.56	0.24	2
LBY72	92765.3	—	—	—	10.5	0.06	7	—	—	—
LBY72	92766.4	—	—	—	11.0	0.09	12	5.85	L	7
LBY36	92526.1	—	—	—	12.2	L	24	6.16	L	13
LBY32	92830.3	—	—	—	—	—	—	6.14	L	13
LBY30	92326.1	—	—	—	11.0	L	12	5.77	L	6
LBY233	92477.1	—	—	—	11.7	0.20	19	5.95	L	9
LBY233	92477.2	—	—	—	11.7	L	19	6.10	L	12
LBY214	92760.3	—	—	—	10.5	0.07	6	5.76	0.23	6
LBY204	92827.1	—	—	—	12.8	0.26	30	6.13	0.25	12
LBY204	92828.1	—	—	—	—	—	—	5.80	0.07	6
LBY204	92828.3	—	—	—	12.7	0.02	29	5.98	0.04	10
LBY165	92678.3	—	—	—	11.2	L	14	5.88	0.03	8
LBY137	92752.1	—	—	—	11.6	L	18	5.88	L	8
LBY126	92834.3	—	—	—	11.0	L	12	—	—	—
LBY110	91179.2	—	—	—	11.2	L	14	6.01	L	10
LBY107	92285.2	—	—	—	10.6	0.07	8	—	—	—
CONT.	—	—	—	—	9.83	—	—	5.45	—	—
LGN60	89175.1	0.269	0.08	26	6.19	0.02	15	4.33	0.02	7
LGN60	89175.2	0.294	L	38	6.26	0.12	16	4.30	0.14	6
LGN60	89176.1	0.260	0.02	22	5.84	0.12	8	4.17	0.16	3
LGN60	89176.3	—	—	—	6.89	0.04	28	4.60	0.04	14
CONT.	—	0.213	—	—	5.40	—	—	4.04	—	—
LGN49	89081.1	—	—	—	7.36	0.24	17	4.68	0.21	7
LGN49	89081.3	—	—	—	7.71	0.18	22	4.77	0.21	8
LGN49	89081.6	—	—	—	8.30	0.12	22	5.13	0.12	11
CONT.	—	—	—	—	6.80	—	—	4.64	—	—
LGN54	88206.1	0.268	0.22	12	—	—	—	—	—	—
LGN54	88206.4	0.274	0.23	10	—	—	—	—	—	—
CONT.	—	0.250	—	—	—	—	—	—	—	—
LGN2	89029.2	—	—	—	8.51	0.04	13	5.06	L	8
CONT.	—	—	—	—	7.51	—	—	4.69	—	—
LGN5	88198.4	—	—	—	8.40	L	28	5.17	L	11
LGN5	88201.1	0.277	0.06	2	—	—	—	—	—	—
LGN5	88201.3	—	—	—	7.87	0.03	20	4.91	0.12	6
LGN5	88203.2	—	—	—	7.23	0.25	10	—	—	—
CONT.	—	0.216	—	—	6.55	—	—	4.64	—	—
LGN24	89094.2	—	—	—	7.28	L	26	4.68	0.01	12
CONT.	—	—	—	—	5.77	—	—	4.18	—	—
LGN54	88206.1	0.268	0.06	15	—	—	—	—	—	—
LGN54	88208.2	0.264	0.15	14	—	—	—	—	—	—
CONT.	—	0.263	—	—	—	—	—	—	—	—
LGN6	89173.1	0.238	0.14	27	—	—	—	—	—	—
CONT.	—	0.188	—	—	—	—	—	—	—	—
LBY79	92221.3	—	—	—	11.0	0.29	15	5.55	0.27	5
LBY72	92764.1	—	—	—	12.2	0.10	27	5.92	0.06	12
LBY72	92765.1	—	—	—	12.9	0.15	34	6.18	L	17
LBY72	92766.2	—	—	—	—	—	—	5.40	0.07	3
LBY72	92766.4	—	—	—	11.0	0.09	15	5.75	L	9
LBY36	92526.1	—	—	—	10.7	0.22	12	5.70	0.07	8
LBY32	92830.1	—	—	—	12.3	0.11	28	6.01	0.03	14
LBY32	92830.3	—	—	—	11.6	0.09	22	6.00	L	14
LBY32	92832.1	—	—	—	10.7	0.10	12	5.48	0.11	4
LBY32	92833.2	—	—	—	—	—	—	5.63	0.13	7
LBY26	92484.4	—	—	—	12.7	0.04	33	6.34	0.19	20
LBY26	92484.5	—	—	—	10.1	0.01	6	5.34	0.30	1
LBY26	92488.1	—	—	—	10.8	0.02	13	5.49	0.03	4
LBY233	92477.1	—	—	—	10.2	0.30	6	5.58	0.07	6
LBY214	92760.1	—	—	—	11.3	0.01	18	5.76	L	9
LBY210	92845.2	—	—	—	—	—	—	5.81	L	10
LBY210	92845.4	—	—	—	10.3	L	8	5.67	0.22	8
LBY210	92846.2	—	—	—	10.0	0.20	5	—	—	—
LBY204	92827.1	—	—	—	10.8	L	13	5.84	0.07	11
LBY204	92828.3	—	—	—	10.7	0.27	11	—	—	—
LBY196	91303.2	—	—	—	12.5	0.21	31	6.14	0.04	17
LBY187	92809.2	—	—	—	11.6	0.20	21	5.90	0.21	12
LBY187	92812.3	—	—	—	11.0	0.23	15	5.65	0.24	7
LBY187	92813.2	—	—	—	—	—	—	5.38	0.11	2
LBY137	92751.2	—	—	—	—	—	—	5.45	0.02	4
LBY126	92837.3	—	—	—	10.3	0.17	8	5.46	0.03	4
LBY126	92837.4	—	—	—	9.98	0.11	4	5.41	0.08	3
LBY126	92838.1	—	—	—	10.5	0.23	9	—	—	—
LBY120	91210.2	—	—	—	9.74	0.29	2	—	—	—
LBY120	91214.1	—	—	—	10.6	0.24	11	5.58	0.29	6
CONT.	—	—	—	—	9.56	—	—	5.26	—	—
LBY83	91330.1	—	—	—	5.34	0.10	12	4.21	0.05	7
LBY83	91330.2	—	—	—	6.47	0.06	36	4.89	L	25
LBY83	91332.1	—	—	—	5.50	0.03	15	4.24	0.02	8
LBY83	91332.2	—	—	—	—	—	—	4.16	0.18	6
LBY63	91326.1	0.222	0.02	18	—	—	—	4.23	0.07	8
LBY51	90981.1	—	—	—	5.28	0.09	11	—	—	—
LBY51	90981.4	0.202	0.28	7	—	—	—	—	—	—
LBY48	90968.1	—	—	—	5.66	0.01	19	4.36	L	11
LBY48	90968.2	—	—	—	5.44	0.07	14	4.26	0.01	9
LBY48	90970.2	0.218	0.03	16	—	—	—	—	—	—
LBY224	91527.4	0.214	0.18	14	5.43	0.29	14	4.29	0.23	9
LBY224	91529.1	—	—	—	5.47	0.11	15	4.29	0.01	9
LBY22	90961.1	0.213	0.06	13	—	—	—	—	—	—
LBY22	90961.2	—	—	—	5.41	0.17	14	4.19	0.16	7
LBY22	90965.5	—	—	—	5.45	0.10	14	4.23	0.12	8
LBY196	91300.1	0.212	0.18	13	5.42	0.04	14	4.30	0.04	10
LBY196	91303.2	—	—	—	5.65	0.29	19	4.34	0.24	11
LBY188	91557.3	0.225	0.01	20	—	—	—	—	—	—
LBY150	91642.1	0.237	0.15	26	—	—	—	—	—	—
LBY150	91644.2	0.220	0.14	17	—	—	—	—	—	—
LBY150	91644.3	—	—	—	5.98	L	26	4.47	L	14
LBY134	91281.5	—	—	—	—	—	—	4.26	0.08	9
LBY134	91284.1	0.241	0.21	28	—	—	—	—	—	—
LBY133	91139.2	—	—	—	—	—	—	4.15	0.16	6
LBY133	91139.4	—	—	—	6.17	0.05	29	4.42	0.02	13
LBY132	91277.1	—	—	—	6.57	0.20	38	4.71	0.04	20
LBY132	91279.3	0.205	0.20	9	6.87	0.03	44	4.84	L	23
LBY125	91273.2	0.211	0.23	12	—	—	—	—	—	—
LBY125	91273.3	—	—	—	6.41	0.10	35	4.62	0.08	18
LBY125	91273.4	0.224	0.26	19	—	—	—	—	—	—
LBY102	91262.1	—	—	—	5.32	0.17	12	4.18	0.14	6
CONT.	—	0.188	—	—	4.77	—	—	3.92	—	—
NUE102	90003.5	0.262	0.25	13	6.13	0.15	15	4.57	0.25	5
NUE102	90004.1	0.292	0.12	26	5.90	0.27	11	4.60	0.18	6
CONT.	—	0.232	—	—	5.33	—	—	4.35	—	—
LGN24	89094.2	—	—	—	8.10	0.04	19	4.96	0.06	8
LGN24	89094.3	—	—	—	7.53	0.16	11	4.88	0.15	6
CONT.	—	—	—	—	6.79	—	—	4.61	—	—
LBY91	91630.1	—	—	—	—	—	—	6.29	0.27	12
LBY91	91633.2	0.252	0.15	12	—	—	—	6.02	0.19	7
LBY91	91634.3	0.258	0.27	14	12.5	0.16	13	6.01	0.13	7
LBY81	92013.2	—	—	—	13.5	0.06	22	6.18	0.19	10
LBY77	92061.2	—	—	—	14.2	0.01	29	6.34	0.01	13
LBY77	92062.1	0.253	0.20	12	14.6	L	32	6.67	L	18
LBY49	92039.4	—	—	—	12.3	0.25	11	5.99	0.17	6
LBY49	92043.1	0.270	0.03	19	—	—	—	—	—	—
LBY29	91617.1	0.253	0.14	12	—	—	—	—	—	—
LBY29	91619.1	0.270	0.04	19	12.5	0.17	13	5.94	0.20	5
LBY29	91619.5	0.268	0.10	19	12.8	0.14	16	6.08	0.08	8
LBY23	91396.3	—	—	—	12.9	0.22	17	—	—	—
LBY23	91397.4	0.264	0.05	17	—	—	—	—	—	—
LBY174	92079.1	—	—	—	12.7	0.19	15	6.04	0.15	7
LBY174	92080.1	—	—	—	12.1	0.30	10	—	—	—
LBY158	91647.3	—	—	—	12.6	0.24	14	5.95	0.22	6
LBY158	91649.1	—	—	—	13.1	0.26	19	6.14	0.15	9
LBY146	91590.1	0.255	0.22	13	—	—	—	—	—	—
LBY146	91593.3	0.256	0.15	13	13.4	0.05	21	6.06	0.13	8
LBY138	92075.2	—	—	—	12.2	0.28	10	—	—	—
LBY138	92076.1	—	—	—	—	—	—	5.97	0.20	6
LBY115	92073.1	—	—	—	12.7	0.12	15	6.05	0.09	7
LBY112	92053.2	0.270	0.04	19	—	—	—	—	—	—
LBY108	91422.2	—	—	—	12.5	0.15	13	6.04	0.11	7
LBY108	91423.1	—	—	—	13.4	0.05	21	6.33	0.10	12
LBY104	91269.2	—	—	—	12.6	0.28	14	6.14	0.13	9
CONT.	—	0.226	—	—	11.0	—	—	5.63	—	—
LGN2	89029.2	0.257	0.10	16	8.47	L	46	5.25	0.01	15
CONT.	—	0.221	—	—	5.80	—	—	4.56	—	—
NUE102	90004.1	0.199	0.15	18	—	—	—	—	—	—
CONT.	—	0.168	—	—	—	—	—	—	—	—
LGN60	89174.2	0.334	L	23	—	—	—	—	—	—
LGN60	89175.1	0.321	L	18	—	—	—	—	—	—
LGN60	89175.2	0.296	0.03	9	6.59	0.05	8	4.56	0.19	3
LGN60	89176.1	0.323	L	19	—	—	—	—	—	—
LGN60	89176.3	—	—	—	7.54	0.08	11	4.83	0.13	6
CONT.	—	0.305	—	—	6.82	—	—	4.58	—	—
LBY77	92061.2	0.221	0.15	30	—	—	—	—	—	—
LBY77	92062.1	—	—	—	8.18	0.19	11	5.03	0.06	8
LBY77	92063.4	0.205	0.21	21	—	—	—	—	—	—
LBY54	92084.4	—	—	—	10.5	L	43	5.54	0.04	19
LBY54	92086.1	—	—	—	8.33	0.11	13	4.96	0.11	6
LBY49	92043.2	0.232	0.23	37	—	—	—	—	—	—
LBY29	91617.1	0.206	0.18	21	9.45	L	2	5.25	L	12
LBY29	91619.1	0.202	0.12	19	—	—	—	4.90	0.19	5
LBY25	91335.2	—	—	—	10.3	L	39	5.50	L	18
LBY230	91667.1	0.193	0.24	14	—	—	—	—	—	—
LBY230	91669.2	—	—	—	—	—	—	5.20	0.19	11
LBY23	91397.3	—	—	—	9.60	0.07	30	5.41	0.05	16
LBY225	91605.3	—	—	—	9.27	0.03	26	5.12	0.09	10
LBY225	91607.3	0.269	L	58	10.4	0.30	41	5.51	0.29	18
LBY225	91607.5	0.233	0.01	37	9.65	L	31	5.25	0.09	12
LBY217	92363.1	—	—	—	8.06	0.23	9	4.97	0.08	6
LBY213	92032.1	0.201	0.14	18	—	—	—	—	—	—
LBY213	92033.1	—	—	—	9.92	0.06	35	5.46	0.02	17
LBY212	92024.2	—	—	—	—	—	—	4.99	0.16	7
LBY212	92024.3	—	—	—	8.95	0.03	21	5.23	0.01	12
LBY202	92022.1	0.205	0.21	21	8.70	0.04	18	5.07	0.05	9
LBY182	92396.1	0.225	0.16	33	8.81	0.28	20	5.10	0.15	9
LBY182	92398.2	0.223	0.23	31	—	—	—	—	—	—
LBY182	92398.3	0.204	0.11	20	—	—	—	—	—	—
LBY136	91442.6	—	—	—	8.98	0.03	22	5.19	0.01	11
LBY136	91442.9	—	—	—	9.27	0.13	26	5.15	0.18	10
CONT.	—	0.170	—	—	7.37	—	—	4.67	—	—
LGN49	89079.3	0.200	0.22	7	—	—	—	—	—	—
LGN49	89081.6	—	—	—	7.66	0.08	19	5.01	0.18	9
LGN49	89082.1	0.208	0.13	11	—	—	—	—	—	—
CONT.	—	0.190	—	—	6.42	—	—	4.61	—	—

Table 244. “CONT.”=Control: “Ave.”=Average; “% Incr.”=% increment: “p-val.”=p-value, L=p<0.01.

TABLE 245
Genes showing improved plant performance at Normal growth
conditions under regulation of At6669 promoter
Gene		Seed Yield [mg]	1000 Seed Weight [mg]
Name	Event #	Ave.	P-Val.	% Incr.	Ave.	P-Val.	% Incr.
LBY96	92428.4	—	—	—	20.1	0.09	13
LBY89	92259.1	—	—	—	22.3	0.11	25
LBY87	92255.2	—	—	—	19.1	0.04	7
LBY87	92256.1	334.1	0.07	21	—	—	—
LBY55	92422.6	—	—	—	20.1	L	13
LBY30	92326.2	—	—	—	19.9	0.01	12
LBY225	91605.3	300.9	0.26	9	—	—	—
LBY225	91607.2	—	—	—	18.6	0.19	4
LBY225	91607.3	323.9	0.06	17	—	—	—
LBY212	92028.3	310.9	0.13	13	—	—	—
LBY202	92021.1	319.5	0.16	16	—	—	—
LBY202	92022.1	—	—	—	18.8	0.21	5
LBY193	91660.2	358.4	0.04	30	21.1	L	18
LBY182	92398.3	—	—	—	19.6	L	10
LBY174	92079.8	—	—	—	21.3	0.07	19
LBY139	92239.1	—	—	—	20.5	0.03	15
LBY135	92321.1	—	—	—	19.1	L	7
LBY135	92321.6	—	—	—	19.8	0.04	11
LBY135	92322.1	363.2	0.01	32	—	—	—
LBY135	92323.1	—	—	—	18.2	0.19	2
LBY135	92323.3	298.7	0.30	8	—	—	—
CONT.	—	275.8	—	—	17.9	—	—
LGN5	88198.1	273.6	0.08	11	19.5	0.02	8
LGN5	88198.4	279.4	0.21	14	18.4	0.21	2
LGN5	88201.3	—	—	—	21.4	0.22	12
CONT.	—	245.7	—	—	19.2	—	—
LGN60	89175.1	279.8	0.13	18	—	—	—
LGN60	89175.2	301.9	0.02	28	—	—	—
LGN60	89176.1	283.5	0.06	20	—	—	—
LGN60	89176.3	—	—	—	22.7	L	22
CONT.	—	236.5	—	—	18.7	—	—
LGN49	89081.3	—	—	—	22.3	L	19
LGN49	89081.6	—	—	—	20.9	0.03	12
CONT.	—	—	—	—	18.7	—	—
LGN5	88198.1	—	—	—	21.0	0.07	—
LGN5	88198.4	—	—	—	19.1	0.25	4
LGN5	88201.1	267.2	0.29	11	—	—	—
LGN5	88201.3	—	—	—	22.0	0.05	14
CONT.	—	241.2	—	—	19.3	—	—
LGN24	89094.2	—	—	—	21.7	0.08	17
CONT.	—	—	—	—	18.5	—	—
LGN54	88206.1	282.8	0.28	8	—	—	—
CONT.	—	284.5	—	—	—	—	—
LGN6	89169.2	—	—	—	19.5	0.12	6
LGN6	89173.1	206.9	0.29	18	—	—	—
CONT.	—	175.5	—	—	18.3	—	—
LGN36	89044.1	128.6	0.23	39	—	—	—
CONT.	—	92.6	—	—	—	—	—
LGN6	89169.2	—	—	—	17.9	L	14
LGN6	89171.4	—	—	—	16.5	0.22	5
CONT.	—	—	—	—	15.7	—	—
LBY83	91330.1	288.6	0.30	11	—	—	—
LBY63	91325.2	—	—	—	19.5	L	7
LBY63	91326.1	289.0	0.21	11	—	—	—
LBY51	90981.4	288.9	0.25	11	19.6	0.05	8
LBY22	90961.1	299.6	0.09	15	—	—	—
LBY22	90961.2	—	—	—	19.9	0.28	10
LBY196	91300.1	308.0	0.05	18	—	—	—
LBY196	91303.2	—	—	—	21.3	0.03	17
LBY188	91557.3	335.0	0.22	28	—	—	—
LBY150	91642.1	332.3	L	27	—	—	—
LBY150	91644.2	301.5	0.08	16	—	—	—
LBY134	91282.1	304.3	0.23	17	21.3	L	17
LBY134	91284.1	382.4	L	47	—	—	—
LBY132	91279.3	289.8	0.28	11	20.3	L	12
LBY125	91273.2	—	—	—	19.4	L	7
LBY125	91273.4	305.3	0.06	17	—	—	—
LBY102	91262.1	—	—	—	20.5	0.04	13
CONT.	—	261.0	—	—	18.2	—	—
NUE102	90003.5	287.4	0.01	30	—	—	—
NUE102	90004.1	294.7	0.01	33	—	—	—
CONT.	—	221.6	—	—	—	—	—
LGN24	89094.2	—	—	—	19.6	L	18
CONT.	—	—	—	—	16.7	—	—
LBY91	91630.1	—	—	—	20.0	0.04	30
LBY91	91633.1	—	—	—	18.5	0.12	21
LBY91	91633.2	—	—	—	19.0	0.08	24
LBY81	92009.1	—	—	—	19.6	0.05	28
LBY81	92009.3	—	—	—	17.6	0.25	15
LBY81	92009.4	—	—	—	18.1	0.17	18
LBY77	92061.1	—	—	—	17.9	0.20	17
LBY77	92061.2	—	—	—	18.7	0.11	22
LBY77	92062.1	344.8	0.10	18	—	—	—
LBY77	92063.6	—	—	—	17.6	0.25	15
LBY54	92084.7	—	—	—	17.7	0.25	15
LBY54	92087.3	—	—	—	17.9	0.22	17
LBY35	92119.2	—	—	—	18.0	0.18	17
LBY29	91617.1	—	—	—	18.7	0.19	22
LBY29	91617.4	—	—	—	18.5	0.12	21
LBY29	91619.1	—	—	—	17.8	0.25	16
LBY29	91619.5	—	—	—	18.9	0.09	23
LBY23	91397.2	324.9	0.29	12	—	—	—
LBY174	92079.7	—	—	—	17.7	0.26	15
LBY158	91647.2	—	—	—	17.5	0.2.7	14
LBY158	91647.5	—	—	—	18.4	0.13	20
LBY158	91648.1	—	—	—	19.8	0.05	29
LBY146	91593.3	364.5	0.18	25	20.8	0.02	36
LBY138	92076.1	—	—	—	19.8	0.05	29
LBY117	91365.1	—	—	—	18.4	0.25	20
LBY117	91366.1	—	—	—	18.5	0.17	21
LBY115	92071.2	—	—	—	17.6	0.25	15
LBY112	92051.3	—	—	—	20.3	0.08	32
LBY112	92052.2	—	—	—	17.7	0.23	16
LBY112	92053.2	337.9	0.16	16	—	—	—
LBY108	91423.4	—	—	—	19.4	0.06	27
LBY103	91381.8	—	—	—	18.0	0.18	18
LBY103	91381.9	—	—	—	18.8	0.11	22
CONT.	—	291.3	—	—	15.3	—	—
LGN2	89029.2	268.5	0.01	20	—	—	—
CONT.	—	224.7	—	—	—	—	—
LGN26	89036.1	—	—	—	20.2	0.18	13
LGN26	89037.2	—	—	—	20.8	0.15	16
LGN26	89037.3	—	—	—	20.4	L	14
LGN26	89037.4	—	—	—	19.1	0.05	7
CONT.	—	—	—	—	17.9	—	—
NUE102	90004.1	208.7	0.03	20	—	—	—
CONT.	—	174.1	—	—	—	—	—
LGN60	89174.2	373.2	0.09	18	—	—	—
LGN60	89175.1	328.5	0.13	11	—	—	—
LGN60	89175.2	332.8	L	12	—	—	—
LGN60	89176.1	342.8	L	16	—	—	—
LGN60	89176.3	334.2	0.20	13	23.2	0.22	13
CONT.	—	316.5	—	—	21.3	—	—
LBY91	91630.1	—	—	—	18.6	L	15
LBY91	91633.1	—	—	—	17.7	0.03	10
LBY77	92062.1	—	—	—	17.5	0.02	8
LBY49	92039.4	—	—	—	18.2	L	12
LBY49	92043.1	—	—	—	17.3	0.04	7
LBY49	92043.2	—	—	—	16.8	0.15	4
LBY35	92122.1	—	—	—	17.8	0.01	10
LBY29	91617.1	275.7	0.23	19	—	—	—
LBY25	91335.2	—	—	—	18.6	L	15
LBY25	91338.2	—	—	—	17.4	0.03	7
LBY25	91339.1	—	—	—	17.1	0.08	6
LBY225	91607.3	318.7	0.03	38	—	—	—
LBY225	91607.5	304.7	0.06	32	—	—	—
LBY217	92363.1	—	—	—	18.7	0.13	16
LBY202	92022.2	—	—	—	17.7	0.12	9
LBY193	91660.2	—	—	—	18.7	0.26	16
LBY182	92396.2	—	—	—	17.3	0.03	7
LBY182	92398.2	—	—	—	17.0	0.19	5
LBY182	92398.3	—	—	—	16.9	0.17	5
LBY118	91434.4	—	—	—	17.1	0.30	6
CONT.	—	231.5	—	—	16.2	—	—
LGN49	89081.3	202.2	0.20	11	22.1	L	14
LGN49	89081.6	—	—	—	20.8	0.25	7
CONT.	—	201.5	—	—	19.5	—	—
LGN26	89036.1	—	—	—	17.9	L	7
LGN26	89036.4	—	—	—	17.9	L	6
LGN26	89037.2	—	—	—	19.5	0.02	16
LGN26	89037.3	—	—	—	20.6	L	23
LGN26	89037.4	—	—	—	17.7	0.21	5
CONT.	—	—	—	—	16.8	—	—

Table 245. “CONT”=Control; “Ave.”=Average; “Incr.=% ncrement; “p-val.”=p-value, L=p<0.01.

TABLE 246
Genes showing improved plant performance at Normal growth
conditions under regulation of At6669 promoter
	1000 Seed Weight [mg]
	Gene Name	Event #	Ave.	P-Val.	% Incr.
	LBY96	92428.4	20.1	0.09	13
	LBY89	92259.1	22.3	0.11	25
	LBY87	92255.2	19.1	0.04	7
	LBY55	92422.6	20.1	L	13
	LBY30	92326.2	19.9	0.01	12
	LBY225	91607.2	18.6	0.19	4
	LBY202	92022.1	18.8	0.21	5
	LBY193	91660.2	21.1	L	18
	LBY182	92398.3	19.6	L	10
	LBY174	92079.8	21.3	0.07	19
	LBY139	92239.1	20.5	0.03	15
	LBY135	92321.1	19.1	L	7
	LBY135	92321.6	19.8	0.04	11
	LBY135	92323.1	18.2	0.19	2
	CONT.	—	17.9	—	—
	LGN5	88198.1	19.5	0.02	8
	LGN5	88198.4	18.4	0.21	2
	LGN5	88201.3	21.4	0.22	12
	CONT.	—	19.2	—	—
	LGN60	89176.3	22.7	L	22
	CONT.	—	18.7	—	—
	LGN49	89081.3	22.3	L	19
	LGN49	89081.6	20.9	0.03	12
	CONT.	—	18.7	—	—
	LGN5	88198.1	21.0	0.07	9
	LGN5	88198.4	19.1	0.25	4
	LGN5	88201.3	22.0	0.05	14
	CONT.	—	19.3	—	—
	LGN24	89094.2	21.7	0.08	17
	CONT.	—	18.5	—	—
	LGN6	89169.2	19.5	0.12	6
	CONT.	—	18.3	—	—
	LGN6	89169.2	17.9	L	14
	LGN6	89171.4	16.5	0.22	5
	CONT.	—	15.7	—	—
	LBY63	91325.2	19.5	L	7
	LBY51	90981.4	19.6	0.05	8
	LBY22	90961.2	19.9	0.28	10
	LBY196	91303.2	21.3	0.03	17
	LBY134	91282.1	21.3	L	17
	LBY132	91279.3	20.3	L	12
	LBY125	91273.2	19.4	L	7
	LBY102	91262.1	20.5	0.04	13
	CONT.	—	18.2	—	—
	LGN24	89094.2	19.6	L	18
	CONT.	—	16.7	—	—
	LBY91	91630.1	20.0	0.04	30
	LBY91	91633.1	18.5	0.12	21
	LBY91	91633.2	19.0	0.08	24
	LBY81	92009.1	19.6	0.05	28
	LBY81	92009.3	17.6	0.25	15
	LBY81	92009.4	18.1	0.17	18
	LBY77	92061.1	17.9	0.20	17
	LBY77	92061.2	18.7	0.11	22
	LBY77	92063.6	17.6	0.25	15
	LBY54	92084.7	17.7	0.25	15
	LBY54	92087.3	17.9	0.22	17
	LBY35	92119.2	18.0	0.18	17
	LBY29	91617.1	18.7	0.19	22
	LBY29	91617.4	18.5	0.12	21
	LBY29	91619.1	17.8	0.25	16
	LBY29	91619.5	18.9	0.09	23
	LBY174	92079.7	17.7	0.26	15
	LBY158	91647.2	17.5	0.27	14
	LBY158	91647.5	18.4	0.13	20
	LBY158	91648.1	19.8	0.05	29
	LBY146	91593.3	20.8	0.02	36
	LBY138	92076.1	19.8	0.05	29
	LBY117	91365.1	18.4	0.25	20
	LBY117	91366.1	18.5	0.17	21
	LBY115	92071.2	17.6	0.25	15
	LBY112	92051.3	20.3	0.08	32
	LBY112	92052.2	17.7	0.23	16
	LBY108	91423.4	19.4	0.06	27
	LBY103	91381.8	18.0	0.18	18
	LBY103	91381.9	18.8	0.11	22
	CONT.	—	15.3	—	—
	LGN26	89036.1	20.2	0.18	13
	LGN26	89037.2	20.8	0.15	16
	LGN26	89037.3	20.4	L	14
	LGN26	89037.4	19.1	0.05	7
	CONT.	—	17.9	—	—
	LGN60	89176.3	23.2	0.22	13
	CONT.	—	21.3	—	—
	LBY91	91630.1	18.6	L	15
	LBY91	91633.1	17.7	0.03	10
	LBY77	92062.1	17.5	0.02	8
	LBY49	92039.4	18.2	L	12
	LBY49	92043.1	17.3	0.04	7
	LBY49	92043.2	16.8	0.15	4
	LBY35	92122.1	17.8	0.01	10
	LBY25	91335.2	18.6	L	15
	LBY25	91338.2	17.4	0.03	7
	LBY25	91339.1	17.1	0.08	6
	LBY217	92363.1	18.7	0.13	16
	LBY202	92022.2	17.7	0.12	9
	LBY193	91660.2	18.7	0.26	16
	LBY182	92396.2	17.3	0.03	7
	LBY182	92398.2	17.0	0.19	5
	LBY182	92398.3	16.9	0.17	5
	LBY118	91434.4	17.1	0.30	6
	CONT.	—	16.2	—	—
	LGN49	89081.3	22.1	L	14
	LGN49	89081.6	20.8	0.25	7
	CONT.	—	19.5	—	—
	LGN26	89036.1	17.9	L	7
	LGN26	89036.4	17.9	L	6
	LGN26	89037.2	19.5	0.02	16
	LGN26	89037.3	20.6	L	23
	LGN26	89037.4	17.7	0.21	5
	CONT.	—	16.8	—	—

Table 246. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 247
Genes showing improved plant performance at Normal growth
conditions under regulation of At6669 promoter
	Harvest Index
	Gene Name	Event #	Ave.	P-Val.	% Incr.
	LBY87	92256.1	0.237	0.20	14
	LBY225	91605.3	0.241	0.06	16
	LBY225	91607.3	0.245	0.05	18
	LBY212	92026.4	0.246	0.29	19
	LBY202	92022.1	0.224	0.29	8
	LBY193	91660.2	0.254	0.06	23
	LBY193	91662.1	0.229	0.30	10
	LBY135	92322.1	0.243	0.05	17
	CONT.	—	0.207	—	—
	LGN5	88198.1	0.268	L	10
	LGN5	88198.4	0.278	0.27	14
	CONT.	—	0.260	—	—
	LGN60	89175.1	0.269	0.08	26
	LGN60	89175.2	0.294	L	38
	LGN60	89176.1	0.260	0.02	22
	CONT.	—	0.213	—	—
	LGN54	88206.1	0.268	0.22	12
	LGN54	88206.4	0.274	0.23	10
	CONT.	—	0.250	—	—
	LGN5	88201.1	0.277	0.06	28
	CONT.	—	0.216	—	—
	LGN54	88206.1	0.268	0.06	15
	LGN54	88208.2	0.264	0.15	14
	CONT.	—	0.263	—	—
	LGN6	89173.1	0.238	0.14	27
	CONT.	—	0.188	—	—
	LBY63	91326.1	0.222	0.02	18
	LBY51	90981.4	0.202	0.28	7
	LBY48	90970.2	0.218	0.03	16
	LBY224	91527.4	0.214	0.18	14
	LBY22	90961.1	0.213	0.06	13
	LBY196	91300.1	0.212	0.18	13
	LBY188	91557.3	0.225	0.01	20
	LBY150	91642.1	0.237	0.15	26
	LBY150	91644.2	0.220	0.14	17
	LBY134	91284.1	0.241	0.21	28
	LBY132	91279.3	0.205	0.20	9
	LBY125	91273.2	0.211	0.23	12
	LBY125	91273.4	0.224	0.26	19
	CONT.	—	0.188	—	—
	NUE102	90003.5	0.262	0.25	13
	NUE102	90004.1	0.292	0.12	26
	CONT.	—	0.232	—	—
	LBY91	91633.2	0.252	0.15	12
	LBY91	91634.3	0.258	0.27	14
	LBY77	92062.1	0.253	0.20	12
	LBY49	92043.1	0.270	0.03	19
	LBY29	91617.1	0.253	0.14	12
	LBY29	91619.1	0.270	0.04	19
	LBY29	91619.5	0.268	0.10	19
	LBY23	91397.4	0.264	0.05	17
	LBY146	91590.1	0.255	0.22	13
	LBY146	91593.3	0.256	0.15	13
	LBY112	92053.2	0.270	0.04	19
	CONT.	—	0.226	—	—
	LGN2	89029.2	0.257	0.10	16
	CONT.	—	0.221	—	—
	NUE102	90004.1	0.199	0.15	18
	CONT.	—	0.168	—	—
	LGN60	89174.2	0.334	L	23
	LGN60	89175.1	0.321	L	18
	LGN60	89175.2	0.296	0.03	9
	LGN60	89176.1	0.323	L	19
	CONT.	—	0.305	—	—
	LBY77	92061.2	0.221	0.15	30
	LBY77	92063.4	0.205	0.21	21
	LBY49	92043.2	0.232	0.23	37
	LBY29	91617.1	0.206	0.18	21
	LBY29	91619.1	0.202	0.12	19
	LBY230	91667.1	0.193	0.24	14
	LBY225	91607.3	0.269	L	58
	LBY225	91607.5	0.233	0.01	37
	LBY213	92032.1	0.201	0.14	18
	LBY202	92022.1	0.205	0.21	21
	LBY182	92396.1	0.225	0.16	33
	LBY182	92398.2	0.223	0.23	31
	LBY182	92398.3	0.204	0.11	20
	CONT.	—	0.170	—	—
	LGN49	89079.3	0.200	0.22	7
	LGN49	89082.1	0.208	0.13	11
	CONT.	—	0.190	—	—

Table 247. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

Tables 248-254 summarize the observed phenotypes of transgenic plants exogenously expressing the gene constructs using the seed maturation (GH-SM) assays under drought conditions. The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value<0.1 was considered statistically significant.

TABLE 248
Genes showing improved plant performance at Drought growth
conditions under regulation of At6669 promoter
								Inflorescence
		Dry Weight [mg]	Flowering	Emergence
Gene			P-	%		P-	%		P-	%
Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY83	91330.2	1126.9	0.26	6	—	—	—	40.2	0.06	−2
LBY83	91330.3	—	—	—	—	—	—	39.9	0.19	−3
LBY82	91184.3	1192.0	0.21	12	—	—	—	—	—	—
LBY51	90984.2	1136.0	0.08	7	—	—	—	—	—	—
LBY224	91527.4	—	—	—	—	—	—	40.3	0.24	−2
LBY224	91529.2	1103.8	0.17	4	—	—	—	—	—	—
LBY22	90961.1	1126.2	L	6	—	—	—	—	—	—
LBY22	90961.2	1252.1	L	18	—	—	—	—	—	—
LBY196	91300.1	1101.9	0.07	4	47.8	0.29	−1	40.1	0.20	−2
LBY196	91303.2	1162.1	0.28	9	—	—	—	—	—	—
LBY196	91304.2	1181.0	0.06	11	—	—	—	—	—	—
LBY188	91557.3	1142.5	0.18	8	—	—	—	—	—	—
LBY150	91644.3	1142.1	0.28	8	—	—	—	—	—	—
LBY134	91281.5	—	—	—	—	—	—	39.9	0.02	−2
LBY134	91282.1	1225.0	0.11	15	—	—	—	—	—	—
LBY133	91139.1	—	—	—	—	—	—	40.2	0.09	−2
LBY133	91139.2	1092.5	0.11	3	—	—	—	—	—	—
LBY132	91279.3	1106.9	0.11	4	—	—	—	—	—	—
LBY102	91262.1	1142.5	L	8	—	—	—	—	—	—
LBY102	91264.1	—	—	—	46.8	L	−3	39.9	0.19	−3
CONT.	—	1061.5	—	—	48.2	—	—	40.9	—	—
LBY79	92221.2	—	—	—	23.8	L	−6	19.1	0.01	−3
LBY79	92221.6	—	—	—	—	—	—	19.2	0.15	−3
LBY79	92223.3	—	—	—	—	—	—	19.3	0.09	−2
LBY72	92764.1	—	—	—	—	—	—	19.2	0.15	−3
LBY72	92765.1	—	—	—	24.4	0.05	−4	19.1	0.01	−3
LBY72	92766.2	—	—	—	24.6	0.01	−3	19.1	0.01	−3
LBY32	92830.1	—	—	—	24.7	0.23	−3	19.0	L	−4
LBY32	92830.3	—	—	—	24.3	L	−4	19.1	0.01	−3
LBY32	92833.2	—	—	—	24.2	L	−4	19.2	0.09	−3
LBY26	92484.4	—	—	—	24.2	L	−5	19.0	L	−4
LBY26	92484.5	—	—	—	—	—	—	19.2	0.09	−3
LBY233	92474.3	—	—	—	24.1	L	−5	19.0	L	−4
LBY233	92477.2	—	—	—	24.8	0.14	−2	—	—	—
LBY233	92477.3	—	—	—	24.6	0.01	−3	19.3	0.09	−2
LBY214	92760.3	—	—	—	24.1	L	−5	19.0	L	−4
LBY210	92845.2	—	—	—	25.0	0.17	−1	19.2	0.09	−3
LBY210	92845.3	—	—	—	24.8	0.17	−2	19.2	0.26	−2
LBY210	92845.4	—	—	—	24.6	0.01	−3	19.2	0.06	−2
LBY210	92846.1	—	—	—	—	—	—	19.2	0.06	−2
LBY204	92826.1	—	—	—	24.6	0.01	−3	—	—	—
LBY204	92827.1	—	—	—	24.8	0.14	−2	19.1	0.01	−3
LBY204	92828.1	—	—	—	24.5	0.01	−3	19.2	0.06	−2
LBY204	92828.3	—	—	—	25.0	0.17	−1	—	—	—
LBY196	91303.2	—	—	—	24.1	L	−5	19.0	L	−4
LBY187	92809.2	—	—	—	—	—	—	19.2	0.09	−3
LBY187	92812.3	—	—	—	24.6	0.01	−3	19.3	0.09	−2
LBY187	92813.2	—	—	—	25.0	0.17	−1	19.0	L	−4
LBY154	92432.3	—	—	—	—	—	—	19.0	L	−4
LBY137	92751.2	—	—	—	24.6	0.02	−3	19.2	0.02	−2
LBY126	92834.3	—	—	—	24.4	L	−4	19.0	L	−4
LBY126	92837.3	—	—	—	25.0	0.17	−1	19.1	0.01	−3
LBY126	92838.1	—	—	—	24.7	0.23	−3	—	—	—
LBY120	91211.2	—	—	—	—	—	—	19.1	0.02	−3
LBY120	91214.1	—	—	—	24.6	0.28	−3	19.0	L	−4
LBY107	92284.1	—	—	—	—	—	—	19.2	0.09	−3
LBY107	92284.2	—	—	—	24.7	0.23	−3	19.1	0.01	−3
CONT.	—	—	—	—	25.4	—	—	19.7	—	—
LBY96	92428.3	1027.5	0.14	11	—	—	—	—	—	—
LBY89	92259.1	1135.0	0.09	23	37.0	0.02	−1	—	—	—
LBY87	92257.3	1034.4	0.09	12	—	—	—	—	—	—
LBY55	92422.6	1055.6	0.15	14	—	—	—	—	—	—
LBY30	92324.3	1052.5	0.26	14	—	—	—	—	—	—
LBY30	92324.4	—	—	—	35.6	L	−5	28.6	0.16	−4
LBY30	92326.1	—	—	—	35.7	0.07	−5	—	—	—
LBY30	92326.2	1171.7	0.05	26	—	—	—	—	—	—
LBY225	91607.5	—	—	—	35.7	L	−5	—	—	—
LBY225	91607.6	—	—	—	36.0	L	−4	28.2	L	−5
LBY213	92032.1	1023.7	0.01	11	—	—	—	—	—	—
LBY213	92033.3	958.1	0.28	3	36.8	0.09	−2	28.7	0.11	−3
LBY212	92024.3	990.6	0.15	7	34.6	0.18	−8	28.5	0.19	−4
LBY212	92026.4	—	—	—	37.0	0.02	−1	—	—	—
LBY212	92028.3	1088.8	L	18	37.2	0.16	−1	—	—	—
LBY202	92019.2	—	—	—	36.1	0.20	−4	—	—	—
LBY202	92021.1	—	—	—	36.0	L	−4	—	—	—
LBY202	92022.2	1128.8	0.07	22	37.0	0.02	−1	28.8	0.07	−3
LBY193	91660.2	1047.5	0.22	13	36.5	0.28	−3	—	—	—
LBY193	91662.1	—	—	—	36.8	0.09	−2	28.2	L	−5
LBY193	91664.2	998.1	0.24	8	—	—	—	—	—	—
LBY193	91664.5	1026.9	L	11	37.1	0.18	−1	—	—	—
LBY182	92396.1	—	—	—	37.1	0.18	−1	—	—	—
LBY182	92396.2	1061.9	0.20	15	—	—	—	—	—	—
LBY182	92396.4	—	—	—	—	—	—	28.8	0.07	−3
LBY174	92079.1	1062.5	0.16	15	—	—	—	28.6	0.15	−4
LBY174	92079.7	—	—	—	37.3	0.23	−1	—	—	—
LBY174	92079.8	1035.6	0.11	12	—	—	—	—	—	—
LBY174	92081.1	1024.4	0.20	11	—	—	—	—	—	—
LBY158	91647.3	—	—	—	36.9	0.03	−2	—	—	—
LBY154	92433.4	—	—	—	35.6	L	−5	28.4	0.22	−4
LBY154	92433.5	—	—	—	36.3	0.10	−3	—	—	—
LBY146	91590.2	960.0	0.28	4	34.8	0.16	−7	28.0	L	−6
LBY146	91590.4	1020.6	0.02	10	35.5	0.01	−5	28.1	L	−5
LBY146	91593.3	—	—	—	35.0	0.11	−7	28.5	0.01	−4
LBY146	91594.1	—	—	—	36.9	0.03	−2	—	—	—
LBY139	92241.2	1013.1	0.28	9	35.1	L	−6	27.5	L	−7
LBY135	92321.1	982.1	0.10	6	—	—	—	—	—	—
LBY135	92321.6	—	—	—	35.8	0.03	−5	—	—	—
LBY135	92322.1	—	—	—	36.2	0.15	−3	28.3	L	−4
LBY113	92234.2	—	—	—	37.3	0.23	−1	—	—	—
LBY113	92234.5	—	—	—	36.8	0.09	−2	—	—	—
LBY113	92234.6	—	—	—	37.2	0.16	−1	—	—	—
CONT.	—	926.5	—	—	37.5	—	—	29.7	—	—
LBY91	91633.1	—	—	—	35.5	0.27	−5	—	—	—
LBY91	91634.2	—	—	—	36.5	0.13	−3	28.3	0.03	−5
LBY77	92062.1	1136.9	0.27	13	36.5	0.11	−2	—	—	—
LBY54	92084.4	1104.6	0.12	9	35.9	0.05	−4	29.1	0.14	−2
LBY54	92084.7	1176.6	0.09	17	—	—	—	—	—	—
LBY54	92084.8	1045.0	0.21	3	—	—	—	—	—	—
LBY54	92086.1	—	—	—	36.4	0.08	−3	29.1	0.14	−2
LBY49	92039.4	1155.0	L	14	36.5	0.11	−2	29.4	0.29	−2
LBY49	92041.1	1072.5	0.16	6	—	—	—	—	—	—
LBY35	92119.1	1091.2	0.29	8	—	—	—	—	—	—
LBY29	91619.1	1080.6	0.01	7	36.4	0.08	−3	29.1	0.11	−2
LBY29	91619.2	1038.1	0.25	3	36.2	0.20	−3	—	—	—
LBY25	91336.1	1086.9	0.06	8	—	—	—	—	—	—
LBY25	91338.2	—	—	—	36.6	0.15	−2	—	—	—
LBY230	91665.1	1049.4	0.10	4	—	—	—	29.2	0.26	−2
LBY230	91667.2	—	—	—	36.5	0.11	−2	—	—	—
LBY230	91669.2	—	—	—	36.6	0.26	−2	—	—	—
LBY230	91669.3	—	—	—	35.9	0.02	−4	28.3	0.22	−5
LBY23	91396.3	—	—	—	36.2	0.20	−3	—	—	—
LBY23	91397.4	1103.8	L	9	36.6	0.15	−2	—	—	—
LBY23	91398.2	—	—	—	36.8	0.27	−2	—	—	—
LBY225	91605.3	—	—	—	35.9	0.05	−4	28.4	0.29	−5
LBY225	91607.3	—	—	—	36.6	0.15	−2	—	—	—
LBY225	91607.6	—	—	—	36.1	0.04	−3	28.6	0.27	−4
LBY217	92363.1	1160.3	L	15	36.5	0.29	−3	—	—	—
LBY213	92033.1	1095.0	0.17	8	36.8	0.27	−2	—	—	—
LBY213	92033.3	1131.2	0.15	12	35.9	0.05	−4	—	—	—
LBY212	92024.3	1050.6	0.08	4	—	—	—	—	—	—
LBY202	92019.2	1085.6	L	8	—	—	—	—	—	—
LBY202	92021.1	1052.5	0.29	4	—	—	—	—	—	—
LBY202	92022.2	1215.0	L	20	36.2	0.17	−3	29.1	0.29	−3
LBY193	91660.2	1080.0	0.01	7	—	—	—	—	—	—
LBY193	91662.1	1092.6	0.14	8	—	—	—	—	—	—
LBY193	91664.5	1146.9	L	14	36.6	0.15	−2	—	—	—
LBY182	92396.1	1035.6	0.24	3	35.4	0.18	−5	28.2	0.14	−6
LBY182	92396.2	1065.0	0.04	5	—	—	—	—	—	—
LBY182	92398.2	1081.9	0.19	7	35.9	0.05	−4	28.3	0.03	−5
LBY136	91442.1	1048.8	0.12	4	—	—	—	—	—	—
LBY136	91442.2	1068.1	0.02	6	—	—	—	—	—	—
LBY136	91442.6	—	—	—	36.7	0.20	−2	—	—	—
LBY136	91442.8	1098.8	0.02	9	35.8	0.02	−4	28.8	0.05	−3
LBY136	91442.9	—	—	—	36.6	0.15	−2	—	—	—
LBY118	91434.4	1111.9	L	10	—	—	—	—	—	—
CONT.	—	1009.8	—	—	37.4	—	—	29.8	—	—
LBY97	92038.2	—	—	—	28.4	0.05	−4	—	—	—
LBY87	92256.1	—	—	—	28.2	0.02	−4	21.2	L	−6
LBY81	92009.1	—	—	—	28.3	0.07	−4	—	—	—
LBY81	92013.2	—	—	—	28.1	L	−5	21.3	0.05	−5
LBY25	91338.2	—	—	—	28.8	0.18	−2	22.0	0.18	−2
LBY230	91669.2	—	—	—	29.0	0.28	−1	—	—	—
LBY217	92362.2	—	—	—	28.2	0.02	−4	21.5	0.23	−5
LBY138	92078.1	—	—	—	28.1	0.02	−5	L	0.02	−5
LBY138	92078.4	—	—	—	28.6	0.23	−3	21.4	0.03	−5
LBY136	91442.8	—	—	—	28.5	0.04	−3	21.1	L	−6
LBY135	92322.1	—	—	—	—	—	—	21.8	0.12	−3
LBY120	91212.1	—	—	—	—	—	—	21.8	0.12	−3
LBY120	91214.1	—	—	—	28.7	0.19	−3	21.7	0.14	−4
LBY118	91432.3	—	—	—	28.2	0.04	−4	21.2	L	−6
LBY117	91366.1	—	—	—	28.3	0.07	−4	21.5	0.23	−5
LBY117	91366.3	—	—	—	26.6	0.01	−10	21.0	L	−7
LBY117	91367.1	—	—	—	28.3	0.07	−4	—	—	—
LBY115	92073.3	—	—	—	28.6	0.06	−3	—	—	—
LBY112	92051.1	—	—	—	28.1	0.01	−4	21.4	0.03	−5
LBY112	92051.3	—	—	—	28.5	0.04	−3	21.8	0.12	−3
LBY108	91422.2	—	—	—	28.2	0.02	−4	21.8	0.12	−3
LBY108	91423.1	—	—	—	27.9	L	−5	21.0	L	−7
LBY108	91423.4	—	—	—	28.2	0.02	−4	21.6	0.20	−4
LBY104	91267.4	—	—	—	28.7	0.20	−3	—	—	—
LBY103	91381.11	—	—	—	28.3	0.02	−4	21.3	0.01	−5
LBY103	91381.9	—	—	—	27.9	0.02	−5	21.3	0.05	−5
CONT.	—	—	—	—	29.4	—	—	22.5	—	—
LBY96	92428.4	—	—	—	24.6	0.18	−6	18.4	L	−8
LBY79	92221.2	—	—	—	24.9	0.09	−5	—	—	—
LBY79	92223.2	—	—	—	25.6	0.08	−2	19.6	0.14	−2
LBY79	92223.3	—	—	—	25.5	0.06	−3	—	—	—
LBY72	92764.1	—	—	—	25.3	0.14	−3	—	—	—
LBY36	92526.1	—	—	—	24.3	0.28	−7	18.6	0.12	−7
LBY36	92526.2	—	—	—	25.6	0.08	−2	—	—	—
LBY30	92326.1	—	—	—	25.1	0.02	−4	—	—	—
LBY233	92474.3	—	—	—	—	—	—	18.6	0.12	−7
LBY233	92477.3	—	—	—	25.1	L	−4	19.3	0.18	−4
LBY214	92760.3	—	—	—	25.3	0.14	−3	—	—	—
LBY210	92845.2	—	—	—	25.0	L	−4	—	—	—
LBY204	92827.1	—	—	—	—	—	—	19.3	0.18	−4
LBY204	92828.1	—	—	—	25.2	L	−4	—	—	—
LBY187	92813.2	—	—	—	25.1	0.06	−4	—	—	—
LBY165	92678.1	—	—	—	25.1	L	−4	19.1	0.28	−5
LBY165	92678.3	—	—	—	25.0	L	−4	18.7	0.07	−7
LBY137	92751.5	—	—	—	24.7	0.04	−5	18.5	L	−8
LBY127	92744.2	—	—	—	—	—	—	19.2	0.05	−4
LBY127	92748.2	—	—	—	—	—	—	19.3	0.18	−4
LBY126	92834.3	—	—	—	25.1	L	−4	—	—	—
LBY126	92838.1	—	—	—	24.9	L	−5	18.5	0.15	−8
LBY110	91176.1	—	—	—	25.2	0.01	−3	—	—	—
LBY107	92284.3	—	—	—	25.5	0.06	−3	—	—	—
LBY107	92285.2	—	—	—	—	—	—	18.7	0.07	−7
CONT.	—	—	—	—	26.1	—	—	20.0	—	—
LBY91	91630.1	1156.9	0.19	16	35.8	0.19	−2	28.3	0.18	−2
LBY81	92009.1	—	—	—	—	—	—	28.2	0.05	−3
LBY81	92013.2	1096.2	0.03	10	35.8	0.18	−2	27.6	0.18	−5
LBY54	92084.7	1066.2	0.12	7	—	—	—	—	—	—
LBY54	92084.8	1105.0	0.29	11	34.8	0.21	−5	28.1	0.03	−3
LBY54	92087.3	—	—	—	—	—	—	28.4	0.16	−2
LBY49	92039.4	1093.8	0.20	10	35.1	0.09	−4	28.0	0.02	−3
LBY49	92043.1	—	—	—	35.3	0.03	−3	28.3	0.06	−3
LBY49	92043.2	1070.0	0.10	8	—	—	—	—	—	—
LBY35	92122.1	1069.4	0.26	8	—	—	—	—	—	—
LBY29	91619.1	—	—	—	—	—	—	28.3	0.18	−2
LBY29	91619.2	—	—	—	35.6	0.22	−2	28.0	0.02	−3
LBY29	91619.5	1073.1	0.16	8	—	—	—	—	—	—
LBY23	91397.2	—	—	—	35.1	0.02	−4	28.6	0.24	−1
LBY174	92079.7	1065.0	0.12	7	—	—	—	—	—	—
LBY146	91590.2	—	—	—	33.9	0.17	−7	27.6	0.18	−5
LBY146	91590.4	—	—	—	34.2	0.15	−6	27.8	0.01	−4
LBY146	91593.3	—	—	—	—	—	—	27.8	0.01	−4
LBY146	91594.1	1053.1	0.20	6	—	—	—	—	—	—
LBY138	92076.2	1042.5	0.24	5	—	—	—	—	—	—
LBY117	91366.1	—	—	—	—	—	—	28.3	0.18	−2
LBY117	91366.3	1127.5	0.23	14	31.9	0.08	−12	25.0	0.13	−14
LBY115	92071.2	—	—	—	—	—	—	28.5	0.16	−2
LBY112	92053.2	—	—	—	35.8	0.19	−2	28.5	0.16	−2
LBY112	92053.4	—	—	—	35.3	0.03	−3	28.1	0.03	−3
LBY108	91423.1	—	—	—	33.0	L	−10	27.7	0.04	−5
LBY108	91423.4	1091.9	0.29	10	—	—	—	—	—	—
LBY108	91423.6	—	—	—	36.0	0.30	−1	—	—	—
LBY104	91269.2	—	—	—	35.5	0.06	−3	28.2	0.21	−3
LBY103	91381.9	—	—	—	35.5	0.24	−3	—	—	—
CONT.	—	993.3	—	—	36.5	—	—	29.0	—	—

Table 248. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value. L—p<0.01.

TABLE 249
Genes showing improved plant performance at Drought growth
conditions under regulation of At6669 promoter
		Leaf Blade Area [cm2]	Leaf Number	Plot Coverage [cm2]
Gene			P-	%		P-	%		P-	%
Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY83	91330.2	0.741	L	21	—	—	—	44.5	L	22
LBY83	91330.3	0.704	0.05	15	—	—	—	42.1	0.25	16
LBY63	91325.4	—	—	—	10.3	L	5	—	—	—
LBY63	91326.1	—	—	—	10.2	0.27	3	—	—	—
LBY51	90981.1	—	—	—	—	—	—	39.1	0.29	8
LBY48	90968.1	0.658	0.09	7	10.1	0.20	3	40.0	0.07	10
LBY224	91527.4	0.666	0.17	9	—	—	—	40.9	0.04	13
LBY224	91529.1	0.672	0.08	10	10.8	0.11	9	42.7	L	18
LBY224	91529.2	0.679	0.15	11	—	—	—	39.6	0.15	9
LBY196	91300.1	0.688	0.17	12	—	—	—	44.7	0.04	23
LBY196	91303.2	0.726	0.26	19	—	—	—	43.8	0.26	21
LBY196	91304.3	0.685	0.01	12	10.4	0.04	5	40.6	0.04	12
LBY150	91644.3	0.714	0.25	16	—	—	—	—	—	—
LBY134	91282.1	0.696	0.27	14	—	—	—	—	—	—
LBY133	91139.4	—	—	—	10.3	0.17	5	—	—	—
LBY132	91277.1	0.760	0.12	24	10.2	0.09	4	50.1	0.24	38
LBY125	91273.3	0.763	L	24	—	—	—	45.8	L	26
LBY102	91262.1	—	—	—	10.5	0.02	7	—	—	—
CONT.	—	0.613	—	—	9.85	—	—	36.3	—	—
LBY79	92221.2	1.33	L	12	12.4	0.17	18	82.7	0.10	23
LBY79	92221.3	1.37	0.20	16	11.1	L	5	79.5	0.06	18
LBY79	92221.6	1.25	0.27	5	—	—	—	—	—	—
LBY72	92764.1	—	—	—	11.2	0.29	6	—	—	—
LBY72	92765.1	1.42	0.10	20	13.2	0.13	25	93.0	0.11	38
LBY72	92765.3	—	—	—	11.1	0.04	—	—	—	—
LBY72	92766.2	1.30	0.01	9	11.8	L	12	78.5	L	17
LBY72	92766.4	1.28	0.03	8	11.8	0.07	11	74.1	0.03	10
LBY36	92526.1	—	—	—	12.6	0.20	19	—	—	—
LBY32	92830.1	1.49	0.25	26	11.4	0.12	8	88.0	0.13	31
LBY32	92830.3	—	—	—	12.6	L	19	85.6	0.29	27
LBY32	92830.4	—	—	—	11.4	0.01	8	—	—	—
LBY26	92484.4	1.31	L	11	12.1	L	15	83.7	L	24
LBY26	92484.5	1.31	0.27	10	—	—	—	74.8	0.17	11
LBY26	92485.1	1.36	0.17	14	11.7	L	10	82.9	0.07	23
LBY26	92488.1	—	—	—	12.1	0.01	14	—	—	—
LBY733	92474.3	—	—	—	11.5	L	9	—	—	—
LBY233	92477.2	—	—	—	11.8	0.30	11	—	—	—
LBY233	92478.3	—	—	—	11.6	0.18	10	79.1	0.13	18
LBY214	92760.1	—	—	—	11.2	L	6	—	—	—
LBY214	92760.3	—	—	—	11.8	0.19	12	—	—	—
LBY214	92760.4	—	—	—	11.6	0.24	9	—	—	—
LBY214	92761.1	—	—	—	10.8	0.19	2	—	—	—
LBY214	92763.2	—	—	—	11.2	L	6	—	—	—
LBY210	92845.2	1.40	L	18	11.6	L	10	82.9	0.12	23
LBY210	92845.3	—	—	—	11.5	0.15	8	—	—	—
LBY210	92846.1	—	—	—	11.2	0.16	6	77.5	0.21	15
LBY210	92846.2	1.28	0.21	8	—	—	—	—	—	—
LBY204	92825.1	—	—	—	11.4	L	8	—	—	—
LBY204	92826.1	1.33	L	12	12.5	0.14	18	80.8	0.03	20
LBY204	92827.1	1.41	L	18	12.0	0.12	13	87.0	L	29
LBY204	92828.1	1.42	L	19	12.6	0.17	19	91.7	L	36
LBY196	91301.3	—	—	—	11.1	0.02	5	—	—	—
LBY196	91303.2	1.44	L	21	11.8	L	11	88.2	L	31
LBY187	92809.2	1.37	L	15	12.5	L	18	84.9	L	26
LBY187	92813.2	—	—	—	12.0	0.25	13	—	—	—
LBY154	92433.4	—	—	—	11.1	0.02	5	—	—	—
LBY139	92239.1	—	—	—	11.3	0.07	7	—	—	—
LBY137	92751.2	1.27	0.10	7	11.4	0.05	8	77.6	0.14	15
LBY137	92753.1	—	—	—	11.2	0.16	6	—	—	—
LBY126	92834.3	—	—	—	11.7	L	10	—	—	—
LBY126	92837.3	1.32	0.03	11	11.4	0.27	8	76.2	0.23	13
LBY120	91211.2	1.25	0.12	5	11.6	L	9	73.0	0.09	9
LBY120	91212.1	—	—	—	11.1	0.21	5	—	—	—
LBY120	91214.1	1.26	0.14	6	—	—	—	73.7	0.06	10
LBY113	92234.2	1.34	0.02	13	11.9	0.17	13	80.8	L	20
LBY107	92284.1	—	—	—	11.2	0.29	6	—	—	—
LBY107	92284.2	1.26	0.07	6	10.9	0.19	3	—	—	—
CONT.	—	1.19	—	—	10.6	—	—	67.3	—	—
LBY96	92428.4	0.851	0.19	13	—	—	—	47.8	0.04	11
LBY89	92259.2	0.797	0.23	6	—	—	—	45.8	0.28	6
LBY89	92261.6	0.976	L	29	—	—	—	58.4	0.02	36
LBY89	92263.3	—	—	—	10.2	0.25	5	—	—	—
LBY87	92256.1	—	—	—	10.1	0.19	4	—	—	—
LBY87	92257.1	0.821	0.19	9	—	—	—	48.9	0.20	14
LBY87	92257.3	0.933	0.02	23	—	—	—	53.5	0.07	24
LBY55	92419.1	—	—	—	10.1	0.23	3	—	—	—
LBY55	92419.2	—	—	—	10.1	0.23	3	—	—	—
LBY55	92422.5	0.902	0.04	19	—	—	—	49.6	0.13	15
LBY30	92324.2	0.817	0.20	8	10.2	0.21	4	47.8	0.08	11
LBY30	92324.3	—	—	—	10.2	0.10	5	—	—	—
LBY30	92324.4	1.03	L	36	11.0	0.04	13	67.9	L	58
LBY30	92326.2	0.901	L	19	—	—	—	52.4	L	22
LBY225	91605.3	0.872	0.04	15	10.2	0.21	4	48.0	0.10	12
LBY225	91607.2	0.791	0.23	5	10.6	0.28	8	47.2	0.29	10
LBY225	91607.5	0.877	0.16	16	—	—	—	—	—	—
LBY225	91607.6	0.804	0.21	7	—	—	—	46.2	0.16	7
LBY213	92030.2	0.864	0.07	14	—	—	—	—	—	—
LBY213	92033.1	0.934	L	24	10.6	0.01	9	53.6	L	25
LBY213	92033.3	0.952	L	26	10.5	0.02	7	56.0	L	30
LBY212	92024.3	0.906	0.20	20	—	—	—	53.2	0.27	24
LBY212	92026.4	0.948	0.12	26	—	—	—	51.5	0.07	20
LBY212	92028.3	—	—	—	10.1	0.14	4	—	—	—
LBY202	92019.2	0.882	0.03	17	—	—	—	51.5	0.20	20
LBY202	92021.1	0.893	0.17	18	—	—	—	49.9	0.15	16
LBY202	92022.1	0.823	0.06	9	—	—	—	48.8	0.25	14
LBY193	91660.2	—	—	—	10.4	0.05	6	48.5	0.21	13
LBY193	91662.1	0.869	0.25	15	—	—	—	51.6	0.26	20
LBY193	91664.2	—	—	—	10.1	0.14	4	—	—	—
LBY182	92396.1	—	—	—	10.1	0.19	4	46.1	0.16	7
LBY182	92396.2	0.866	0.03	15	—	—	—	—	—	—
LBY182	92396.4	0.790	0.27	5	10.8	0.17	10	47.6	0.06	11
LBY182	92398.3	—	—	—	10.1	0.14	4	—	—	—
LBY174	92079.1	0.905	L	20	—	—	—	—	—	—
LBY174	92079.7	—	—	—	10.2	0.10	5	—	—	—
LBY174	92079.8	0.880	0.29	17	10.2	0.21	4	—	—	—
LBY158	91647.3	0.870	0.07	15	—	—	—	49.2	0.04	14
LBY158	91649.1	0.833	0.10	10	—	—	—	47.0	0.09	9
LBY154	92433.4	1.01	L	34	10.6	L	9	54.7	0.16	27
LBY154	92433.5	—	—	—	10.7	0.24	9	49.9	0.26	16
LBY146	91590.4	0.833	0.04	10	—	—	—	—	—	—
LBY146	91594.1	0.825	0.05	9	—	—	—	49.9	0.18	16
LBY139	92239.2	0.853	0.07	13	10.4	0.17	6	51.0	L	19
LBY139	92241.2	1.01	L	34	10.4	0.02	7	60.9	L	42
LBY135	92321.6	1.04	0.06	38	11.1	L	13	66.7	0.08	55
LBY135	92323.1	0.826	0.05	9	—	—	—	47.5	0.06	10
LBY113	92234.1	0.872	0.10	15	—	—	—	48.5	0.23	13
LBY113	92234.2	0.952	L	26	10.7	0.10	10	52.6	0.28	22
LBY113	92234.5	0.829	0.03	10	10.2	0.10	4	49.0	0.02	14
LBY113	92234.6	0.821	0.24	9	—	—	—	47.1	0.07	9
CONT.	—	0.755	—	—	9.77	—	—	43.0	—	—
LBY91	91633.1	0.918	0.29	17	—	—	—	58.0	0.08	18
LBY91	91634.2	0.861	0.16	10	—	—	—	53.8	0.18	10
LBY77	92062.1	0.950	0.02	22	11.4	0.03	7	63.2	L	29
LBY54	92086.1	0.942	0.08	21	11.7	0.21	9	63.6	0.17	30
LBY35	92119.1	0.827	0.28	6	—	—	—	55.6	0.08	14
LBY29	91619.1	0.912	0.09	17	—	—	—	60.6	0.12	24
LBY29	91619.2	0.917	0.09	17	11.6	0.18	9	62.1	0.08	27
LBY25	91335.2	0.918	0.11	17	—	—	—	60.7	0.18	24
LBY230	91669.3	0.938	0.08	20	11.3	0.03	6	64.1	0.09	31
LBY23	91397.3	0.956	0.16	22	11.4	0.01	7	64.8	0.04	32
LBY225	91605.3	0.944	L	21	11.6	0.25	8	66.0	L	35
LBY225	91607.3	—	—	—	—	—	—	53.8	0.21	10
LBY225	91607.5	0.996	0.07	27	11.9	0.07	12	70.1	L	43
LBY217	92363.1	0.903	0.10	16	—	—	—	—	—	—
LBY202	92022.1	—	—	—	11.2	0.04	5	61.5	0.28	26
LBY202	92022.2	—	—	—	12.0	0.03	12	60.1	0.29	23
LBY193	91664.5	0.827	0.27	6	—	—	—	53.7	0.18	10
LBY182	92396.1	0.963	L	23	—	—	—	63.3	0.02	29
LBY182	92398.2	1.02	L	30	11.4	0.03	7	71.4	L	46
LBY136	91442.1	0.844	0.28	8	—	—	—	57.6	0.19	18
LBY136	91442.6	0.925	L	18	—	—	—	—	—	—
LBY136	91442.8	1.02	L	30	11.4	0.05	7	69.1	0.01	41
LBY136	91442.9	0.979	0.06	25	11.4	0.13	7	67.4	0.14	38
LBY118	91434.5	0.883	0.04	13	11.4	0.03	7	58.8	0.02	20
CONT.	—	0.781	—	—	10.7	—	—	49.0	—	—
LBY97	92034.3	—	—	—	10.1	0.16	4	—	—	—
LBY97	92038.2	0.941	0.13	12	10.7	0.11	10	58.0	0.08	23
LBY87	92255.1	—	—	—	10.2	0.16	5	—	—	—
LBY87	92256.1	0.899	0.26	7	10.9	L	12	—	—	—
LBY87	92258.1	—	—	—	10.2	0.07	6	—	—	—
LBY81	92009.1	0.939	0.08	12	—	—	—	—	—	—
LBY81	92013.1	—	—	—	10.1	0.16	4	—	—	—
LBY25	91335.3	0.946	0.07	12	10.2	0.20	6	55.1	0.08	17
LBY230	91665.1	0.892	0.28	6	—	—	—	50.3	0.29	6
LBY230	91667.1	1.02	L	21	—	—	—	58.6	0.14	24
LBY217	92359.1	—	—	—	10.6	0.25	9	—	—	—
LBY217	92362.2	1.13	L	35	10.6	0.07	10	69.0	L	46
LBY138	92076.2	—	—	—	10.0	0.27	3	—	—	—
LBY138	92078.4	0.938	0.27	11	—	—	—	56.4	0.24	19
LBY136	91442.8	—	—	—	10.1	0.14	4	—	—	—
LBY135	92321.1	—	—	—	10.4	0.27	7	—	—	—
LBY135	92321.6	1.00	L	19	10.1	0.27	4	57.7	L	22
LBY135	92322.1	—	—	—	10.0	0.27	3	—	—	—
LBY120	91212.1	—	—	—	10.0	0.27	3	—	—	—
LBY118	91432.3	1.13	L	34	10.9	0.28	12	65.3	0.02	38
LBY118	91434.5	—	—	—	10.0	0.27	3	51.2	0.20	8
LBY112	92051.1	0.942	0.06	12	10.4	0.02	7	54.4	0.09	15
LBY112	92051.3	1.01	L	20	10.6	L	10	59.9	L	27
LBY112	92053.2	—	—	—	10.0	0.27	3	—	—	—
LBY108	91422.2	—	—	—	10.6	L	9	51.6	0.17	9
LBY108	91423.1	—	—	—	10.6	L	10	55.2	0.06	17
LBY108	91423.4	1.02	0.11	21	10.5	0.01	8	60.0	0.08	27
LBY104	91267.4	0.944	0.05	12	—	—	—	—	—	—
LBY104	91269.2	—	—	—	10.8	0.24	11	—	—	—
LBY103	91381.11	0.950	0.07	13	10.2	0.07	5	56.2	0.01	19
LBY103	91381.9	—	—	—	—	—	—	54.2	0.21	15
CONT.	—	0.841	—	—	9.70	—	—	47.3	—	—
LBY96	92425.4	—	—	—	—	—	—	59.2	0.22	5
LBY96	92428.4	1.28	L	30	11.4	0.14	9	77.7	0.08	38
LBY89	92259.1	1.03	0.26	4	10.8	0.24	3	—	—	—
LBY89	92259.2	—	—	—	10.9	0.10	4	58.4	0.25	3
LBY89	92261.6	—	—	—	11.0	0.06	4	—	—	—
LBY79	92221.2	1.28	0.16	29	11.2	0.13	7	71.5	0.08	27
LBY72	92764.1	1.08	0.06	9	—	—	—	64.9	0.30	15
LBY72	92765.1	—	—	—	10.9	0.20	3	65.6	0.17	16
LBY72	92766.2	—	—	—	11.2	0.08	6	—	—	—
LBY72	92766.4	1.15	0.20	16	11.4	L	9	70.1	0.17	24
LBY36	92526.1	1.21	0.30	23	11.6	0.05	10	74.1	0.26	31
LBY36	92526.2	—	—	—	—	—	—	59.4	0.26	5
LBY32	92833.2	1.18	0.06	19	11.6	0.05	10	66.8	0.14	18
LBY30	92324.2	1.13	L	15	—	—	—	59.4	0.28	5
LBY30	92324.4	1.13	0.02	14	—	—	—	66.7	0.19	18
LBY30	92326.2	1.14	0.25	15	11.0	0.10	4	67.2	0.10	19
LBY233	92477.3	—	—	—	11.1	0.03	6	61.2	0.11	8
LBY233	92478.3	1.05	0.11	6	—	—	—	59.1	0.25	5
LBY214	92760.1	1.13	0.25	14	—	—	—	—	—	—
LBY214	92760.3	1.06	0.10	7	—	—	—	—	—	—
LBY214	92760.4	—	—	—	11.1	0.30	5	—	—	—
LBY214	92761.1	—	—	—	—	—	—	63.7	0.26	13
LBY210	92845.2	—	—	—	11.6	0.29	10	71.4	0.30	27
LBY210	92846.2	1.21	0.15	23	—	—	—	66.5	0.27	18
LBY210	92846.3	—	—	—	11.1	0.18	6	—	—	—
LBY204	92826.1	1.07	0.09	8	—	—	—	60.8	0.02	8
LBY204	92827.1	—	—	—	11.2	0.02	6	—	—	—
LBY204	92828.1	1.10	0.05	11	—	—	—	—	—	—
LBY187	92809.2	—	—	—	11.0	0.10	4	62.2	L	10
LBY187	92813.2	—	—	—	11.3	L	7	61.5	0.18	9
LBY165	92677.7	—	—	—	11.1	0.30	5	—	—	—
LBY165	92678.1	1.05	0.17	6	—	—	—	59.1	0.11	5
LBY165	92678.3	1.27	0.08	28	—	—	—	70.6	0.03	25
LBY137	92751.5	—	—	—	12.0	0.03	14	74.1	0.21	31
LBY137	92752.1	—	—	—	11.4	L	8	—	—	—
LBY137	92753.1	—	—	—	10.9	0.20	3	—	—	—
LBY127	92744.1	—	—	—	10.8	0.24	3	—	—	—
LBY127	92744.2	—	—	—	—	—	—	62.3	0.27	11
LBY127	92745.4	1.04	0.22	5	—	—	—	59.9	0.05	6
LBY126	92834.3	1.12	0.05	13	—	—	—	65.5	0.23	16
LBY126	92838.1	—	—	—	11.0	0.26	4	—	—	—
LBY110	91176.1	1.08	0.28	9	10.9	0.22	4	—	—	—
LBY110	91177.3	1.23	0.05	24	10.8	0.24	3	72.0	0.22	28
LBY110	91179.3	1.09	0.02	10	11.4	0.25	9	64.1	0.08	14
LBY107	92284.3	1.13	0.28	14	—	—	—	—	—	—
LBY107	92285.2	1.39	L	40	—	—	—	82.6	L	46
CONT.	—	0.991	—	—	10.5	—	—	56.4	—	—
LBY91	91633.2	1.65	0.11	15	—	—	—	109.8	L	23
LBY91	91634.3	—	—	—	12.6	0.03	7	94.6	0.28	6
LBY81	92009.1	—	—	—	13.0	0.03	10	—	—	—
LBY81	92009.4	—	—	—	12.6	0.20	7	95.0	0.30	7
LBY81	92013.2	—	—	—	12.9	0.07	10	—	—	—
LBY77	92062.1	1.61	0.09	12	12.5	0.14	6	106.4	L	20
LBY54	92084.8	1.66	0.25	16	12.6	0.03	7	109.1	0.19	23
LBY54	92087.3	—	—	—	12.9	L	9	—	—	—
LBY49	92039.4	—	—	—	—	—	—	101.9	0.11	15
LBY49	92043.1	1.52	0.27	6	12.5	0.06	6	101.5	0.30	14
LBY35	92122.1	—	—	—	—	—	—	97.2	0.26	9
LBY29	91619.1	1.57	0.11	10	—	—	—	—	—	—
LBY29	91619.5	1.60	0.07	12	—	—	—	99.8	0.07	12
LBY23	91397.2	1.56	0.10	9	—	—	—	—	—	—
LBY23	91397.3	—	—	—	12.5	0.14	6	—	—	—
LBY174	92079.8	—	—	—	12.5	0.05	6	—	—	—
LBY158	91648.1	—	—	—	12.6	0.03	7	95.2	0.29	7
LBY146	91594.1	1.54	0.21	8	—	—	—	97.9	0.11	10
LBY138	92076.1	1.52	0.29	6	13.0	0.19	10	102.9	0.20	16
LBY138	92076.2	—	—	—	12.6	0.17	6	104.9	0.24	18
LBY138	92078.3	—	—	—	12.3	0.13	4	—	—	—
LBY117	91366.3	1.72	0.23	20	—	—	—	—	—	—
LBY117	91367.2	—	—	—	12.7	0.02	7	—	—	—
LBY112	92051.3	—	—	—	12.9	0.16	10	101.2	0.04	14
LBY112	92053.2	—	—	—	12.5	0.05	6	—	—	—
LBY112	92053.4	—	—	—	12.4	0.11	5	105.4	0.01	19
LBY108	91423.1	1.78	0.02	24	12.4	0.23	5	113.7	L	28
LBY108	91423.4	—	—	—	12.7	0.04	7	—	—	—
LBY108	91423.6	1.56	0.10	9	—	—	—	99.1	0.08	12
LBY104	91269.2	1.83	0.22	28	12.8	0.16	8	121.0	0.06	36
LBY103	91381.9	—	—	—	13.1	0.06	11	—	—	—
CONT.	—	1.43	—	—	11.8	—	—	88.9	—	—

Table 249. “CONT.”—Contro; Ave.—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 250
Genes showing improved plant performance at Drought growth
conditions under regulation of At6669 promoter
		RGR Of Leaf	RGR Of Plot	RGR Of Rosette
		Number	Coverage	Diameter
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY83	91330.2	—	—	—	4.58	0.20	20	0.332	0.15	20
LBY63	91329.3	0.640	0.17	19	—	—	—	—	—	—
LBY224	91529.1	—	—	—	4.51	0.25	18	—	—	—
LBY196	91300.1	—	—	—	4.64	0.17	22	—	—	—
LBY196	91303.2	—	—	—	4.56	0.21	20	—	—	—
LBY150	91644.3	—	—	—	4.45	0.29	17	—	—	—
LBY133	91139.4	0.622	0.25	15	—	—	—	—	—	—
LBY132	91277.1	—	—	—	5.08	0.04	33	—	—	—
LBY125	91273.3	—	—	—	4.81	0.10	26	—	—	—
CONT.	—	0.540	—	—	3.82	—	—	0.278	—	—
LBY79	92221.2	0.754	0.19	15	10.0	0.07	21	0.502	0.10	11
LBY79	92221.3	—	—	—	9.52	0.20	15	0.488	0.28	8
LBY72	92765.1	0.810	0.06	24	11.3	L	36	—	—	—
LBY72	92765.3	0.732	0.23	12	—	—	—	—	—	—
LBY72	92766.2	—	—	—	9.65	0.15	16	—	—	—
LBY36	92526.1	0.875	L	34	9.68	0.19	17	—	—	—
LBY32	92830.1	—	—	—	10.6	0.03	27	0.512	0.08	13
LBY32	92830.3	0.776	0.15	19	10.3	0.06	24	—	—	—
LBY32	92830.4	0.744	0.18	14	—	—	—	—	—	—
LBY32	92833.2	—	—	—	9.59	0.20	16	—	—	—
LBY26	92484.4	0.752	0.20	15	10.2	0.05	23	—	—	—
LBY26	92485.1	—	—	—	10.2	0.05	23	—	—	—
LBY26	92488.1	0.776	0.08	19	—	—	—	—	—	—
LBY233	92477.1	0.758	0.16	16	—	—	—	—	—	—
LBY233	92477.2	0.742	0.26	13	—	—	—	—	—	—
LBY233	92478.3	—	—	—	9.74	0.13	17	—	—	—
LBY214	92760.1	0.744	0.17	14	—	—	—	—	—	—
LBY214	92760.3	0.750	0.18	15	—	—	—	—	—	—
LBY214	92760.4	0.772	0.09	18	—	—	—	—	—	—
LBY210	92845.2	—	—	—	10.2	0.05	22	0.502	0.12	11
LBY210	92845.3	0.763	0.15	17	—	—	—	—	—	—
LBY210	92846.1	—	—	—	9.52	0.20	15	—	—	—
LBY204	92826.1	0.811	0.06	24	9.85	0.11	19	0.487	0.26	8
LBY204	92827.1	0.756	0.17	16	10.8	0.01	30	0.502	0.10	11
LBY204	92828.1	0.790	0.10	21	11.2	L	34	0.505	0.10	12
LBY196	91301.3	0.739	0.19	13	—	—	—	—	—	—
LBY196	91303.2	—	—	—	10.7	0.01	29	0.499	0.12	10
LBY187	92809.2	0.814	0.05	24	10.4	0.03	25	0.486	0.26	7
LBY187	92813.2	0.752	0.23	15	9.53	0.20	—	—	—	—
LBY137	92751.2	—	—	—	9.50	0.21	15	0.498	0.15	10
LBY126	92834.3	—	—	—	10.1	0.08	21	—	—	—
LBY126	92837.4	0.780	0.07	19	—	—	—	—	—	—
LBY120	91211.2	0.730	0.29	11	—	—	—	—	—	—
LBY120	91212.1	0.722	0.29	10	—	—	—	—	—	—
LBY113	92234.2	—	—	—	9.78	0.11	18	—	—	—
CONT.	—	0.654	—	—	8.30	—	—	0.453	—	—
LBY96	92428.4	—	—	—	—	—	—	0.352	0.24	12
LBY89	92261.6	—	—	—	6.84	0.02	36	0.355	0.22	13
LBY87	92257.3	—	—	—	6.22	0.12	23	0.352	0.26	12
LBY55	92422.5	—	—	—	—	—	—	0.354	0.26	13
LBY30	92324.3	0.747	0.19	22	—	—	—	—	—	—
LBY30	92324.4	—	—	—	7.73	L	53	0.363	0.15	16
LBY30	92326.2	—	—	—	6.05	0.17	20	—	—	—
LBY225	91605.3	—	—	—	—	—	—	0.358	0.19	14
LBY225	91607.2	0.734	0.23	20	—	—	—	—	—	—
LBY225	91607.3	—	—	—	—	—	—	0.352	0.30	12
LBY213	92030.2	—	—	—	5.83	0.29	16	—	—	—
LBY213	92033.1	—	—	—	6.26	0.10	24	0.353	0.24	13
LBY213	92033.3	—	—	—	6.48	0.06	29	0.352	0.26	12
LBY212	92024.3	—	—	—	6.18	0.13	23	—	—	—
LBY212	92026.4	—	—	—	6.01	0.20	19	0.371	0.13	18
LBY202	92019.2	—	—	—	6.08	0.16	21	0.370	0.09	18
LBY202	92021.1	—	—	—	5.83	0.28	16	0.359	0.19	14
LBY193	91662.1	—	—	—	5.93	0.24	18	—	—	—
LBY182	92396.4	0.728	0.24	19	—	—	—	—	—	—
LBY174	92079.1	—	—	—	5.95	0.22	18	—	—	—
LBY174	92079.8	—	—	—	5.81	0.30	15	—	—	—
LBY158	91647.3	—	—	—	—	—	—	0.352	0.26	12
LBY154	92433.4	—	—	—	6.23	0.11	24	0.365	0.14	16
LBY154	92433.5	0.735	0.22	20	—	—	—	—	—	—
LBY139	92239.2	—	—	—	5.96	0.21	18	—	—	—
LBY139	92241.2	—	—	—	7.03	0.01	40	0.362	0.15	15
LBY135	92321.6	—	—	—	7.65	L	52	0.357	0.22	14
LBY135	92322.1	—	—	—	6.06	0.18	20	—	—	—
LBY113	92234.2	—	—	—	6.07	0.17	20	0.375	0.07	20
CONT.	—	0.613	—	—	5.04	—	—	0.314	—	—
LBY91	91633.1	—	—	—	6.93	0.20	19	—	—	—
LBY77	92062.1	—	—	—	7.50	0.06	29	0.384	0.18	13
LBY54	92086.1	—	—	—	7.48	0.07	28	0.385	0.19	14
LBY35	92120.2	—	—	—	6.92	0.25	19	—	—	—
LBY29	91617.1	—	—	—	7.08	0.24	22	—	—	—
LBY29	91619.1	—	—	—	7.14	0.14	23	0.376	0.29	11
LBY279	91619.2	—	—	—	7.25	0.11	24	—	—	—
LBY25	91335.2	—	—	—	7.15	0.14	23	0.384	0.20	13
LBY230	91669.3	—	—	—	7.62	0.05	31	0.386	0.20	14
LBY23	91397.3	—	—	—	7.68	0.04	32	0.386	0.17	14
LBY225	91605.3	—	—	—	7.86	0.03	35	0.384	0.19	13
LBY225	91607.5	—	—	—	8.34	L	43	0.381	0.21	12
LBY213	92033.3	—	—	—	7.23	0.17	24	0.383	0.26	13
LBY212	92026.3	—	—	—	7.08	0.19	22	—	—	—
LBY202	92022.1	—	—	—	7.19	0.14	23	—	—	—
LBY202	92022.2	—	—	—	7.19	0.12	23	—	—	—
LBY182	92396.1	—	—	—	7.61	0.05	31	0.400	0.07	18
LBY182	92398.2	—	—	—	8.54	L	47	0.405	0.06	19
LBY136	91442.1	—	—	—	6.84	0.26	17	—	—	—
LBY136	91442.8	—	—	—	8.24	0.01	41	0.403	0.07	19
LBY136	91442.9	—	—	—	8.03	0.02	38	0.375	0.28	10
LBY118	91434.5	—	—	—	6.83	0.25	17	—	—	—
CONT.	—	—	—	—	5.83	—	—	0.339	—	—
LBY97	92038.2	—	—	—	7.49	0.09	22	—	—	—
LBY87	92256.1	—	—	—	7.16	0.20	17	—	—	—
LBY25	91335.3	—	—	—	7.01	0.26	14	—	—	—
LBY230	91667.1	—	—	—	7.56	0.08	23	—	—	—
LBY217	92362.2	—	—	—	8.95	L	46	0.485	0.02	21
LBY138	92078.4	—	—	—	7.14	0.20	16	—	—	—
LBY135	92321.1	—	—	—	7.02	0.28	14	—	—	—
LBY135	92321.6	—	—	—	7.45	0.09	21	—	—	—
LBY118	91432.3	—	—	—	8.43	L	37	0.458	0.09	15
LBY117	91366.1	—	—	—	7.09	0.24	16	—	—	—
LBY112	92051.1	—	—	—	7.00	0.26	14	—	—	—
LBY112	92051.3	—	—	—	7.78	0.04	27	—	—	—
LBY108	91423.1	—	—	—	7.08	0.23	15	—	—	—
LBY108	91423.4	—	—	—	7.83	0.04	28	0.451	0.16	13
LBY104	91269.2	0.821	0.13	29	—	—	—	—	—	—
LBY103	91381.11	—	—	—	7.23	0.16	18	—	—	—
LBY103	91381.9	—	—	—	6.96	0.29	13	—	—	—
CONT.	—	0.636	—	—	6.13	—	—	0.399	—	—
LBY96	92428.4	—	—	—	7.83	L	37	0.441	L	16
LBY89	92263.1	—	—	—	6.50	0.2.5	13	0.408	0.12	8
LBY79	92221.2	—	—	—	7.30	0.01	27	0.432	L	14
LBY79	92223.2	—	—	—	6.40	0.28	12	0.413	0.08	9
LBY72	92764.1	—	—	—	6.61	0.15	15	—	—	—
LBY72	92765.1	—	—	—	6.50	0.21	13	—	—	—
LBY72	92766.2	—	—	—	6.88	0.10	20	0.420	0.07	11
LBY72	92766.4	—	—	—	7.08	0.04	24	0.411	0.07	9
LBY36	92526.1	—	—	—	7.49	0.01	31	0.413	0.09	9
LBY32	92830.1	—	—	—	6.41	0.27	12	—	—	—
LBY35	92830.3	—	—	—	6.76	0.15	18	0.422	0.05	12
LBY32	92830.4	0.639	0.24	12	—	—	—	—	—	—
LBY32	92833.2	—	—	—	6.80	0.09	19	0.404	0.17	7
LBY30	92324.4	—	—	—	6.79	0.09	18	0.404	0.17	7
LBY30	92326.2	—	—	—	6.79	0.09	19	—	—	—
LBY30	92326.3	—	—	—	6.45	0.26	13	—	—	—
LBY233	92474.3	—	—	—	6.48	0.24	13	—	—	—
LBY233	92477.1	—	—	—	6.49	0.23	13	—	—	—
LBY214	92760.1	—	—	—	6.51	0.21	14	—	—	—
LBY214	92761.1	—	—	—	6.58	0.16	15	0.406	0.14	7
LBY210	92845.2	—	—	—	7.27	0.02	27	0.409	0.13	8
LBY210	92846.1	0.639	0.25	12	—	—	—	—	—	—
LBY210	92846.2	—	—	—	6.79	0.10	18	0.417	0.04	10
LBY204	92827.1	—	—	—	6.77	0.14	18	0.404	0.29	7
LBY187	92812.1	—	—	—	—	—	—	0.401	0.20	6
LBY165	92678.3	—	—	—	7.20	0.02	26	0.427	0.01	13
LBY137	92751.5	—	—	—	7.47	0.01	30	0.427	0.01	13
LBY137	92752.1	—	—	—	6.51	0.22	14	—	—	—
LBY127	92744.2	—	—	—	6.40	0.27	12	—	—	—
LBY126	92834.3	—	—	—	6.69	0.12	17	0.413	0.08	9
LBY126	92837.3	—	—	—	6.51	0.23	14	—	—	—
LBY110	91177.3	—	—	—	7.27	0.03	27	0.439	L	16
LBY110	91179.3	—	—	—	6.55	0.18	14	—	—	—
LBY107	92285.2	—	—	—	8.35	L	46	0.463	L	22
CONT.	—	0.571	—	—	5.73	—	—	0.378	—	—
LBY91	91633.2	—	—	—	12.5	0.20	23	—	—	—
LBY81	92009.1	0.593	0.18	32	—	—	—	—	—	—
LBY81	92013.2	—	—	—	12.1	0.30	19	—	—	—
LBY77	92062.1	—	—	—	12.3	0.24	21	—	—	—
LBY54	92084.8	—	—	—	12.7	0.18	25	—	—	—
LBY54	92087.3	0.582	0.24	30	—	—	—	—	—	—
LBY35	92119.2	0.576	0.22	28	—	—	—	—	—	—
LBY158	91648.1	0.575	0.21	28	—	—	—	—	—	—
LBY117	91366.3	—	—	—	12.1	0.28	19	—	—	—
LBY112	92051.3	0.564	0.27	26	—	—	—	—	—	—
LBY112	92053.4	—	—	—	12.1	0.29	19	—	—	—
LBY112	92053.6	0.580	0.22	29	—	—	—	—	—	—
LBY108	91423.1	—	—	—	13.0	0.13	28	—	—	—
LBY108	91423.4	0.562	0.29	25	—	—	—	—	—	—
LBY104	91269.2	—	—	—	13.8	0.06	36	—	—	—
LBY103	91381.9	0.619	0.12	38	—	—	—	—	—	—
CONT.	—	0.449	—	—	10.2	—	—	—	—	—

Table 250. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 251
Genes showing improved plant petformance at Drought growth conditions under regulation
of At6669 promoter
Gene		Harvest Index	Rosette Area [cm2]	Rosette Diameter [cm]
Name	Event #	Ave.	P-Val.	% Incr.	Ave.	P-Val.	% Incr.	Ave.	P-Val.	% Incr.
LBY83	91330.1	0.204	0.10	20	—	—	—	4.16	0.17	7
LBY83	91330.2	—	—	—	5.56	L	22	4.71	0.01	21
LBY83	91330.3	—	—	—	5.26	0.25	16	4.28	L	10
LBY63	91325.1	0.186	0.05	9	—	—	—	—	—	—
LBY63	91325.2	0.192	0.03	13	—	—	—	—	—	—
LBY63	91325.4	0.197	0.10	16	—	—	—	—	—	—
LBY51	90981.1	—	—	—	4.89	0.29	8	4.15	0.03	7
LBY48	90968.1	—	—	—	5.00	0.07	10	4.15	0.12	7
LBY48	90970.2	—	—	—	—	—	—	4.16	0.13	7
LBY224	91527.4	—	—	—	5.11	0.04	13	4.23	0.02	9
LBY224	91529.1	—	—	—	5.34	L	18	4.15	0.05	7
LBY224	91529.2	—	—	—	4.95	0.15	9	4.11	0.20	6
LBY196	91300.1	—	—	—	5.59	0.04	23	4.41	0.12	13
LBY196	91303.2	—	—	—	5.47	0.26	21	4.36	0.12	12
LBY196	91304.3	—	—	—	5.07	0.04	12	4.23	L	9
LBY134	91281.5	—	—	—	—	—	—	4.17	0.25	7
LBY134	91282.1	—	—	—	4.88	0.17	7	4.18	0.02	7
LBY132	91277.1	—	—	—	6.26	0.24	38	4.64	0.12	19
LBY125	91273.3	—	—	—	5.73	L	26	4.48	0.03	15
LBY102	91262.1	—	—	—	—	—	—	4.10	0.16	5
LBY102	91262.8	0.192	0.07	13	—	—	—	—	—	—
LBY102	91264.1	0.241	0.07	41	—	—	—	—	—	—
CONT.	—	0.170	—	—	4.54	—	—	3.89	—	—
LBY79	92221.2	—	—	—	10.3	0.10	23	5.69	L	14
LBY79	92221.3	—	—	—	9.94	0.06	18	—	—	—
LBY72	92765.1	—	—	—	11.6	0.11	38	5.71	0.17	14
LBY72	92766.2	—	—	—	9.81	L	17	5.37	0.10	7
LBY72	92766.4	—	—	—	9.26	0.03	10	5.21	0.09	4
LBY32	92830.1	—	—	—	11.0	0.13	31	5.86	0.17	17
LBY32	92830.3	—	—	—	10.7	0.29	27	—	—	—
LBY26	92484.4	—	—	—	10.5	L	24	5.47	L	9
LBY26	92484.5	—	—	—	9.35	0.17	11	—	—	—
LBY26	92485.1	—	—	—	10.4	0.07	23	5.40	0.18	8
LBY233	92477.2	—	—	—	—	—	—	5.26	0.20	5
LBY233	92478.3	—	—	—	9.89	0.13	18	5.32	0.16	6
LBY210	92845.2	—	—	—	10.4	0.12	23	5.65	0.07	13
LBY210	92846.1	—	—	—	9.69	0.21	15	5.34	0.26	7
LBY210	92846.2	—	—	—	—	—	—	5.12	0.26	2
LBY204	92826.1	—	—	—	10.1	0.03	20	5.42	0.02	8
LBY204	92827.1	—	—	—	10.9	L	29	5.59	L	12
LBY204	92828.1	—	—	—	11.5	L	36	5.86	0.02	17
LBY196	91303.2	—	—	—	11.0	L	31	5.73	L	15
LBY187	92809.2	—	—	—	10.6	L	26	5.54	L	11
LBY137	92751.2	—	—	—	9.69	0.14	15	5.43	0.09	9
LBY126	92837.3	—	—	—	9.53	0.23	13	—	—	—
LBY120	91211.2	—	—	—	9.13	0.09	9	5.19	0.09	4
LBY120	91214.1	—	—	—	9.21	0.06	10	5.16	0.18	3
LBY113	92234.2	—	—	—	10.1	L	20	5.45	L	9
LBY107	92284.2	—	—	—	—	—	—	5.17	0.12	3
CONT.	—	—	—	—	8.41	—	—	5.00	—	—
LBY96	92428.4	—	—	—	5.97	0.04	11	4.44	L	8
LBY89	92259.2	—	—	—	5.72	0.28	6	—	—	—
LBY89	92261.6	—	—	—	7.30	0.02	36	4.70	L	15
LBY89	92263.3	—	—	—	—	—	—	4.35	0.24	6
LBY87	92257.1	—	—	—	6.11	0.20	14	—	—	—
LBY87	92257.3	—	—	—	6.69	0.07	24	4.55	0.12	11
LBY55	92422.5	—	—	—	6.20	0.13	15	4.49	0.05	10
LBY30	92324.2	—	—	—	5.97	0.08	11	4.38	0.06	7
LBY30	92324.4	—	—	—	8.49	L	58	5.04	L	23
LBY30	92326.2	—	—	—	6.55	L	22	4.54	L	11
LBY225	91605.3	—	—	—	6.00	0.10	12	4.47	0.13	9
LBY225	91607.2	—	—	—	5.90	0.29	10	4.31	0.04	5
LBY225	91607.5	—	—	—	—	—	—	4.35	0.19	6
LBY225	91607.6	—	—	—	5.78	0.16	7	4.30	0.05	5
LBY213	92030.2	—	—	—	—	—	—	4.40	0.07	7
LBY213	92033.1	0.280	0.04	24	6.71	L	25	4.62	L	13
LBY213	92033.3	—	—	—	7.01	L	30	4.71	L	15
LBY212	92024.2	0.259	0.19	15	—	—	—	—	—	—
LBY212	92024.3	—	—	—	6.65	0.27	24	4.58	0.19	12
LBY212	92026.4	—	—	—	6.44	0.07	20	4.62	0.20	13
LBY202	92019.2	—	—	—	6.43	0.20	20	4.56	0.08	11
LBY202	92021.1	—	—	—	6.24	0.15	16	4.45	0.22	8
LBY202	92022.1	0.256	0.21	14	6.10	0.25	14	4.28	0.24	4
LBY193	91660.2	—	—	—	6.07	0.21	13	—	—	—
LBY193	91662.1	—	—	—	6.45	0.26	20	4.48	0.19	9
LBY193	91664.1	0.265	0.12	18	—	—	—	—	—	—
LBY182	92396.1	—	—	—	5.76	0.16	7	4.28	0.06	4
LBY182	92396.2	—	—	—	—	—	—	4.51	0.23	10
LBY182	92396.4	—	—	—	5.95	0.06	11	4.25	0.14	4
LBY174	92079.1	—	—	—	—	—	—	4.50	L	10
LBY174	92079.8	—	—	—	—	—	—	4.46	0.13	9
LBY174	92080.1	0.270	0.12	20	—	—	—	—	—	—
LBY158	91647.3	—	—	—	6.15	0.04	14	4.63	L	13
LBY158	91649.1	—	—	—	5.87	0.09	9	4.42	0.09	8
LBY154	92433.4	—	—	—	7.30	L	36	4.88	L	19
LBY154	92433.5	—	—	—	6.23	0.26	16	—	—	—
LBY146	91590.4	—	—	—	—	—	—	4.29	0.28	5
LBY146	91594.1	—	—	—	6.24	0.18	16	4.29	0.29	5
LBY139	92239.2	—	—	—	6.38	L	19	4.32	0.04	5
LBY139	92241.2	—	—	—	7.62	L	42	4.87	0.06	19
LBY135	92321.6	0.255	0.25	13	8.34	0.08	55	4.95	0.06	21
LBY135	92322.1	0.265	0.23	17	—	—	—	—	—	—
LBY135	92323.1	—	—	—	5.94	0.06	10	4.36	0.02	6
LBY113	92234.1	—	—	—	6.07	0.23	13	4.35	0.24	6
LBY113	92234.2	0.272	0.09	21	7.00	L	30	4.70	L	15
LBY113	92234.5	0.277	0.06	23	6.13	0.02	14	4.40	0.03	7
LBY113	92234.6	0.285	0.13	27	5.88	0.07	9	4.22	0.29	3
LBY113	92235.2	—	—	—	—	—	—	4.26	0.09	4
CONT.	—	0.225	—	—	5.38	—	—	4.10	—	—
LBY91	91633.1	0.232	0.01	28	7.25	0.08	18	4.65	0.17	8
LBY91	91633.2	0.237	0.04	31	—	—	—	—	—	—
LBY91	91634.2	0.220	0.19	21	6.72	0.18	10	—	—	—
LBY77	92062.1	—	—	—	7.90	L	29	4.85	L	13
LBY54	92086.1	0.221	0.03	22	7.95	0.17	30	4.90	0.17	14
LBY35	92119.1	—	—	—	6.95	0.08	14	4.55	0.06	6
LBY29	91619.1	—	—	—	7.58	0.12	24	4.85	0.10	13
LBY29	91619.2	—	—	—	7.76	0.08	27	4.83	0.02	12
LBY25	91335.2	—	—	—	7.59	0.18	24	4.94	0.11	15
LBY230	91669.2	0.202	0.27	11	—	—	—	—	—	—
LBY230	91669.3	0.243	L	34	8.01	0.09	31	4.89	0.17	14
LBY23	91397.3	—	—	—	8.10	0.04	32	4.91	0.06	14
LBY225	91605.3	0.216	0.14	19	8.25	L	35	4.86	0.04	13
LBY225	91607.2	0.199	0.25	10	—	—	—	—	—	—
LBY225	91607.3	0.206	0.13	14	6.72	0.21	10	4.59	0.03	7
LBY225	91607.5	—	—	—	8.77	L	43	5.03	L	17
LBY225	91607.6	0.245	L	35	—	—	—	—	—	—
LBY217	92363.1	—	—	—	—	—	—	4.67	0.08	9
LBY202	92022.1	—	—	—	7.69	0.28	26	4.84	0.26	13
LBY202	92022.2	—	—	—	7.51	0.29	23	—	—	—
LBY193	91664.5	—	—	—	6.71	0.18	10	4.47	0.29	4
LBY182	92396.1	0.234	L	29	7.92	0.02	29	4.93	L	15
LBY182	92398.2	0.204	0.25	12	8.92	L	46	5.14	L	20
LBY136	91442.1	—	—	—	7.20	0.19	18	4.68	0.10	9
LBY136	91442.6	—	—	—	7.45	0.14	22	4.86	0.08	13
LBY136	91442.8	0.208	0.14	15	8.63	0.01	41	5.04	0.03	17
LBY136	91442.9	—	—	—	8.43	0.14	38	4.90	0.02	14
LBY118	91432.3	0.209	0.13	15	—	—	—	—	—	—
LBY118	91434.4	—	—	—	—	—	—	4.44	0.23	3
LBY118	91434.5	—	—	—	7.34	0.02	20	4.68	0.01	9
CONT.	—	0.181	—	—	6.12	—	—	4.30	—	—
LBY97	92038.2	—	—	—	7.25	0.08	23	4.73	0.16	8
LBY87	92256.1	—	—	—	—	—	—	4.66	0.18	7
LBY25	91335.3	—	—	—	6.89	0.08	17	4.62	0.30	5
LBY230	91665.1	—	—	—	6.29	0.29	6	4.64	0.13	6
LBY230	91667.1	—	—	—	7.33	0.14	24	4.84	0.06	11
LBY217	92362.2	—	—	—	8.62	L	46	5.30	L	21
LBY217	92363.1	—	—	—	—	—	—	4.61	0.10	5
LBY138	92078.4	—	—	—	7.05	0.24	19	4.66	0.19	6
LBY136	91442.6	—	—	—	—	—	—	4.56	0.26	4
LBY135	92321.6	—	—	—	7.21	L	22	4.80	0.01	10
LBY118	91432.3	—	—	—	8.16	0.02	38	5.07	L	16
LBY118	91434.5	—	—	—	6.40	0.20	8	—	—	—
LBY117	91367.1	—	—	—	—	—	—	4.57	0.21	4
LBY112	92051.1	—	—	—	6.80	0.09	15	4.64	0.17	6
LBY112	92051.3	—	—	—	7.49	L	27	4.78	0.02	9
LBY108	91422.2	—	—	—	6.45	0.17	9	—	—	—
LBY108	91423.1	—	—	—	6.90	0.06	17	4.77	0.02	9
LBY108	91423.4	—	—	—	7.50	0.08	27	4.82	0.23	10
LBY104	91267.4	—	—	—	—	—	—	4.68	0.05	7
LBY103	91381.11	—	—	—	7.03	0.01	19	4.72	0.04	8
LBY103	91381.9	—	—	—	6.78	0.21	15	4.61	0.17	5
CONT.	—	—	—	—	5.91	—	—	4.38	—	—
LBY96	92425.4	—	—	—	7.40	0.22	5	—	—	—
LBY96	92428.4	—	—	—	9.71	0.08	38	5.45	0.11	17
LBY89	92259.2	—	—	—	7.30	0.25	3	—	—	—
LBY89	92263.1	—	—	—	—	—	—	5.09	0.21	9
LBY79	92221.2	—	—	—	8.94	0.08	27	5.23	L	12
LBY72	92764.1	—	—	—	8.11	0.30	15	—	—	—
LBY72	92765.1	—	—	—	8.20	0.17	16	5.05	0.11	8
LBY72	92766.4	—	—	—	8.76	0.17	24	5.14	0.08	10
LBY36	92526.1	—	—	—	9.26	0.26	31	5.26	0.27	13
LBY36	92526.2	—	—	—	7.42	0.26	5	—	—	—
LBY32	92830.1	—	—	—	—	—	—	4.88	0.16	5
LBY32	92833.2	—	—	—	8.35	0.14	18	5.02	0.20	8
LBY30	92324.2	—	—	—	7.43	0.28	5	—	—	—
LBY30	92324.4	—	—	—	8.34	0.19	18	5.00	0.25	7
LBY30	92326.2	—	—	—	8.39	0.10	19	5.13	0.17	10
LBY30	92326.3	—	—	—	—	—	—	4.88	0.16	5
LBY233	92477.1	—	—	—	—	—	—	5.05	0.27	8
LBY233	92477.3	—	—	—	7.65	0.11	8	4.87	0.04	5
LBY233	92478.3	—	—	—	7.39	0.25	5	—	—	—
LBY214	92760.1	—	—	—	—	—	—	4.91	0.14	5
LBY214	92761.1	—	—	—	7.96	0.26	13	5.06	0.21	9
LBY210	92845.2	—	—	—	8.93	0.30	27	5.18	0.30	11
LBY210	92846.2	—	—	—	8.31	0.27	18	4.96	L	7
LBY204	92826.1	—	—	—	7.60	0.02	8	—	—	—
LBY204	92828.1	—	—	—	—	—	—	4.88	0.04	5
LBY187	92809.2	—	—	—	7.78	L	10	—	—	—
LBY187	92812.1	—	—	—	—	—	—	4.82	0.09	4
LBY187	92813.2	—	—	—	7.68	0.18	9	4.79	0.15	3
LBY165	92678.1	—	—	—	7.39	0.11	5	—	—	—
LBY165	92678.3	—	—	—	8.82	0.03	25	5.13	0.14	10
LBY137	92751.5	—	—	—	9.26	0.21	31	5.33	0.03	15
LBY127	92744.2	—	—	—	7.79	0.27	11	—	—	—
LBY127	92745.4	—	—	—	7.49	0.05	6	—	—	—
LBY126	92834.3	—	—	—	8.19	0.23	16	—	—	—
LBY110	91177.3	—	—	—	9.00	0.22	28	5.28	0.20	14
LBY110	91179.3	—	—	—	8.02	0.08	14	4.84	0.29	4
LBY107	92285.2	—	—	—	10.3	L	46	5.70	L	22
CONT.	—	—	—	—	7.05	—	—	4.65	—	—
LBY91	91633.1	0.230	0.03	20	—	—	—	—	—	—
LBY91	91633.2	—	—	—	13.7	L	23	6.20	0.05	9
LBY91	91634.3	—	—	—	11.8	0.28	6	—	—	—
LBY81	92009.4	—	—	—	11.9	0.30	7	—	—	—
LBY77	92062.1	—	—	—	13.3	L	20	—	—	—
LBY54	92084.8	—	—	—	13.6	0.19	23	—	—	—
LBY49	92039.4	—	—	—	12.7	0.11	15	—	—	—
LBY49	92043.1	—	—	—	12.7	0.30	14	—	—	—
LBY35	92119.2	0.208	0.26	8	—	—	—	—	—	—
LBY35	92122.1	—	—	—	12.1	0.26	9	—	—	—
LBY29	91619.1	0.221	0.15	15	—	—	—	—	—	—
LBY29	91619.5	—	—	—	12.5	0.07	12	—	—	—
LBY174	92079.1	0.223	0.14	16	—	—	—	—	—	—
LBY158	91648.1	—	—	—	11.9	0.29	7	—	—	—
LBY146	91590.4	0.226	0.04	17	—	—	—	—	—	—
LBY146	91594.1	—	—	—	12.2	0.11	10	5.93	0.25	4
LBY138	92076.1	—	—	—	12.9	0.20	16	—	—	—
LBY138	92076.2	—	—	—	13.1	0.24	18	—	—	—
LBY117	91366.3	—	—	—	—	—	—	6.07	0.10	7
LBY112	92051.3	—	—	—	12.7	0.04	14	—	—	—
LBY112	92053.4	—	—	—	13.2	0.01	19	6.07	0.24	7
LBY108	91423.1	0.226	0.08	18	14.2	L	28	6.39	L	12
LBY108	91423.6	—	—	—	12.4	0.08	12	5.94	0.22	4
LBY108	91424.1	0.219	0.19	14	—	—	—	—	—	—
LBY104	91269.1	0.232	0.23	21	—	—	—	—	—	—
LBY104	91269.2	0.217	0.20	13	15.1	0.06	36	6.54	0.23	15
CONT.	—	0.192	—	—	11.1	—	—	5.68	—	—

Table 251. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 252
Genes showing improved plant petformance at Drought growth
conditions under regulation of At6669 promoter
					1000 Seed
		Seed Yield [mg]	Weight [mg]
Gene			P-	%		P-	%
Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY83	91330.1	203.5	0.27	13	—	—	—
LBY83	91332.2	211.8	0.27	18	—	—	—
LBY63	91325.1	198.6	0.02	10	—	—	—
LBY63	91325.4	212.8	0.29	18	—	—	—
LBY63	91329.3	198.4	0.04	10	—	—	—
LBY51	90981.3	—	—	—	21.4	0.21	6
LBY48	90967.3	—	—	—	21.1	0.12	4
LBY224	91529.1	—	—	—	21.2	0.20	4
LBY22	90961.2	—	—	—	24.5	0.02	21
LBY150	91644.3	—	—	—	21.5	0.11	6
LBY134	91281.5	—	—	—	20.8	0.25	2
LBY134	91282.1	—	—	—	24.1	0.12	19
LBY133	91139.1	—	—	—	21.1	0.05	4
LBY102	91264.1	264.2	0.24	47	—	—	—
CONT.	—	180.0	—	—	20.3	—	—
LBY96	92428.4	—	—	—	20.2	0.02	13
LBY89	92259.2	—	—	—	18.9	0.28	6
LBY87	92257.1	—	—	—	18.2	0.26	2
LBY55	92422.5	—	—	—	19.4	0.28	9
LBY55	92423.2	—	—	—	19.0	L	7
LBY30	92324.4	—	—	—	19.8	0.28	11
LBY30	92326.2	—	—	—	21.8	0.03	22
LBY225	91607.3	235.5	0.16	14	—	—	—
LBY225	91607.6	—	—	—	20.0	0.03	13
LBY213	92030.2	—	—	—	18.7	0.05	5
LBY213	92033.1	232.1	0.16	13	—	—	—
LBY213	92033.3	228.5	0.29	11	18.8	0.03	5
LBY212	92024.3	234.2	0.26	14	—	—	—
LBY202	92022.1	242.8	0.07	18	—	—	—
LBY202	92022.3	—	—	—	18.2	0.30	2
LBY193	91660.2	—	—	—	21.6	0.03	21
LBY193	91664.1	242.7	0.06	18	18.4	0.12	3
LBY182	92396.2	—	—	—	18.8	0.03	6
LBY174	92079.1	235.5	0.13	14	—	—	—
LBY174	92079.7	—	—	—	18.8	0.11	5
LBY174	92080.1	249.2	0.04	21	—	—	—
LBY154	92433.5	—	—	—	19.2	L	8
LBY146	91590.1	227.6	0.26	11	—	—	—
LBY146	91590.2	233.0	0.28	13	—	—	—
LBY146	91593.3	—	—	—	19.4	0.02	9
LBY135	92322.1	239.5	0.08	16	19.4	0.01	9
LBY135	92323.3	—	—	—	18.4	0.22	4
LBY113	92234.2	225.5	0.28	10	18.8	0.03	6
LBY113	92234.5	247.1	0.04	20	19.0	0.01	7
LBY113	92234.6	247.5	0.09	20	—	—	—
CONT.	—	205.7	—	—	17.8	—	—
LBY91	91630.1	—	—	—	21.1	L	8
LBY91	91633.1	244.1	0.26	34	21.4	L	10
LBY91	91633.2	240.4	0.17	32	—	—	—
LBY91	91634.2	228.4	0.23	25	—	—	—
LBY54	92084.4	241.9	0.29	33	20.5	0.08	5
LBY54	92086.1	239.9	0.07	32	—	—	—
LBY49	92043.2	198.4	0.28	9	—	—	—
LBY35	92122.1	—	—	—	22.3	L	14
LBY29	91617.1	—	—	—	21.3	L	9
LBY29	91619.1	—	—	—	20.7	0.01	6
LBY29	91619.2	—	—	—	20.7	0.02	6
LBY25	91335.2	—	—	—	21.3	0.06	9
LBY230	91669.3	250.4	L	37	20.2	0.10	4
LBY225	91605.3	223.7	0.21	23	—	—	—
LBY225	91607.2	—	—	—	20.3	0.29	4
LBY225	91607.3	210.1	0.16	15	—	—	—
LBY225	91607.6	247.0	L	35	21.8	0.08	12
LBY217	92359.1	—	—	—	20.0	0.24	2
LBY217	92362.2	—	—	—	20.0	0.24	2
LBY217	92363.1	—	—	—	22.0	L	13
LBY212	92026.3	—	—	—	20.5	0.04	5
LBY202	92022.2	—	—	—	24.2	0.22	24
LBY193	91660.2	—	—	—	24.0	L	23
LBY182	92396.1	242.8	L	33	—	—	—
LBY182	92396.4	—	—	—	20.1	0.21	3
LBY182	92398.2	220.8	0.21	21	—	—	—
LBY136	91442.8	228.5	0.02	25	—	—	—
LBY118	91432.3	214.4	0.06	18	—	—	—
LBY118	91433.1	210.4	0.14	15	—	—	—
LBY118	91434.5	—	—	—	20.4	0.15	5
CONT.	—	182.5	—	—	19.5	—	—
LBY91	91630.1	—	—	—	23.2	L	L
LBY91	91633.1	219.2	0.19	16	—	—	—
LBY81	92009.1	—	—	—	21.0	0.26	10
LBY81	92013.2	—	—	—	21.0	L	10
LBY77	92061.1	209.5	0.28	10	—	—	—
LBY54	92086.1	—	—	—	19.6	0.29	3
LBY49	92039.4	—	—	—	21.3	0.04	11
LBY29	91619.1	219.8	0.07	16	—	—	—
LBY174	92079.1	212.4	0.15	12	—	—	—
LBY174	92079.7	—	—	—	19.8	0.18	4
LBY146	91593.3	—	—	—	21.4	0.12	12
LBY138	92076.1	—	—	—	21.1	0.13	10
LBY117	91366.3	—	—	—	25.0	L	31
LBY108	91423.1	219.9	0.14	16	—	—	—
LBY108	91423.4	—	—	—	20.3	0.09	6
LBY108	91424.1	217.3	0.05	14	—	—	—
LBY104	91269.2	222.4	0.02	17	—	—	—
CONT.	—	189.8	—	—	19.1	—	—

Table 252. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value. L—p<0.01.

TABLE 253
Genes showing improved plant performance at Drought
growth conditions under regulation of At6669 promoter
	1000 Seed Weight [mg]
	Gene Name	Event #	Ave.	P-Val.	% Incr.
	LBY51	90981.3	21.4	0.21	6
	LBY48	90967.3	21.1	0.12	4
	LBY224	91529.1	21.2	0.20	4
	LBY22	90961.2	24.5	0.02	21
	LBY150	91644.3	21.5	0.11	6
	LBY134	91281.5	20.8	0.25	2
	LBY134	91282.1	24.1	0.12	19
	LBY133	91139.1	21.1	0.05	4
	CONT.	—	20.3	—	—
	LBY96	92428.4	20.2	0.02	13
	LBY89	92259.2	18.9	0.28	6
	LBY87	92257.1	18.2	0.26	2
	LBY55	92422.5	19.4	0.28	9
	LBY55	92423.2	19.0	L	7
	LBY30	92324.4	19.8	0.28	11
	LBY30	92326.2	21.8	0.03	22
	LBY225	91607.6	20.0	0.03	13
	LBY213	92030.2	18.7	0.05	5
	LBY213	92033.3	18.8	0.03	5
	LBY202	92022.3	18.2	0.30	2
	LBY193	91660.2	21.6	0.03	21
	LBY193	91664.1	18.4	0.12	3
	LBY182	92396.2	18.8	0.03	6
	LBY174	92079.7	18.8	0.11	5
	LBY154	92433.5	19.2	L	8
	LBY146	91593.3	19.4	0.02	9
	LBY135	92322.1	19.4	0.01	9
	LBY135	92323.3	18.4	0.22	4
	LBY113	92234.2	18.8	0.03	6
	LBY113	92234.5	19.0	0.01	7
	CONT.	—	17.8	—	—
	LBY91	91630.1	21.1	L	8
	LBY91	91633.1	21.4	L	10
	LBY54	92084.4	20.5	0.08	5
	LBY35	92122.1	22.3	L	14
	LBY29	91617.1	21.3	L	9
	LBY29	91619.1	20.7	0.01	6
	LBY29	91619.2	20.7	0.02	6
	LBY25	91335.2	21.3	0.06	9
	LBY230	91669.3	20.2	0.10	4
	LBY225	91607.2	20.3	0.29	4
	LBY225	91607.6	21.8	0.08	12
	LBY217	92359.1	20.0	0.24	2
	LBY217	92362.2	20.0	0.24	2
	LBY217	92363.1	22.0	L	13
	LBY212	92026.3	20.5	0.04	5
	LBY202	92022.2	24.2	0.22	24
	LBY193	91660.2	24.0	L	23
	LBY182	92396.4	20.1	0.21	3
	LBY118	91434.5	20.4	0.15	5
	CONT.	—	19.5	—	—
	LBY91	91630.1	23.2	L	21
	LBY81	92009.1	21.0	0.26	10
	LBY81	92013.2	21.0	L	10
	LBY54	92086.1	19.6	0.29	3
	LBY49	92039.4	21.3	0.04	11
	LBY174	92079.7	19.8	0.18	4
	LBY146	91593.3	21.4	0.12	12
	LBY138	92076.1	21.1	0.13	10
	LBY117	91366.3	25.0	L	31
	LBY108	91423.4	20.3	0.09	6
	CONT.	—	19.1	—	—

Table 253. “CONT.”—Control; “Ave.”—Average: “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 254
Genes showing improved plant performance at Drought
growth conditions under regulation of 6669 promoter
	Harvest Index
	Gene Name	Event #	Ave.	P-Val.	% Incr.
	LBY83	91330.1	0.204	0.10	20
	LBY63	91325.1	0.186	0.05	9
	LBY63	91325.2	0.192	0.03	13
	LBY63	91325.4	0.197	0.10	16
	LBY102	91262.8	0.192	0.07	13
	LBY102	91264.1	0.241	0.07	41
	CONT.	—	0.170	—	—
	LBY213	92033.1	0.280	0.04	24
	LBY212	92024.2	0.259	0.19	15
	LBY202	92022.1	0.256	0.21	14
	LBY193	91664.1	0.265	0.12	18
	LBY174	92080.1	0.270	0.12	20
	LBY135	92321.6	0.255	0.25	13
	LBY135	92322.1	0.265	0.23	17
	LBY113	92234.2	0.272	0.09	21
	LBY113	92234.5	0.277	0.06	23
	LBY113	92234.6	0.285	0.13	27
	CONT.	—	0.225	—	—
	LBY91	91633.1	0.232	0.01	28
	LBY91	91633.2	0.237	0.04	31
	LBY91	91634.2	0.220	0.19	21
	LBY54	92086.1	0.221	0.03	22
	LBY230	91669.2	0.202	0.27	11
	LBY230	91669.3	0.243	L	34
	LBY225	91605.3	0.216	0.14	19
	LBY225	91607.2	0.199	0.25	10
	LBY225	91607.3	0.206	0.13	14
	LBY225	91607.6	0.245	L	35
	LBY182	92396.1	0.234	L	29
	LBY182	92398.2	0.204	0.25	12
	LBY136	91442.8	0.208	0.14	15
	LBY118	91432.3	0.209	0.13	15
	CONT.	—	0.181	—	—
	LBY91	91633.1	0.230	0.03	20
	LBY35	92119.2	0.208	0.26	8
	LBY29	91619.1	0.221	0.15	15
	LBY174	92079.1	0.223	0.14	16
	LBY146	91590.4	0.226	0.04	17
	LBY108	91423.1	0.226	0.08	18
	LBY108	91424.1	0.219	0.19	14
	LBY104	91269.1	0.232	0.23	21
	LBY104	91269.2	0.217	0.20	13
	CONT.	—	0.192	—	—

Table 254. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value. L—p<0.01.

Example 30

Evaluation of Transgenic Arabidopsis for Seed Yield and Plant Growth Rate Under Normal Conditions in Greenhouse Assays Until Bolting (GH-SB Assays)

Assay 2: Plant Performance Improvement Measured Until Bolting Stage: Plant Biomass and Plant Growth Rate in Greenhouse Conditions (GH-SB Assays)

Under normal (standard conditions)—This assay follows the plant biomass formation and the rosette area growth of plants grown in the greenhouse under normal growth conditions. Transgenic Arabidopsis seeds were sown in agar media supplemented with ½ MS medium and a selection agent (Kanamycin). The T₂ transgenic seedlings were then transplanted to 1.7 trays filled with peat and perlite in a 1:2 ratio. Plants were grown under normal conditions which included irrigation of the trays with a solution containing of 6 mM inorganic nitrogen in the form of KNO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄. 1.5 mM CaCl₂ and microelements. Under normal conditions the plants grow in a controlled environment in a closed transgenic greenhouse; temperature was 18-22° C. humidity around 70%; Irrigation was done by flooding with a water solution containing 6 mM N (nitrogen) (as described hereinabove), and flooding was repeated whenever water loss reached 50%. All plants were grown in the greenhouse until bolting stage. Plant biomass (the above ground tissue) was weighted directly after harvesting the rosette (plant fresh weight [FW]). Following plants were dried in an oven at 50° C. for 48 hours and weighted (plant dry weight [DW]).

Under drought and standard growth conditions—This assay follows the plant biomass formation and the rosette area growth of plants grown in the greenhouse under drought conditions and standard growth conditions. Transgenic Arabidopsis seeds were sown in phytogel media supplemented with ½ MS medium and a selection agent (Kanamycin). The T₂ transgenic seedlings are then transplanted to 1.7 trays filled with peat and perlite in a 1:2 ratio and tuff at the bottom of the tray and a net below the trays (in order to facilitate water drainage). Half of the plants were irrigated with tap water (standard growth conditions) when tray weight reached 50% of its field capacity. The other half of the plants were irrigated with tap water when tray weight reached 20% of its field capacity in order to induce drought stress (drought conditions). All plants were grown in the greenhouse until bolting stage. At harvest, plant biomass (the above ground tissue) was weighted directly after harvesting the rosette (plant fresh weight [FW]). Thereafter, plants were dried in an oven at 50° C. for 48 hours and weighted (plant dry weight [DW]).

Under limited and optimal nitrogen concentration—This assay follows the plant biomass formation and the rosette area growth of plants grown in the greenhouse at limiting and non-limiting nitrogen growth conditions. Transgenic Arabidopsis seeds were sown in agar media supplemented with ½ MS medium and a selection agent (Kanamycin). The T₂ transgenic seedlings were then transplanted to 1.7 trays filled with peat and perlite in a 1:1 ratio. The trays were irrigated with a solution containing nitrogen limiting conditions, which were achieved by irrigating the plants with a solution containing 2.8 mM inorganic nitrogen in the form of KNO₃, supplemented with 1 mM KH₂PO₄. 1 mM MgSO₄, 1.5 mM CaCl₂ and microelements, while normal nitrogen levels were achieved by applying a solution of 5.5 mM inorganic nitrogen also in the form of KNO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄, 1.5 mM CaCl₂ and microelements. All plants were grown in the greenhouse until mature seeds. Plant biomass (the above ground tissue) was weight in directly after harvesting the rosette (plant fresh weight [FW]). Following plants were dried in an oven at 50° C. for 48 hours and weighted (plant dry weight [DW]). Each construct was validated at its T₂ generation. Transgenic plants transformed with a construct conformed by an empty vector carrying a promoter and the selectable marker were used as control [The promoters which were used are described in Example 25 above, e.g., the At6669 promoter (SEQ ID NO: 10654) or the 35S promoter (SEQ ID NO: 10650]. Additionally or alternatively. Mock-transgenic plants expressing the uidA reporter gene (GUS-Intron) or with no gene at all, under the same promoter were used as control.

The plants were analyzed for their overall size, growth rate, fresh weight and dry matter. Transgenic plants performance was compared to control plants grown in parallel under the same conditions. The experiment was planned in nested randomized plot distribution. For each gene of the invention three to five independent transformation events were analyzed from each construct.

Digital imaging—A laboratory image acquisition system, which consists of a digital reflex camera (Canon EOS 300D) attached with a 55 mm focal length lens (Canon EF-S series), mounted on a reproduction device (Kaiser RS), which includes 4 light units (4×150 Watts light bulb) was used for capturing images of plant samples.

The image capturing process was repeated every 2 days starting from day 1 after transplanting till day 15. Same camera, placed in a custom made iron mount, was used for capturing images of larger plants sawn in white tubs in an environmental controlled greenhouse. The tubs were square shape include 1.7 liter trays. During the capture process, the tubes were placed beneath the iron mount, while avoiding direct sun light and casting of shadows.

An image analysis system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.39 [Java based image processing program which was developed at the U.S. National Institutes of Health and freely available on the internet at rsbweb (dot) nih (dot) gov/]. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Leaf analysis—Using the digital analysis leaves data was calculated, including leaf number, rosette area, rosette diameter, and leaf blade area.

Vegetative growth rate: the relative growth rate (RGR) of leaf number (Formula VIII, described above), rosette area (Formula IX described above) and plot coverage (Formula XI, described above) were calculated using the indicated formulas.

Plant Fresh and Dry weight—On about day 80 from sowing, the plants were harvested and directly weight for the determination of the plant fresh weight (FW) and left to dry at 50° C. in a drying chamber for about 48 hours before weighting to determine plant dry weight (DW).

Statistical analyses—To identify outperforming genes and constructs, results from the independent transformation events tested were analyzed separately. Data was analyzed using Student's t-test and results were considered significant if the p value was less than 0.1. The JMP statistics software package was used (Version 5.2.1, SAS Institute Inc., Cary, N.C., USA).

Experimental Results:

Tables 255-263 summarize the observed phenotypes of transgenic plants expressing the genes constructs using the GH-SB Assays.

The genes listed in Tables 255-257 improved plant performance when grown at drought conditions. These genes produced larger plants with a larger photosynthetic area, biomass (fresh weight, dry weight, rosette diameter, rosette area and plot coverage), relative growth rate, blade relative area and petiole relative area. The genes were cloned under the regulation of a constitutive At6669 promoter (SEQ ID NO: 10654). The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value<0.1 was considered statistically significant.

TABLE 255
Genes showing unproved plant performance at Drought growth conditions under regulation
of At6669 promoter
		Dry Weight [mg]	Fresh Weight [mg]	Leaf Number
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY98	91152.3	—	—	—	—	—	—	12.2	0.01	8
LBY98	91152.8	300.6	0.29	6	—	—	—	—	—	—
LBY94	92333.7	—	—	—	—	—	—	11.8	0.18	4
LBY84	92212.2	—	—	—	—	—	—	12.2	0.04	8
LBY84	92212.3	—	—	—	—	—	—	11.8	0.11	4
LBY75	92094.2	—	—	—	3943.8	0.04	10	—	—	—
LBY73	92388.1	—	—	—	—	—	—	12.4	0.02	10
LBY69	92169.2	301.9	0.26	7	—	—	—	12.0	0.27	6
LBY69	92171.1	—	—	—	3806.2	0.06	6	—	—	—
LBY62	91400.5	—	—	—	3750.0	0.13	5	12.1	0.18	7
LBY62	91401.3	—	—	—	—	—	—	12.4	L	9
LBY58	91376.6	—	—	—	—	—	—	12.1	0.10	7
LBY58	91378.2	—	—	—	—	—	—	12.4	0.14	9
LBY28	92281.1	—	—	—	—	—	—	11.9	0.09	5
LBY28	92281.3	—	—	—	4031.2	L	13	—	—	—
LBY28	92283.2	—	—	—	—	—	—	11.9	0.05	5
LBY218	92159.3	—	—	—	—	—	—	12.8	0.02	13
LBY197	92399.1	—	—	—	—	—	—	12.1	0.06	7
LBY195	92191.4	—	—	—	3943.8	L	10	12.4	0.23	9
LBY195	92193.1	—	—	—	—	—	—	12.1	0.02	7
LBY195	92193.2	—	—	—	3787.5	0.15	6	12.8	0.11	13
LBY195	92193.3	305.0	0.22	8	—	—	—	—	—	—
LBY190	91510.2	—	—	—	—	—	—	12.4	0.02	10
LBY190	91513.2	328.8	0.02	16	4087.5	0.20	14	12.5	0.04	10
LBY184	92145.2	—	—	—	—	—	—	12.6	L	11
LBY184	92147.3	—	—	—	3925.0	0.24	10	12.5	L	10
LBY184	92148.4	—	—	—	—	—	—	13.0	0.19	15
LBY163	91481.2	—	—	—	—	—	—	12.2	0.01	8
LBY163	91481.3	—	—	—	—	—	—	12.0	0.27	6
LBY163	91484.3	324.4	0.06	15	—	—	—	12.1	0.06	7
LBY160	92302.7	—	—	—	—	—	—	11.8	0.18	4
LBY105	91385.1	—	—	—	3825.0	0.13	7	12.1	0.03	7
LBY105	91385.2	—	—	—	—	—	—	11.9	0.24	5
LBY105	91386.6	—	—	—	3818.8	0.22	7	12.3	0.10	9
CONT.	—	282.3	—	—	3575.0	—	—	11.3	—	—
LBY94	92332.1	167.7	0.25	21	—	—	—	—	—	—
LBY94	92333.2	—	—	—	1950.0	0.25	24	10.1	0.26	5
LBY84	92210.3	159.4	0.24	15	—	—	—	—	—	—
LBY84	92212.3	162.5	0.14	17	1812.5	0.17	15	—	—	—
LBY84	92213.3	163.8	0.22	18	1856.2	0.11	18	—	—	—
LBY75	92094.1	162.5	0.14	17	1956.2	0.06	24	10.2	0.27	6
LBY75	92094.2	166.2	0.10	20	—	—	—	—	—	—
LBY75	92096.1	184.4	0.14	33	2093.8	0.02	33	10.8	0.14	13
LBY73	92386.2	165.6	0.11	20	1743.8	0.30	11	—	—	—
LBY73	92387.3	—	—	—	2175.0	0.10	35	10.8	0.02	13
LBY73	92388.1	218.1	0.11	58	2187.5	0.02	39	11.2	0.03	16
LBY69	92169.3	—	—	—	2181.2	0.01	39	11.2	0.01	17
LBY66	92089.3	180.6	0.03	31	1943.8	0.05	24	10.5	0.03	9
LBY66	92091.1	171.9	0.10	24	2168.8	0.05	38	—	—	—
LBY66	92093.3	—	—	—	—	—	—	10.2	0.09	7
LBY62	91400.5	—	—	—	—	—	—	10.0	0.29	4
LBY62	91401.3	—	—	—	1837.5	0.17	17	10.2	0.18	7
LBY58	91376.5	180.0	0.09	30	2318.8	L	47	10.6	0.11	10
LBY58	91376.6	—	—	—	—	—	—	10.5	0.04	9
LBY58	91378.2	166.9	0.15	21	2112.5	0.01	34	10.4	0.06	9
LBY45	92194.6	—	—	—	—	—	—	10.1	0.26	5
LBY45	92197.3	—	—	—	1750.0	0.28	11	—	—	—
LBY37	91217.1	—	—	—	—	—	—	10.4	0.15	9
LBY37	91218.2	—	—	—	2337.5	0.05	49	11.6	L	20
LBY28	92281.3	181.2	0.02	31	2187.5	0.04	39	10.6	0.02	11
LBY211	92411.1	—	—	—	1788.4	0.23	14	—	—	—
LBY211	92412.1	186.9	0.02	35	2050.0	0.02	30	10.6	0.11	10
LBY206	92350.3	160.6	0.20	16	1918.8	0.15	22	10.4	0.25	9
LBY206	92350.4	—	—	—	1843.8	0.15	17	—	—	—
LBY206	92351.1	174.4	0.12	26	1975.0	0.03	26	10.8	0.14	13
LBY206	92353.2	—	—	—	1950.0	0.25	24	—	—	—
LBY199	92307.1	189.4	0.01	37	2200.0	0.16	40	10.8	0.06	13
LBY199	92308.1	—	—	—	2156.2	0.04	37	10.8	0.04	12
LBY176	92509.2	190.7	0.01	38	2185.7	L	39	10.2	0.18	7
LBY176	92511.2	165.0	0.14	19	1806.2	0.17	15	10.2	0.12	6
LBY176	92512.1	174.4	0.05	26	2043.8	0.05	30	10.1	0.18	5
LBY164	92669.4	—	—	—	—	—	—	10.2	0.10	7
LBY151	92651.2	—	—	—	1825.0	0.17	16	10.8	L	13
LBY151	92651.3	—	—	—	1837.5	0.14	17	—	—	—
LBY143	91470.4	177.5	0.09	28	2031.2	0.20	29	10.2	0.27	6
LBY143	91470.7	—	—	—	—	—	—	10.5	0.04	9
LBY143	91470.8	—	—	—	1956.2	0.07	24	10.9	L	13
LBY143	91473.2	—	—	—	1825.0	0.21	16	—	—	—
CONT.	—	138.3	—	—	1572.4	—	—	9.61	—	—
LBY99	91635.3	—	—	—	—	—	—	10.6	0.01	8
LBY99	91635.4	—	—	—	2756.2	0.11	26	—	—	—
LBY99	91635.5	220.5	0.18	29	2730.4	0.08	25	10.4	0.02	6
LBY99	91636.1	195.6	0.05	14	2926.8	0.01	34	—	—	—
LBY99	91636.4	—	—	—	—	—	—	10.2	0.08	4
LBY66	92093.1	191.9	0.16	12	—	—	—	10.2	0.08	4
LBY66	92093.3	218.8	L	28	3006.2	L	37	—	—	—
LBY218	92159.1	200.0	0.26	17	—	—	—	—	—	—
LBY218	92159.3	196.9	0.18	15	2881.2	0.02	32	—	—	—
LBY218	92160.3	196.9	0.07	15	—	—	—	—	—	—
LBY218	92162.3	197.5	0.15	15	—	—	—	10.4	0.09	6
LBY211	92409.1	191.2	0.05	12	—	—	—	—	—	—
LBY211	92412.1	195.6	0.05	14	—	—	—	—	—	—
LBY205	92164.1	—	—	—	2593.8	0.21	18	—	—	—
LBY199	92306.2	186.2	0.14	9	—	—	—	—	—	—
LBY197	92399.1	199.4	0.12	16	—	—	—	—	—	—
LBY195	92191.4	205.6	0.05	20	—	—	—	—	—	—
LBY195	92192.2	193.1	0.02	13	—	—	—	—	—	—
LBY195	92193.2	196.2	0.28	15	—	—	—	10.4	0.06	6
LBY195	92193.3	—	—	—	2818.8	0.02	29	—	—	—
LBY190	91510.2	181.2	0.24	6	—	—	—	—	—	—
LBY190	91513.2	198.8	0.10	16	—	—	—	10.3	0.06	5
LBY184	92147.3	209.4	L	72	—	—	—	10.8	0.08	9
LBY184	92148.3	—	—	—	2455.4	0.25	12	—	—	—
LBY176	92509.2	—	—	—	—	—	—	10.3	0.15	5
LBY176	92510.1	200.0	L	17	—	—	—	10.6	0.10	8
LBY176	92512.1	187.5	0.21	10	—	—	—	—	—	—
LBY164	92669.4	191.9	0.03	12	—	—	—	—	—	—
LBY164	92670.2	197.5	0.15	15	—	—	—	—	—	—
LBY163	91482.2	—	—	—	—	—	—	10.5	0.14	7
LBY163	91484.3	198.8	0.28	16	—	—	—	—	—	—
LBY163	91484.6	220.0	L	29	2981.2	L	36	—	—	—
LBY160	92302.6	—	—	—	2581.2	0.12	18	—	—	—
LBY160	92302.7	200.0	0.29	17	—	—	—	—	—	—
LBY151	92649.1	208.1	L	22	2606.2	0.26	19	—	—	—
LBY143	91470.4	187.5	0.07	10	2556.2	0.14	17	—	—	—
LBY143	91472.1	213.1	L	24	—	—	—	—	—	—
LBY105	91386.6	190.0	0.04	11	2737.5	0.04	25	—	—	—
LBY105	91388.1	188.1	0.22	10	—	—	—	—	—	—
LBY100	91410.3	211.2	0.29	23	—	—	—	10.5	0.03	7
LBY100	91410.4	—	—	—	2437.5	0.28	11	—	—	—
LBY100	91410.6	183.1	0.16	7	—	—	—	—	—	—
CONT.	—	171.2	—	—	2190.0	—	—	9.82	—	—
LBY47	91626.1	—	—	—	—	—	—	12.1	0.28	4
LBY18	91298.3	—	—	—	—	—	—	12.2	0.29	5
LBY16	91595.2	210.6	0.25	10	—	—	—	—	—	—
LBY16	91595.3	—	—	—	—	—	—	12.2	0.12	5
CONT.	—	191.1	—	—	—	—	—	11.6	—	—

Table 255. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value. L—p<0.01.

TABLE 256
Genes showing improved plant performance at Drought growth conditions under regulation
of At6669 promoter
		Plot Coverage [cm2]	Rosette Area [cm2]	Rosette Diameter [cm]
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY62	91400.5	—	—	—	—	—	—	5.20	0.22	8
LBY62	91401.3	72.7	0.14	11	9.09	0.14	11	—	—	—
LBY58	91378.2	76.2	0.04	16	9.52	0.04	16	4.97	0.27	3
LBY28	92281.1	71.4	0.24	9	8.92	0.24	9	—	—	—
LBY195	92193.1	81.8	0.21	25	10.2	0.21	25	5.26	0.25	9
LBY195	92193.2	79.1	0.07	21	9.89	0.07	21	5.19	0.23	8
LBY190	91510.2	75.0	0.08	15	9.37	0.08	15	5.06	0.08	5
LBY190	91513.2	88.3	0.10	35	11.0	0.10	35	5.41	0.22	12
LBY184	92145.2	83.3	0.01	27	10.4	0.01	27	5.25	L	9
LBY184	92147.3	87.0	0.21	33	10.9	0.21	33	—	—	—
LBY184	92148.4	79.4	0.15	21	9.92	0.15	21	5.16	0.26	7
LBY163	91481.2	70.6	0.27	8	8.83	0.27	8	—	—	—
LBY163	91481.3	80.8	0.02	23	10.1	0.02	23	5.29	0.04	10
LBY163	91482.3	73.6	0.10	12	9.19	0.10	12	5.14	0.27	7
LBY163	91484.3	92.3	0.03	41	11.5	0.03	41	5.77	L	20
LBY105	91385.1	80.9	0.02	24	10.1	0.02	24	5.21	0.02	8
CONT.	—	65.5	—	—	8.18	—	—	4.81	—	—
LBY94	92333.2	62.3	0.10	34	7.79	0.10	34	4.92	0.05	15
LBY84	92213.3	56.6	0.09	22	7.07	0.09	22	4.57	0.25	7
LBY75	92094.1	56.7	0.20	22	7.09	0.20	22	4.71	0.16	10
LBY75	92094.7	53.9	0.20	16	6.74	0.20	16	4.60	0.20	8
LBY75	92096.1	66.5	L	43	8.31	L	43	5.08	0.01	19
LBY73	92387.3	62.3	0.14	34	7.79	0.14	34	4.86	0.19	14
LBY73	92388.1	66.6	0.04	44	8.32	0.04	44	5.09	0.04	19
LBY69	92169.3	72.7	L	57	9.08	L	57	5.19	L	21
LBY66	92089.3	57.2	0.09	23	7.15	0.09	23	4.75	0.08	11
LBY66	92091.1	66.1	0.06	43	8.27	0.06	43	5.15	0.04	20
LBY66	92093.1	—	—	—	—	—	—	4.57	0.28	7
LBY66	92093.3	60.1	0.09	30	7.51	0.09	30	5.00	0.16	17
LBY62	91400.3	56.6	0.08	22	7.08	0.08	22	4.66	0.14	9
LBY62	91401.3	61.9	0.03	33	7.73	0.03	33	4.87	0.07	14
LBY58	91376.5	70.4	L	52	8.80	L	52	5.33	L	25
LBY58	91376.6	53.3	0.28	15	6.66	0.28	15	4.57	0.27	7
LBY58	91378.7	65.8	0.01	42	8.23	0.01	42	5.05	0.03	18
LBY45	92194.6	56.4	0.11	22	7.05	0.11	22	4.84	0.13	13
LBY45	92197.3	63.7	0.01	37	7.96	0.01	37	4.98	0.02	16
LBY37	91217.1	52.3	0.28	13	6.54	0.28	13	—	—	—
LBY37	91218.2	73.8	L	59	9.22	L	59	5.20	L	22
LBY28	92281.3	66.5	0.14	43	8.31	0.14	43	5.14	0.26	20
LBY211	92412.1	66.8	L	44	8.35	L	44	5.00	0.02	17
LBY206	92350.3	61.9	0.09	33	7.74	0.09	33	4.90	0.06	15
LBY206	92350.4	53.3	0.27	15	6.66	0.27	15	4.72	0.13	10
LBY206	92351.1	65.1	L	40	8.14	L	40	5.02	0.02	17
LBY206	92353.2	—	—	—	—	—	—	4.79	0.26	12
LBY199	92307.1	71.0	0.15	53	8.87	0.15	53	5.29	0.16	24
LBY176	92509.1	52.6	0.27	14	6.58	0.27	14	4.54	0.29	6
LBY176	92509.2	61.9	0.02	34	7.74	0.02	34	4.90	0.03	15
LBY176	92511.2	52.4	0.27	13	6.54	0.27	13	4.61	0.19	—
LBY176	92512.1	60.4	0.06	30	7.55	0.06	30	4.82	0.05	13
LBY151	92651.2	60.9	0.06	31	7.61	0.06	31	4.74	0.22	11
LBY151	92651.3	54.9	0.24	18	6.86	0.24	18	4.68	0.21	10
LBY143	91470.4	69.6	0.03	50	8.70	0.03	50	5.12	0.04	20
LBY143	91470.7	60.1	0.05	30	7.51	0.05	30	4.80	0.06	12
LBY143	91470.8	68.5	0.01	48	8.57	0.01	48	5.02	0.03	18
LBY143	91473.2	—	—	—	—	—	—	4.59	0.23	7
CONT.	—	46.4	—	—	5.79	—	—	4.27	—	—
LBY99	91635.3	46.4	0.19	16	5.80	0.19	16	—	—	—
LBY99	91635.4	49.0	0.08	23	6.12	0.08	23	4.31	0.25	7
LBY99	91635.5	56.5	0.08	42	7.07	0.08	42	4.87	0.07	21
LBY66	92093.1	47.3	L	19	5.91	L	19	4.45	L	10
LBY66	92093.3	56.4	L	42	7.05	L	42	4.72	0.01	17
LBY66	92093.5	42.6	0.15	7	5.32	0.15	7	4.29	0.09	7
LBY218	92159.1	48.6	0.03	22	6.07	0.03	22	4.47	L	11
LBY218	92159.3	—	—	—	—	—	—	4.57	0.26	13
LBY218	92162.3	54.3	0.05	36	6.78	0.05	36	4.76	0.11	18
LBY211	92409.1	42.7	0.13	7	5.33	0.13	7	4.19	0.19	4
LBY211	92412.1	46.2	0.12	16	5.77	0.12	16	4.38	0.06	9
LBY205	92164.3	46.7	0.07	17	5.83	0.07	17	4.31	0.16	7
LBY199	92306.2	49.5	0.05	24	6.19	0.05	24	4.50	0.10	12
LBY199	92308.1	—	—	—	—	—	—	4.23	0.09	5
LBY197	92399.1	47.5	0.02	19	5.94	0.02	19	4.49	L	11
LBY195	92191.4	47.5	0.10	19	5.94	0.10	19	4.41	0.10	10
LBY195	92193.2	53.4	L	34	6.68	L	34	4.65	L	15
LBY195	92193.3	53.2	0.08	33	6.65	0.08	33	4.60	0.08	14
LBY190	91510.2	—	—	—	—	—	—	4.15	0.75	3
LBY190	91513.2	59.9	L	50	7.49	L	50	4.87	L	21
LBY190	91513.3	50.2	0.05	26	6.27	0.05	26	4.43	0.11	10
LBY184	92147.3	57.9	0.03	45	7.24	0.03	45	4.78	L	19
LBY184	92148.1	47.2	0.04	18	5.90	0.04	18	4.38	0.07	9
LBY176	92509.2	50.5	0.19	27	6.31	0.19	27	—	—	—
LBY176	92510.1	53.7	0.06	35	6.71	0.06	35	4.63	L	15
LBY176	92512.1	—	—	—	—	—	—	4.28	0.27	6
LBY164	92669.1	43.0	0.30	8	5.38	0.30	8	—	—	—
LBY163	91481.3	43.7	0.07	10	5.46	0.07	10	—	—	—
LBY163	91482.2	52.3	L	31	6.54	L	31	4.51	L	12
LBY163	91482.3	47.5	L	19	5.93	L	19	4.37	0.04	8
LBY163	91484.6	54.4	L	37	6.81	L	37	4.80	L	19
LBY160	92302.7	55.5	0.05	39	6.94	0.05	39	4.66	0.07	16
LBY151	92649.1	58.6	0.05	47	7.32	0.05	47	4.93	0.07	22
LBY143	91470.4	50.2	0.22	26	6.28	0.22	26	4.50	0.27	12
LBY143	91472.1	48.6	L	22	6.08	L	22	4.51	0.09	12
LBY105	91386.6	42.9	0.11	8	5.36	0.11	8	4.16	0.21	3
LBY105	91388.1	50.3	0.03	26	6.29	0.03	26	4.45	0.05	10
LBY100	91410.6	44.6	0.03	12	5.58	0.03	12	4.17	0.23	3
CONT.	—	39.8	—	—	4.98	—	—	4.03	—	—
LBY90	91193.1	99.3	0.14	23	12.4	0.14	23	6.48	0.08	17
LBY47	91627.1	86.3	0.18	7	10.8	0.18	7	—	—	—
LBY47	91628.1	89.7	0.14	11	11.2	0.14	11	5.84	0.21	5
LBY45	92196.3	85.6	0.15	6	10.7	0.15	6	5.77	0.29	4
LBY45	92197.3	97.9	0.04	21	12.2	0.04	21	6.26	L	13
LBY222	91604.3	84.4	0.14	5	10.5	0.14	5	5.68	0.02	2
LBY220	91306.4	84.9	0.27	5	10.6	0.27	5	—	—	—
LBY194	91147.1	88.4	0.24	10	11.1	0.24	10	—	—	—
LBY18	91297.1	—	—	—	—	—	—	6.18	0.18	11
LBY18	91298.3	84.3	0.24	4	10.5	0.24	4	5.76	L	4
LBY162	91809.4	—	—	—	—	—	—	5.80	0.03	4
LBY16	91599.1	88.2	0.01	9	11.0	0.01	9	—	—	—
LBY100	91410.3	95.1	L	18	11.9	L	18	6.11	0.09	10
LBY100	91410.6	90.0	0.23	11	11.2	0.23	11	—	—	—
CONT.	—	80.7	—	—	10.1	—	—	5.56	—	—

Table 256. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 257
Genes showing improved plant performance at Drought growth conditions under regulation
of At6669 promoter
								RGR Of Rosette
		RGR Of Leaf Number	RGR Of Plot Coverage	Diameter
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY98	91152.3	0.699	0.18	27	—	—	—	—	—	—
LBY94	92333.7	0.665	0.29	21	—	—	—	—	—	—
LBY84	92212.3	0.671	0.28	22	—	—	—	—	—	—
LBY75	92097.4	0.672	0.25	22	—	—	—	—	—	—
LBY73	92388.1	0.666	0.28	21	—	—	—	—	—	—
LBY69	92171.4	0.666	0.28	21	—	—	—	—	—	—
LBY69	92172.2	0.695	0.18	26	—	—	—	—	—	—
LBY62	91400.3	0.671	0.28	22	—	—	—	—	—	—
LBY62	91401.3	0.672	0.26	22	—	—	—	—	—	—
LBY58	91376.6	0.700	0.15	27	—	—	—	—	—	—
LBY58	91377.1	0.669	0.27	21	—	—	—	—	—	—
LBY58	91378.2	0.670	0.28	21	—	—	—	—	—	—
LBY218	92159.3	0.720	0.14	31	—	—	—	—	—	—
LBY197	92399.3	0.672	0.26	22	—	—	—	—	—	—
LBY197	92403.4	0.667	0.26	21	—	—	—	—	—	—
LBY195	92191.4	0.706	0.17	28	—	—	—	—	—	—
LBY195	92193.1	—	—	—	9.70	0.16	27	—	—	—
LBY195	92193.2	0.778	0.03	41	9.27	0.23	21	—	—	—
LBY195	92193.3	0.697	0.17	26	—	—	—	—	—	—
LBY190	91513.2	—	—	—	10.4	0.06	36	—	—	—
LBY184	92145.2	0.748	0.06	36	9.80	0.12	28	—	—	—
LBY184	92147.3	—	—	—	10.2	0.08	33	—	—	—
LBY184	92148.1	0.687	0.21	25	—	—	—	—	—	—
LBY184	92148.4	—	—	—	9.16	0.26	20	—	—	—
LBY163	91481.3	—	—	—	9.36	0.20	22	—	—	—
LBY163	91484.3	—	—	—	10.8	0.03	41	0.444	0.14	19
LBY163	91484.6	0.713	0.13	29	—	—	—	—	—	—
LBY160	92302.6	0.693	0.19	26	—	—	—	—	—	—
LBY160	92302.7	0.698	0.18	27	—	—	—	—	—	—
LBY105	91385.1	—	—	—	9.29	0.22	22	—	—	—
LBY105	91386.6	0.718	0.11	30	—	—	—	—	—	—
CONT.	—	0.552	—	—	7.64	—	—	0.374	—	—
LBY94	92333.2	—	—	—	7.91	0.13	35	—	—	—
LBY75	92096.1	0.709	0.10	44	8.51	0.06	45	0.462	0.26	21
LBY73	92387.3	—	—	—	7.86	0.14	34	—	—	—
LBY73	92388.1	0.734	0.07	49	8.45	0.06	45	—	—	—
LBY69	92169.3	0.726	0.07	48	9.31	0.02	59	—	—	—
LBY66	92089.3	0.670	0.16	36	7.26	0.29	24	—	—	—
LBY66	92091.1	0.649	0.24	32	8.47	0.06	45	0.463	0.26	21
LBY66	92093.3	—	—	—	7.54	0.21	29	—	—	—
LBY62	91401.3	—	—	—	7.78	0.16	33	—	—	—
LBY58	91376.5	—	—	—	9.06	0.02	55	0.490	0.13	28
LBY58	91378.2	0.660	0.20	34	8.42	0.06	44	—	—	—
LBY45	92197.3	—	—	—	8.05	0.11	38	—	—	—
LBY37	91217.1	0.624	0.30	27	—	—	—	—	—	—
LBY37	91218.2	0.744	0.05	51	9.45	0.01	62	0.466	0.24	21
LBY28	92281.3	—	—	—	8.46	0.07	45	—	—	—
LBY211	92412.1	0.674	0.16	37	8.47	0.06	45	—	—	—
LBY206	92350.3	0.650	0.22	32	7.79	0.15	33	—	—	—
LBY206	92351.1	0.674	0.16	37	8.32	0.08	42	—	—	—
LBY199	92307.1	0.625	0.29	27	9.10	0.03	56	0.476	0.21	24
LBY199	92308.1	—	—	—	7.48	0.25	28	—	—	—
LBY176	92509.2	—	—	—	7.82	0.15	34	—	—	—
LBY176	92512.1	—	—	—	7.61	0.19	30	—	—	—
LBY151	92651.2	0.625	0.29	27	7.62	0.19	30	—	—	—
LBY143	91470.4	—	—	—	8.87	0.03	52	—	—	—
LBY143	91470.7	—	—	—	7.56	0.20	29	—	—	—
LBY143	91470.8	0.656	0.20	34	8.65	0.05	48	—	—	—
CONT.	—	0.491	—	—	5.85	—	—	0.383	—	—
LBY99	91635.4	—	—	—	6.28	0.20	22	—	—	—
LBY99	91635.5	—	—	—	7.36	0.02	43	0.470	0.07	20
LBY66	92093.1	—	—	—	6.19	0.24	20	0.441	0.20	13
LBY66	92093.3	0.787	0.06	27	7.28	0.02	41	0.449	0.16	15
LBY218	92159.1	—	—	—	6.33	0.19	23	—	—	—
LBY218	92159.3	—	—	—	6.59	0.13	28	0.442	0.24	13
LBY218	92162.3	—	—	—	7.03	0.04	36	0.461	0.10	18
LBY199	92306.2	—	—	—	6.44	0.15	25	—	—	—
LBY197	92399.1	—	—	—	6.15	0.26	19	—	—	—
LBY195	92191.4	—	—	—	6.15	0.27	19	—	—	—
LBY195	92192.2	—	—	—	6.43	0.18	24	—	—	—
LBY195	92193.1	—	—	—	6.19	0.29	20	—	—	—
LBY195	92193.2	—	—	—	6.92	0.05	34	0.448	0.18	14
LBY195	92193.3	—	—	—	6.85	0.07	33	—	—	—
LBY190	91513.2	—	—	—	7.79	L	51	0.467	0.07	19
LBY190	91513.3	—	—	—	6.50	0.14	26	—	—	—
LBY184	92147.3	—	—	—	7.49	0.02	45	0.448	0.17	14
LBY176	92509.2	—	—	—	6.52	0.15	26	0.438	0.27	12
LBY176	92510.1	—	—	—	6.92	0.06	34	0.440	0.23	12
LBY164	92670.2	—	—	—	6.29	0.23	22	—	—	—
LBY163	91482.2	—	—	—	6.80	0.07	32	—	—	—
LBY163	91482.3	—	—	—	6.17	0.25	20	—	—	—
LBY163	91484.6	—	—	—	7.08	0.04	37	0.469	0.06	20
LBY160	92302.7	—	—	—	7.24	0.03	40	0.446	0.18	14
LBY151	92649.1	—	—	—	7.53	0.01	46	0.467	0.08	19
LBY143	91470.4	—	—	—	6.46	0.15	25	0.441	0.24	13
LBY143	91472.1	—	—	—	6.24	0.22	21	—	—	—
LBY105	91388.1	—	—	—	6.50	0.14	26	—	—	—
LBY100	91410.3	—	—	—	6.97	0.06	35	—	—	—
CONT.	—	0.618	—	—	5.16	—	—	0.392	—	—
LBY90	91193.1	—	—	—	11.8	0.07	23	0.536	0.03	16
LBY90	91193.4	—	—	—	—	—	—	0.479	0.28	4
LBY47	91626.1	—	—	—	—	—	—	0.481	0.11	4
LBY4.7	91627.1	—	—	—	10.2	0.14	6	0.480	0.20	4
LBY47	91627.3	0.645	0.15	15	—	—	—	—	—	—
LBY47	91628.1	—	—	—	10.7	0.10	11	—	—	—
LBY45	92194.4	—	—	—	—	—	—	0.506	0.30	9
LBY45	92196.3	—	—	—	10.2	0.21	6	—	—	—
LBY45	92197.3	—	—	—	11.6	0.02	21	0.514	0.11	11
LBY212	91417.2	0.686	0.05	22	—	—	—	—	—	—
LBY220	91305.3	0.641	0.19	14	—	—	—	—	—	—
LBY194	91145.1	0.652	0.26	16	—	—	—	—	—	—
LBY194	91147.1	—	—	—	10.6	0.20	11	0.498	0.28	8
LBY18	91297.1	—	—	—	—	—	—	0.492	0.14	6
LBY18	91298.3	—	—	—	9.99	0.26	4	—	—	—
LBY162	91809.4	—	—	—	—	—	—	0.475	0.22	3
LBY16	91599.1	—	—	—	10.4	0.02	9	—	—	—
LBY129	91585.1	0.631	0.22	12	—	—	—	—	—	—
LBY129	91589.1	—	—	—	—	—	—	0.477	0.11	3
LBY100	91410.3	—	—	—	11.3	0.18	18	0.499	0.28	8
LBY100	91410.6	—	—	—	10.7	0.13	11	0.473	0.27	2
CONT.	—	0.562	—	—	9.58	—	—	0.462	—	—

Table 257. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

The genes listed in Tables 258-260 improved plant performance when grown at normal conditions. These genes produced larger plants with a larger photosynthetic area, biomass (fresh weight, dry weight, rosette diameter, rosette area and plot coverage), relative growth rate, blade relative area and petiole relative area. The genes were cloned under the regulation of a constitutive At6669 promoter (SEQ ID NO: 10654). The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value<0.1 was considered statistically significant.

TABLE 258
Genes showing improved plant performance at Normal
growth conditions under regulation of At6669 promoter
		Dry Weight [mg]	Fresh Weight [mg]	Leaf Number
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Vol.	Incr.
LGN43	89053.2	—	—	—	—	—	—	11.6	0.17	9
CONT.	—	—	—	—	—	—	—	10.6	—	—
LGN44	89055.7	—	—	—	3258.3	0.21	8	—	—	—
LGN44	89056.1	—	—	—	3220.8	0.20	7	—	—	—
LGN44	89057.3	—	—	—	3129.2	0.27	4	—	—	—
CONT.	—	—	—	—	3008.3	—	—	—	—	—
LGN40	90346.2	—	—	—	—	—	—	11.5	0.30	3
CONT.	—	—	—	—	—	—	—	11.2	—	—
LGN20	89089.3	—	—	—	4583.3	0.26	7	—	—	—
CONT.	—	—	—	—	4270.8	—	—	—	—	—
LGN17	89028.4	361.7	0.13	7	5450.0	0.09	8	—	—	—
CONT.	—	338.1	—	—	5046.9	—	—	—	—	—
LGN44	89055.2	381.7	0.22	4	—	—	—	—	—	—
CONT.	—	366.2	—	—	—	—	—	—	—	—
LGN17	89027.1	—	—	—	—	—	—	12.3	0.05	10
LGN17	89027.2	384.6	0.28	7	4798.2	0.08	8	—	—	—
LGN17	89028.4	383.8	0.17	7	4879.2	0.05	10	12.5	0.02	12
CONT.	—	358.1	—	—	4431.2	—	—	11.2	—	—
LBY90	91192.3	—	—	—	—	—	—	11.7	0.23	4
LBY90	91193.4	277.5	0.14	24	2812.5	0.03	16	—	—	—
LBY88	91185.1	257.6	0.18	15	—	—	—	—	—	—
LBY59	91322.3	261.9	0.13	17	2850.0	0.01	17	—	—	—
LBY57	90974.1	—	—	—	—	—	—	11.9	0.03	6
LBY47	91627.1	—	—	—	—	—	—	11.9	0.06	5
LBY47	91628.1	—	—	—	—	—	—	11.9	0.03	6
LBY45	92197.3	—	—	—	2862.5	0.08	18	—	—	—
LBY40	91310.1	—	—	—	2718.8	0.12	12	11.7	0.14	4
LBY40	91310.2	—	—	—	—	—	—	11.6	0.28	3
LBY228	91610.2	—	—	—	—	—	—	12.2	0.03	8
LBY228	91610.4	—	—	—	2712.5	0.22	12	11.9	0.06	5
LBY194	91149.2	—	—	—	—	—	—	11.6	0.28	3
LBY18	91297.2	248.8	0.25	11	—	—	—	—	—	—
LBY16	91599.3	251.2	0.27	12	2793.8	0.06	15	—	—	—
LBY128	91439.6	—	—	—	—	—	—	11.9	0.08	6
LBY100	91410.2	—	—	—	—	—	—	11.8	0.14	5
LBY100	91410.3	—	—	—	2887.5	0.07	19	—	—	—
LBY100	91410.4	—	—	—	—	—	—	11.7	0.14	4
CONT.	—	224.5	—	—	2430.4	—	—	11.3	—	—
LGN61	89107.2	—	—	—	5204.2	0.28	3	12.7	0.15	3
LGN61	89107.3	351.7	0.09	9	5341.7	0.24	6	—	—	—
CONT.	—	322.5	—	—	5037.5	—	—	12.4	—	—
LGN20	89089.3	348.9	0.10	7	—	—	—	—	—	—
LGN20	89091.4	347.5	0.25	6	—	—	—	—	—	—
CONT.	—	327.1	—	—	—	—	—	—	—	—
LBY98	91152.5	—	—	—	7268.8	0.27	5	12.2	0.02	3
LBY75	92094.1	—	—	—	—	—	—	12.1	0.16	2
LBY218	92159.1	—	—	—	—	—	—	12.2	0.26	3
LBY218	92159.3	521.9	0.22	8	7593.8	0.01	9	—	—	—
LBY205	92167.4	511.9	0.07	6	—	—	—	12.2	0.26	3
LBY195	92192.2	499.4	0.27	3	—	—	—	—	—	—
LBY190	91513.2	—	—	—	—	—	—	12.5	0.03	6
LBY163	91481.2	—	—	—	7575.0	0.17	9	12.8	L	8
LBY163	91481.3	524.4	0.02	8	7156.2	0.29	3	—	—	—
LBY163	91484.3	506.9	0.13	5	7487.5	0.03	8	—	—	—
LBY160	92302.7	508.1	0.27	5	—	—	—	—	—	—
LBY105	91385.2	511.2	0.08	6	—	—	—	—	—	—
CONT.	—	483.9	—	—	6955.4	—	—	11.8	—	—
LGN40	90346.2	395.0	0.03	11	5885.1	0.04	9	—	—	—
LGN40	90347.1	385.0	0.06	8	—	—	—	—	—	—
CONT.	—	356.7	—	—	5383.3	—	—	—	—	—
LBY94	92332.1	—	—	—	2848.2	0.16	12	—	—	—
LBY94	92333.2	—	—	—	2881.2	0.12	13	—	—	—
LBY84	92212.3	—	—	—	—	—	—	10.2	0.24	4
LBY84	92213.3	—	—	—	3000.0	0.10	18	10.8	0.01	9
LBY75	92096.1	—	—	—	3131.2	0.09	23	10.9	0.01	10
LBY73	92387.3	—	—	—	2912.5	0.22	15	11.5	0.01	16
LBY73	92388.1	228.8	0.25	14	2787.5	0.26	10	—	—	—
LBY69	92169.3	273.8	0.02	36	3137.5	0.05	23	11.5	0.30	16
LBY66	92089.3	—	—	—	—	—	—	10.5	0.17	6
LBY66	92091.1	229.4	0.28	14	2943.8	0.20	16	11.2	L	13
LBY66	92093.1	—	—	—	—	—	—	10.2	0.29	3
LBY66	92093.3	239.4	0.14	19	2975.0	0.26	17	10.8	0.12	9
LBY62	91401.3	—	—	—	—	—	—	10.2	0.29	3
LBY58	91376.5	256.2	0.05	27	3125.0	0.12	23	10.4	0.13	5
LBY58	91378.2	—	—	—	3187.5	0.03	25	10.5	0.17	6
LBY45	92196.3	229.4	0.27	14	—	—	—	10.3	0.15	4
LBY45	92197.3	—	—	—	—	—	—	11.4	0.04	16
LBY37	91217.1	240.6	0.20	20	2762.5	0.27	9	—	—	—
LBY37	91218.2	231.4	0.26	15	—	—	—	—	—	—
LBY211	92412.1	248.1	0.07	23	3406.2	0.08	34	11.0	0.04	11
LBY206	92350.3	—	—	—	3093.8	0.03	22	10.4	0.14	6
LBY199	92305.2	—	—	—	—	—	—	10.2	0.29	3
LBY199	92307.1	—	—	—	3018.8	0.04	19	10.6	0.24	7
LBY199	92308.1	231.2	0.22	15	3212.5	L	26	—	—	—
LBY176	92509.1	—	—	—	—	—	—	11.0	0.13	11
LBY176	92509.2	246.9	0.08	23	3362.5	0.02	32	12.1	L	23
LBY164	92670.4	251.9	0.16	25	—	—	—	—	—	—
LBY151	92649.2	—	—	—	2787.5	0.22	10	10.4	0.10	5
LBY151	92651.2	—	—	—	—	—	—	10.4	0.28	6
LBY151	92651.3	233.1	0.23	16	—	—	—	—	—	—
LBY143	91470.4	250.0	0.23	24	3281.2	L	29	10.4	0.14	6
LBY143	91470.7	258.8	0.14	29	3018.8	0.04	19	10.9	L	11
LBY143	91470.8	230.6	0.23	15	3108.0	0.02	22	—	—	—
CONT.	—	201.3	—	—	2540.6	—	—	9.89	—	—
LBY99	91635.3	261.2	L	14	—	—	—	10.8	0.30	10
LBY99	91635.4	287.5	L	26	—	—	—	11.4	0.06	17
LBY99	91635.5	—	—	—	—	—	—	10.8	0.08	10
LBY99	91636.1	247.5	0.13	8	3162.5	0.11	10	—	—	—
LBY99	91636.4	256.2	L	12	—	—	—	11.0	0.14	12
LBY66	92089.2	—	—	—	3056.2	0.30	6	—	—	—
LBY66	92093.3	279.4	L	22	3431.2	0.02	19	—	—	—
LBY218	92159.1	—	—	—	—	—	—	10.4	0.23	7
LBY218	92159.3	241.2	0.09	5	—	—	—	—	—	—
LBY218	92160.3	264.2	0.20	16	—	—	—	10.4	0.01	7
LBY218	92162.3	—	—	—	3168.8	0.10	10	10.1	0.11	3
LBY211	92412.1	—	—	—	—	—	—	10.1	0.19	3
LBY205	92164.1	—	—	—	—	—	—	10.9	0.06	11
LBY205	92164.3	258.1	0.27	13	—	—	—	—	—	—
LBY205	92166.2	—	—	—	3218.8	0.14	11	—	—	—
LBY199	92308.1	248.8	L	9	—	—	—	10.6	L	8
LBY197	92400.4	270.0	L	18	—	—	—	—	—	—
LBY197	92403.4	242.5	0.28	6	—	—	—	10.4	0.04	6
LBY195	92193.1	239.4	0.04	5	—	—	—	—	—	—
LBY195	92193.2	262.8	L	15	3450.0	0.21	19	10.3	0.13	5
LBY195	92193.3	251.2	L	10	3537.5	L	22	10.9	L	11
LBY190	91513.2	—	—	—	3318.8	0.26	15	—	—	—
LBY190	91513.3	275.7	L	21	3157.1	0.15	9	10.3	0.30	5
LBY176	92509.2	251.2	L	10	—	—	—	—	—	—
LBY176	92512.1	—	—	—	3306.2	0.16	14	—	—	—
LBY176	92513.1	—	—	—	3141.1	0.23	9	—	—	—
LBY164	92669.1	275.6	L	21	3118.8	0.16	8	11.1	0.17	13
LBY164	92671.1	—	—	—	3225.0	0.13	12	—	—	—
LBY163	91481.3	—	—	—	—	—	—	10.8	0.03	10
LBY163	91482.2	278.1	L	22	—	—	—	10.8	0.08	10
LBY163	91482.3	235.6	0.22	3	—	—	—	—	—	—
LBY163	91484.6	255.6	L	12	—	—	—	10.7	0.04	9
LBY160	92302.6	256.9	L	12	—	—	—	10.4	0.18	6
LBY160	92302.7	—	—	—	—	—	—	10.9	0.27	12
LBY151	92649.1	—	—	—	3237.5	0.21	12	11.0	0.28	12
LBY143	91470.4	—	—	—	3567.9	0.12	24	10.6	0.18	8
LBY143	91470.7	262.1	0.23	15	3214.3	0.22	11	—	—	—
LBY143	91470.8	255.0	L	12	—	—	—	—	—	—
LBY105	91386.6	239.4	0.03	5	—	—	—	10.5	0.13	7
LBY100	91410.2	239.6	0.23	5	—	—	—	—	—	—
LBY100	91410.3	270.0	L	18	—	—	—	10.6	L	9
CONT.	—	228.7	—	—	2887.8	—	—	9.79	—	—
LGN43	89052.3	376.2	0.15	7	5541.7	0.25	4	12.4	0.21	6
LGN43	89053.1	370.4	0.25	5	—	—	—	12.8	0.09	9
LGN43	89053.2	378.8	0.17	8	5645.8	0.17	6	12.3	0.26	5
CONT.	—	351.5	—	—	5322.8	—	—	11.7	—	—

Table 258. “CONT.”=Control; “Ave.”=Average; “% Incr.”=% increment; “p-val.”=p-value, L=p<0.01.

TABLE 259
Genes showing improved plant performance at Normal
growth conditions under regulation of At6669 promoter
		Plot Coverage [cm2]	Rosette Area [cm2]	Rosette Diameter [cm]
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN43	89053.2	65.1	0.02	32	8.14	0.02	32	4.76	L	14
CONT.	—	49.2	—	—	6.15	—	—	4.17	—	—
LGN17	89028.4	75.2	0.13	16	9.40	0.13	16	5.29	0.10	—
CONT.	—	64.6	—	—	8.08	—	—	4.91	—	—
LGN17	89027.1	74.5	0.20	23	9.32	0.20	23	4.99	0.19	13
LGN17	89028.4	72.3	0.27	19	9.03	0.27	19	—	—	—
CONT.	—	60.5	—	—	7.56	—	—	4.40	—	—
LBY90	91192.3	75.2	0.25	7	9.39	0.25	7	—	—	—
LBY90	91193.1	78.0	0.06	11	9.75	0.06	11	5.42	0.18	4
LBY88	91186.4	78.2	0.18	12	9.78	0.18	12	5.52	0.09	6
LBY59	91322.3	85.7	L	22	10.7	L	22	5.69	L	9
LBY47	91626.1	77.7	0.16	11	9.71	0.16	11	5.42	0.12	4
LBY45	92194.4	81.0	0.24	16	10.1	0.24	16	5.71	L	9
LBY45	92196.3	82.3	L	18	10.3	L	18	5.72	L	10
LBY45	92197.3	98.7	0.05	41	12.3	0.05	41	6.12	0.10	17
LBY40	91310.1	83.0	L	19	10.4	L	19	5.42	0.12	4
LBY40	91310.2	80.0	0.01	14	10.0	0.01	14	5.61	0.01	7
LBY228	91610.4	82.2	0.10	17	10.3	0.10	17	5.62	0.03	8
LBY18	91297.2	—	—	—	—	—	—	5.75	0.06	10
LBY16	91599.3	77.4	0.05	11	9.68	0.05	11	5.59	0.01	7
LBY128	91439.6	77.7	0.04	11	9.71	0.04	11	—	—	—
LBY100	91410.3	96.6	L	38	12.1	L	38	6.18	L	18
CONT.	—	70.0	—	—	8.75	—	—	5.23	—	—
LGN61	89105.3	—	—	—	—	—	—	5.63	0.03	5
CONT.	—	—	—	—	—	—	—	5.37	—	—
LGN61	89105.3	85.9	0.27	16	10.7	0.27	16	5.50	0.21	13
LGN61	89107.3	89.7	0.22	21	11.2	0.22	21	5.60	0.18	15
CONT.	—	74.0	—	—	9.25	—	—	4.89	—	—
LBY75	92094.1	—	—	—	—	—	—	5.65	0.10	4
LBY75	92094.2	92.2	0.15	10	11.5	0.15	10	5.70	0.18	5
LBY62	91401.3	88.1	0.24	5	11.0	0.24	5	5.58	0.24	3
LBY218	92159.3	92.6	0.05	10	11.6	0.05	10	5.73	0.07	5
LBY190	91513.2	89.0	0.27	6	11.1	0.27	6	5.64	0.18	4
LBY163	91481.2	93.6	0.02	11	11.7	0.02	11	5.78	0.03	6
LBY163	91481.3	89.5	0.14	6	11.2	0.14	6	5.82	0.02	7
LBY163	91484.3	96.8	L	15	12.1	L	15	5.86	0.03	8
CONT.	—	84.1	—	—	10.5	—	—	5.43	—	—
LGN40	90347.1	78.9	0.09	6	9.86	0.09	6	5.54	0.04	9
CONT.	—	74.2	—	—	9.28	—	—	5.07	—	—
LBY94	92333.2	—	—	—	8.40	0.07	19	5.24	0.13	12
LBY84	92213.3	68.3	0.14	21	8.54	0.14	21	5.21	0.20	12
LBY75	92096.1	75.9	0.01	35	9.49	0.01	35	5.44	0.02	17
LBY73	92387.3	64.8	0.17	15	8.10	0.17	15	—	—	—
LBY73	92388.1	69.6	0.04	23	8.70	0.04	23	5.17	0.07	11
LBY69	92169.3	79.6	L	41	9.95	L	41	5.50	0.04	18
LBY66	92089.3	64.3	0.18	14	8.03	0.18	14	5.11	0.09	9
LBY66	92091.1	71.7	0.02	27	8.97	0.02	27	5.37	0.02	15
LBY66	92093.3	71.3	0.12	26	8.91	0.12	26	5.26	0.11	13
LBY62	91400.7	—	—	—	—	—	—	4.95	0.28	6
LBY62	91401.3	64.7	0.16	15	8.08	0.16	15	—	—	—
LBY58	91376.5	73.8	0.02	31	9.22	0.02	31	5.58	0.07	20
LBY58	91378.2	73.0	0.04	29	9.12	0.04	29	5.39	0.02	16
LBY37	91217.1	62.9	0.29	11	7.86	0.29	11	4.97	0.22	7
LBY211	92412.1	88.5	0.01	57	11.1	0.01	57	6.03	0.02	29
LBY206	92350.3	74.3	0.01	32	9.29	0.01	32	5.38	0.02	15
LBY199	92307.1	74.5	0.04	32	9.31	0.04	32	5.39	0.03	15
LBY199	92308.1	69.9	0.17	24	8.74	0.17	24	5.39	0.02	16
LBY176	92509.2	85.3	0.01	51	10.7	0.01	51	5.78	0.01	24
LBY151	92649.2	64.4	0.21	14	8.05	0.21	14	5.18	0.15	11
LBY151	92651.3	64.4	0.27	14	8.05	0.27	14	5.03	0.19	8
LBY143	91470.4	76.4	L	35	9.55	L	35	5.57	L	19
LBY143	91470.7	67.7	0.19	20	9.03	0.02	28	5.44	0.02	17
LBY143	91470.8	71.1	0.07	26	8.89	0.07	26	5.26	0.07	13
CONT.	—	56.4	—	—	7.05	—	—	4.67	—	—
LBY99	91635.3	62.6	0.07	36	7.82	0.07	36	4.96	L	12
LBY99	91635.4	71.0	L	55	8.88	L	55	5.29	L	19
LBY99	91635.5	63.3	0.02	38	7.91	0.02	38	5.07	0.14	14
LBY99	91636.4	58.0	0.22	26	7.25	0.22	26	4.79	0.05	8
LBY66	92093.3	64.2	0.05	40	8.02	0.05	40	5.08	L	15
LBY218	92159.1	61.5	0.27	34	7.69	0.27	34	5.06	0.24	14
LBY218	92159.3	58.1	L	27	7.26	L	27	4.94	L	12
LBY218	92160.3	59.5	0.03	30	7.44	0.03	30	4.92	0.09	11
LBY218	92162.3	57.6	0.09	26	7.20	0.09	26	4.81	0.21	9
LBY211	92412.1	49.4	0.20	8	6.17	0.20	8	—	—	—
LBY205	92164.1	59.5	0.07	30	7.44	0.07	30	4.90	0.04	11
LBY205	92164.3	59.0	L	29	7.38	L	29	5.06	L	14
LBY199	92308.1	—	—	—	—	—	—	4.97	0.26	12
LBY197	92399.1	51.3	0.26	12	6.42	0.26	12	4.70	0.18	6
LBY197	92400.4	57.6	L	26	7.20	L	26	4.87	0.06	10
LBY197	92403.4	60.5	0.06	32	7.56	0.06	32	4.89	0.10	10
LBY195	92191.4	55.7	0.15	21	6.96	0.15	21	4.73	0.14	7
LBY195	92193.2	60.4	0.01	32	7.55	0.01	32	4.99	L	13
LBY195	92193.3	71.0	L	55	8.88	L	55	5.30	L	20
LBY190	91510.2	62.2	L	35	7.77	L	35	4.98	L	13
LBY190	91513.2	63.0	L	37	7.88	L	37	5.07	L	15
LBY190	91513.3	67.2	0.06	46	8.40	0.06	46	5.23	0.02	18
LBY176	92509.2	63.0	0.07	37	7.87	0.07	37	5.07	0.19	14
LBY176	92510.1	54.8	0.21	20	6.85	0.21	20	4.87	0.25	10
LBY164	92669.1	69.8	0.19	52	8.73	0.19	52	5.23	0.21	18
LBY163	91481.3	64.2	0.12	40	8.03	0.12	40	5.05	0.11	14
LBY163	91482.2	66.9	L	46	8.36	L	46	5.19	L	17
LBY163	91482.3	50.9	0.16	11	6.37	0.16	11	4.66	0.06	5
LBY163	91484.6	64.2	L	40	8.03	L	40	5.23	L	18
LBY160	92302.5	54.3	0.01	18	6.78	0.01	18	4.83	L	9
LBY160	92302.6	57.9	0.11	26	7.24	0.11	26	4.78	0.07	8
LBY160	92302.7	61.1	0.22	33	7.63	0.22	33	4.98	0.06	12
LBY151	92649.1	60.6	0.21	32	7.57	0.21	32	5.04	0.22	14
LBY151	92649.3	48.8	0.26	6	6.10	0.26	6	—	—	—
LBY143	91470.4	59.4	0.12	30	7.43	0.12	30	4.83	0.01	9
LBY143	91470.8	52.8	0.02	15	6.60	0.02	15	4.61	0.11	4
LBY105	91386.6	53.5	0.13	17	6.69	0.13	17	—	—	—
LBY100	91410.2	—	—	—	—	—	—	4.65	0.13	5
LBY100	91410.3	59.2	L	29	7.41	L	29	4.91	0.13	11
LBY100	91410.6	57.7	0.29	26	7.22	0.29	26	4.86	0.19	10
CONT.	—	45.9	—	—	5.74	—	—	4.43	—	—
LGN43	89052.3	81.0	0.12	17	10.1	0.12	17	5.50	0.14	11
CONT.	—	69.2	—	—	8.65	—	—	4.94	—	—
LGN13	89084.3	85.3	0.29	11	10.7	0.29	11	—	—	—
CONT.	—	76.8	—	—	9.60	—	—	—	—	—

Table 259. “CONT.”=Control; “Ave.”=Average; “% Incr.”=% increment; “p-val.”=p-value, L p<0.01.

TABLE 260
Genes showing improved plant performance at Normal growth
conditions under regulation of At6669 promoter
		RGR Of	RGR Of	RGR Of
		Leaf Number	Plot Coverage	Rosette Diameter
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN43	89053.2	—	—	—	7.48	0.04	32	0.365	0.08	9
CONT.	—	—	—	—	5.65	—	—	0.335	—	—
LGN17	89028.4	—	—	—	8.75	0.16	16	—	—	—
CONT.	—	—	—	—	7.54	—	—	—	—	—
LGN44	89056.1	0.724	0.28	16	—	—	—	—	—	—
CONT.	—	0.625	—	—	—	—	—	—	—	—
LGN17	89027.1	0.672	0.19	13	8.89	0.21	23	0.394	0.12	18
LGN17	89028.4	0.687	0.08	15	—	—	—	—	—	—
CONT.	—	0.597	—	—	7.23	—	—	0.334	—	—
LBY90	91192.2	0.689	0.19	21	—	—	—	—	—	—
LBY90	91192.3	—	—	—	8.86	0.21	7	—	—	—
LBY90	91193.1	—	—	—	9.31	0.04	13	0.456	0.20	4
LBY88	91186.4	—	—	—	9.36	0.11	13	0.479	0.01	9
LBY59	91321.3	—	—	—	—	—	—	0.461	0.12	5
LBY59	91322.3	—	—	—	10.1	0.13	22	—	—	—
LBY57	90974.1	0.648	0.08	14	—	—	—	—	—	—
LBY47	91626.1	—	—	—	9.17	0.16	11	—	—	—
LBY47	91627.3	0.629	0.14	10	—	—	—	—	—	—
LBY47	91628.1	0.672	0.21	18	—	—	—	—	—	—
LBY45	92194.4	—	—	—	9.66	0.20	17	0.485	L	11
LBY45	92196.3	—	—	—	9.70	0.24	17	0.476	0.07	8
LBY45	92197.3	—	—	—	11.5	0.01	39	0.496	0.18	13
LBY40	91310.1	—	—	—	9.87	0.19	19	—	—	—
LBY40	91310.2	—	—	—	9.46	0.02	14	0.454	0.19	4
LBY40	91311.1	0.681	0.24	20	—	—	—	—	—	—
LBY40	91314.1	0.623	0.24	9	—	—	—	—	—	—
LBY228	91610.2	0.712	0.10	25	—	—	—	—	—	—
LBY228	91610.4	—	—	—	9.71	0.23	17	0.463	0.07	6
LBY222	91602.2	0.688	0.16	21	—	—	—	—	—	—
LBY222	91604.4	0.680	0.19	19	—	—	—	—	—	—
LBY221	91417.1	0.621	0.23	9	—	—	—	—	—	—
LBY220	91305.2	0.663	0.23	16	—	—	—	—	—	—
LBY18	91297.2	—	—	—	—	—	—	0.487	0.27	11
LBY18	91297.4	0.614	0.26	8	—	—	—	—	—	—
LBY16	91595.3	0.671	0.21	18	—	—	—	—	—	—
LBY16	91599.3	—	—	—	9.06	0.06	10	0.458	0.26	4
LBY16	91599.7	—	—	—	9.95	0.23	20	—	—	—
LBY129	91585.1	0.656	0.07	15	—	—	—	—	—	—
LBY129	91585.4	0.675	0.21	18	—	—	—	—	—	—
LBY128	91437.2	0.649	0.15	14	—	—	—	—	—	—
LBY128	91439.6	—	—	—	9.08	0.06	10	—	—	—
LBY100	91410.3	—	—	—	11.4	0.01	37	0.495	0.19	13
LBY100	91410.4	0.626	0.15	10	—	—	—	—	—	—
CONT.	—	0.570	—	—	8.27	—	—	0.439	—	—
LGN61	89105.3	—	—	—	—	—	—	0.451	0.02	8
CONT.	—	—	—	—	—	—	—	0.420	—	—
LGN61	89106.1	0.696	0.30	18	—	—	—	—	—	—
LGN61	89107.3	—	—	—	10.6	0.26	20	0.440	0.21	17
CONT.	—	0.590	—	—	8.80	—	—	0.375	—	—
LBY75	92097.4	0.723	0.19	20	—	—	—	—	—	—
LBY73	92386.2	0.717	0.18	19	—	—	—	—	—	—
LBY69	92171.1	0.707	0.24	17	—	—	—	—	—	—
LBY69	92172.3	0.713	0.20	18	—	—	—	—	—	—
LBY62	91400.7	0.791	0.05	31	—	—	—	—	—	—
LBY190	91513.2	0.699	0.28	16	—	—	—	—	—	—
LBY163	91481.3	—	—	—	—	—	—	0.488	0.27	13
LBY160	92302.7	0.696	0.28	15	—	—	—	—	—	—
LBY105	91388.1	0.765	0.07	27	—	—	—	—	—	—
CONT.	—	0.603	—	—	—	—	—	0.434	—	—
LGN40	90345.1	0.776	0.16	14	—	—	—	—	—	—
LGN40	90346.2	—	—	—	—	—	—	0.424	0.20	7
LGN40	90347.1	—	—	—	9.23	0.09	6	0.440	0.06	11
CONT.	—	0.682	—	—	8.69	—	—	0.397	—	—
LBY84	92213.3	—	—	—	8.88	0.28	23	—	—	—
LBY75	92096.1	—	—	—	9.74	0.11	35	0.504	0.28	17
LBY73	92387.3	0.714	0.13	32	—	—	—	—	—	—
LBY73	92388.1	—	—	—	8.86	0.28	23	—	—	—
LBY69	92169.3	0.775	0.07	44	10.2	0.06	42	—	—	—
LBY66	92091.1	0.703	0.16	30	9.22	0.19	28	—	—	—
LBY66	92093.3	0.701	0.19	30	9.09	0.22	26	—	—	—
LBY58	91376.5	—	—	—	9.39	0.15	30	0.504	0.29	17
LBY58	91378.2	—	—	—	9.41	0.16	30	—	—	—
LBY45	92197.3	0.699	0.18	30	—	—	—	—	—	—
LBY211	92412.1	—	—	—	11.4	0.01	57	0.567	0.06	31
LBY206	92350.3	—	—	—	9.54	0.13	32	—	—	—
LBY199	92307.1	—	—	—	9.58	0.13	33	—	—	—
LBY199	92308.1	—	—	—	8.99	0.25	25	0.505	0.28	17
LBY176	92509.1	0.708	0.19	31	—	—	—	—	—	—
LBY176	92509.2	0.826	0.02	53	10.9	0.02	51	0.522	0.18	21
LBY143	91470.4	—	—	—	9.80	0.10	36	0.531	0.14	23
LBY143	91470.7	0.665	0.29	23	—	—	—	—	—	—
LBY143	91470.8	—	—	—	9.16	0.21	27	—	—	—
CONT.	—	0.540	—	—	7.21	—	—	0.431	—	—
LBY99	91635.3	—	—	—	8.22	0.06	37	—	—	—
LBY99	91635.4	0.775	0.04	28	9.33	L	56	0.523	0.10	19
LBY99	91635.5	0.709	0.21	17	8.25	0.06	38	0.495	0.30	12
LBY99	91636.4	—	—	—	7.60	0.16	27	—	—	—
LBY66	92093.3	—	—	—	8.39	0.04	40	0.493	0.28	12
LBY218	92159.1	—	—	—	8.09	0.07	35	0.497	0.26	13
LBY218	92159.3	—	—	—	7.62	0.14	27	—	—	—
LBY218	92160.3	—	—	—	7.80	0.11	30	—	—	—
LBY218	92162.3	—	—	—	7.56	0.16	26	—	—	—
LBY205	92164.1	0.726	0.16	20	7.83	0.11	30	—	—	—
LBY205	92164.3	—	—	—	7.76	0.11	29	0.512	0.16	16
LBY205	92166.2	—	—	—	7.25	0.28	21	—	—	—
LBY199	92308.1	—	—	—	7.89	0.11	32	—	—	—
LBY197	92400.4	—	—	—	7.55	0.16	26	—	—	—
LBY197	92403.4	—	—	—	7.94	0.09	32	—	—	—
LBY195	92191.4	—	—	—	7.28	0.24	21	—	—	—
LBY195	92193.2	—	—	—	7.95	0.08	33	0.500	0.23	14
LBY195	92193.3	0.711	0.19	17	9.31	L	55	0.517	0.13	17
LBY190	91510.2	—	—	—	8.17	0.05	36	0.492	0.29	12
LBY190	91513.2	—	—	—	8.25	0.04	38	0.504	0.18	14
LBY190	91513.3	—	—	—	8.84	0.02	47	0.514	0.15	17
LBY184	92148.1	—	—	—	7.46	0.22	24	—	—	—
LBY176	92509.2	—	—	—	8.23	0.05	37	0.499	0.22	13
LBY176	92510.1	—	—	—	7.20	0.28	20	—	—	—
LBY176	92512.1	—	—	—	7.28	0.26	21	—	—	—
LBY164	92669.1	0.735	0.11	21	9.19	0.01	53	0.511	0.19	16
LBY163	91481.3	0.766	0.05	26	8.44	0.04	41	0.493	0.29	12
LBY163	91482.2	—	—	—	8.83	0.02	47	0.513	0.14	16
LBY163	91484.6	—	—	—	8.41	0.03	40	0.524	0.09	19
LBY160	92302.5	—	—	—	7.12	0.29	19	—	—	—
LBY160	92302.6	—	—	—	7.61	0.15	27	—	—	—
LBY160	92302.7	0.704	0.24	16	7.99	0.08	33	—	—	—
LBY151	92649.1	0.757	0.07	25	7.86	0.10	31	0.494	0.29	12
LBY143	91470.4	—	—	—	7.79	0.10	30	—	—	—
LBY100	91410.3	—	—	—	7.76	0.11	29	—	—	—
LBY100	91410.6	0.703	0.25	16	7.62	0.16	27	—	—	—
CONT.	—	0.608	—	—	6.00	—	—	0.440	—	—
LGN43	89052.3	—	—	—	9.44	0.13	17	0.416	0.21	11
CONT.	—	—	—	—	8.07	—	—	0.374	—	—
LGN13	89084.5	0.727	0.03	26	—	—	—	—	—	—
LGN13	89084.6	0.657	0.12	14	—	—	—	—	—	—
CONT.	—	0.577	—	—	—	—	—	—	—	—

Table 260. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

The genes listed in Tables 261-263 improved plant performance when grown at low nitrogen (Low N) conditions. These genes produced larger plants with a larger photosynthetic area, biomass (fresh weight, dry weight, rosette diameter, rosette area and plot coverage) and relative growth rate (RGR). The genes were cloned under the regulation of a constitutive At6669 promoter (SEQ ID NO: 10654). The evaluation of each gene was performed by testing the performance of different number of events. Event with p-value<0.1 was considered statistically significant.

TABLE 261
Genes showing improved plant performance at Low
Nitrogen growth conditions under regulation of At6669 promoter
		Dry Weight [mg]	Fresh Weight [mg]	Leaf Number
Gene	Event		P-	%		P-	%		P-	%
Name	#	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN43	89052.2	—	—	—	2487.5	0.13	3	10.5	0.30	5
LGN43	89052.3	—	—	—	2495.8	0.23	3	—	—	—
LGN43	89053.2	241.7	0.04	9	2587.5	0.11	7	—	—	—
CONT.	—	221.7	—	—	2412.5	—	—	10.0	—	—
LGN44	89055.7	—	—	—	—	—	—	10.5	0.27	2
LGN44	89056.1	187.5	0.11	7	2195.8	0.23	38	—	—	—
CONT.	—	175.4	—	—	1587.5	—	—	10.3	—	—
LGN61	89105.2	242.9	0.27	4	3008.3	0.26	4	11.5	0.29	4
LGN61	89105.3	—	—	—	3175.0	0.04	10	11.2	0.08	2
LGN61	89107.2	—	—	—	—	—	—	11.6	0.05	5
CONT.	—	232.9	—	—	2895.8	—	—	11.0	—	—
LGN40	90345.1	—	—	—	2491.7	0.12	4	—	—	—
LGN40	90346.2	—	—	—	2466.7	0.20	3	—	—	—
LGN40	90347.1	—	—	—	2454.2	0.27	3	—	—	—
CONT.	—	—	—	—	2387.1	—	—	—	—	—
LGN17	89028.4	303.8	0.14	15	3579.2	0.09	8	—	—	—
CONT.	—	263.1	—	—	3328.1	—	—	—	—	—
LGN44	89057.3	—	—	—	—	—	—	12.7	0.15	6
CONT.	—	—	—	—	—	—	—	12.0	—	—
LGN17	89024.1	315.0	0.09	8	3258.3	0.26	5	12.1	0.09	6
LGN17	89028.4	316.7	0.04	9	3262.5	0.24	5	11.8	0.11	3
CONT.	—	290.6	—	—	3103.1	—	—	11.4	—	—
LGN20	89089.3	—	—	—	—	—	—	10.8	0.06	4
LGN20	89091.4	260.0	0.10	7	3258.3	0.13	7	—	—	—
CONT.	—	243.8	—	—	3057.1	—	—	10.4	—	—
LGN40	90345.1	—	—	—	—	—	—	11.8	0.08	11
LGN40	90345.4	271.2	0.03	4	3583.3	0.03	5	11.7	0.05	10
LGN40	90347.1	—	—	—	—	—	—	11.4	0.18	8
CONT.	—	261.7	—	—	3408.3	—	—	10.6	—	—
LGN13	89084.3	302.9	0.25	4	—	—	—	12.5	0.27	6
CONT.	—	290.0	—	—	—	—	—	11.9	—	—

Table 261. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value. L—p<0.01.

TABLE 262
Genes showing improved plant performance at Low Nitrogen
growth conditions under regulation of At6669 promoter
	Plot Coverage	Rosette Area	Rosette Diameter
	[cm2]	[cm2]	[cm]
Gene			P-	%		P-	%		P-	%
Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN43	89053.2	40.5	0.05	27	5.07	0.05	27	3.60	0.07	14
CONT.	—	31.9	—	—	3.99	—	—	3.15	—	—
LGN61	89105.3	—	—	—	—	—	—	3.94	0.04	4
LGN61	89107.2	—	—	—	—	—	—	4.01	0.29	6
LGN61	89107.3	53.4	0.17	13	6.67	0.17	13	4.14	0.09	9
CONT.	—	47.1	—	—	5.89	—	—	3.78	—	—
LGN17	89028.4	45.8	0.13	14	5.73	0.13	14	3.69	0.19	5
CONT.	—	40.1	—	—	5.02	—	—	3.50	—	—
LGN61	89107.3	57.7	0.29	12	7.21	0.29	12	—	—	—
CONT.	—	51.3	—	—	6.42	—	—	—	—	—
LGN17	89024.1	59.6	0.03	26	7.45	0.03	26	4.31	0.05	15
LGN17	89028.4	58.3	L	24	7.29	L	24	4.18	L	11
CONT.	—	47.2	—	—	5.90	—	—	3.76	—	—
LGN40	90345.4	60.8	0.25	22	7.59	0.28	12	—	—	—
CONT.	—	49.9	—	—	6.78	—	—	—	—	—
LGN13	89084.3	75.5	0.12	24	9.44	0.12	24	4.86	0.12	13
CONT.	—	60.9	—	—	7.62	—	—	4.32	—	—

Table 262. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 263
Genes showing improved plant performance at Low Nitrogen
growth conditions under regulation of At6669 promoter
	RGR Of	RGR Of	RGR Of Rosette
	Leaf Number	Plot Coverage	Diameter
Gene			P-	%		P-	%		P-	%
Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN43	89052.2	0.751	0.22	16	—	—	—	—	—	—
LGN43	89052.3	—	—	—	—	—	—	0.276	0.25	15
LGN43	89053.2	—	—	—	4.60	0.06	25	0.267	0.14	11
CONT.	—	0.646	—	—	3.68	—	—	0.240	—	—
LGN61	89105.2	—	—	—	—	—	—	0.273	0.21	8
LGN61	89105.3	—	—	—	—	—	—	0.273	0.29	8
LGN61	89106.1	—	—	—	—	—	—	0.268	0.25	6
LGN61	89107.2	0.724	0.28	13	—	—	—	0.292	0.10	16
LGN61	89107.3	—	—	—	5.85	0.28	10	0.278	0.12	11
CONT.	—	0.642	—	—	5.32	—	—	0.252	—	—
LGN40	90345.1	—	—	—	—	—	—	0.260	0.27	8
LGN40	90345.3	—	—	—	—	—	—	0.257	0.27	7
LGN40	90347.1	—	—	—	—	—	—	0.252	0.22	5
CONT.	—	—	—	—	—	—	—	0.241	—	—
LGN17	89028.4	—	—	—	5.19	0.21	12	—	—	—
CONT.	—	—	—	—	4.62	—	—	—	—	—
LGN44	89055.7	0.754	0.23	8	—	—	—	—	—	—
LGN44	89057.3	0.792	0.17	14	—	—	—	—	—	—
CONT.	—	0.696	—	—	—	—	—	—	—	—
LGN17	89024.1	0.744	0.26	6	7.16	0.04	29	0.328	0.05	22
LGN17	89028.4	—	—	—	6.83	0.01	23	0.290	0.18	8
CONT.	—	0.699	—	—	5.56	—	—	0.269	—	—
LGN20	89089.3	0.784	0.13	14	—	—	—	—	—	—
LGN20	89091.4	0.772	0.20	12	—	—	—	—	—	—
LGN20	89093.4	0.719	0.29	4	—	—	—	—	—	—
CONT.	—	0.691	—	—	—	—	—	—	—	—
LGN40	90345.1	0.797	0.04	25	—	—	—	—	—	—
LGN40	90345.4	0.734	0.27	15	7.17	0.28	22	—	—	—
LGN40	90347.1	0.754	0.08	19	—	—	—	—	—	—
CONT.	—	0.636	—	—	5.87	—	—	—	—	—
LGN13	89084.2	0.728	0.21	6	—	—	—	—	—	—
CONT.	—	0.684	—	—	—	—	—	—	—	—
LGN13	89084.3	0.693	0.29	11	8.92	0.14	24	—	—	—
CONT.	—	0.624	—	—	7.20	—	—	—	—	—

Table 263. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

Example 31

Evaluating Transgenic Arabidopsis Under Normal and Low Nitrogen Conditions Using Seedling Analyses of T2 and T1 Plants

Seedling analysis of plants growth under favorable (normal) nitrogen concentration levels—Surface sterilized seeds were sown in basal media [50% Murashige-Skoog medium (MS) supplemented with 0.8% plant agar as solidifying agent] in the presence of Kanamycin (used as a selecting agent). After sowing, plates were transferred for 2-3 days for stratification at 4° C. and then grown at 25° C. under 12-hour light 12-hour dark daily cycles for 7 to 10 days. At this time point, seedlings randomly chosen were carefully transferred to plates containing ½ MS media (15 mM N, normal conditions). For experiments performed in T₂ lines, each plate contained 5 seedlings of the same transgenic event, and 3-4 different plates (replicates) for each event. For each polynucleotide of the invention at least four-five independent transformation events were analyzed from each construct. For experiments performed in T₁ lines, each plate contained 5 seedlings of 5 independent transgenic events and 3-4 different plates (replicates) were planted. In total, for T₁ lines, 20 independent events were evaluated. Plants expressing the polynucleotides of the invention were compared to the average measurement of the control plants (empty vector or GUS reporter gene under the same promoter) used in the same experiment.

Seedling analysis of plants growth under low and favorable nitrogen concentration levels—Low nitrogen is an abiotic stress that impact root growth and seedling growth. Therefore, an assay that examines plant performance under low (0.75 mM Nitrogen) and favorable (15 mM Nitrogen) nitrogen concentrations was performed, as follows.

Surface sterilized seeds were sown in basal media [50% Murashige-Skoog medium (MS) supplemented with 0.8% plant agar as solidifying agent] in the presence of Kanamycin (used as a selecting agent). After sowing, plates were transferred for 2-3 days for stratification at 4° C. and then grown at 25° C. under 12-hour light 12-hour dark daily cycles for 7 to 10 days. At this time point, seedlings randomly chosen were carefully transferred to plates containing ½ MS media (15 mM N) for the normal nitrogen concentration treatment and 0.75 mM nitrogen for the low nitrogen concentration treatments. For experiments performed in T2 lines, each plate contained 5 seedlings of the same transgenic event, and 3-4 different plates (replicates) for each event. For each polynucleotide of the invention at least four-five independent transformation events were analyzed from each construct. For experiments performed in T1 lines, each plate contained 5 seedlings of 5 independent transgenic events and 3-4 different plates (replicates) were planted. In total, for T1 lines, 20 independent events were evaluated. Plants expressing the polynucleotides of the invention were compared to the average measurement of the control plants (empty vector or GUS reporter gene under the same promoter) used in the same experiment.

Digital imaging—A laboratory image acquisition system, which consists of a digital reflex camera (Canon EOS 300D) attached with a 55 mm focal length lens (Canon EF-S series), mounted on a reproduction device (Kaiser RS), which includes 4 light units (4×150 Watts light bulb) and located in a darkroom, was used for capturing images of plantlets sawn in agar plates.

The image capturing process was repeated every 3-4 days starting at day 1 till day 10 (see for example the images in FIGS. 3A-F). An image analysis system was used, which consists of a personal desktop computer (Intel P4 3.0 GHz processor) and a public domain program—ImageJ 1.39 [Java based image processing program which was developed at the U.S. National Institutes of Health and freely available on the internet at rsbweb (dot) nih (dot) gov/]. Images were captured in resolution of 10 Mega Pixels (3888×2592 pixels) and stored in a low compression JPEG (Joint Photographic Experts Group standard) format. Next, analyzed data was saved to text files and processed using the JMP statistical analysis software (SAS institute).

Seedling analysis—Using the digital analysis seedling data was calculated, including leaf area, root coverage and root length.

The relative growth rate for the various seedling parameters was calculated according to the following Formulas XIII (RGR leaf area, above), XXVIII (RGR root coverage, described above) and VI (RGR root length, below).

At the end of the experiment, plantlets were removed from the media and weighed for the determination of plant fresh weight. Plantlets were then dried for 24 hours at 60° C., and weighed again to measure plant dry weight for later statistical analysis. The fresh and dry weights were provided for each Arabidopsis plant. Growth rate was determined by comparing the leaf area coverage, root coverage and root length, between each couple of sequential photographs, and results were used to resolve the effect of the gene introduced on plant vigor under optimal conditions. Similarly, the effect of the gene introduced on biomass accumulation, under optimal conditions, was determined by comparing the plants' fresh and dry weight to that of control plants (containing an empty vector or the GUS reporter gene under the same promoter). From every construct created, 3-5 independent transformation events were examined in replicates.

Statistical analyses—To identify genes conferring significantly improved plant vigor or enlarged root architecture, the results obtained from the transgenic plants were compared to those obtained from control plants. To identify outperforming genes and constructs, results from the independent transformation events tested were analyzed separately. To evaluate the effect of a gene event over a control the data was analyzed by Student's t-test and the p value was calculated. Results were considered significant if p≦0.1. The JMP statistics software package was used (Version 5.2.1, SAS Institute Inc., Cary, N.C., USA).

Experimental Results:

Tables 264-266 summarize the observed phenotypes of transgenic plants expressing the gene constructs using the TC-T2 assays [tissue culture (seedling assays), T2 plants, seedling (plantlets) analyses].

The genes presented in Table 264 showed a significant improvement as they produced larger plant biomass (plant fresh and dry weight) in T2 generation when grown under low nitrogen growth conditions, compared to control plants. The genes were cloned under the regulation of a constitutive promoter (At6669, SEQ ID NO: 10654). The evaluation of each gene was carried out by testing the performance of different number of events. Some of the genes were evaluated in more than one seedling assay. The results obtained in these second experiments were significantly positive as well.

TABLE 264
Genes showing improved plant performance at Low
Nitrogen growth conditions under regulation of At6669 promoter
	Dry Weight	Fresh Weight
	[mg]	[mg]
Gene				%			%
Name	Event #	Ave.	P-Val.	Incr.	Ave.	P-Val.	Incr.
LGN35	89043.1	4.15	L	15	65.7	0.02	28
LGN35	89043.2	4.15	0.01	15	57.3	0.25	11
LGN35	89043.3	—	—	—	58.4	0.03	14
LGN35	89043.4	4.20	L	16	60.5	0.07	18
CONT.	—	3.61	—	—	51.4	—	—
LGN39	89931.1	—	—	—	84.7	0.17	10
LGN39	89931.3	5.47	0.18	15	84.5	0.12	10
LGN39	89931.4	—	—	—	85.2	0.08	11
LGN34	90400.2	5.35	0.09	12	—	—	—
LGN34	90403.3	5.75	0.20	21	92.8	0.11	21
CONT.	—	4.76	—	—	76.7	—	—
NUE3	88975.1	4.30	0.14	17	—	—	—
NUE3	88977.1	3.92	0.27	7	98.6	0.05	40
NUE3	88977.2	4.17	0.18	14	85.8	0.06	21
LGN9	89186.1	3.98	0.29	8	103.6	0.21	47
LGN9	89186.2	—	—	—	78.9	0.23	12
LGN7	89181.1	—	—	—	133.4	0.19	89
LGN14	89168.2	—	—	—	78.6	0.14	11
CONT.	—	3.67	—	—	70.6	—	—
LGN26	89036.1	5.65	0.05	25	79.5	0.05	21
LGN26	89036.3	4.88	0.26	8	—	—	—
LGN26	89037.2	6.10	L	35	90.8	0.02	38
LGN26	89037.3	5.75	0.02	27	75.3	0.16	14
CONT.	—	4.53	—	—	65.9	—	—
LGN46	89101.1	—	—	—	74.2	0.15	10
LGN46	89101.4	4.90	0.10	12	83.0	0.12	22
LGN46	89101.7	—	—	—	74.1	0.18	9
CONT.	—	4.71	—	—	76.8	—	—
LGN57	89064.2	5.98	0.03	55	97.2	0.20	40
LGN57	89065.1	4.90	0.10	27	—	—	—
LGN57	89067.1	5.30	0.01	38	88.0	0.18	27
LGN57	89067.2	4.92	0.04	28	—	—	—
CONT.	—	3.85	—	—	69.3	—	—
LGN4	89075.2	—	—	—	81.5	L	23
CONT.	—	—	—	—	66.4	—	—
LGN52	90578.6	4.30	0.19	5	73.8	0.03	9
LGN52	90581.1	4.72	0.02	15	72.9	0.05	7
LGN52	90581.2	5.07	0.04	24	—	—	—
CONT.	—	4.10	—	—	72.7	—	—
LGN46	89101.9	5.03	0.16	23	—	—	—
CONT.	—	4.09	—	—	—	—	—
LGN45	91579.5	5.38	0.17	7	—	—	—
CONT.	—	5.04	—	—	—	—	—
LGN23	92317.2	4.42	0.20	12	—	—	—
CONT.	—	3.96	—	—	—	—	—
LGN18	92468.3	4.95	0.17	6	—	—	—
CONT.	—	4.66	—	—	—	—	—
LGN35	89043.2	4.72	0.29	8	—	—	—
CONT.	—	4.38	—	—	—	—	—
LGN33	91570.4	—	—	—	72.3	0.29	13
LGN33	91572.1	4.15	0.04	14	—	—	—
LGN33	91572.3	3.92	0.08	8	—	—	—
LGN33	91574.4	3.90	0.23	7	—	—	—
CONT.	—	3.64	—	—	64.0	—	—
LGN47	91171.4	4.88	0.24	14	—	—	—
LGN47	91174.4	4.77	L	11	—	—	—
CONT.	—	4.29	—	—	—	—	—
LGN42	92204.1	5.35	0.19	5	—	—	—
CONT.	—	5.07	—	—	—	—	—
NUE3	88977.1	3.98	0.23	8	69.9	0.25	11
NUE3	88977.2	4.47	0.03	22	72.5	0.15	15
NUE3	88977.5	4.65	0.07	27	74.9	0.22	19
LGN9	89186.1	—	—	—	87.5	0.19	39
LGN7	89181.1	4.28	0.13	16	—	—	—
LGN7	89183.2	3.98	0.28	8	—	—	—
LGN14	89165.3	3.98	0.28	8	—	—	—
CONT.	—	3.67	—	—	62.8	—	—
LGN49	89079.3	—	—	—	86.8	0.29	12
LGN49	89081.3	5.98	0.02	18	108.1	0.29	40
LGN49	89081.6	—	—	—	85.0	0.12	10
CONT.	—	5.05	—	—	77.2	—	—
LGN4	89075.2	5.00	L	27	87.5	0.02	19
CONT.	—	3.92	—	—	73.5	—	—
LGN23	92316.2	3.95	0.09	11	—	—	—
LGN23	92317.2	4.15	0.27	16	—	—	—
CONT.	—	3.56	—	—	—	—	—
LGN24	89096.3	3.55	0.25	3	—	—	—
CONT.	—	3.45	—	—	—	—	—
LGN5	88198.1	5.40	0.07	8	95.8	0.17	17
LGN5	88198.4	5.88	0.26	18	98.4	0.06	20
LGN5	88203.2	5.00	0.19	7	—	—	—
CONT.	—	4.99	—	—	82.2	—	—
LGN47	91174.3	4.98	0.20	13	—	—	—
CONT.	—	4.40	—	—	—	—	—
LGN1	92184.1	4.22	0.10	8	104.6	0.14	32
LGN1	92185.1	4.50	L	15	—	—	—
LGN1	92185.2	4.40	0.10	12	—	—	—
LGN1	92187.1	4.33	0.05	11	122.5	0.23	54
LGN1	92188.1	4.77	0.08	22	—	—	—
CONT.	—	3.91	—	—	90.8	—	—
LGN2	89029.2	4.35	0.13	10	—	—	—
LGN2	89029.5	4.30	0.15	9	—	—	—
LGN2	89032.2	4.40	0.11	11	—	—	—
LGN2	89033.1	4.42	0.15	12	75.8	0.22	11
CONT.	—	3.96	—	—	68.1	—	—
LGN45	91575.2	—	—	—	70.5	L	25
LGN45	91575.3	—	—	—	67.1	0.27	19
LGN45	91579.3	—	—	—	81.8	0.12	45
LGN45	91579.4	—	—	—	87.3	0.12	55
LGN45	91579.5	—	—	—	62.4	0.24	11
CONT.	—	—	—	—	56.3	—	—
LGN33	91574.4	4.15	0.09	10	69.8	0.19	22
CONT.	—	3.76	—	—	57.3	—	—
LGN57	89064.2	4.90	0.03	25	84.4	0.02	21
LGN57	89065.1	3.88	0.28	3	—	—	—
LGN57	89066.1	—	—	—	76.1	0.25	9
CONT.	—	3.92	—	—	70.0	—	—
NUE102	90005.1	—	—	—	67.8	0.18	19
CONT.	—	—	—	—	57.0	—	—
LGN42	92204.2	4.60	0.04	11	—	—	—
LGN42	92204.5	5.17	0.12	25	—	—	—
CONT.	—	4.15	—	—	—	—	—
LGN60	89176.1	5.47	0.13	23	81.9	0.29	8
CONT.	—	4.45	—	—	75.9	—	—

Table 264. “CONT.”—Control; “Ave.”—Average: “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

The genes presented in Table 265 showed a significant improvement as they produced larger plant biomass (plant fresh and dry weight) in T2 generation when grown under normal growth conditions, compared to control plants. The genes were cloned under the regulation of a constitutive promoter (At6669. SEQ ID NO: 10654). The evaluation of each gene was carried out by testing the performance of different number of events. Some of the genes were evaluated in more than one seedling assay. The results obtained in these second experiments were significantly positive as well.

TABLE 265
Genes showing improved plant performance at Normal
growth conditions under regulation of At6669 promoter
	Dry Weight	Fresh Weight
	[mg]	[mg]
Gene				%			%
Name	Event #	Ave.	P-Val.	Incr.	Ave.	P-Val.	Incr.
LBY200	92754.1	9.63	0.04	43	181.0	L	45
LBY200	92754.3	7.60	0.16	13	159.2	0.02	27
LBY200	92757.1	9.05	0.03	34	214.7	0.16	72
LBY200	92757.2	8.27	0.03	23	168.6	0.08	35
LBY200	92758.3	—	—	—	149.5	0.27	20
LBY141	92564.1	10.3	0.08	53	188.0	0.07	50
LBY141	92565.2	8.43	0.02	25	173.5	0.06	39
LBY141	92566.3	8.70	0.17	29	158.8	0.16	27
LBY141	92566.4	—	—	—	151.2	0.19	21
LBY141	92568.1	7.77	0.12	15	154.4	0.15	24
CONT.	—	6.74	—	—	124.9	—	—
LGN35	89043.2	8.68	0.04	20	—	—	—
CONT.	—	7.21	—	—	—	—	—
LBY175	92179.1	10.6	0.24	22	—	—	—
LBY175	92181.2	10.4	0.05	20	—	—	—
LBY175	92181.4	9.75	0.29	12	—	—	—
LBY149	92245.2	11.1	0.20	28	—	—	—
LBY140	92265.2	11.1	0.03	28	—	—	—
LBY116	92136.4	11.0	0.10	27	—	—	—
LBY116	92138.6	13.0	L	50	—	—	—
CONT.	—	8.68	—	—	—	—	—
LGN39	89931.3	7.60	0.15	40	131.1	0.15	36
LGN34	90400.2	9.70	L	78	160.7	L	67
LGN34	90403.3	7.22	0.15	33	132.1	0.15	37
CONT.	—	5.44	—	—	96.2	—	—
NUE3	88975.1	—	—	—	131.7	0.26	20
NUE3	88977.1	7.60	0.06	35	148.5	0.08	36
NUE3	88977.2	6.42	0.09	14	168.8	0.15	54
LGN9	89186.1	6.38	0.19	14	140.9	0.03	29
LGN7	89183.3	—	—	—	125.9	0.29	15
LGN7	89183.8	—	—	—	133.5	0.10	22
LGN14	89168.1	—	—	—	128.2	0.21	17
LGN14	89168.2	6.17	0.28	10	122.0	0.20	12
LGN14	89168.5	—	—	—	148.4	0.26	36
CONT.	—	5.61	—	—	109.4	—	—
LBY52	93946.3	10.4	0.29	22	—	—	—
LBY34_H2	93855.2	10.0	0.17	17	—	—	—
LBY34_H2	93856.1	11.2	0.04	30	185.2	0.02	39
LBY27_H4	93931.4	10.3	0.19	21	170.9	0.12	28
LBY148	93767.2	9.57	0.29	12	163.6	0.10	23
CONT.	—	8.55	—	—	133.3	—	—
LGN26	89037.2	10.2	0.23	13	177.4	0.28	13
LGN26	89037.3	12.9	L	43	224.2	0.04	43
LGN26	89037.4	12.4	L	38	208.7	0.01	33
CONT.	—	9.00	—	—	156.9	—	—
LGN46	89101.3	9.67	0.25	8	—	—	—
LGN46	89101.7	10.6	0.23	15	187.6	0.21	20
CONT.	—	9.18	—	—	156.5	—	—
LGN57	89064.2	11.2	0.09	45	212.9	0.11	58
LGN57	89065.1	10.9	0.04	42	179.2	0.05	33
LGN57	89067.1	9.67	0.08	25	188.2	0.05	39
LGN57	89067.2	—	—	—	159.0	0.26	18
CONT.	—	7.74	—	—	135.1	—	—
LGN36	89044.1	11.3	0.10	25	212.2	0.03	33
CONT.	—	9.03	—	—	159.9	—	—
LBY185	91498.2	10.7	0.10	29	—	—	—
LBY185	91499.2	10.9	0.12	32	—	—	—
LBY185	91499.3	9.70	0.26	17	242.3	0.23	41
LBY179	91545.2	10.6	L	28	—	—	—
LBY173	91652.1	11.8	L	43	242.5	0.06	41
LBY173	91653.1	11.4	0.26	38	238.1	0.29	38
LBY121	92290.4	11.0	0.07	33	231.8	0.10	35
CONT.	—	8.27	—	—	172.1	—	—
LGN54	88208.2	10.7	0.06	18	195.3	0.17	10
CONT.	—	9.05	—	—	180.3	—	—
LBY80	92270.1	8.97	0.02	32	—	—	—
LBY78	92311.3	—	—	—	166.2	0.28	16
LBY78	92311.4	8.97	L	32	177.0	0.04	24
LBY78	92312.2	7.75	0.20	14	165.0	0.28	15
LBY78	92313.5	8.43	0.08	24	176.6	0.24	24
LBY53	92414.1	7.75	0.09	14	—	—	—
LBY53	92418.1	7.75	0.10	14	—	—	—
LBY208	92356.1	8.45	0.03	24	173.0	0.03	21
LBY208	92357.1	9.15	0.02	35	165.8	0.30	16
LBY208	92358.2	8.38	0.02	23	—	—	—
LBY208	92358.4	7.83	0.20	15	178.1	0.27	25
LBY153	92249.2	9.53	0.01	40	194.5	0.01	36
LBY153	92252.2	8.38	0.25	23	—	—	—
LBY153	92253.2	8.35	0.16	23	—	—	—
LBY149	92246.3	8.72	0.27	29	172.2	0.26	20
LBY121	92290.3	8.60	0.10	27	—	—	—
LBY121	92291.4	7.95	0.16	17	188.8	0.20	32
LBY121	92293.2	8.30	0.11	22	167.4	0.29	17
CONT.	—	6.79	—	—	143.0	—	—
LGN4	89075.2	—	—	—	167.8	0.27	16
CONT.	—	—	—	—	144.4	—	—
LGN52	90578.6	7.38	0.25	20	156.5	0.08	30
LGN52	90581.1	6.98	0.26	13	139.1	0.17	16
CONT.	—	6.16	—	—	119.9	—	—
LGN41	92101.1	8.93	0.04	31	—	—	—
LGN41	92102.3	8.78	0.11	28	—	—	—
CONT.	—	6.84	—	—	—	—	—
LGN46	89101.4	7.75	0.08	24	140.6	0.27	14
LGN46	89101.9	7.80	0.11	25	152.3	0.10	24
CONT.	—	6.24	—	—	122.9	—	—
LGN45	91575.2	12.9	0.02	28	237.4	L	29
LGN45	91575.3	13.0	L	29	283.7	L	54
LGN45	91579.4	11.3	0.16	12	248.0	0.10	35
CONT.	—	10.1	—	—	183.7	—	—
LBY92	93921.2	14.2	0.03	53	239.5	L	66
LBY92	93923.3	12.4	0.21	33	197.2	0.18	37
LBY201	93928.1	10.3	0.10	11	—	—	—
LBY148	93764.1	—	—	—	163.2	0.14	13
LBY106_H3	93918.1	14.4	0.09	55	218.1	0.12	51
CONT.	—	9.30	—	—	144.0	—	—
LBY50	91317.3	9.18	0.01	39	177.3	L	42
LBY50	91319.2	6.98	0.20	6	146.2	0.25	17
LBY24	91220.6	7.45	0.25	13	144.4	0.08	16
LBY24	91221.2	8.70	0.22	32	183.0	0.17	46
LBY24	91223.1	7.47	0.29	13	152.3	0.25	22
LBY21	90977.1	7.55	0.14	14	138.2	0.14	11
LBY21	90978.4	—	—	—	151.9	0.28	22
LBY161	91293.3	8.60	L	30	195.4	0.11	56
LBY161	91294.1	8.78	0.02	33	200.6	0.17	61
LBY161	91294.2	—	—	—	152.0	0.24	22
LBY15	91142.2	8.40	L	27	149.2	0.02	19
LBY15	91144.2	7.75	0.23	17	—	—	—
LBY15	91144.3	7.62	0.20	16	142.9	0.30	14
CONT.	—	6.60	—	—	124.9	—	—
LGN23	92316.2	9.55	0.10	16	187.0	0.15	24
LGN23	92317.2	11.3	0.09	38	225.3	0.01	49
LGN23	92318.1	—	—	—	169.7	0.30	13
CONT.	—	8.21	—	—	150.9	—	—
LGN48	89063.2	—	—	—	159.5	0.05	24
CONT.	—	—	—	—	128.4	—	—
LGN18	92466.3	12.3	0.06	44	239.0	0.03	64
CONT.	—	8.59	—	—	146.0	—	—
LBY41	91620.4	11.4	L	40	201.0	0.12	30
LBY41	91621.1	10.2	0.05	26	197.6	L	28
LBY41	91623.1	—	—	—	194.6	0.27	26
LBY41	91623.2	9.95	0.08	22	185.4	0.19	20
LBY186	91657.1	12.0	0.03	48	204.2	0.06	32
LBY186	91659.1	12.9	L	59	208.0	0.12	34
LBY186	91659.3	10.8	L	33	202.0	0.10	30
LBY186	91659.4	10.1	0.21	25	203.0	0.12	31
LBY166	91542.5	9.32	0.09	15	198.1	0.04	28
LBY166	91544.3	14.4	L	77	257.0	L	66
LBY166	91544.4	9.25	0.14	14	186.1	0.06	20
LBY166	91544.5	10.1	0.03	24	206.3	0.08	33
CONT.	—	8.14	—	—	155.0	—	—
LGN35	89043.1	12.3	L	40	231.9	0.04	47
LGN35	89043.4	10.5	0.13	19	—	—	—
CONT.	—	8.80	—	—	157.3	—	—
LGN33	91572.1	7.45	0.02	24	127.4	0.05	20
LGN33	91572.3	7.95	0.02	32	144.4	0.02	36
LGN33	91574.2	7.00	0.26	16	130.4	0.20	23
CONT.	—	6.01	—	—	106.3	—	—
LGN18	92468.3	10.3	0.03	33	170.2	0.06	31
LGN18	92468.5	9.62	0.23	24	188.2	0.08	45
CONT.	—	7.75	—	—	130.2	—	—
LBY186	91657.1	9.30	0.20	23	161.8	0.12	28
LBY186	91659.1	10.2	0.11	36	161.5	0.15	28
LBY179	91549.1	10.2	0.02	35	164.2	0.02	30
LBY179	91549.3	10.2	0.18	36	170.1	0.15	35
LBY152	91286.1	9.95	0.16	32	171.2	0.10	35
LBY152	91287.1	8.82	0.28	17	147.7	0.27	17
LBY152	91289.2	10.6	0.04	40	173.8	0.08	37
LBY123	91427.1	9.12	0.11	21	170.6	0.07	35
CONT.	—	7.56	—	—	126.4	—	—
LBY203	92841.2	9.28	0.05	14	209.4	0.13	49
LBY180	92578.5	9.38	0.02	15	—	—	—
LBY177	92497.1	—	—	—	195.0	0.15	39
LBY144	93061.6	9.75	L	19	193.8	0.03	38
LBY111	92797.3	10.1	0.08	24	—	—	—
CONT.	—	8.16	—	—	140.5	—	—
LGN47	91174.2	9.65	0.22	20	179.3	0.26	17
LGN47	91174.3	10.3	0.17	20	—	—	—
LGN47	91174.4	9.67	0.21	12	170.8	0.21	11
CONT.	—	8.64	—	—	177.7	—	—
LGN42	92204.2	11.1	0.12	23	—	—	—
CONT.	—	9.00	—	—	—	—	—
LBY203	92841.2	—	—	—	143.4	0.20	14
LBY203	92842.4	—	—	—	165.9	L	32
LBY191	92519.1	—	—	—	200.1	0.07	59
LBY191	92519.2	10.1	0.17	25	169.4	0.15	34
LBY191	92522.1	—	—	—	151.0	0.16	20
LBY191	92523.3	—	—	—	176.1	0.26	40
LBY167	92772.1	—	—	—	190.1	0.21	51
LBY167	92773.4	9.67	0.08	20	168.5	0.02	34
LBY144	93059.3	10.1	0.03	25	202.9	0.02	61
LBY144	93061.4	—	—	—	167.1	0.12	33
LBY144	93061.5	8.72	0.21	8	181.0	L	44
LBY144	93061.6	11.1	L	37	190.3	L	51
LBY144	93062.2	—	—	—	164.4	0.19	31
LBY111	92797.3	8.95	0.25	11	160.0	0.17	27
LBY111	92798.1	9.45	0.18	17	—	—	—
CONT.	—	8.08	—	—	126.0	—	—
LGN41	92102.2	6.50	0.02	31	113.5	0.27	11
LGN41	92102.3	6.47	0.23	30	152.8	0.24	49
CONT.	—	4.98	—	—	102.3	—	—
NUE3	88975.2	4.70	0.05	17	—	—	—
NUE3	88977.2	5.20	0.12	29	93.5	0.05	27
NUE3	88977.5	—	—	—	95.2	0.03	29
LGN7	89181.1	5.07	0.19	26	—	—	—
LGN7	89183.2	4.42	0.19	10	—	—	—
LGN14	89165.3	4.98	0.12	24	84.5	0.15	15
LGN14	89167.3	5.40	0.06	34	92.1	0.03	25
LGN14	89168.1	4.47	0.20	11	—	—	—
LGN14	89168.2	4.53	0.13	12	86.0	0.15	17
LGN14	89168.5	—	—	—	86.7	0.12	18
CONT.	—	4.03	—	—	73.6	—	—
LGN4	89075.2	5.77	0.13	22	111.9	0.03	19
CONT.	—	4.75	—	—	93.9	—	—
LGN49	89079.1	—	—	—	185.7	0.23	23
LGN49	89081.3	14.6	0.02	65	265.8	0.04	76
LGN49	89081.4	10.8	0.03	23	190.3	0.03	26
LGN49	89081.6	—	—	—	174.2	0.21	16
CONT.	—	8.82	—	—	150.7	—	—
LGN34	90403.2	9.70	0.26	14	—	—	—
CONT.	—	8.47	—	—	—	—	—
LGN52	90581.4	—	—	—	148.5	0.04	26
CONT.	—	—	—	—	117.5	—	—
LBY71	93769.2	7.25	0.08	24	131.9	0.08	26
LBY71	93769.3	7.10	0.13	22	128.9	0.14	23
LBY71	93773.2	8.02	0.06	37	139.7	0.04	33
LBY68	93860.3	7.28	0.06	25	137.0	0.09	31
LBY68	93862.1	7.65	0.11	31	139.1	0.08	33
LBY68	93862.2	6.88	0.19	18	124.4	0.18	19
LBY61	94019.1	6.65	0.27	14	—	—	—
LBY61	94023.2	6.80	0.18	16	128.2	0.10	22
LBY6	94111.3	—	—	—	128.5	0.20	23
LBY52	93946.2	6.92	0.23	19	128.8	0.23	23
LBY5	93941.3	7.58	0.14	30	135.2	0.21	29
LBY44	92492.1	6.72	0.19	15	—	—	—
LBY34_H2	93855.2	8.38	0.03	43	145.2	0.01	39
LBY34_H2	93857.1	8.47	0.03	45	142.5	0.06	36
LBY34_H2	93857.2	8.30	0.02	42	152.4	0.05	45
LBY181	92479.3	7.17	0.14	23	137.1	0.02	31
LBY181	92480.5	7.10	0.10	22	123.9	0.18	18
LBY181	92482.1	7.15	0.11	22	127.9	0.08	22
LBY142	93199.1	7.28	0.06	25	136.8	0.01	31
LBY142	93203.3	8.82	0.02	51	153.2	0.02	46
LBY142	93203.4	8.40	L	44	148.9	L	42
CONT.	—	5.84	—	—	104.8	—	—
LBY41	91621.2	8.18	0.04	21	—	—	—
LBY41	91623.1	7.83	0.23	16	—	—	—
LBY41	91623.2	8.05	0.07	19	149.5	0.11	22
LBY173	91652.1	11.4	L	69	198.8	L	63
LBY173	91652.2	7.75	0.26	15	143.2	0.15	17
LBY173	91652.5	16.3	0.02	142	256.3	0.05	110
LBY173	91653.1	7.75	0.20	15	—	—	—
LBY166	91542.5	10.7	0.04	58	188.8	0.08	54
LBY166	91544.5	9.60	0.12	42	165.3	0.25	35
CONT.	—	6.75	—	—	122.3	—	—
LBY85	92064.1	8.05	0.19	10	210.5	0.18	33
LBY85	92066.2	8.40	0.27	15	183.0	0.19	16
LBY85	92066.3	9.67	0.04	32	225.5	0.05	43
LBY85	92066.5	9.62	0.02	32	213.3	0.04	35
LBY85	92068.3	8.93	0.28	22	—	—	—
LBY64	91340.4	8.02	0.22	10	178.5	0.13	13
LBY64	91342.3	8.20	0.13	12	193.4	0.01	23
LBY46	92200.3	8.35	0.09	14	—	—	—
LBY46	92201.4	8.70	0.23	19	—	—	—
LBY207	92155.1	9.40	0.06	29	189.7	0.28	20
LBY207	92158.2	9.30	0.20	27	—	—	—
LBY185	91497.2	9.53	L	30	192.1	0.25	22
LBY185	91498.2	8.00	0.27	9	—	—	—
LBY185	91499.2	11.4	0.01	56	260.1	0.05	65
LBY185	91499.3	8.85	0.07	21	190.4	0.06	21
LBY17	92215.4	9.03	0.06	23	215.6	0.07	37
LBY17	92216.2	11.8	0.04	61	241.7	L	53
LBY155	92015.1	10.1	L	38	227.4	0.04	44
LBY155	92016.4	9.48	0.25	30	—	—	—
LBY155	92016.5	8.25	0.24	13	177.9	0.13	13
LBY122	91370.2	11.0	0.05	51	257.8	L	63
LBY122	91371.3	—	—	—	192.8	0.14	22
LBY122	91371.6	11.2	0.02	54	243.3	0.05	54
LBY122	91374.1	8.57	0.15	17	194.1	0.18	23
CONT.	—	7.31	—	—	157.8	—	—
LBY50	91319.2	—	—	—	178.2	0.12	17
LBY24	91220.6	10.2	0.21	12	175.8	0.24	16
LBY24	91221.2	11.3	0.05	24	183.2	0.28	21
LBY21	90978.4	—	—	—	172.7	0.09	14
LBY21	90980.1	11.2	0.08	23	—	—	—
LBY152	91286.1	9.97	0.16	9	186.0	0.03	23
LBY152	91289.4	—	—	—	166.7	0.25	10
LBY123	91428.2	10.8	0.03	18	184.8	0.02	22
LBY123	91429.2	10.1	0.25	11	—	—	—
LBY123	91429.3	10.5	0.07	15	195.1	L	29
LBY114	91393.1	12.1	0.16	32	214.1	0.06	41
LBY114	91393.2	13.2	0.04	45	199.1	0.02	31
CONT.	—	9.11	—	—	151.7	—	—
LGN24	89096.3	7.80	0.13	25	—	—	—
CONT.	—	6.24	—	—	—	—	—
LGN23	92316.2	10.4	L	37	208.5	0.08	21
LGN23	92317.2	8.93	0.02	17	—	—	—
CONT.	—	7.60	—	—	172.5	—	—
LBY93	92656.1	—	—	—	200.3	0.28	14
LBY93	92657.3	—	—	—	227.9	0.24	29
LBY76	92642.1	12.6	L	40	233.2	0.01	32
LBY76	92642.2	11.3	0.20	25	—	—	—
LBY76	92642.3	12.7	L	40	234.7	0.01	33
LBY76	92642.4	10.3	0.25	14	241.8	0.30	37
LBY70	92684.2	13.5	L	49	290.3	0.05	65
LBY70	92685.5	11.1	0.08	23	217.6	0.11	23
LBY70	92686.2	12.4	L	38	237.9	0.22	35
LBY227	92851.1	11.1	0.17	23	223.8	0.26	27
LBY227	92852.3	10.6	0.24	18	240.6	0.03	36
LBY227	92853.1	13.6	L	44	—	—	—
LBY183	92516.2	11.0	0.11	21	—	—	—
LBY180	92578.5	—	—	—	200.7	0.24	14
LBY159	92150.4	10.6	0.07	17	226.2	0.16	28
LBY159	92152.1	10.3	0.21	14	—	—	—
LBY159	92152.2	13.6	L	50	271.5	0.03	54
LBY159	92152.3	10.9	0.14	21	—	—	—
LBY159	92153.1	10.7	0.21	18	—	—	—
LBY156	92294.1	13.6	L	50	233.4	0.10	32
LBY156	92294.2	10.7	0.05	18	—	—	—
LBY156	92294.3	12.7	0.07	41	239.4	0.16	36
LBY156	92298.1	11.3	0.23	25	—	—	—
LBY156	92298.2	11.8	0.23	30	—	—	—
LBY145	92604.1	—	—	—	233.8	0.17	33
LBY145	92607.1	—	—	—	238.0	0.22	35
LBY145	92608.4	11.2	0.18	24	—	—	—
CONT.	—	9.04	—	—	176.3	—	—
LGN47	91174.3	10.1	0.06	30	163.8	0.06	23
LGN47	91174.6	9.40	L	22	—	—	—
CONT.	—	7.73	—	—	133.1	—	—
LGN1	92185.1	9.05	0.21	27	—	—	—
LGN1	92185.2	8.70	0.28	23	—	—	—
LGN1	92187.1	7.75	0.29	8	163.1	0.24	18
LGN1	92188.1	10.6	0.05	48	210.0	0.12	52
CONT.	—	7.15	—	—	138.4	—	—
LGN33	91572.1	—	—	—	156.2	0.06	32
CONT.	—	—	—	—	117.9	—	—
LGN45	91575.3	14.2	0.02	70	275.9	L	82
LGN45	91579.4	10.4	0.24	24	—	—	—
LGN45	91579.5	10.7	L	28	215.8	0.13	42
CONT.	—	8.36	—	—	151.9	—	—
LBY44	92491.2	—	—	—	152.8	0.26	18
LBY43	92680.1	8.97	0.09	13	—	—	—
LBY181	92479.3	11.7	0.01	47	172.8	0.04	34
LBY181	92480.4	9.80	0.27	23	—	—	—
LBY181	92480.5	12.6	L	58	199.9	0.02	55
LBY181	92482.1	10.6	L	33	171.7	0.05	33
LBY167	92770.4	10.7	0.02	34	180.9	0.16	40
LBY167	92772.2	10.3	0.08	29	196.0	0.02	52
LBY167	92773.1	9.53	0.12	20	163.6	0.12	26
LBY157	92799.3	10.6	0.17	33	165.5	0.16	28
LBY157	92802.2	10.1	0.21	27	—	—	—
LBY157	92802.3	9.50	0.04	19	—	—	—
LBY157	92803.1	11.7	0.01	47	177.2	0.13	37
LBY157	92803.2	11.5	0.05	45	214.5	0.21	66
CONT.	—	7.96	—	—	129.4	—	—
LBY53	92414.1	9.65	0.19	31	187.2	0.28	34
LBY53	92416.1	10.7	0.10	46	212.1	0.18	52
LBY53	92417.3	8.88	0.17	21	—	—	—
LBY31	92344.2	—	—	—	186.1	0.20	33
LBY31	92347.1	—	—	—	166.8	0.16	19
LBY208	92358.2	9.30	0.29	26	211.8	0.04	51
LBY208	92358.4	9.32	0.14	27	177.9	0.14	27
LBY207	92154.1	8.95	0.19	22	195.9	0.12	40
LBY207	92155.1	9.65	0.09	31	189.6	0.12	36
LBY207	92157.3	10.6	0.07	36	—	—	—
LBY175	92179.3	9.10	0.29	24	—	—	—
LBY175	92180.3	10.8	0.16	46	213.7	0.24	53
LBY175	92181.3	10.5	0.18	42	210.2	0.24	50
LBY175	92181.4	12.1	0.07	65	213.9	0.10	53
LBY140	92265.2	10.6	L	43	181.4	0.06	30
LBY140	92266.3	8.60	0.26	17	161.8	0.30	16
LBY116	92136.3	10.1	0.03	37	185.6	0.04	33
LBY116	92136.4	11.8	0.14	60	206.2	0.27	47
LBY116	92138.6	11.0	0.04	49	200.2	0.09	43
CONT.	—	7.36	—	—	139.9	—	—
LGN2	89029.2	11.2	0.03	46	218.5	0.13	58
LGN2	89029.5	9.70	L	27	192.2	0.10	39
LGN2	89032.2	9.07	0.28	19	—	—	—
LGN2	89032.3	8.68	0.07	14	196.9	0.14	43
LGN2	89033.1	9.83	0.09	29	166.9	0.18	21
CONT.	—	7.61	—	—	138.1	—	—
LGN57	89064.2	9.28	L	45	184.3	L	41
LGN57	89067.3	7.85	L	23	139.2	0.15	9
CONT.	—	6.39	—	—	131.1	—	—
LGN42	92204.3	8.62	0.06	17	—	—	—
CONT.	—	7.35	—	—	—	—	—
NUE102	90004.2	11.4	0.19	22	190.5	0.24	29
NUE102	90004.3	10.6	0.07	14	169.4	0.06	15
NUE102	90005.1	11.9	0.13	28	189.8	0.12	28
NUE102	90005.3	11.5	0.03	24	181.9	0.03	23
CONT.	—	9.30	—	—	147.8	—	—
LBY85	92064.1	9.97	L	27	178.8	L	26
LBY85	92066.3	8.90	0.06	13	170.1	0.15	20
LBY85	92066.5	9.28	0.12	18	177.7	0.05	25
LBY64	91342.6	9.45	0.18	20	173.7	0.10	22
LBY46	92200.3	—	—	—	247.5	0.05	74
LBY46	92201.2	10.2	0.12	29	184.8	0.01	30
LBY46	92201.4	10.4	0.08	32	197.7	0.07	39
LBY46	92202.1	8.93	0.18	13	157.7	0.22	11
LBY17	92215.4	—	—	—	205.7	0.18	45
LBY17	92216.3	10.9	L	39	218.8	0.02	54
LBY155	92015.1	9.85	0.07	25	211.3	L	49
LBY155	92016.7	10.2	0.06	29	186.8	0.02	31
LBY122	91371.2	8.72	0.15	11	172.9	0.23	22
LBY122	91371.3	—	—	—	200.1	0.08	41
LBY122	91371.4	—	—	—	170.1	0.12	20
LBY122	91371.6	—	—	—	167.7	0.21	18
LBY122	91374.1	9.72	0.23	23	190.0	0.23	33
CONT.	—	7.88	—	—	142.3	—	—
LGN60	89174.2	9.32	0.04	27	170.0	0.19	14
LGN60	89175.3	8.78	0.08	19	169.6	0.25	14
LGN60	89176.1	10.2	0.16	38	—	—	—
LGN60	89176.2	8.60	0.16	17	—	—	—
CONT.	—	7.35	—	—	148.5	—	—
LBY92	93921.2	14.2	0.03	53	239.5	L	66
LBY92	93923.3	12.4	0.21	33	197.2	0.18	37
CONT.	—	9.30	—	—	144.0	—	—

Table 265. “CONT.”—Control; “Ave.”—Average; “% Incr.”=increment; “p-val.”—p-value, L—p<0.01.

The genes presented in Table 264 showed a significant improvement as they produced larger plant biomass (plant fresh and dry weight) in T2 generation when grown under low nitrogen growth conditions, compared to control plants. The genes were cloned under the regulation of a constitutive promoter (At6669, SEQ ID NO: 10654). The evaluation of each gene was carried out by testing the performance of different number of events. Some of the genes were evaluated in more than one seedling assay. The results obtained in these second experiments were significantly positive as well.

TABLE 266
Genes showing improved plant performance at Low Nitrogen growth
conditions under regulation of At6669 promoter
	Dry Weight [mg]	Fresh Weight [mg]
Gene			P-	%			%
Name	Event #	Ave.	Val.	Incr.	Ave.	P-Val.	Incr.
LBY186	91657.1	4.45	0.11	16	—	—	—
LBY186	91659.1	4.15	0.23	8	—	—	—
LBY186	91659.3	4.42	0.02	15	75.2	0.08	17
LBY179	91549.1	4.25	0.27	10	—	—	—
LBY152	91286.1	4.50	0.01	17	—	—	—
LBY152	91288.2	4.45	0.05	16	—	—	—
LBY123	91428.2	4.15	0.16	8	—	—	—
LBY123	91429.2	4.10	0.19	6	—	—	—
LBY123	91429.3	4.20	0.15	9	—	—	—
LBY114	91391.2	4.30	0.13	12	73.7	0.16	15
CONT.	—	3.85	—	—	64.1	—	—
LBY203	92839.1	4.83	0.13	10	73.0	0.14	20
LBY203	92841.2	—	—	—	80.9	0.03	33
LBY203	92842.3	—	—	—	95.1	0.06	56
LBY180	92576.2	—	—	—	75.8	0.10	25
LBY180	92576.3	4.65	0.25	6	71.3	0.18	17
LBY180	92578.5	4.85	0.04	11	—	—	—
LBY177	92495.1	—	—	—	77.1	0.10	27
LBY177	92497.3	—	—	—	72.2	0.29	19
LBY144	93059.3	—	—	—	80.1	0.13	32
LBY144	93061.4	—	—	—	78.3	L	29
LBY144	93061.6	5.10	0.29	16	82.5	0.15	36
LBY111	92794.4	5.00	0.11	14	72.2	0.17	19
LBY111	92797.1	—	—	—	80.7	0.02	33
LBY111	92798.1	—	—	—	69.0	0.11	13
LBY111	92798.4	—	—	—	70.5	0.18	16
CONT.	—	4.39	—	—	60.9	—	—
LBY191	92523.3	4.72	0.08	7	—	—	—
LBY167	92773.4	4.62	0.26	5	—	—	—
LBY144	93059.3	4.80	0.09	8	—	—	—
CONT.	—	4.42	—	—	—	—	—
LBY78	92311.4	4.88	0.22	10	—	—	—
LBY31	92344.1	5.00	0.08	13	99.2	0.04	31
LBY31	92345.4	5.20	0.15	18	—	—	—
LBY175	92179.1	5.05	0.07	14	—	—	—
LBY175	92181.2	5.22	L	18	87.0	0.11	15
LBY175	92181.4	5.55	0.09	26	91.9	0.20	21
LBY140	92268.2	—	—	—	81.6	0.18	8
LBY116	92136.4	4.95	0.18	12	84.8	0.19	12
CONT.	—	4.41	—	—	75.7	—	—
LBY5	93939.4	5.95	0.19	35	100.7	0.17	44
LBY34_H2	93856.1	4.90	0.08	11	—	—	—
LBY27_H4	93930.1	—	—	—	93.3	0.22	34
LBY183	92516.5	5.70	0.14	29	87.6	0.03	26
LBY159	92152.3	—	—	—	83.5	0.04	20
LBY159	92153.1	4.95	0.21	12	—	—	—
LBY157	92803.1	5.58	L	26	—	—	—
LBY148	93767.2	—	—	—	81.2	0.09	16
LBY148	93768.1	4.85	0.11	10	—	—	—
CONT.	—	4.41	—	—	69.7	—	—
LBY80	92269.3	4.60	L	17	66.8	0.05	25
LBY80	92270.1	4.55	0.01	16	68.1	0.21	28
LBY80	92272.2	4.42	0.20	13	67.3	0.27	26
LBY80	92273.1	4.55	L	16	86.4	0.19	62
LBY185	91497.1	4.70	L	20	73.8	0.26	38
LBY185	91497.2	4.42	0.03	13	60.6	0.03	14
LBY185	91498.2	5.03	0.04	28	69.2	0.23	30
LBY185	91499.2	5.30	L	35	—	—	—
LBY179	91545.2	4.60	0.01	17	—	—	—
LBY179	91547.2	4.88	0.03	24	—	—	—
LBY179	91549.1	4.95	0.11	26	—	—	—
LBY173	91651.2	4.28	0.21	9	—	—	—
LBY173	91652.1	5.58	0.07	42	75.0	0.02	41
LBY173	91652.2	5.58	L	42	79.7	L	49
LBY173	91652.3	—	—	—	69.7	0.08	31
LBY173	91653.1	4.92	0.07	25	74.4	0.14	39
LBY153	92249.2	—	—	—	59.0	0.11	11
LBY153	92253.2	4.53	0.07	15	—	—	—
LBY121	92290.3	4.30	0.09	10	60.2	0.27	13
LBY121	92291.2	—	—	—	59.0	0.20	11
LBY121	92291.4	4.25	0.09	8	60.7	0.18	14
CONT.	—	3.92	—	—	53.4	—	—
LBY71	93773.2	—	—	—	69.4	0.24	12
LBY68	93862.1	—	—	—	71.4	0.12	15
LBY52	93946.2	—	—	—	77.7	L	26
LBY44	92491.2	—	—	—	71.7	0.24	16
LBY216	94080.3	—	—	—	71.2	0.03	15
LBY20	94085.1	4.58	0.08	15	75.1	0.05	21
LBY181	92479.3	—	—	—	74.3	0.10	20
LBY142	93199.1	—	—	—	72.0	0.03	16
LBY142	93203.4	4.45	0.06	12	76.5	0.11	23
CONT.	—	3.98	—	—	61.9	—	—
LBY41	91621.1	4.00	L	13	66.4	0.18	10
LBY41	91621.2	4.00	L	13	—	—	—
LBY41	91623.2	4.03	0.03	13	65.1	0.30	8
LBY173	91651.2	3.85	0.11	8	—	—	—
LBY173	91652.1	4.60	L	30	75.3	0.10	24
LBY173	91652.5	5.75	L	62	76.6	0.08	26
LBY166	91542.5	4.05	0.03	14	70.6	0.09	17
LBY166	91544.4	—	—	—	64.6	0.25	7
LBY166	91544.5	4.05	0.18	14	—	—	—
CONT.	—	3.55	—	—	60.6	—	—
LBY85	92064.1	3.95	0.28	7	—	—	—
LBY85	92066.2	4.22	0.13	15	—	—	—
LBY85	92066.3	4.72	L	29	—	—	—
LBY85	92066.5	4.75	L	29	—	—	—
LBY85	92068.3	4.33	0.16	18	—	—	—
LBY64	91340.4	4.05	0.14	10	—	—	—
LBY64	91342.3	4.40	0.02	20	101.0	0.29	21
LBY46	92200.3	4.60	0.07	25	—	—	—
LBY207	92155.1	4.58	0.01	24	—	—	—
LBY207	92157.3	4.25	0.07	16	—	—	—
LBY207	92158.2	4.65	0.05	27	109.4	0.30	31
LBY185	91497.1	4.25	0.14	16	—	—	—
LBY185	91497.2	4.42	0.01	20	—	—	—
LBY185	91498.2	4.42	0.02	20	—	—	—
LBY185	91499.2	4.85	0.17	32	—	—	—
LBY17	92216.2	4.38	0.09	19	—	—	—
LBY155	92015.1	4.38	0.05	19	—	—	—
LBY155	92016.4	4.33	0.02	18	—	—	—
LBY122	91370.2	4.75	0.01	29	—	—	—
LBY122	91371.3	4.20	0.20	14	—	—	—
LBY122	91371.6	4.75	L	29	—	—	—
LBY122	91374.1	4.45	0.01	21	—	—	—
CONT.	—	3.67	—	—	83.3	—	—
LBY50	91317.3	—	—	—	73.0	0.15	14
LBY50	91318.1	4.83	0.18	11	75.2	0.26	17
LBY50	91318.2	4.90	0.17	13	78.7	0.05	23
LBY50	91318.4	—	—	—	75.6	0.03	18
LBY50	91319.2	5.05	0.02	16	80.6	0.13	26
LBY24	91220.6	4.72	0.06	9	81.2	0.08	27
LBY24	91221.1	4.77	0.26	10	79.2	L	23
LBY24	91221.2	5.00	0.09	15	78.0	0.07	22
LBY24	91223.2	—	—	—	86.6	0.17	35
LBY21	90977.1	—	—	—	79.2	0.12	23
LBY21	90980.1	4.80	0.19	11	73.1	0.15	14
LBY161	91292.1	—	—	—	76.1	0.02	19
LBY161	91292.5	4.92	L	14	76.2	0.02	19
LBY161	91293.3	5.33	L	23	81.4	0.02	27
LBY152	91286.1	—	—	—	74.3	0.04	16
LBY152	91287.1	4.83	0.02	11	81.2	L	27
LBY152	91288.2	—	—	—	72.3	0.11	13
LBY152	91289.2	5.33	0.06	23	73.5	0.22	15
LBY152	91289.4	4.55	0.28	5	—	—	—
LBY15	91143.1	—	—	—	76.5	0.21	19
LBY15	91144.1	4.80	0.03	11	70.2	0.27	10
LBY15	91144.2	4.58	0.24	5	88.8	L	39
LBY15	91144.3	4.92	0.08	14	—	—	—
LBY123	91429.3	5.00	0.26	15	—	—	—
LBY114	91391.2	—	—	—	77.0	0.02	20
LBY114	91393.1	4.62	0.16	7	—	—	—
CONT.	—	4.34	—	—	64.1	—	—
LBY80	92269.4	4.85	0.19	14	—	—	—
LBY53	92418.1	—	—	—	106.3	0.15	35
LBY153	92252.2	4.62	0.23	9	109.9	0.18	40
LBY149	92246.3	5.00	0.08	18	—	—	—
CONT.	—	4.24	—	—	78.5	—	—
LBY180	92576.2	—	—	—	149.2	0.30	54
LBY156	92294.3	5.33	0.17	5	—	—	—
CONT.	—	5.07	—	—	96.7	—	—
LBY20	94085.1	5.33	0.26	10	—	—	—
LBY106_H3	93918.1	5.72	0.29	18	—	—	—
CONT.	—	4.86	—	—	—	—	—
LBY53	92415.1	5.62	L	23	—	—	—
LBY31	92344.1	5.33	0.13	16	101.1	0.14	26
LBY208	92358.2	5.47	0.04	19	—	—	—
LBY207	92155.1	5.40	0.11	18	—	—	—
LBY207	92157.3	5.72	L	25	—	—	—
LBY175	92179.1	5.20	0.23	13	—	—	—
LBY175	92181.3	5.15	0.22	12	95.0	0.10	18
LBY175	92181.4	5.03	0.25	10	—	—	—
LBY140	92265.2	5.12	0.01	12	—	—	—
LBY140	92266.3	5.35	0.05	17	89.6	0.26	11
LBY116	92136.3	5.50	0.02	20	—	—	—
LBY116	92138.6	5.17	0.10	13	—	—	—
CONT.	—	4.59	—	—	80.4	—	—
LBY44	92491.2	—	—	—	62.9	0.11	15
LBY181	92482.1	4.98	0.04	8	—	—	—
LBY167	92770.4	—	—	—	68.0	0.20	24
LBY167	92773.1	5.28	L	15	67.2	0.15	22
LBY167	92773.4	4.85	0.15	5	66.4	0.09	21
LBY157	92802.2	5.10	0.16	11	70.3	0.08	28
LBY157	92802.3	5.30	0.23	15	68.7	0.13	25
LBY157	92803.1	5.03	0.21	9	72.3	L	32
LBY157	92803.2	—	—	—	63.8	0.29	16
CONT.	—	4.60	—	—	54.9	—	—
LBY41	91621.2	5.15	0.17	9	—	—
LBY41	91623.1	5.10	0.20	8	—	—	—
LBY41	91623.2	—	—	—	94.7	0.28	14
CONT.	—	4.71	—	—	83.1	—	—
LBY85	92066.3	4.30	0.12	7	—	—	—
LBY64	91342.3	4.42	0.03	10	86.1	0.04	16
LBY46	92200.3	4.38	0.22	9	—	—	—
LBY46	92201.2	4.68	L	16	—	—	—
LBY46	92201.4	4.65	0.19	16	—	—	—
LBY122	91371.2	4.75	L	18	—	—	—
LBY122	91371.6	4.42	0.30	10	—	—	—
LBY122	91374.1	—	—	—	78.2	0.25	5
CONT.	—	4.03	—	—	74.3	—	—

Table 266. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

The genes presented in Tables 267 and 268 below show a significant improvement in plant performance since they produced a larger leaf biomass (leaf area) and root biomass (root length and root coverage) (Table 267) and a higher relative growth rate of leaf area, root coverage and root length (Table 268) when grown under normal growth conditions, compared to control plants. Plants producing larger root biomass have better possibilities to absorb larger amount of nitrogen from soil. Plants producing larger leaf biomass have better ability to produce assimilates. The genes were cloned under the regulation of a constitutive promoter (At6669). The evaluation of each gene was performed by testing the performance of different number of events. Some of the genes were evaluated in more than one seedling analysis. This second experiment confirmed the significant increment in leaf and root performance. Event with p-value<0.1 was considered statistically significant.

TABLE 267
Genes showing improved plant performance at Normal growth
conditions under regulation of At6669 promoter
	Leaf Area	Roots Coverage	Roots Length
	[cm2]	[cm2]	[cm]
			P-	%		P-	%		P-	%
Gene Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY200	92754.1	0.888	L	26	11.9	0.01	22	—	—	—
LBY200	92754.3	—	—	—	11.4	0.15	17	—	—	—
LBY200	92757.1	0.871	0.04	23	12.9	0.01	31	—	—	—
LBY200	92757.2	0.819	0.03	16	12.2	L	25	—	—	—
LBY141	92564.1	0.907	0.10	28	—	—	—	—	—	—
LBY141	92565.2	0.808	0.01	14	—	—	—	—	—	—
LBY141	92566.3	0.790	0.28	12	—	—	—	—	—	—
CONT.	—	0.706	—	—	9.78	—	—	—	—	—
LGN35	89043.2	0.791	0.14	14	—	—	—	—	—	—
LGN35	89043.3	—	—	—	9.81	0.21	18	7.62	L	11
LGN35	89043.4	0.896	0.03	29	10.3	0.10	24	—	—	—
CONT.	—	0.693	—	—	8.29	—	—	6.85	—	—
LBY78	92311.4	—	—	—	13.8	0.18	18	7.88	0.04	7
LBY78	92312.2	—	—	—	—	—	—	7.77	0.25	5
LBY78	92313.1	—	—	—	—	—	—	7.79	0.14	5
LBY31	92344.1	—	—	—	—	—	—	7.58	0.29	3
LBY175	92179.1	0.968	0.29	15	—	—	—	7.84	0.04	6
LBY175	92179.3	0.949	0.19	12	—	—	—	—	—	—
LBY175	92181.2	1.01	L	19	13.3	0.16	14	7.83	0.09	6
LBY175	92181.3	—	—	—	—	—	—	7.65	0.27	4
LBY175	92181.4	—	—	—	—	—	—	7.75	0.14	5
LBY140	92265.1	—	—	—	—	—	—	7.76	0.28	5
LBY140	92265.2	0.971	0.04	15	—	—	—	7.82	0.03	6
LBY140	92266.1	—	—	—	—	—	—	7.77	0.13	5
LBY116	92136.4	0.958	0.12	13	—	—	—	—	—	—
LBY116	92138.6	1.10	L	30	—	—	—	—	—	—
CONT.	—	0.845	—	—	11.7	—	—	7.39	—	—
LGN39	89931.3	—	—	—	8.07	0.27	18	—	—	—
LGN39	89931.4	0.603	0.11	28	—	—	—	—	—	—
LGN34	90400.2	0.763	L	62	9.34	0.06	37	—	—	—
LGN34	90403.3	0.568	0.07	21	8.90	0.14	30	—	—	—
CONT.	—	0.470	—	—	6.83	—	—	—	—	—
NUE3	88975.1	—	—	—	9.37	0.18	26	—	—	—
NUE3	88975.2	—	—	—	9.73	L	31	7.65	L	14
NUE3	88977.1	0.789	0.08	25	10.1	0.06	35	7.80	L	16
NUE3	88977.2	0.700	0.19	11	9.43	L	27	7.60	0.02	13
NUE3	88977.4	—	—	—	—	—	—	7.21	0.19	7
LGN9	89186.1	0.702	0.18	11	9.11	0.16	22	—	—	—
LGN9	89186.2	—	—	—	8.81	0.05	18	7.77	L	16
LGN9	89187.2	—	—	—	9.44	L	27	7.16	0.05	7
LGN7	89181.2	—	—	—	—	—	—	7.20	0.04	7
LGN7	89183.3	—	—	—	—	—	—	7.39	0.04	10
LGN7	89183.8	0.692	0.29	10	8.84	0.29	19	7.28	0.08	9
LGN14	89167.3	—	—	—	10.3	0.06	38	7.46	0.04	11
LGN14	89168.2	0.685	0.27	9	9.24	0.01	24	7.14	0.07	6
LGN14	89168.5	—	—	—	8.73	0.22	17	—	—	—
CONT.	—	0.630	—	—	7.45	—	—	6.71	—	—
LBY68	93862.2	—	—	—	12.0	0.04	18	8.20	0.16	6
LBY52	93946.2	0.876	0.29	12	—	—	—	—	—	—
LBY52	93946.3	0.901	0.27	15	—	—	—	—	—	—
LBY34_H2	93856.1	0.940	L	20	13.3	0.05	31	8.30	0.10	8
LBY27_H4	93931.4	0.937	0.11	19	—	—	—	—	—	—
LBY183	92516.5	0.920	0.03	17	11.3	0.18	12	—	—	—
LBY159	92153.1	—	—	—	12.6	0.26	24	8.15	0.26	6
LBY157	92803.1	0.963	0.06	23	—	—	—	—	—	—
LBY148	93764.3	—	—	—	—	—	—	8.14	0.26	5
LBY148	93767.2	—	—	—	11.5	0.13	13	8.11	0.29	5
LBY148	93768.1	0.884	0.14	13	—	—	—	—	—	—
CONT.	—	0.785	—	—	10.2	—	—	7.72	—	—
LGN26	89037.2	0.849	0.29	12	—	—	—	—	—	—
LGN26	89037.3	1.04	L	37	—	—	—	—	—	—
LGN26	89037.4	1.13	L	49	—	—	—	—	—	—
CONT.	—	0.755	—	—	—	—	—	—	—	—
LGN46	89101.1	—	—	—	13.2	0.11	13	7.92	0.16	2
LGN46	89101.7	0.935	0.23	12	—	—	—	7.84	0.23	3
CONT.	—	0.833	—	—	11.7	—	—	7.73	—	—
LGN57	89064.2	0.863	0.29	21	12.0	0.03	29	7.78	0.14	9
LGN57	89065.1	0.907	0.05	27	10.6	0.23	13	—	—	—
LGN57	89067.1	0.834	0.16	17	—	—	—	—	—	—
CONT.	—	0.714	—	—	9.36	—	—	7.15	—	—
LGN36	89044.1	0.878	0.22	11	—	—	—	—	—	—
CONT.	—	0.791	—	—	—	—	—	—	—	—
LBY80	92273.1	—	—	—	—	—	—	7.81	0.18	4
LBY185	91497.2	—	—	—	—	—	—	7.74	0.22	3
LBY185	91498.2	0.956	0.09	16	—	—	—	—	—	—
LBY179	91545.2	0.929	0.07	12	12.7	0.09	14	7.97	0.02	6
LBY179	91545.4	—	—	—	—	—	—	8.11	L	8
LBY179	91549.3	—	—	—	—	—	—	8.02	0.03	7
LBY173	91652.1	0.986	0.08	19	—	—	—	7.72	0.17	3
LBY121	92290.4	0.914	0.07	10	—	—	—	—	—	—
LBY121	92291.4	0.943	0.17	14	—	—	—	—	—	—
CONT.	—	0.827	—	—	11.2	—	—	7.52	—	—
LGN54	88206.1	—	—	—	—	—	—	7.94	0.07	5
LGN54	88206.4	—	—	—	—	—	—	7.83	0.22	4
LGN54	88207.1	—	—	—	—	—	—	7.76	0.29	3
LGN54	88208.2	0.963	0.02	17	—	—	—	—	—	—
CONT.	—	0.820	—	—	—	—	—	7.53	—	—
LBY80	92269.3	—	—	—	9.36	0.01	20	7.82	0.03	9
LBY80	92270.1	0.784	0.02	25	9.40	0.04	21	7.69	0.08	7
LBY78	92311.3	0.704	0.12	12	9.96	0.08	28	7.81	0.07	9
LBY78	92311.4	0.723	L	15	10.2	0.11	31	8.09	0.04	13
LBY78	92312.2	—	—	—	9.28	0.06	19	7.99	0.07	12
LBY78	92313.5	—	—	—	9.38	L	21	7.88	0.06	10
LBY53	92414.1	0.689	6.09	10	9.14	0.04	18	7.69	0.08	7
LBY53	92418.1	0.688	0.04	10	—	—	—	7.57	0.26	6
LBY208	92356.1	0.680	0.07	8	8.62	0.11	11	—	—	—
LBY208	92357.1	0.750	0.07	20	9.20	0.05	18	—	—	—
LBY208	92358.2	0.705	L	12	8.45	0.25	9	—	—	—
LBY153	92249.2	0.779	L	24	9.51	0.09	22	—	—	—
LBY153	92252.2	—	—	—	8.82	0.12	14	7.55	0.23	5
LBY153	92253.2	0.709	0.23	13	9.77	0.02	26	7.77	0.05	8
LBY149	92246.3	—	—	—	11.3	0.14	45	7.76	0.08	8
LBY149	92247.3	0.686	0.12	9	8.68	0.21	12	7.65	0.08	7
LBY121	92290.3	0.738	0.09	18	9.44	L	22	7.93	0.02	11
LBY121	92291.4	0.709	0.02	13	—	—	—	—	—	—
LBY121	92293.2	0.710	0.05	13	—	—	—	—	—	—
CONT.	—	0.627	—	—	7.77	—	—	7.16	—	—
LGN4	89075.2	0.780	0.25	14	—	—	—	—	—	—
CONT.	—	0.682	—	—	—	—	—	—	—	—
LGN52	90578.6	—	—	—	9.04	0.26	17	—	—	—
LGN52	90581.1	—	—	—	8.96	0.29	16	7.88	0.15	5
LGN52	90581.4	—	—	—	11.0	0.13	43	—	—	—
CONT.	—	—	—	—	7.72	—	—	7.53	—	—
LGN41	92101.1	0.768	0.18	18	—	—	—	—	—	—
LGN41	92102.1	0.731	0.17	13	—	—	—	—	—	—
LGN41	92102.3	0.813	0.05	25	—	—	—	—	—	—
CONT.	—	0.649	—	—	—	—	—	—	—	—
LGN46	89101.4	—	—	—	13.2	0.04	38	8.67	0.07	10
LGN46	89101.9	0.698	0.16	17	—	—	—	—	—	—
CONT.	—	0.594	—	—	9.53	—	—	7.91	—	—
LGN45	91575.2	0.926	0.02	17	—	—	—	—	—	—
LGN45	91575.3	0.912	L	15	—	—	—	7.68	0.19	4
LGN45	91579.3	0.887	0.30	12	—	—	—	—	—	—
LGN45	91579.4	0.860	0.22	9	—	—	—	—	—	—
CONT.	—	0.791	—	—	—	—	—	7.39	—	—
LBY95	94683.4	0.894	0.27	14	—	—	—	8.26	0.09	6
LBY92	93921.2	1.09	0.01	39	20.5	L	86	—	—	—
LBY92	93923.3	0.931	0.30	19	19.6	0.06	78	8.16	0.19	5
LBY6	94111.3	—	—	—	—	—	—	8.09	0.21	4
LBY201	93925.1	—	—	—	12.4	0.06	13	—	—	—
LBY148	93765.1	—	—	—	—	—	—	8.08	0.27	4
LBY148	93767.2	—	—	—	12.4	0.28	12	8.16	0.18	5
LBY106_H3	93918.1	0.927	0.20	18	—	—	—	—	—	—
CONT.	—	0.786	—	—	11.0	—	—	7.80	—	—
LBY50	91317.3	0.872	L	49	11.1	L	39	7.74	0.03	5
LBY50	91318.2	0.766	0.17	31	—	—	—	—	—	—
LBY50	91319.2	—	—	—	9.31	0.05	16	—	—	—
LBY24	91220.6	—	—	—	10.2	0.04	21	7.79	0.01	6
LBY24	91221.2	0.758	0.11	30	—	—	—	—	—	—
LBY24	91223.1	0.680	0.25	16	—	—	—	—	—	—
LBY24	91223.3	—	—	—	—	—	—	7.62	0.04	4
LBY21	90977.1	—	—	—	9.48	0.10	18	7.76	0.04	6
LBY21	90978.4	0.661	0.14	13	8.73	0.26	9	7.54	0.24	3
LBY21	90979.2	0.645	0.11	10	—	—	—	—	—	—
LBY161	91292.1	0.653	0.21	12	—	—	—	—	—	—
LBY161	91292.5	0.722	0.03	24	9.51	0.09	19	—	—	—
LBY161	91293.3	0.789	L	35	8.87	0.21	11	—	—	—
LBY161	91294.1	0.789	0.02	35	10.6	0.08	32	7.65	0.03	4
LBY161	91294.2	0.719	L	23	9.21	0.30	15	—	—	—
LBY15	91142.2	0.729	L	25	9.57	0.10	19	7.64	0.03	4
LBY15	91143.1	—	—	—	—	—	—	7.83	0.08	7
LBY15	91144.2	0.668	0.22	14	9.73	0.18	21	7.59	0.21	3
LBY15	91144.3	0.653	0.06	12	9.28	0.12	16	—	—	—
CONT.	—	0.584	—	—	8.03	—	—	7.35	—	—
LGN23	92316.2	0.781	0.10	10	—	—	—	—	—	—
LGN23	92317.2	0.861	0.02	21	—	—	—	—	—	—
CONT.	—	0.711	—	—	—	—	—	—	—	—
LGN48	89060.1	0.919	0.06	24	—	—	—	—	—	—
LGN48	89061.2	—	—	—	—	—	—	7.38	0.25	4
CONT.	—	0.743	—	—	—	—	—	7.20	—	—
LGN18	92466.3	0.967	0.06	21	—	—	—	—	—	—
CONT.	—	0.797	—	—	—	—	—	—	—	—
LBY41	91620.4	1.06	L	36	14.1	L	31	8.13	0.29	2
LBY41	91621.1	0.947	0.05	21	—	—	—	—	—	—
LBY41	91623.2	0.982	0.07	25	—	—	—	8.09	0.28	2
LBY186	91657.1	1.01	0.11	29	13.2	0.06	23	—	—	—
LBY186	91659.1	1.19	L	52	14.9	L	38	8.22	0.09	3
LBY186	91659.3	0.996	L	27	14.4	L	34	8.22	0.08	3
LBY186	91659.4	0.967	0.11	24	—	—	—	—	—	—
LBY166	91542.5	0.890	0.09	14	—	—	—	—	—	—
LBY166	91544.3	1.17	0.03	49	14.1	0.12	32	—	—	—
LBY166	91544.5	0.896	0.07	14	—	—	—	—	—	—
CONT.	—	0.782	—	—	10.8	—	—	7.96	—	—
LGN35	89043.1	1.06	0.07	21	12.3	L	29	7.77	0.25	6
LGN35	89043.4	1.02	0.16	17	10.9	0.22	14	—	—	—
CONT.	—	0.873	—	—	9.53	—	—	7.35	—	—
LGN33	91572.1	0.691	0.04	16	8.93	0.17	21	—	—	—
LGN33	91572.3	0.709	0.04	19	—	—	—	—	—	—
LGN33	91574.2	0.697	0.12	17	—	—	—	—	—	—
LGN33	91574.4	0.671	0.12	13	—	—	—	—	—	—
CONT.	—	0.596	—	—	7.39	—	—	—	—	—
LGN18	92466.3	0.797	0.21	15	—	—	—	—	—	—
LGN18	92468.3	0.883	0.01	27	12.3	0.12	13	—	—	—
LGN18	92468.5	0.840	0.13	21	—	—	—	—	—	—
CONT.	—	0.695	—	—	10.9	—	—	—	—	—
LBY186	91657.1	0.851	0.14	17	—	—	—	—	—	—
LBY186	91659.1	0.932	0.01	28	11.8	0.04	34	—	—	—
LBY186	91659.4	0.827	0.07	14	—	—	—	—	—	—
LBY179	91549.1	0.910	L	25	10.6	0.03	20	—	—	—
LBY152	91286.1	0.866	0.16	19	—	—	—	—	—	—
LBY152	91288.2	—	—	—	—	—	—	7.85	0.06	5
LBY152	91289.2	0.861	0.07	18	10.9	0.13	24	—	—	—
LBY123	91427.1	—	—	—	10.8	0.03	23	7.85	0.24	5
LBY123	91429.3	—	—	—	11.2	0.09	26	—	—	—
CONT.	—	0.727	—	—	8.83	—	—	7.45	—	—
LBY180	92578.5	0.944	0.06	12	—	—	—	—	—	—
LBY144	93061.5	—	—	—	—	—	—	8.44	0.16	5
LBY144	93061.6	0.942	0.04	12	—	—	—	—	—	—
LBY111	92794.4	—	—	—	—	—	—	8.14	0.27	2
LBY111	92797.1	0.918	0.29	9	—	—	—	—	—	—
CONT.	—	0.842	—	—	—	—	—	8.01	—	—
LGN47	91171.4	—	—	—	12.3	0.24	12	7.91	0.26	2
LGN47	91174.3	—	—	—	12.1	0.04	11	—	—	—
LGN47	91174.4	0.948	0.25	8	12.9	0.20	18	7.81	0.03	3
CONT.	—	0.916	—	—	12.2	—	—	7.75	—	—
LGN42	92204.1	0.810	0.28	11	11.7	0.13	24	7.93	0.02	10
LGN42	92204.3	—	—	—	11.4	0.20	21	7.82	0.07	9
LGN42	92204.5	—	—	—	—	—	—	7.87	0.02	9
LGN42	92207.1	—	—	—	—	—	—	7.94	0.19	10
CONT.	—	0.732	—	—	9.44	—	—	7.20	—	—
LBY191	92519.2	0.832	0.14	21	—	—	—	—	—	—
LBY191	92523.3	—	—	—	10.9	0.28	8	—	—	—
LBY144	93059.3	0.773	0.05	13	—	—	—	—	—	—
LBY144	93061.6	0.846	L	23	—	—	—	—	—	—
LBY111	92797.1	—	—	—	—	—	—	7.73	0.22	4
LBY111	92797.3	—	—	—	—	—	—	7.83	0.12	6
LBY111	92798.1	—	—	—	11.4	0.04	13	7.97	0.06	8
CONT.	—	0.686	—	—	10.1	—	—	7.41	—	—
LGN41	92102.3	0.676	0.28	21	—	—	—	—	—	—
CONT.	—	0.559	—	—	—	—	—	—	—	—
NUE3	88975.2	0.423	0.15	13	—	—	—	—	—	—
NUE3	88977.1	—	—	—	6.65	0.10	31	—	—	—
NUE3	88977.2	0.450	0.11	21	6.91	0.04	36	6.31	0.24	8
NUE3	88977.5	0.477	0.09	28	5.86	0.12	16	—	—	—
LGN9	89186.2	0.411	0.08	10	—	—	—	6.47	0.07	11
LGN7	89181.1	0.456	0.14	22	—	—	—	6.59	0.07	13
LGN7	89183.2	0.440	0.04	18	—	—	—	—	—	—
LGN14	89165.3	0.408	0.25	9	5.87	0.27	16	—	—	—
LGN14	89167.3	0.430	0.12	15	—	—	—	—	—	—
LGN14	89168.1	0.434	0.16	16	—	—	—	—	—	—
LGN14	89168.2	0.420	0.08	13	—	—	—	—	—	—
LGN14	89168.5	0.398	0.30	7	—	—	—	—	—	—
CONT.	—	0.373	—	—	5.07	—	—	5.82	—	—
LGN1	92185.1	—	—	—	—	—	—	8.22	0.01	4
LGN1	92185.2	—	—	—	13.3	0.21	15	8.35	0.02	6
LGN1	92187.1	—	—	—	—	—	—	8.33	0.03	5
LGN1	92188.1	1.08	0.26	12	14.5	0.15	25	8.20	0.28	4
CONT.	—	0.963	—	—	11.6	—	—	7.91	—	—
LGN4	89075.2	0.594	0.02	24	9.30	0.17	20	7.28	0.20	8
CONT.	—	0.478	—	—	7.77	—	—	6.74	—	—
LGN49	89081.3	1.000	L	36	12.8	0.18	18	—	—	—
LGN49	89081.4	0.879	0.02	20	—	—	—	—	—	—
CONT.	—	0.735	—	—	10.8	—	—	—	—	—
LGN39	89930.2	—	—	—	11.0	0.04	28	7.70	0.04	13
LGN34	90403.4	—	—	—	11.2	0.23	29	—	—	—
CONT.	—	—	—	—	8.63	—	—	6.84	—	—
LGN52	90581.1	—	—	—	—	—	—	7.66	0.20	5
CONT.	—	—	—	—	—	—	—	7.27	—	—
LBY71	93769.2	0.714	0.16	17	—	—	—	—	—	—
LBY71	93769.3	0.697	0.22	14	—	—	—	—	—	—
LBY71	93773.2	0.766	0.04	25	10.5	0.02	35	7.52	0.01	6
LBY68	93860.3	0.710	0.05	16	9.31	0.12	19	7.45	0.27	5
LBY68	93862.1	0.716	0.10	17	9.81	0.04	26	7.53	0.24	7
LBY68	93862.2	0.680	0.15	11	10.6	L	35	7.36	0.26	4
LBY68	93862.4	—	—	—	9.68	0.07	24	7.97	L	13
LBY68	93862.5	—	—	—	9.38	0.09	20	—	—	—
LBY61	94019.1	0.719	0.09	18	—	—	—	—	—	—
LBY61	94019.4	0.780	0.11	27	9.76	0.10	25	—	—	—
LBY61	94023.2	0.698	0.15	14	—	—	—	—	—	—
LBY6	94108.3	—	—	—	8.80	0.24	13	—	—	—
LBY52	93944.1	—	—	—	9.38	0.06	20	7.28	0.30	3
LBY52	93944.2	—	—	—	9.81	0.04	26	7.67	0.18	9
LBY52	93946.2	0.759	0.01	24	—	—	—	—	—	—
LBY5	93939.4	—	—	—	—	—	—	7.28	0.25	3
LBY5	93940.2	—	—	—	9.42	0.07	21	7.53	0.08	7
LBY5	93941.3	0.736	0.20	20	10.1	0.05	30	7.54	0.13	7
LBY5	93941.4	—	—	—	—	—	—	7.52	0.06	6
LBY44	92491.2	—	—	—	8.70	0.29	11	—	—	—
LBY44	92492.1	0.671	0.21	10	—	—	—	—	—	—
LBY34_H2	93855.2	0.708	0.18	16	—	—	—	—	—	—
LBY34_H2	93856.1	—	—	—	9.22	0.17	18	7.40	0.18	5
LBY34_H2	93857.1	0.728	0.06	19	10.4	0.02	33	7.54	0.15	7
LBY34_H2	93857.2	0.754	0.05	23	10.6	L	35	7.52	0.02	6
LBY34_H2	93857.4	—	—	—	—	—	—	7.73	0.01	9
LBY216	94082.2	—	—	—	10.2	L	30	7.48	0.26	6
LBY20	94084.1	—	—	—	—	—	—	7.30	0.20	3
LBY20	94087.3	—	—	—	—	—	—	7.44	0.22	5
LBY181	92479.3	0.697	0.18	14	—	—	—	—	—	—
LBY181	92480.5	0.706	0.09	15	—	—	—	—	—	—
LBY181	92482.1	0.754	0.05	23	8.70	0.26	11	—	—	—
LBY142	93199.1	0.690	0.11	13	9.24	0.12	18	—	—	—
LBY142	93202.1	—	—	—	8.71	0.26	12	7.36	0.29	4
LBY142	93203.3	0.854	0.01	40	10.6	0.11	36	—	—	—
LBY142	93203.4	0.780	0.01	28	11.1	L	42	7.35	0.17	4
CONT.	—	0.612	—	—	7.81	—	—	7.06	—	—
LBY41	91621.1	0.739	0.22	17	—	—	—	7.76	0.09	5
LBY41	91621.2	0.722	0.17	14	—	—	—	—	—	—
LBY41	91623.1	0.737	0.22	16	10.3	0.13	16	7.90	L	7
LBY41	91623.2	0.747	0.10	18	9.61	0.27	8	—	—	—
LBY173	91651.2	0.713	0.23	12	—	—	—	—	—	—
LBY173	91652.1	0.985	L	55	11.3	0.02	27	—	—	—
LBY173	91652.2	0.737	0.09	16	—	—	—	—	—	—
LBY173	91652.5	1.04	0.02	64	13.8	L	55	7.83	0.13	6
LBY173	91653.1	0.699	0.26	10	—	—	—	—	—	—
LBY166	91542.5	0.979	0.02	54	—	—	—	—	—	—
LBY166	91544.5	0.865	0.06	36	9.83	0.26	10	—	—	—
CONT.	—	0.634	—	—	8.91	—	—	7.36	—	—
LBY85	92066.2	—	—	—	—	—	—	7.91	0.17	5
LBY64	91340.4	—	—	—	—	—	—	7.80	0.23	3
LBY64	91342.2	—	—	—	—	—	—	7.78	0.23	3
LBY46	92201.4	—	—	—	13.4	L	22	—	—	—
LBY207	92157.3	—	—	—	—	—	—	7.91	0.08	5
LBY207	92158.2	1.04	0.16	22	14.2	0.11	29	8.01	0.09	6
LBY185	91497.2	1.03	0.03	21	—	—	—	—	—	—
LBY185	91499.2	1.01	0.03	18	14.0	0.12	27	—	—	—
LBY17	92216.2	1.10	0.04	29	14.3	0.03	30	—	—	—
LBY17	92216.4	—	—	—	—	—	—	7.86	0.11	4
LBY155	92015.1	0.990	0.07	16	12.7	0.17	15	—	—	—
LBY122	91370.2	1.02	0.13	20	—	—	—	—	—	—
LBY122	91371.6	1.02	0.02	20	12.4	0.23	13	—	—	—
CONT.	—	0.851	—	—	11.0	—	—	7.57	—	—
LBY50	91319.2	—	—	—	14.3	0.08	19	—	—	—
LBY24	91220.6	1.03	0.07	18	13.8	0.07	15	8.04	0.28	4
LBY24	91221.2	1.11	0.15	26	—	—	—	—	—	—
LBY21	90978.4	—	—	—	13.3	0.19	12	—	—	—
LBY21	90979.1	—	—	—	13.5	0.21	13	—	—	—
LBY21	90980.1	1.02	0.16	16	13.7	0.14	14	—	—	—
LBY161	91293.3	—	—	—	13.1	0.23	10	—	—	—
LBY161	91294.1	0.975	0.15	11	14.9	0.26	25	8.16	0.18	5
LBY152	91289.4	—	—	—	13.0	0.26	9	8.06	0.25	4
LBY15	91144.1	—	—	—	13.5	0.16	13	—	—	—
LBY123	91428.2	0.944	0.17	7	—	—	—	—	—	—
LBY123	91429.2	1.06	0.08	20	—	—	—	—	—	—
LBY123	91429.3	1.000	0.13	14	13.9	0.11	16	8.03	0.28	3
LBY114	91393.1	—	—	—	13.8	0.14	15	—	—	—
LBY114	91393.2	1.15	0.02	31	13.4	0.22	12	—	—	—
CONT.	—	0.880	—	—	12.0	—	—	7.76	—	—
LGN24	89096.3	0.799	0.12	20	10.8	0.17	17	—	—	—
CONT.	—	0.668	—	—	9.18	—	—	—	—	—
LGN23	92316.2	0.966	0.02	26	11.8	0.09	14	—	—	—
LGN23	92317.2	0.857	0.07	12	—	—	—	—	—	—
CONT.	—	0.767	—	—	10.3	—	—	—	—	—
LBY93	92656.1	0.838	0.28	14	—	—	—	—	—	—
LBY93	92657.1	0.901	0.23	22	11.7	0.23	22	7.81	0.20	7
LBY76	92642.1	0.927	0.01	26	11.9	0.06	23	7.56	0.29	4
LBY76	92642.2	0.828	0.18	12	—	—	—	—	—	—
LBY76	92642.3	0.870	0.03	18	—	—	—	—	—	—
LBY76	92642.4	0.829	0.24	12	—	—	—	—	—	—
LBY70	92684.2	1.03	L	39	11.7	0.09	21	—	—	—
LBY70	92685.5	0.875	0.10	19	—	—	—	7.51	0.28	3
LBY70	92685.6	0.831	0.28	13	—	—	—	—	—	—
LBY70	92686.2	0.949	0.01	29	12.9	0.02	34	7.71	0.06	6
LBY70	92686.3	0.833	0.16	13	—	—	—	—	—	—
LBY227	92851.1	0.868	0.13	18	11.0	0.29	14	—	—	—
LBY227	92852.2	—	—	—	10.7	0.16	11	—	—	—
LBY227	92852.3	0.846	0.18	15	—	—	—	7.65	0.10	5
LBY227	92853.1	0.999	L	36	13.5	L	40	7.84	0.03	8
LBY209	92499.7	—	—	—	11.1	0.09	15	—	—	—
LBY209	92500.1	—	—	—	—	—	—	7.67	0.09	5
LBY183	92516.2	0.885	0.08	20	11.0	0.14	15	7.59	0.26	4
LBY180	92578.5	0.941	0.06	28	—	—	—	—	—	—
LBY159	92150.4	0.839	0.08	14	—	—	—	—	—	—
LBY159	92152.1	0.823	0.21	12	11.0	0.08	14	7.62	0.10	5
LBY159	92152.2	0.972	L	32	—	—	—	—	—	—
LBY159	92152.3	0.861	0.06	17	12.0	0.14	24	7.66	0.06	5
LBY159	92153.1	0.893	0.05	21	12.1	0.03	26	7.90	0.06	9
LBY156	92294.1	0.987	L	34	11.7	0.20	21	—	—	—
LBY156	92294.2	0.847	0.05	15	—	—	—	—	—	—
LBY156	92294.3	0.915	0.05	24	13.0	0.02	35	8.07	L	11
LBY156	92298.1	0.886	0.06	20	—	—	—	7.57	0.25	4
LBY156	92298.2	0.909	0.16	23	—	—	—	—	—	—
LBY145	92604.1	0.837	0.09	13	—	—	—	—	—	—
LBY145	92606.2	—	—	—	10.4	0.29	8	—	—	—
LBY145	92608.4	—	—	—	11.8	0.06	22	7.84	0.06	8
CONT.	—	0.737	—	—	9.65	—	—	7.27	—	—
LGN48	89060.1	—	—	—	—	—	—	7.71	0.26	4
LGN48	89063.2	—	—	—	—	—	—	7.83	0.14	6
CONT.	—	—	—	—	—	—	—	7.41	—	—
LGN5	88198.1	0.819	0.29	5	—	—	—	—	—	—
CONT.	—	0.812	—	—	—	—	—	—	—	—
LGN47	91174.3	0.858	0.08	18	9.30	0.19	14	7.64	0.22	3
LGN47	91174.6	0.899	L	24	9.52	0.05	17	—	—	—
CONT.	—	0.725	—	—	8.13	—	—	7.41	—	—
LGN1	92184.1	—	—	—	—	—	—	7.96	0.23	4
LGN1	92185.1	0.789	0.20	22	9.86	0.18	21	7.65	0.16	7
LGN1	92185.2	0.786	0.26	22	—	—	—	—	—	—
LGN1	92187.1	—	—	—	9.86	0.05	21	8.02	0.19	4
LGN1	92188.1	0.885	0.04	37	9.91	0.12	22	7.43	0.27	4
CONT.	—	0.646	—	—	8.15	—	—	7.68	—	—
LGN45	91575.3	1.02	L	51	11.7	0.20	24	—	—	—
LGN45	91579.3	0.748	0.19	10	—	—	—	—	—	—
LGN45	91579.5	0.821	0.06	21	11.6	L	23	7.73	0.20	5
CONT.	—	0.678	—	—	9.47	—	—	7.35	—	—
LBY44	92491.2	0.769	0.06	16	—	—	—	7.42	0.11	7
LBY44	92492.1	0.730	0.22	10	10.7	0.20	15	—	—	—
LBY43	92680.1	0.748	0.14	12	—	—	—	7.77	L	12
LBY181	92479.3	0.843	0.05	27	10.6	0.27	14	—	—	—
LBY181	92480.5	0.881	L	33	11.2	0.07	21	—	—	—
LBY181	92482.1	0.816	L	23	—	—	—	—	—	—
LBY167	92770.4	0.760	0.05	14	12.7	0.02	37	7.45	0.21	7
LBY167	92772.2	0.739	0.30	11	—	—	—	—	—	—
LBY167	92773.1	0.723	0.30	9	—	—	—	—	—	—
LBY157	92799.3	0.791	0.21	19	—	—	—	—	—	—
LBY157	92802.2	0.747	0.29	12	11.2	0.06	20	7.48	0.07	8
LBY157	92802.3	0.781	0.03	18	11.1	0.09	20	7.35	0.08	6
LBY157	92803.1	0.859	0.07	29	11.1	0.14	19	7.69	L	11
LBY157	92803.2	0.838	0.04	26	—	—	—	—	—	—
CONT.	—	0.665	—	—	9.30	—	—	6.95	—	—
LBY53	92414.1	0.750	0.29	12	11.7	0.13	20	7.96	0.15	6
LBY53	92415.1	—	—	—	12.1	0.26	23	7.91	0.16	6
LBY53	92416.1	0.807	0.25	20	—	—	—	—	—	—
LBY53	92417.3	0.777	0.24	16	—	—	—	—	—	—
LBY53	92418.1	—	—	—	—	—	—	8.03	0.04	7
LBY31	92344.2	0.772	0.22	15	—	—	—	7.85	0.25	5
LBY31	92347.2	0.818	0.05	22	11.6	0.04	18	—	—	—
LBY208	92358.4	0.870	0.10	30	11.8	0.19	20	—	—	—
LBY207	92154.1	0.788	0.12	18	12.1	0.23	23	—	—	—
LBY207	92155.1	0.806	0.13	20	12.0	0.23	23	8.12	0.02	9
LBY207	92157.3	0.862	0.02	29	13.4	0.04	37	8.16	0.02	9
LBY207	92158.2	0.757	0.22	13	12.2	0.05	25	—	—	—
LBY175	92179.3	0.776	0.27	16	—	—	—	—	—	—
LBY175	92180.3	0.807	0.17	20	—	—	—	—	—	—
LBY175	92181.3	0.855	0.20	27	13.4	0.03	37	7.93	0.25	6
LBY175	92181.4	0.904	0.02	35	11.7	0.23	20	7.82	0.25	5
LBY140	92265.2	0.884	0.02	32	13.9	L	42	—	—	—
LBY140	92265.5	—	—	—	10.8	0.25	11	7.74	0.28	4
LBY140	92266.1	0.760	0.27	13	—	—	—	—	—	—
LBY140	92268.2	—	—	—	10.9	0.19	11	7.96	0.07	7
LBY116	92136.3	0.868	0.02	29	—	—	—	—	—	—
LBY116	92136.4	0.881	0.19	31	12.5	0.19	27	—	—	—
LBY116	92138.6	0.924	0.02	38	13.7	L	40	7.92	0.10	6
CONT.	—	0.670	—	—	9.79	—	—	7.48	—	—
LGN2	89029.2	1.06	0.03	36	12.8	0.02	40	7.95	0.21	6
LGN2	89029.5	0.976	L	25	12.3	L	35	7.83	0.28	4
LGN2	89032.2	0.935	0.17	19	12.0	0.16	31	—	—	—
LGN2	89032.3	0.879	0.09	12	10.7	0.20	17	—	—	—
LGN2	89033.1	0.933	0.09	19	13.2	0.08	45	—	—	—
CONT.	—	0.784	—	—	9.14	—	—	7.49	—	—
LGN57	89064.2	0.786	L	28	9.46	L	48	7.33	L	19
LGN57	89067.3	0.665	0.18	8	—	—	—	—	—	—
CONT.	—	0.615	—	—	6.40	—	—	6.15	—	—
LGN42	92204.3	0.717	0.20	10	—	—	—	—	—	—
LGN42	92204.5	0.720	0.17	10	—	—	—	—	—	—
CONT.	—	0.652	—	—	—	—	—	—	—	—
NUE102	90004.2	1.01	0.10	17	—	—	—	—	—	—
NUE102	90005.1	0.946	6.12	9	13.2	0.29	12	—	—	—
NUE102	90005.3	0.930	0.20	7	—	—	—	—	—	—
CONT.	—	0.867	—	—	11.9	—	—	—	—	—
LBY85	92064.1	0.764	0.05	16	11.3	L	27	8.12	0.06	4
LBY85	92066.3	0.749	0.05	13	—	—	—	—	—	—
LBY85	92066.5	0.778	0.05	18	9.97	0.18	12	—	—	—
LBY64	91342.2	0.750	6.14	13	—	—	—	—	—	—
LBY64	91342.6	0.744	0.13	13	—	—	—	—	—	—
LBY46	92200.3	0.793	0.10	20	—	—	—	—	—	—
LBY46	92201.2	0.841	0.02	27	—	—	—	7.99	0.24	2
LBY46	92201.4	0.841	0.02	27	10.6	0.02	20	—	—	—
LBY17	92215.4	0.876	0.15	33	—	—	—	—	—	—
LBY17	92216.2	—	—	—	—	—	—	8.00	0.17	3
LBY17	92216.3	0.769	6.03	16	11.8	L	33	8.16	0.03	5
LBY17	92216.4	—	—	—	—	—	—	8.05	0.25	3
LBY155	92015.1	0.796	0.01	20	—	—	—	—	—	—
LBY155	92016.7	0.810	0.02	23	9.85	0.18	11	7.96	0.25	2
LBY122	91371.2	0.746	0.09	13	10.4	0.14	17	8.07	0.14	3
LBY122	91371.3	0.758	0.14	15	10.8	L	22	8.05	0.15	3
LBY122	91371.4	0.723	0.13	9	10.7	0.19	20	—	—	—
LBY122	91371.6	0.732	0.24	11	—	—	—	—	—	—
CONT.	—	0.661	—	—	8.89	—	—	7.80	—	—
LGN60	89174.2	0.928	0.03	26	—	—	—	—	—	—
LGN60	89175.3	0.868	0.09	18	—	—	—	—	—	—
LGN60	89176.1	0.933	0.08	27	11.3	0.21	20	—	—	—
LGN60	89176.2	0.824	0.21	12	11.5	0.04	22	—	—	—
CONT.	—	0.737	—	—	9.46	—	—	—	—	—
LBY92	93921.2	1.09	0.01	39	20.5	L	86	—	—	—
LBY92	93923.3	0.931	0.30	19	19.6	0.06	78	8.16	0.19	5
CONT.	—	0.786	—	—	11.0	—	—	7.80	—	—

Table 267. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”=p-value. L=p<0.01.

TABLE 268
Genes showing improved plant performance at Normal growth conditions under regulation
of At6669 promoter
	RGR Of	RGR Of Roots	RGR Of Root
	Leaf Area	Coverage	Length
			P-	%		P-	%		P-	%
Gene Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY200	92754.1	0.0926	0.03	28	1.42	0.09	24	—	—	—
LBY200	92754.3	—	—	—	1.35	0.21	18	—	—	—
LBY200	92757.1	0.0899	0.05	25	1.51	0.02	32	—	—	—
LBY200	92757.2	0.0844	0.14	17	1.45	0.05	26	—	—	—
LBY141	92564.1	0.0981	0.02	36	—	—	—	0.728	0.07	15
LBY141	92565.2	0.0836	0.14	16	—	—	—	—	—	—
CONT.	—	0.0722	—	—	1.15	—	—	0.631	—	—
LGN35	89042.4	—	—	—	—	—	—	0.705	0.12	5
LGN35	89043.1	—	—	—	—	—	—	0.712	0.23	6
LGN35	89043.2	0.0825	0.11	17	—	—	—	—	—	—
LGN35	89043.3	—	—	—	1.20	0.22	18	0.727	0.05	8
LGN35	89043.4	0.0963	0.02	37	1.27	0.09	25	0.711	0.19	6
CONT.	—	0.0703	—	—	1.01	—	—	0.672	—	—
LBY78	92311.3	—	—	—	—	—	—	0.707	0.30	11
LBY78	92311.4	—	—	—	1.66	0.13	20	0.708	0.26	11
LBY175	92179.1	0.102	0.17	17	—	—	—	—	—	—
LBY175	92181.2	0.104	0.03	20	1.58	0.23	14	—	—	—
LBY175	92181.3	—	—	—	—	—	—	0.707	0.28	11
LBY149	92245.2	0.0994	0.26	14	—	—	—	—	—	—
LBY149	92247.1	—	—	—	—	—	—	0.731	0.14	15
LBY140	92265.2	0.0996	0.12	14	—	—	—	0.713	0.26	12
LBY140	92266.1	—	—	—	—	—	—	0.770	0.04	21
LBY140	92268.2	—	—	—	—	—	—	0.729	0.13	14
LBY116	92136.3	—	—	—	—	—	—	0.721	0.17	13
LBY116	92136.4	0.0999	0.14	15	—	—	—	0.740	0.10	16
LBY116	92138.6	0.112	L	29	—	—	—	0.735	0.15	15
CONT.	—	0.0871	—	—	1.39	—	—	0.638	—	—
LGN39	89931.3	—	—	—	0.927	0.24	20	—	—	—
LGN39	89931.4	0.0566	0.23	21	—	—	—	—	—	—
LGN34	90400.2	0.0757	L	62	1.09	0.03	41	—	—	—
LGN34	90403.3	0.0580	0.13	24	1.03	0.08	34	—	—	—
CONT.	—	0.0467	—	—	0.770	—	—	—	—	—
NUE3	88975.1	—	—	—	1.12	0.09	26	—	—	—
NUE3	88975.2	—	—	—	1.16	0.02	30	0.719	0.06	13
NUE3	88977.1	0.0810	0.07	25	1.21	0.02	36	0.745	0.03	18
NUE3	88977.2	—	—	—	1.12	0.04	26	0.711	0.11	12
LGN9	89186.1	—	—	—	1.08	0.14	22	—	—	—
LGN9	89186.2	—	—	—	1.06	0.14	19	0.718	0.07	13
LGN9	89187.2	—	—	—	1.12	0.04	26	—	—	—
LGN14	89165.3	—	—	—	—	—	—	0.678	0.28	7
LGN14	89167.3	—	—	—	1.22	0.02	37	0.708	0.10	12
LGN14	89168.1	—	—	—	—	—	—	0.686	0.23	8
LGN14	89168.2	—	—	—	1.13	0.05	26	0.711	0.07	12
LGN14	89168.5	—	—	—	1.04	0.21	17	—	—	—
CONT.	—	0.0648	—	—	0.890	—	—	0.634	—	—
LBY68	93862.2	—	—	—	1.50	0.11	19	—	—	—
LBY52	93946.2	0.0951	0.23	14	—	—	—	—	—	—
LBY52	93946.3	0.0996	0.13	19	—	—	—	—	—	—
LBY34_H2	93856.1	0.104	0.03	25	1.65	0.02	31	—	—	—
LBY27_H4	93931.4	0.102	0.07	22	—	—	—	—	—	—
LBY183	92516.5	0.0998	0.09	20	—	—	—	—	—	—
LBY159	92153.1	—	—	—	1.57	0.10	24	—	—	—
LBY157	92803.1	0.104	0.04	25	—	—	—	—	—	—
LBY148	93767.2	—	—	—	1.43	0.25	13	—	—	—
LBY148	93768.1	0.0937	0.26	12	—	—	—	—	—	—
CONT.	—	0.0833	—	—	1.26	—	—	—	—	—
LGN26	89037.2	0.0893	0.19	20	—	—	—	—	—	—
LGN26	89037.3	0.112	L	49	—	—	—	—	—	—
LGN26	89037.4	0.120	L	61	—	—	—	—	—	—
CONT.	—	0.0747	—	—	—	—	—	—	—	—
LGN46	89101.1	—	—	—	1.58	0.12	13	—	—	—
LGN46	89101.7	0.0975	0.22	15	—	—	—	0.723	0.15	5
LGN46	89103.1	—	—	—	—	—	—	0.705	0.23	2
CONT.	—	0.0851	—	—	1.40	—	—	0.690	—	—
LGN57	89064.2	—	—	—	1.46	0.03	29	0.766	0.07	13
LGN57	89065.1	0.0941	0.06	31	1.29	0.22	14	—	—	—
LGN57	89067.1	0.0859	0.14	20	—	—	—	—	—	—
CONT.	—	0.0717	—	—	1.13	—	—	0.681	—	—
LGN36	89044.1	0.0904	0.25	11	—	—	—	—	—	—
LGN36	89047.2	—	—	—	—	—	—	0.770	0.14	8
CONT.	—	0.0812	—	—	—	—	—	0.716	—	—
LBY80	92273.1	—	—	—	—	—	—	0.728	0.06	6
LBY185	91497.2	—	—	—	—	—	—	0.736	0.02	7
LBY185	91498.2	0.0986	0.19	16	—	—	—	—	—	—
LBY185	91499.2	—	—	—	—	—	—	0.738	0.22	7
LBY185	91499.3	0.0959	0.26	13	—	—	—	0.735	0.24	7
LBY179	91545.2	0.0991	0.16	16	1.53	0.27	15	0.755	0.09	10
LBY179	91545.4	—	—	—	—	—	—	0.732	L	6
LBY179	91547.2	—	—	—	—	—	—	0.745	0.14	8
LBY179	91549.1	—	—	—	—	—	—	0.729	0.20	6
LBY179	91549.3	—	—	—	—	—	—	0.776	0.03	13
LBY173	91651.2	—	—	—	—	—	—	0.764	0.06	11
LBY173	91652.1	0.0999	0.16	17	—	—	—	0.777	0.02	13
LBY173	91653.1	—	—	—	—	—	—	0.740	0.25	7
LBY121	92290.4	0.0992	0.02	17	—	—	—	0.743	0.18	8
LBY121	92291.2	—	—	—	—	—	—	0.735	0.29	6
LBY121	92291.4	0.0982	0.23	15	—	—	—	—	—	—
CONT.	—	0.0852	—	—	1.34	—	—	0.690	—	—
LGN54	88206.4	—	—	—	—	—	—	0.714	L	10
LGN54	88207.1	—	—	—	—	—	—	0.730	L	12
LGN54	88208.2	0.104	0.02	17	—	—	—	0.787	L	21
CONT.	—	0.0885	—	—	—	—	—	0.650	—	—
LBY80	92269.3	—	—	—	1.13	0.06	21	—	—	—
LBY80	92270.1	0.0790	0.03	23	1.14	0.06	21	—	—	—
LBY78	92311.3	—	—	—	1.21	0.03	29	—	—	—
LBY78	92311.4	0.0738	0.11	15	1.22	0.03	30	—	—	—
LBY78	92312.2	—	—	—	1.12	0.09	20	—	—	—
LBY78	92313.1	—	—	—	—	—	—	0.763	0.26	10
LBY78	92313.5	0.0735	0.18	14	1.13	0.06	20	0.782	0.20	12
LBY53	92414.1	0.0718	0.20	12	1.10	0.10	18	—	—	—
LBY53	92415.1	—	—	—	1.07	0.28	13	—	—	—
LBY53	92418.1	0.0712	0.22	11	—	—	—	—	—	—
LBY208	92356.1	0.0706	0.27	10	—	—	—	—	—	—
LBY208	92357.1	0.0752	0.10	17	1.11	0.09	18	—	—	—
LBY208	92358.2	0.0715	0.19	11	—	—	—	—	—	—
LBY153	92249.2	0.0820	L	27	1.15	0.08	22	—	—	—
LBY153	92252.2	—	—	—	1.07	0.20	14	—	—	—
LBY153	92253.2	0.0724	0.23	12	1.18	0.02	26	0.768	0.25	10
LBY149	92246.3	—	—	—	1.38	L	47	0.766	0.30	10
LBY149	92247.3	—	—	—	1.05	0.26	12	—	—	—
LBY121	92290.3	0.0774	0.05	20	1.14	0.04	21	0.760	0.30	9
LBY121	92291.4	0.0728	0.13	13	—	—	—	—	—	—
LBY121	92293.2	0.0758	0.06	18	—	—	—	—	—	—
CONT.	—	0.0644	—	—	0.940	—	—	0.697	—	—
LGN4	89075.2	0.0827	0.21	15	—	—	—	—	—	—
CONT.	—	0.0719	—	—	—	—	—	—	—	—
LGN52	90578.6	—	—	—	1.09	0.25	18	—	—	—
LGN52	90581.1	—	—	—	—	—	—	0.772	0.08	7
LGN52	90581.4	—	—	—	1.35	0.12	46	—	—	—
CONT.	—	—	—	—	0.921	—	—	0.723	—	—
LGN41	92101.1	0.0803	0.16	22	—	—	—	—	—	—
LGN41	92102.1	0.0764	0.13	16	—	—	—	—	—	—
LGN41	92102.3	0.0841	0.05	28	—	—	—	—	—	—
CONT.	—	0.0657	—	—	—	—	—	—	—	—
LGN46	89101.4	—	—	—	1.62	0.04	40	0.861	0.09	10
LGN46	89101.9	0.0714	0.24	16	—	—	—	—	—	—
LGN46	89103.1	0.0673	0.29	9	—	—	—	—	—	—
CONT.	—	0.0616	—	—	1.16	—	—	0.781	—	—
LGN45	91575.2	0.0957	0.02	19	—	—	—	0.781	0.02	11
LGN45	91575.3	0.0925	0.02	15	—	—	—	0.738	0.24	5
LGN45	91579.3	0.0920	0.26	14	—	—	—	—	—	—
LGN45	91579.4	0.0885	0.18	10	—	—	—	—	—	—
CONT.	—	0.0806	—	—	—	—	—	0.701	—	—
LBY92	93921.2	0.115	0.01	37	2.52	L	89	0.808	0.18	7
LBY92	93923.3	0.0977	0.29	16	2.41	L	81	—	—	—
LBY201	93925.1	—	—	—	1.51	0.27	14	—	—	—
LBY20	94087.1	—	—	—	—	—	—	0.856	0.06	13
LBY106_H3	93918.1	0.0964	0.29	15	—	—	—	—	—	—
CONT.	—	0.0840	—	—	1.33	—	—	0.755	—	—
LBY50	91317.3	0.0930	L	59	1.36	L	42	0.773	0.03	13
LBY50	91318.1	—	—	—	—	—	—	0.760	0.05	12
LBY50	91318.2	0.0809	0.03	38	—	—	—	—	—	—
LBY50	91319.2	0.0660	0.28	12	1.14	0.11	19	0.744	0.09	9
LBY24	91220.6	—	—	—	1.26	0.02	30	0.781	L	15
LBY24	91221.1	—	—	—	—	—	—	0.739	0.22	8
LBY24	91221.2	0.0790	0.02	35	—	—	—	—	—	—
LBY24	91223.1	0.0691	0.19	18	1.11	0.26	15	—	—	—
LBY24	91223.3	—	—	—	—	—	—	0.720	0.25	6
LBY21	90977.1	—	—	—	1.17	0.09	21	0.776	0.02	14
LBY21	90978.4	0.0679	0.18	16	—	—	—	0.718	0.26	5
LBY21	90979.2	0.0700	0.09	19	—	—	—	—	—	—
LBY161	91292.1	0.0677	0.20	16	—	—	—	—	—	—
LBY161	91292.5	0.0733	0.05	25	1.14	0.12	19	0.731	0.22	7
LBY161	91293.3	0.0838	L	43	1.09	0.30	13	0.718	0.29	5
LBY161	91294.1	0.0841	L	43	1.30	0.02	35	0.739	0.10	8
LBY161	91294.2	0.0764	0.01	30	1.14	0.18	18	0.749	0.06	10
LBY15	91142.2	0.0781	L	33	1.18	0.07	22	0.756	0.04	11
LBY15	91143.1	0.0667	0.29	14	—	—	—	0.786	L	15
LBY15	91144.2	0.0693	0.15	18	1.20	0.08	24	0.765	0.02	12
LBY15	91144.3	0.0667	0.21	14	1.14	0.14	18	0.774	0.01	14
CONT.	—	0.0586	—	—	0.964	—	—	0.681	—	—
LGN23	92316.2	0.0822	0.17	10	—	—	—	—	—	—
LGN23	92317.2	0.0924	0.03	23	—	—	—	0.743	0.10	5
LGN23	92318.2	—	—	—	—	—	—	0.731	0.19	4
CONT.	—	0.0749	—	—	—	—	—	0.705	—	—
LGN48	89060.1	0.0997	0.05	27	—	—	—	—	—	—
CONT.	—	0.0784	—	—	—	—	—	—	—	—
LGN18	92466.3	0.101	0.05	24	—	—	—	—	—	—
LGN18	92468.3	—	—	—	—	—	—	0.729	0.14	3
CONT.	—	0.0817	—	—	—	—	—	0.706	—	—
LBY41	91620.4	0.111	L	38	1.66	0.02	32	—	—	—
LBY41	91621.1	0.0986	0.06	22	—	—	—	—	—	—
LBY41	91623.2	0.100	0.06	24	—	—	—	—	—	—
LBY186	91657.1	0.108	0.02	33	1.58	0.06	26	0.765	0.19	10
LBY186	91659.1	0.128	L	58	1.77	L	41	0.778	0.15	12
LBY186	91659.3	0.105	L	29	1.74	L	38	0.761	0.19	10
LBY186	91659.4	0.103	0.04	7	—	—	—	0.788	0.09	14
LBY166	91542.5	0.0953	0.10	18	—	—	—	—	—	—
LBY166	91544.3	0.126	L	56	1.70	0.03	36	0.792	0.10	14
LBY166	91544.4	—	—	—	—	—	—	0.761	0.19	10
LBY166	91544.5	0.0939	0.13	16	—	—	—	—	—	—
CONT.	—	0.0808	—	—	1.26	—	—	0.694	—	—
LGN35	89043.1	0.107	0.11	21	1.47	L	30	—	—	—
LGN35	89043.4	0.105	0.19	18	1.29	0.24	14	0.739	0.15	9
CONT.	—	0.0890	—	—	1.13	—	—	0.676	—	—
LGN33	91572.1	0.0715	0.06	16	1.10	0.17	21	—	—	—
LGN33	91572.3	0.0744	0.05	20	—	—	—	—	—	—
LGN33	91574.2	0.0739	0.11	20	—	—	—	—	—	—
LGN33	91574.4	0.0684	0.22	11	—	—	—	—	—	—
CONT.	—	0.0618	—	—	0.907	—	—	—	—	—
LGN18	92465.1	0.0838	0.24	15	—	—	—	—	—	—
LGN18	92466.3	0.0837	0.23	15	—	—	—	—	—	—
LGN18	92468.3	0.0928	0.01	28	1.49	0.12	14	0.792	0.11	7
LGN18	92468.5	0.0880	0.16	21	—	—	—	—	—	—
CONT.	—	0.0727	—	—	1.31	—	—	0.740	—	—
LBY186	91657.1	0.0895	0.15	19	—	—	—	0.777	0.16	8
LBY186	91659.1	0.101	0.01	35	1.44	0.02	34	0.782	0.22	9
LBY186	91659.4	0.0882	0.17	18	—	—	—	—	—	—
LBY179	91545.4	—	—	—	—	—	—	0.774	0.17	7
LBY179	91549.1	0.0979	0.02	31	1.29	0.11	20	—	—	—
LBY179	91549.3	—	—	—	—	—	—	0.783	0.12	9
LBY152	91286.1	0.0911	0.13	22	—	—	—	—	—	—
LBY152	91288.2	—	—	—	—	—	—	0.793	0.08	10
LBY152	91289.2	0.0936	0.07	25	1.33	0.08	24	—	—	—
LBY123	91427.1	—	—	—	1.32	0.07	22	0.807	0.06	12
LBY123	91429.3	—	—	—	1.37	0.06	27	—	—	—
CONT.	—	0.0749	—	—	1.08	—	—	0.720	—	—
LBY180	92576.3	0.0960	0.26	12	—	—	—	—	—	—
LBY180	92578.5	0.0972	0.14	13	—	—	—	—	—	—
LBY144	93061.6	0.0956	0.17	11	—	—	—	—	—	—
CONT.	—	0.0859	—	—	—	—	—	—	—	—
LGN47	91171.4	—	—	—	1.45	0.25	12	0.672	0.29	3
LGN47	91174.2	—	—	—	—	—	—	0.737	0.10	11
LGN47	91174.3	—	—	—	1.46	0.02	12	0.696	0.29	5
LGN47	91174.4	—	—	—	1.52	0.24	17	—	—	—
LGN47	91174.6	—	—	—	—	—	—	0.676	0.30	3
CONT.	—	—	—	—	1.44	—	—	0.665	—	—
LGN42	92204.1	—	—	—	1.41	0.14	24	0.705	0.05	8
LGN42	92204.2	—	—	—	—	—	—	0.720	0.30	10
LGN42	92204.3	—	—	—	1.38	0.21	21	0.696	0.12	6
LGN42	92204.5	—	—	—	—	—	—	0.697	0.18	6
LGN42	92207.1	—	—	—	—	—	—	0.763	0.15	16
CONT.	—	—	—	—	1.14	—	—	0.656	—	—
LBY191	92519.2	0.0858	0.14	21	—	—	—	—	—	—
LBY144	93059.3	0.0815	0.21	15	—	—	—	—	—	—
LBY144	93061.6	0.0902	0.03	27	—	—	—	—	—	—
LBY111	92798.1	—	—	—	1.38	0.23	14	0.771	0.12	9
CONT.	—	0.0710	—	—	1.21	—	—	0.707	—	—
LGN41	92102.2	—	—	—	0.989	0.28	9	—	—	—
LGN41	92102.3	0.0673	0.27	25	—	—	—	—	—	—
CONT.	—	0.0537	—	—	0.910	—	—	—	—	—
NUE3	88977.1	—	—	—	0.782	0.14	28	—	—	—
NUE3	88977.2	0.0420	0.27	18	0.834	0.05	37	—	—	—
NUE3	88977.5	0.0454	0.12	28	—	—	—	—	—	—
LGN7	89181.1	0.0442	0.18	24	—	—	—	0.662	0.04	22
LGN7	89183.2	0.0421	0.26	19	—	—	—	—	—	—
LGN14	89165.3	0.0413	0.30	16	—	—	—	0.602	0.29	11
LGN14	89167.3	0.0423	0.24	19	—	—	—	—	—	—
CONT.	—	0.0355	—	—	0.611	—	—	0.542	—	—
LGN1	92185.2	—	—	—	1.58	0.22	15	0.739	0.05	6
LGN1	92185.4	—	—	—	—	—	—	0.762	0.07	9
LGN1	92188.1	0.114	0.20	13	1.73	0.15	26	—	—	—
CONT.	—	0.101	—	—	1.37	—	—	0.701	—	—
LGN4	89075.2	0.0579	0.01	25	1.11	0.08	22	0.628	0.25	9
CONT.	—	0.0462	—	—	0.909	—	—	0.577	—	—
LGN49	89081.3	0.104	L	37	1.56	0.18	19	—	—	—
LGN49	89081.4	0.0913	0.04	20	—	—	—	—	—	—
CONT.	—	0.0760	—	—	1.31	—	—	—	—	—
LGN39	89930.2	—	—	—	1.29	0.04	31	0.656	0.13	20
LGN34	90403.4	—	—	—	1.30	0.10	32	—	—	—
CONT.	—	—	—	—	0.982	—	—	0.549	—	—
LGN52	90578.6	—	—	—	—	—	—	0.697	0.14	7
LGN52	90581.1	—	—	—	—	—	—	0.712	0.09	9
CONT.	—	—	—	—	—	—	—	0.650	—	—
LBY71	93769.2	0.0828	0.19	20	—	—	—	—	—	—
LBY71	93769.3	0.0798	0.29	16	—	—	—	—	—	—
LBY71	93773.2	0.0874	0.07	27	1.37	0.04	35	—	—	—
LBY68	93860.3	0.0809	0.21	17	1.21	0.22	20	—	—	—
LBY68	93862.1	0.0814	0.23	18	1.27	0.12	26	—	—	—
LBY68	93862.2	0.0791	0.29	15	1.39	0.03	37	—	—	—
LBY68	93862.4	—	—	—	1.24	0.15	23	0.777	0.18	10
LBY68	93862.5	—	—	—	1.23	0.19	21	—	—	—
LBY61	94019.1	0.0814	0.21	18	—	—	—	—	—	—
LBY61	94019.4	0.0891	0.10	29	1.26	0.14	25	—	—	—
LBY6	94108.3	—	—	—	1.18	0.30	16	—	—	—
LBY52	93944.1	—	—	—	1.25	0.13	23	—	—	—
LBY52	93944.2	—	—	—	1.29	0.09	28	0.771	0.26	10
LBY52	93946.2	0.0851	0.10	24	—	—	—	—	—	—
LBY5	93940.1	—	—	—	—	—	—	0.783	0.10	11
LBY5	93940.2	—	—	—	1.24	0.15	22	—	—	—
LBY5	93941.3	0.0827	0.23	20	1.35	0.05	33	0.761	0.25	8
LBY5	93941.4	—	—	—	—	—	—	0.761	0.27	8
LBY34_H2	93855.2	0.0807	0.27	17	—	—	—	—	—	—
LBY34_H2	93856.1	—	—	—	1.21	0.24	19	—	—	—
LBY34_H2	93857.1	0.0837	0.14	22	1.38	0.04	36	0.795	0.09	13
LBY34_H2	93857.2	0.0848	0.13	23	1.40	0.02	39	—	—	—
LBY34_H2	93857.4	—	—	—	—	—	—	0.780	0.11	11
LBY216	94082.2	—	—	—	1.34	0.04	32	—	—	—
LBY20	94087.3	—	—	—	—	—	—	0.803	0.05	14
LBY181	92480.5	0.0817	0.19	19	—	—	—	0.772	0.22	10
LBY181	92482.1	0.0850	0.12	23	—	—	—	—	—	—
LBY142	93199.1	0.0792	0.26	15	1.22	0.17	21	—	—	—
LBY142	93203.3	0.0999	L	45	1.43	0.04	42	0.760	0.29	8
LBY142	93203.4	0.0865	0.09	26	1.47	L	45	—	—	—
CONT.	—	0.0689	—	—	1.01	—	—	0.704	—	—
LBY41	91621.1	0.0768	0.14	18	—	—	—	—	—	—
LBY41	91621.2	0.0756	0.16	16	—	—	—	—	—	—
LBY41	91623.1	0.0762	0.16	17	1.26	0.25	16	—	—	—
LBY41	91623.2	0.0788	0.07	21	—	—	—	—	—	—
LBY173	91651.2	0.0737	0.23	13	—	—	—	—	—	—
LBY173	91652.1	0.102	L	56	1.39	0.06	28	—	—	—
LBY173	91652.2	0.0779	0.09	19	—	—	—	—	—	—
LBY173	91652.5	0.109	L	66	1.70	L	56	0.867	0.02	17
LBY173	91653.1	0.0745	0.20	14	—	—	—	—	—	—
LBY166	91542.5	0.104	L	60	—	—	—	—	—	—
LBY166	91544.5	0.0933	L	43	—	—	—	—	—	—
CONT.	—	0.0653	—	—	1.09	—	—	0.741	—	—
LBY85	92068.3	0.0968	0.30	12	—	—	—	—	—	—
LBY64	91340.4	—	—	—	—	—	—	0.742	0.30	7
LBY64	91342.2	—	—	—	—	—	—	0.762	0.12	10
LBY46	92201.4	—	—	—	1.62	0.04	23	—	—	—
LBY207	92155.1	0.0991	0.24	14	—	—	—	—	—	—
LBY207	92157.3	—	—	—	—	—	—	0.752	0.22	8
LBY207	92158.2	0.107	0.08	24	1.73	0.03	31	—	—	—
LBY185	91497.2	0.104	0.07	20	—	—	—	0.753	0.23	9
LBY185	91498.2	—	—	—	—	—	—	0.762	0.12	10
LBY185	91499.2	0.103	0.08	19	1.71	0.02	30	—	—	—
LBY17	92216.2	0.114	0.01	32	1.72	0.01	30	—	—	—
LBY155	92015.1	0.101	0.14	16	1.52	0.15	16	—	—	—
LBY122	91370.2	0.103	0.12	19	—	—	—	—	—	—
LBY122	91371.6	0.103	0.08	19	1.50	0.21	13	—	—	—
CONT.	—	0.0867	—	—	1.32	—	—	0.693	—	—
LBY50	91319.2	—	—	—	1.68	0.12	19	—	—	—
LBY24	91220.6	0.111	0.15	15	1.60	0.21	14	—	—	—
LBY24	91221.2	0.118	0.10	22	—	—	—	—	—	—
LBY21	90978.4	—	—	—	1.59	0.28	13	—	—	—
LBY21	90980.1	0.111	0.17	15	1.62	0.20	15	—	—	—
LBY161	91294.1	—	—	—	1.74	0.14	23	—	—	—
LBY15	91144.1	—	—	—	1.61	0.23	14	—	—	—
LBY123	91429.2	0.116	0.07	21	—	—	—	—	—	—
LBY123	91429.3	0.109	0.21	13	1.61	0.21	14	—	—	—
LBY114	91393.1	—	—	—	1.66	0.16	18	0.781	0.12	14
LBY114	91393.2	0.124	0.01	29	1.60	0.26	13	0.772	0.20	12
CONT.	—	0.0962	—	—	1.41	—	—	0.688	—	—
LGN24	89096.1	—	—	—	—	—	—	0.701	0.05	4
LGN24	89096.3	0.0816	0.27	15	1.30	0.16	18	—	—	—
CONT.	—	0.0708	—	—	1.10	—	—	0.674	—	—
LGN23	92316.2	0.101	0.02	28	1.43	0.08	15	0.679	0.04	9
LGN23	92317.2	0.0892	0.06	13	—	—	—	0.676	0.03	9
CONT.	—	0.0788	—	—	1.25	—	—	0.623	—	—
LBY93	92657.1	0.0909	0.29	18	1.41	0.18	21	—	—	—
LBY93	92657.4	—	—	—	1.36	0.30	16	—	—	—
LBY76	92642.1	0.0983	0.06	27	1.45	0.10	24	—	—	—
LBY76	92642.2	0.0890	0.27	15	—	—	—	—	—	—
LBY76	92642.3	0.0970	0.07	25	—	—	—	0.750	0.18	7
LBY70	92684.2	0.110	L	43	1.43	0.12	22	—	—	—
LBY70	92685.5	0.0893	0.26	16	—	—	—	—	—	—
LBY70	92686.2	0.0991	0.07	28	1.57	0.04	34	0.749	0.22	7
LBY227	92851.1	0.0892	0.29	15	—	—	—	—	—	—
LBY227	92852.3	0.0893	0.28	15	—	—	—	—	—	—
LBY227	92853.1	0.106	0.01	37	1.65	L	41	0.789	0.03	13
LBY209	92499.7	—	—	—	1.36	0.25	16	—	—	—
LBY183	92516.2	0.0929	0.16	20	1.33	0.29	14	—	—	—
LBY183	92516.4	—	—	—	1.40	0.20	20	0.762	0.18	9
LBY183	92516.5	—	—	—	—	—	—	0.744	0.28	6
LBY180	92578.5	0.101	0.07	30	—	—	—	—	—	—
LBY159	92150.4	0.0891	0.25	15	—	—	—	0.769	0.08	10
LBY159	92152.1	—	—	—	1.34	0.26	15	—	—	—
LBY159	92152.2	0.104	0.02	35	—	—	—	—	—	—
LBY159	92152.3	0.0897	0.23	16	1.46	0.11	24	0.755	0.13	8
LBY159	92153.1	0.0947	0.12	22	1.45	0.10	24	—	—	—
LBY156	92294.1	0.103	0.02	33	1.43	0.15	22	0.782	0.05	12
LBY156	92294.2	0.0880	0.30	14	—	—	—	—	—	—
LBY156	92294.3	0.0960	0.10	24	1.58	0.01	35	—	—	—
LBY156	92298.1	0.0901	0.23	17	—	—	—	—	—	—
LBY156	92298.2	0.0942	0.17	22	—	—	—	—	—	—
LBY145	92608.4	—	—	—	1.44	0.08	23	0.760	0.15	9
CONT.	—	0.0773	—	—	1.17	—	—	0.700	—	—
LGN48	89060.1	—	—	—	—	—	—	0.724	0.06	7
LGN48	89063.1	—	—	—	—	—	—	0.707	0.19	5
CONT.	—	—	—	—	—	—	—	0.674	—	—
LGN5	88198.1	0.0832	0.23	5	—	—	—	—	—	—
LGN5	88201.1	—	—	—	—	—	—	0.698	0.02	6
LGN5	88201.3	—	—	—	—	—	—	0.697	0.10	6
CONT.	—	0.0824	—	—	—	—	—	0.708	—	—
LGN47	91174.3	0.0897	0.08	21	1.14	0.17	16	0.784	0.02	7
LGN47	91174.6	0.0925	0.01	25	1.16	0.04	18	—	—	—
CONT.	—	0.0741	—	—	0.980	—	—	0.731	—	—
LGN1	92184.1	—	—	—	—	—	—	0.757	0.08	3
LGN1	92185.1	0.0802	0.23	22	1.21	0.17	22	0.768	0.14	10
LGN1	92185.2	0.0800	0.27	22	—	—	—	—	—	—
LGN1	92187.1	—	—	—	1.20	0.05	21	0.740	0.02	6
LGN1	92188.1	0.0924	0.03	41	1.22	0.10	23	0.723	0.22	3
CONT.	—	0.0655	—	—	0.990	—	—	0.732	—	—
LGN33	91574.4	—	—	—	—	—	—	0.751	0.25	5
CONT.	—	—	—	—	—	—	—	0.717	—	—
LGN45	91575.3	0.108	L	57	1.43	0.20	25	0.762	0.09	14
LGN45	91579.3	0.0760	0.23	10	—	—	—	—	—	—
LGN45	91579.5	0.0864	0.05	25	1.40	L	22	0.704	0.13	5
CONT.	—	0.0689	—	—	1.14	—	—	0.669	—	—
LBY44	92491.2	0.0825	0.24	14	—	—	—	0.734	0.07	12
LBY43	92680.1	—	—	—	—	—	—	0.750	0.03	14
LBY181	92479.3	0.0922	0.05	27	—	—	—	0.714	0.30	9
LBY181	92480.5	0.0969	0.01	33	1.38	0.16	23	0.726	0.11	10
LBY181	92482.1	0.0891	0.06	23	—	—	—	—	—	—
LBY167	92770.4	0.0815	0.30	12	1.53	0.04	37	0.727	0.13	11
LBY157	92799.3	0.0858	0.19	18	—	—	—	—	—	—
LBY157	92802.2	—	—	—	1.36	0.18	21	0.747	0.03	14
LBY157	92802.3	0.0842	0.19	16	1.34	0.21	20	0.719	0.13	9
LBY157	92803.1	0.0922	0.05	27	1.33	0.23	19	0.750	0.03	14
LBY157	92803.2	0.0896	0.07	23	—	—	—	—	—	—
CONT.	—	0.0727	—	—	1.12	—	—	0.658	—	—
LBY53	92414.1	—	—	—	1.42	0.14	22	—	—	—
LBY53	92415.1	—	—	—	1.46	0.14	25	—	—	—
LBY53	92416.1	0.0838	0.18	25	—	—	—	0.756	0.21	10
LBY53	92417.3	0.0805	0.25	20	—	—	—	—	—	—
LBY31	92344.2	0.0799	0.26	19	—	—	—	—	—	—
LBY31	92347.2	0.0845	0.12	26	1.41	0.16	21	—	—	—
LBY208	92358.1	—	—	—	1.39	0.25	19	—	—	—
LBY208	92358.4	0.0910	0.06	36	1.43	0.16	22	—	—	—
LBY207	92154.1	0.0813	0.21	21	1.46	0.14	25	0.754	0.21	10
LBY207	92155.1	0.0823	0.19	23	1.45	0.14	24	—	—	—
LBY207	92157.3	0.0873	0.07	30	1.63	0.01	39	0.759	0.18	11
LBY207	92158.2	—	—	—	1.49	0.07	27	—	—	—
LBY175	92179.1	0.0826	0.24	23	—	—	—	—	—	—
LBY175	92180.3	0.0865	0.11	29	—	—	—	—	—	—
LBY175	92181.3	0.0859	0.17	28	1.61	0.02	38	—	—	—
LBY175	92181.4	0.0912	0.05	36	1.41	0.17	21	—	—	—
LBY140	92265.2	0.0925	0.03	38	1.68	L	44	—	—	—
LBY140	92266.1	0.0796	0.28	19	—	—	—	0.748	0.21	9
LBY140	92268.2	—	—	—	—	—	—	0.753	0.16	10
LBY116	92136.3	0.0900	0.05	35	—	—	—	—	—	—
LBY116	92136.4	0.0911	0.09	36	1.53	0.08	31	0.740	0.27	8
LBY116	92138.6	0.0961	0.02	44	1.66	L	43	0.753	0.22	10
CONT.	—	0.0669	—	—	1.17	—	—	0.685	—	—
LGN2	89029.2	0.110	0.03	36	1.50	0.03	40	—	—	—
LGN2	89029.5	0.104	L	30	1.44	0.01	35	—	—	—
LGN2	89032.2	0.0994	0.11	24	1.40	0.19	31	—	—	—
LGN2	89032.3	0.0909	0.11	13	1.29	0.14	21	0.727	0.09	9
LGN2	89033.1	0.0965	0.10	20	1.55	0.09	45	—	—	—
CONT.	—	0.0804	—	—	1.07	—	—	0.667	—	—
LGN57	89064.2	0.0798	L	28	1.16	L	49	0.769	L	23
LGN57	89067.3	0.0701	0.10	13	—	—	—	0.664	0.07	6
CONT.	—	0.0622	—	—	0.782	—	—	0.625	—	—
NUE102	90004.1	—	—	—	—	—	—	0.712	0.04	7
NUE102	90004.2	0.109	0.11	17	—	—	—	0.711	0.02	7
NUE102	90005.1	0.101	0.13	9	1.61	0.17	17	0.781	L	17
NUE102	90005.3	0.100	0.17	8	—	—	—	0.743	L	11
CONT.	—	0.0928	—	—	1.38	—	—	0.667	—	—
LBY85	92064.1	0.0812	0.11	18	1.37	L	30	0.769	0.30	6
LBY85	92066.3	0.0784	0.23	13	—	—	—	—	—	—
LBY85	92066.5	0.0829	0.09	20	1.20	0.22	13	—	—	—
LBY64	91340.4	—	—	—	—	—	—	0.788	0.12	8
LBY64	91342.2	0.0794	0.20	15	—	—	—	—	—	—
LBY64	91342.6	0.0788	0.22	14	—	—	—	—	—	—
LBY46	92200.3	0.0825	0.12	20	—	—	—	—	—	—
LBY46	92201.2	0.0890	0.02	29	—	—	—	0.767	0.27	5
LBY46	92201.4	0.0904	0.02	31	1.28	0.06	21	—	—	—
LBY17	92214.1	—	—	—	—	—	—	0.772	0.21	6
LBY17	92215.4	0.0945	0.03	37	—	—	—	—	—	—
LBY17	92216.3	0.0831	0.08	20	1.43	L	35	0.780	0.21	6
LBY17	92216.4	—	—	—	—	—	—	0.770	0.22	6
LBY155	92015.1	0.0847	0.05	23	1.21	0.24	14	0.771	0.22	6
LBY155	92016.7	0.0868	0.03	26	1.19	0.25	12	0.771	0.20	6
LBY122	91371.2	0.0800	0.14	16	1.26	0.10	19	0.777	0.18	7
LBY122	91371.3	0.0815	0.13	18	1.32	0.03	24	0.800	0.05	10
LBY122	91371.4	—	—	—	1.29	0.10	22	0.771	0.26	6
LBY122	91371.6	0.0778	0.28	13	—	—	—	0.773	0.25	6
LBY122	91374.1	0.0800	0.26	16	—	—	—	—	—	—
CONT.	—	0.0691	—	—	1.06	—	—	0.727	—	—
LGN60	89174.2	0.0978	0.02	27	—	—	—	—	—	—
LGN60	89175.3	0.0929	0.07	20	—	—	—	—	—	—
LGN60	89176.1	0.0949	0.12	23	1.38	0.20	21	0.721	0.13	6
LGN60	89176.2	0.0875	0.18	14	1.38	0.05	21	—	—	—
CONT.	—	0.0771	—	—	1.14	—	—	0.696	—	—
LBY92	93921.2	0.115	0.01	37	2.52	L	89	0.808	0.18	7
LBY92	93923.3	0.0977	0.29	16	2.41	L	81	—	—	—
CONT.	—	0.0840	—	—	1.33	—	—	0.755	—	—

Table 268. “CONT.”—Control: “Ave.”—Average; “% Incr.”=% increment; “p-val.”=p-value, L=p<0.01.

The genes presented in Tables 269-272 below show a significant improvement in plant performance since they produced a larger leaf biomass (leaf area) and root biomass (root length and root coverage) (Tables 269 and 271) and a higher relative growth rate of leaf area, root coverage and root length (Tables 270 and 272) when grown under normal growth conditions, compared to control plants. Plants producing larger root biomass have better possibilities to absorb larger amount of nitrogen from soil. Plants producing larger leaf biomass have better ability to produce assimilates. The genes were cloned under the regulation of a constitutive promoter (At6669). The evaluation of each gene was performed by testing the performance of different number of events. Some of the genes were evaluated in more than one seedling analysis. This second experiment confirmed the significant increment in leaf and root performance. Event with p-value<0.1 was considered statistically significant.

TABLE 269
Genes showing improved plant performance at Low Nitrogen growth conditions under
regulation of At6669 promoter
	Leaf	Roots
	Area [cm2]	Coverage [cm2]	Roots Length [cm]
Gene				%		P-	%		P-	%
Name	Event #	Ave.	P-Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN35	89043.1	0.394	L	16	—	—	—	7.47	0.07	8
LGN35	89043.3	—	—	—	—	—	—	7.70	L	12
LGN35	89043.4	0.370	0.06	9	15.2	L	35	7.69	L	12
CONT.	—	0.340	—	—	11.3	—	—	6.90	—	—
LGN39	89931.3	0.441	0.24	9	—	—	—	—	—	—
LGN39	89931.4	0.467	L	16	—	—	—	7.05	0.27	4
LGN34	90400.2	0.465	0.10	15	—	—	—	—	—	—
LGN34	90403.1	0.455	0.04	13	—	—	—	—	—	—
LGN34	90403.3	0.480	0.04	19	12.4	0.26	24	—	—	—
CONT.	—	0.403	—	—	10.0	—	—	6.75	—	—
NUE3	88975.1	—	—	—	12.8	0.24	16	—	—	—
NUE3	88975.2	—	—	—	14.1	L	27	8.11	L	7
NUE3	88977.1	0.431	0.26	4	14.2	L	28	7.93	L	5
NUE3	88977.2	—	—	—	13.5	0.05	22	7.91	0.10	5
NUE3	88977.4	—	—	—	—	—	—	7.92	0.05	5
LGN9	89185.2	—	—	—	12.2	0.20	11	—	—	—
LGN9	89186.1	0.441	0.17	7	12.4	0.28	12	—	—	—
LGN9	89186.2	—	—	—	12.8	0.03	16	7.98	0.02	6
LGN7	89183.3	—	—	—	—	—	—	7.95	0.03	5
LGN7	89183.8	—	—	—	11.8	0.27	6	—	—	—
LGN14	89165.3	—	—	—	14.3	0.03	29	—	—	—
LGN14	89167.3	—	—	—	14.1	0.01	27	7.71	0.28	2
LGN14	89168.1	—	—	—	12.1	0.24	9	—	—	—
LGN14	89168.2	—	—	—	15.4	L	39	7.93	0.01	5
LGN14	89168.5	—	—	—	13.9	0.08	25	7.92	0.17	5
CONT.	—	0.412	—	—	11.1	—	—	7.56	—	—
LGN26	89037.2	0.415	0.23	9	—	—	—	—	—	—
CONT.	—	0.380	—	—	—	—	—	—	—	—
LGN46	89101.1	0.441	L	14	17.1	0.01	21	8.33	0.02	4
LGN46	89101.7	0.433	0.06	12	16.8	L	19	8.12	0.07	4
CONT.	—	0.428	—	—	16.4	—	—	8.03	—	—
LGN57	89064.2	0.435	L	25	19.6	L	49	8.35	0.01	6
LGN57	89065.1	0.401	0.09	15	18.2	0.11	38	—	—	—
LGN57	89067.1	0.433	L	25	18.6	L	41	8.29	0.06	5
LGN57	89067.2	—	—	—	17.1	L	30	8.09	0.13	2
LGN57	89067.3	0.375	0.15	8	—	—	—	—	—	—
CONT.	—	0.348	—	—	13.2	—	—	7.90	—	—
LGN36	89045.2	0.389	0.18	7	—	—	—	8.11	0.12	6
LGN36	89047.1	—	—	—	14.6	0.27	12	8.03	0.04	5
LGN36	89047.2	—	—	—	—	—	—	7.83	0.24	3
CONT.	—	0.364	—	—	13.0	—	—	7.62	—	—
LGN54	88206.4	0.461	0.07	6	—	—	—	—	—	—
LGN54	88207.1	—	—	—	—	—	—	8.21	0.12	2
CONT.	—	0.437	—	—	—	—	—	8.05	—	—
LGN4	89074.3	—	—	—	16.4	L	33	8.14	0.04	9
LGN4	89075.2	—	—	—	14.6	0.23	18	8.02	0.15	8
CONT.	—	—	—	—	12.3	—	—	7.45	—	—
LGN52	90578.6	—	—	—	—	—	—	7.96	0.27	4
LGN52	90581.1	0.398	0.29	5	15.4	0.03	22	7.89	0.05	8
LGN52	90581.4	—	—	—	14.3	0.09	14	—	—	—
CONT.	—	0.383	—	—	12.6	—	—	7.66	—	—
LGN41	92102.1	—	—	—	16.6	0.03	27	8.29	L	12
CONT.	—	—	—	—	13.1	—	—	7.39	—	—
LGN46	89101.1	—	—	—	—	—	—	8.27	0.27	2
LGN46	89101.4	0.382	0.27	3	—	—	—	—	—	—
LGN46	89101.9	0.434	0.02	18	18.8	0.18	34	—	—	—
CONT.	—	0.369	—	—	14.0	—	—	8.07	—	—
LGN45	91575.2	—	—	—	17.1	0.01	35	7.97	0.25	7
LGN45	91579.3	—	—	—	14.6	0.09	15	8.00	0.13	7
LGN45	91579.5	—	—	—	13.9	0.24	10	—	—	—
CONT.	—	—	—	—	12.7	—	—	7.47	—	—
LGN23	92318.2	—	—	—	—	—	—	7.92	0.08	4
CONT.	—	—	—	—	—	—	—	7.64	—	—
LGN48	89060.1	0.386	0.28	5	—	—	—	—	—	—
LGN48	89063.2	0.423	0.25	8	—	—	—	—	—	—
CONT.	—	0.391	—	—	—	—	—	—	—	—
LGN35	89043.3	0.437	0.17	9	—	—	—	—	—	—
LGN35	89043.4	—	—	—	—	—	—	8.46	0.20	3
CONT.	—	0.400	—	—	—	—	—	8.19	—	—
LGN33	91570.4	0.412	0.13	9	14.8	0.20	9	—	—	—
LGN33	91572.1	—	—	—	17.9	0.02	32	—	—	—
LGN33	91572.3	—	—	—	16.5	L	21	—	—	—
CONT.	—	0.378	—	—	13.6	—	—	—	—	—
LGN18	92468.3	0.390	0.16	12	14.9	0.05	34	8.08	0.02	12
CONT.	—	0.347	—	—	11.1	—	—	7.24	—	—
LGN47	91174.4	0.455	0.16	6	—	—	—	—	—	—
LGN47	91174.6	0.465	0.19	5	16.4	0.24	5	—	—	—
CONT.	—	0.443	—	—	15.5	—	—	—	—	—
LGN42	92204.1	0.396	0.03	10	13.7	0.10	21	7.76	0.06	7
LGN42	92204.3	0.388	0.10	8	12.8	0.27	12	7.52	0.27	4
LGN42	92204.5	—	—	—	14.5	0.18	28	7.86	0.09	8
LGN42	92207.1	0.427	0.07	19	18.2	0.02	60	8.28	L	14
CONT.	—	0.359	—	—	11.4	—	—	7.26	—	—
NUE3	88975.2	—	—	—	8.82	0.24	16	6.31	0.03	10
NUE3	88977.1	—	—	—	8.77	0.30	15	—	—	—
NUE3	88977.2	—	—	—	9.81	0.02	28	6.48	0.11	13
NUE3	88977.5	0.451	0.01	26	9.35	0.16	22	6.46	0.09	13
LGN9	89186.1	0.405	0.03	13	—	—	—	—	—	—
LGN7	89183.2	0.372	0.27	4	—	—	—	6.01	0.30	5
CONT.	—	0.358	—	—	7.64	—	—	5.73	—	—
LGN1	92185.1	0.421	0.23	4	—	—	—	—	—	—
LGN1	92185.2	—	—	—	—	—	—	8.56	0.08	3
LGN1	92187.1	—	—	—	—	—	—	8.52	0.09	2
LGN1	92188.1	0.437	0.05	8	—	—	—	—	—	—
CONT.	—	0.420	—	—	—	—	—	8.48	—	—
LGN49	89079.1	0.431	0.25	3	17.3	L	21	8.16	0.17	3
LGN49	89079.3	—	—	—	15.6	0.20	9	—	—	—
LGN49	89081.3	0.463	0.02	10	17.9	0.11	26	8.32	0.16	5
LGN49	89081.6	0.440	0.28	5	15.1	0.26	6	—	—	—
CONT.	—	0.420	—	—	14.3	—	—	7.95	—	—
LGN4	89074.3	0.424	0.04	12	—	—	—	6.48	0.27	9
LGN4	89074.4	0.409	0.25	8	—	—	—	6.45	0.15	8
LGN4	89075.1	—	—	—	10.8	0.06	22	6.36	0.14	7
LGN4	89075.2	0.451	0.04	19	11.3	0.03	29	6.69	0.01	12
CONT.	—	0.380	—	—	8.83	—	—	5.96	—	—
LGN52	90578.6	—	—	—	—	—	—	7.99	0.17	5
LGN52	90581.1	—	—	—	14.5	0.24	13	8.16	0.04	7
LGN52	90581.4	—	—	—	15.2	0.14	19	—	—	—
CONT.	—	—	—	—	12.8	—	—	7.61	—	—
LGN23	92316.2	—	—	—	14.1	0.23	11	8.00	0.18	4
LGN23	92311.2	—	—	—	—	—	—	8.00	0.13	4
CONT.	—	—	—	—	12.7	—	—	7.71	—	—
LGN24	89094.2	0.394	0.25	5	—	—	—	—	—	—
LGN24	89096.1	—	—	—	—	—	—	8.14	0.24	3
LGN24	89096.3	—	—	—	14.3	0.07	11	—	—	—
CONT.	—	0.374	—	—	12.9	—	—	7.88	—	—
LGN5	88198.1	0.466	0.09	8	—	—	—	—	—	—
LGN5	88198.4	0.495	0.03	15	—	—	—	—	—	—
LGN5	88201.1	0.454	0.25	6	18.3	0.06	8	8.54	0.07	3
LGN5	88201.3	0.497	0.01	15	—	—	—	8.39	0.15	2
LGN5	88203.2	0.479	0.01	11	19.5	0.09	15	8.43	0.11	2
CONT.	—	0.431	—	—	16.9	—	—	8.26	—	—
LGN48	89063.2	0.440	0.13	10	—	—	—	8.38	L	8
CONT.	—	0.402	—	—	—	—	—	7.79	—	—
LGN47	91174.3	—	—	—	17.4	0.11	18	8.27	0.17	4
LGN47	91174.4	0.451	0.06	8	16.2	0.22	10	8.31	0.05	4
LGN47	91174.6	0.429	0.22	5	16.9	0.05	15	8.17	0.19	2
CONT.	—	0.417	—	—	14.7	—	—	7.98	—	—
LGN1	92184.1	0.429	0.01	12	14.5	0.17	21	8.30	0.04	6
LGN1	92185.1	0.414	0.22	8	15.2	L	27	8.17	0.07	5
LGN1	92185.2	0.439	0.12	14	14.4	0.23	21	7.96	0.22	3
LGN1	92187.1	0.419	0.04	9	14.4	0.04	20	8.37	L	7
LGN1	92188.1	0.461	0.02	20	14.0	0.20	17	8.10	0.11	4
CONT.	—	0.385	—	—	12.0	—	—	7.80	—	—
LGN2	89029.5	0.460	0.18	7	17.1	0.07	8	—	—	—
LGN2	89032.2	—	—	—	18.6	L	18	—	—	—
LGN2	89033.1	—	—	—	19.0	0.07	20	—	—	—
CONT.	—	0.430	—	—	15.8	—	—	—	—	—
LGN45	91575.2	0.375	0.18	11	15.3	0.08	50	8.03	L	14
LGN45	91575.3	0.405	L	19	13.9	0.12	36	7.50	0.19	7
LGN45	91579.3	0.369	0.19	9	—	—	—	7.64	0.08	9
LGN45	91579.4	—	—	—	13.0	0.10	28	7.53	0.09	7
LGN45	91579.5	0.377	0.14	11	12.1	0.09	19	7.68	0.07	9
CONT.	—	0.339	—	—	10.2	—	—	7.03	—	—
LGN33	91570.4	—	—	—	—	—	—	8.08	0.20	3
CONT.	—	—	—	—	—	—	—	7.84	—	—
LGN57	89064.2	0.418	0.04	17	16.8	0.01	81	7.90	L	17
LGN57	89065.1	—	—	—	12.3	L	33	—	—	—
LGN57	89066.1	0.424	0.08	18	12.8	0.05	38	7.31	0.02	8
LGN57	89067.3	0.373	0.01	4	—	—	—	—	—	—
CONT.	—	0.359	—	—	9.29	—	—	6.77	—	—
NUE102	90004.1	0.416	0.26	9	15.5	0.27	8	—	—	—
NUE102	90004.2	—	—	—	16.6	0.18	15	8.33	0.03	8
NUE102	90005.3	0.408	0.14	7	18.0	0.09	25	8.33	L	8
CONT.	—	0.382	—	—	14.4	—	—	7.74	—	—
LGN42	92204.2	—	—	—	16.5	0.03	19	8.52	0.14	4
LGN42	92204.3	—	—	—	15.8	0.28	13	—	—	—
LGN42	92204.5	—	—	—	18.1	0.02	30	8.42	0.18	2
CONT.	—	—	—	—	13.9	—	—	8.23	—	—
LGN60	89174.2	0.443	0.27	6	15.3	0.17	16	—	—	—
LGN60	89175.3	—	—	—	14.3	0.21	8	—	—	—
LGN60	89176.1	0.443	0.25	8	16.2	0.05	22	—	—	—
LGN60	89176.2	0.435	0.29	6	—	—	—	—	—	—
CONT.	—	0.417	—	—	13.2	—	—	—	—	—
LBY92	93921.2	—	—	—	36.6	L	139	8.93	L	7
LBY92	93923.3	—	—	—	35.1	L	129	8.67	0.07	4
CONT.	—	—	—	—	15.3	—	—	8.32	—	—

Table 269. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 270
Genes showing improved plant performance at Low Nitrogen growth conditions under
regulation of At6669 promoter
	RGR	RGR Of Roots	RGR Of
	Of Leaf Area	Coverage	Root Length
Gene			P-	%		P-	%		P-	%
Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LGN35	89042.4	—	—	—	—	—	—	0.775	0.22	11
LGN35	89043.1	0.0319	0.02	13	—	—	—	0.770	0.03	10
LGN35	89043.3	—	—	—	—	—	—	0.764	0.03	9
LGN35	89043.4	—	—	—	1.88	L	36	0.795	L	13
CONT.	—	0.0282	—	—	1.39	—	—	0.701	—	—
LGN39	89931.4	0.0431	0.21	12	—	—	—	—	—	—
LGN34	90403.3	0.0456	0.08	18	1.47	0.17	25	—	—	—
CONT.	—	0.0386	—	—	1.18	—	—	—	—	—
NUE3	88975.1	—	—	—	1.55	0.19	15	—	—	—
NUE3	88975.2	—	—	—	1.72	L	28	0.801	0.08	8
NUE3	88977.1	—	—	—	1.72	L	28	—	—	—
NUE3	88977.2	—	—	—	1.63	0.05	21	—	—	—
NUE3	88977.4	—	—	—	—	—	—	0.804	0.03	8
LGN9	89185.2	—	—	—	1.50	0.28	12	0.794	0.22	7
LGN9	89186.1	0.0414	0.10	8	—	—	—	—	—	—
LGN9	89186.2	—	—	—	1.56	0.11	16	—	—	—
LGN14	89165.3	—	—	—	1.75	0.01	30	—	—	—
LGN14	89167.3	—	—	—	1.70	0.02	27	—	—	—
LGN14	89168.2	—	—	—	1.90	L	41	0.820	L	10
LGN14	89168.5	—	—	—	1.69	0.03	26	0.780	0.29	5
CONT.	—	0.0383	—	—	1.35	—	—	0.742	—	—
LGN26	89037.3	—	—	—	—	—	—	0.866	0.01	10
CONT.	—	—	—	—	—	—	—	0.787	—	—
LGN46	89101.1	0.0381	0.06	11	2.08	0.01	21	0.765	0.01	8
LGN46	89101.3	—	—	—	—	—	—	0.806	L	13
LGN46	89101.7	0.0366	0.23	7	2.03	L	19	0.773	0.01	9
LGN46	89103.1	—	—	—	—	—	—	0.738	0.28	4
CONT.	—	0.0343	—	—	1.97	—	—	0.711	—	—
LGN57	89064.2	0.0345	0.02	28	2.40	0.01	49	0.844	0.23	7
LGN57	89065.1	0.0295	0.14	9	2.23	0.11	38	0.858	0.15	9
LGN57	89067.1	0.0334	0.06	23	2.29	L	42	0.872	L	11
LGN57	89067.2	—	—	—	2.11	L	31	0.864	L	10
LGN57	89067.3	0.0319	0.03	18	—	—	—	—	—	—
CONT.	—	0.0271	—	—	1.61	—	—	0.786	—	—
LGN36	89045.2	0.0302	0.10	9	—	—	—	0.837	0.06	12
LGN36	89047.1	—	—	—	1.79	0.25	13	0.784	0.18	4
LGN36	89047.2	—	—	—	—	—	—	0.845	L	13
CONT.	—	0.0277	—	—	1.59	—	—	0.750	—	—
LGN54	88206.4	0.0409	L	12	—	—	—	—	—	—
LGN54	88207.1	—	—	—	1.90	0.30	7	0.772	0.05	8
LGN54	88208.2	—	—	—	—	—	—	0.799	L	12
CONT.	—	0.0418	—	—	1.77	—	—	0.713	—	—
LGN4	89074.3	—	—	—	2.03	0.02	35	0.869	0.02	17
LGN4	89075.1	—	—	—	—	—	—	0.803	0.23	9
LGN4	89075.2	—	—	—	1.79	0.21	19	0.816	0.17	10
CONT.	—	—	—	—	1.50	—	—	0.740	—	—
LGN52	90578.6	—	—	—	—	—	—	0.771	0.24	7
LGN52	90581.1	—	—	—	1.88	0.03	22	0.760	0.05	5
LGN52	90581.4	—	—	—	1.76	0.07	14	—	—	—
CONT.	—	—	—	—	1.54	—	—	0.756	—	—
LGN41	92099.1	—	—	—	—	—	—	0.767	0.25	4
LGN41	92102.1	—	—	—	2.05	0.03	27	0.865	L	18
CONT.	—	—	—	—	1.61	—	—	0.735	—	—
LGN46	89101.1	—	—	—	—	—	—	0.822	0.27	4
LGN46	89101.3	0.0378	0.02	14	—	—	—	0.832	0.23	5
LGN46	89101.4	0.0353	0.14	6	—	—	—	—	—	—
LGN46	89101.9	0.0366	0.03	10	2.27	0.20	31	—	—	—
CONT.	—	0.0332	—	—	1.73	—	—	0.793	—	—
LGN45	91575.2	—	—	—	2.10	0.01	36	0.830	L	18
LGN45	91579.3	—	—	—	1.78	0.09	15	0.792	0.03	13
LGN45	91579.5	—	—	—	1.69	0.28	9	—	—	—
CONT.	—	—	—	—	1.55	—	—	0.703	—	—
LGN23	92317.2	—	—	—	—	—	—	0.839	L	13
LGN23	92318.2	—	—	—	—	—	—	0.825	0.02	11
CONT.	—	—	—	—	—	—	—	0.745	—	—
LGN48	89060.1	0.0332	0.10	9	—	—	—	—	—	—
LGN48	89061.2	0.0341	L	12	—	—	—	—	—	—
LGN48	89062.1	—	—	—	—	—	—	0.788	0.13	5
LGN48	89063.1	0.0328	0.06	8	—	—	—	—	—	—
LGN48	89063.2	0.0348	0.05	14	—	—	—	—	—	—
CONT.	—	0.0341	—	—	—	—	—	0.750	—	—
LGN18	92466.3	—	—	—	—	—	—	0.773	0.02	13
CONT.	—	—	—	—	—	—	—	0.681	—	—
LGN35	89043.3	0.0336	0.29	7	—	—	—	—	—	—
LGN35	89043.4	—	—	—	—	—	—	0.811	0.18	5
CONT.	—	0.0316	—	—	—	—	—	0.773	—	—
LGN33	91570.4	0.0366	0.28	6	1.83	0.21	9	—	—	—
LGN33	91572.1	—	—	—	2.22	0.02	32	—	—	—
LGN33	91572.3	—	—	—	2.04	L	22	—	—	—
LGN33	91574.4	—	—	—	—	—	—	0.890	0.19	6
CONT.	—	0.0346	—	—	1.68	—	—	0.840	—	—
LGN18	92466.3	—	—	—	—	—	—	0.727	0.09	11
LGN18	92468.3	—	—	—	1.83	0.05	36	0.798	L	72
LGN18	92468.5	—	—	—	—	—	—	0.731	0.27	12
CONT.	—	—	—	—	1.35	—	—	0.654	—	—
LGN47	91174.2	—	—	—	—	—	—	0.797	0.01	8
LGN47	91174.6	—	—	—	1.98	0.22	6	—	—	—
CONT.	—	—	—	—	1.87	—	—	0.731	—	—
LGN42	92204.1	0.0322	0.07	19	1.65	0.15	20	0.675	0.03	7
LGN42	92204.2	—	—	—	—	—	—	0.733	0.10	16
LGN42	92204.3	0.0296	0.14	9	—	—	—	0.704	0.22	11
LGN42	92204.5	0.0308	0.27	13	1.76	0.10	28	0.722	0.17	14
LGN42	92207.1	0.0318	0.24	17	2.23	L	62	0.805	L	27
CONT.	—	0.0272	—	—	1.38	—	—	0.633	—	—
NUE3	88975.2	—	—	—	—	—	—	0.583	0.19	11
NUE3	88977.1	—	—	—	—	—	—	0.587	0.25	12
NUE3	88977.2	—	—	—	1.20	0.12	29	0.603	0.12	15
NUE3	88977.5	0.0402	0.18	20	1.14	0.26	22	0.589	0.24	12
CONT.	—	0.0334	—	—	0.931	—	—	0.524	—	—
LGN1	92185.1	0.0364	0.14	9	—	—	—	—	—	—
LGN1	92185.4	—	—	—	—	—	—	0.825	0.16	7
LGN1	92188.1	0.0373	0.07	11	—	—	—	—	—	—
CONT.	—	0.0352	—	—	—	—	—	0.773	—	—
LGN49	89079.1	—	—	—	2.13	L	22	0.826	L	8
LGN49	89079.3	—	—	—	1.92	0.15	10	0.824	L	8
LGN49	89081.3	0.0385	0.08	9	2.19	0.11	26	0.834	0.03	10
LGN49	89081.4	—	—	—	1.97	0.26	13	0.899	L	18
LGN49	89081.6	—	—	—	1.86	0.23	7	—	—	—
CONT.	—	0.0353	—	—	1.74	—	—	0.761	—	—
LGN4	89074.3	0.0418	L	21	—	—	—	—	—	—
LGN4	89074.4	0.0396	0.03	15	—	—	—	0.581	0.24	11
LGN4	89075.1	—	—	—	1.31	0.11	23	—	—	—
LGN4	89075.2	0.0387	0.08	12	1.37	0.05	29	—	—	—
CONT.	—	0.0344	—	—	1.06	—	—	0.526	—	—
LGN52	90578.6	—	—	—	—	—	—	0.763	0.02	12
LGN52	90581.1	—	—	—	1.76	0.20	15	0.764	L	13
LGN52	90581.4	—	—	—	1.84	0.12	20	—	—	—
CONT.	—	—	—	—	1.54	—	—	0.678	—	—
LGN23	92316.2	—	—	—	1.72	0.21	12	0.795	0.03	10
LGN23	92317.2	—	—	—	—	—	—	0.809	0.05	12
LGN23	92318.1	—	—	—	—	—	—	0.749	0.16	4
LGN23	92318.2	—	—	—	—	—	—	0.778	L	8
CONT.	—	—	—	—	1.54	—	—	0.722	—	—
LGN24	89096.1	—	—	—	—	—	—	0.773	0.17	7
LGN24	89096.3	—	—	—	1.74	0.06	12	—	—	—
CONT.	—	—	—	—	1.56	—	—	0.723	—	—
LGN5	88198.1	0.0398	0.05	13	—	—	—	—	—	—
LGN5	88198.4	0.0401	L	14	—	—	—	0.785	0.11	8
LGN5	88201.1	0.0388	0.14	11	2.21	0.06	9	0.819	0.09	9
LGN5	88201.3	0.0433	0.03	24	—	—	—	0.761	0.10	5
LGN5	88203.2	0.0410	L	17	2.33	0.12	14	—	—	—
CONT.	—	0.0351	—	—	2.04	—	—	0.750	—	—
LGN48	89060.1	0.0337	L	9	—	—	—	—	—	—
LGN48	89061.2	0.0344	0.08	11	—	—	—	—	—	—
LGN48	89063.1	0.0341	0.24	10	—	—	—	—	—	—
LGN48	89063.2	0.0377	0.25	10	—	—	—	0.774	0.06	4
CONT.	—	0.0344	—	—	—	—	—	0.731	—	—
LGN47	91171.4	0.0371	0.23	5	—	—	—	—	—	—
LGN47	91174.3	—	—	—	2.15	0.10	19	0.859	0.09	6
LGN47	91174.4	0.0393	0.02	12	2.01	0.20	11	0.873	0.04	8
LGN47	91174.6	—	—	—	2.08	0.04	15	0.848	0.06	4
CONT.	—	0.0352	—	—	1.81	—	—	0.812	—	—
LGN1	92184.1	0.0353	0.25	5	1.78	0.18	21	0.792	0.24	4
LGN1	92185.1	—	—	—	1.88	L	28	0.827	L	8
LGN1	92185.2	0.0369	0.19	14	1.78	0.23	21	0.786	0.13	3
LGN1	92187.1	0.0369	0.12	8	1.76	0.19	9	0.793	0.06	4
LGN1	92188.1	0.0390	L	16	1.71	0.23	17	—	—	—
CONT.	—	0.0335	—	—	1.47	—	—	0.765	—	—
LGN2	89029.5	—	—	—	2.04	0.17	6	—	—	—
LGN2	89032.2	—	—	—	2.21	0.02	15	—	—	—
LGN2	89032.3	—	—	—	—	—	—	0.808	0.08	8
LGN2	89033.1	—	—	—	2.27	0.08	19	—	—	—
CONT.	—	—	—	—	1.92	—	—	0.745	—	—
LGN45	91575.2	—	—	—	1.88	0.08	51	0.833	L	30
LGN45	91575.3	0.0300	0.04	14	1.70	0.12	36	0.748	L	17
LGN45	91579.3	0.0291	0.26	11	—	—	—	0.709	0.08	11
LGN45	91579.4	—	—	—	1.58	0.10	27	0.699	0.21	9
LGN45	91579.5	0.0310	0.07	18	1.47	0.09	18	0.693	0.09	9
CONT.	—	0.0262	—	—	1.24	—	—	0.639	—	—
LGN33	91570.4	—	—	—	—	—	—	0.813	0.11	6
LGN33	91572.1	—	—	—	—	—	—	0.861	0.01	12
LGN33	91572.3	—	—	—	—	—	—	0.811	0.11	6
LGN33	91574.2	—	—	—	—	—	—	0.849	0.06	11
LGN33	91574.4	—	—	—	—	—	—	0.859	0.02	12
CONT.	—	—	—	—	—	—	—	0.768	—	—
LGN57	89064.2	0.0341	0.03	14	2.08	0.01	81	0.834	L	17
LGN57	89065.1	—	—	—	1.53	L	33	—	—	—
LGN57	89066.1	—	—	—	1.57	0.06	37	0.756	0.03	6
LGN57	89067.3	0.0333	L	12	—	—	—	—	—	—
CONT.	—	0.0298	—	—	1.15	—	—	0.714	—	—
NUE102	90004.1	—	—	—	1.88	0.18	10	—	—	—
NUE102	90004.2	—	—	—	1.99	0.17	17	0.767	L	12
NUE102	90004.3	—	—	—	—	—	—	0.763	0.04	12
NUE102	90005.1	—	—	—	—	—	—	0.791	0.03	16
NUE102	90005.3	0.0359	0.10	9	2.21	0.07	30	0.871	L	28
CONT.	—	0.0328	—	—	1.70	—	—	0.683	—	—
LGN42	92204.2	—	—	—	2.02	0.12	20	0.826	0.23	6
LGN42	92204.3	—	—	—	1.93	0.28	15	—	—	—
LGN42	92204.5	—	—	—	2.23	0.02	32	0.847	0.10	8
CONT.	—	—	—	—	1.68	—	—	0.781	—	—
LGN60	89174.2	0.0389	0.05	8	1.83	0.27	14	—	—	—
LGN60	89175.3	—	—	—	1.75	0.18	9	0.795	0.15	7
LGN60	89176.1	—	—	—	1.97	0.06	22	0.780	0.19	5
LGN60	89176.2	0.0394	0.22	10	—	—	—	—	—	—
LGN60	89177.1	—	—	—	—	—	—	0.782	0.20	5
CONT.	—	0.0368	—	—	1.61	—	—	0.743	—	—
LBY92	93921.2	—	—	—	4.54	L	142	0.973	0.01	21
LBY92	93923.3	—	—	—	4.35	L	132	0.877	0.24	9
CONT.	—	—	—	—	1.87	—	—	0.803	—	—

Table 270. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 271
Genes showing improved plant performance at Low Nitrogen growth conditions under
regulation of At6669 promoter
		Roots Coverage
	Leaf Area [cm2]	[cm2]	Roots Length [cm]
			P-	%		P-	%		P-	%
Gene Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Vol.	Incr.
LBY186	91657.1	0.416	0.02	9	17.5	0.14	33	8.31	0.03	8
LBY186	91659.1	—	—	—	16.4	L	25	7.88	0.12	2
LBY186	91659.2	—	—	—	15.1	0.06	15	7.95	0.07	3
LBY186	91659.3	0.460	L	20	19.2	L	46	8.27	L	7
LBY179	91545.2	—	—	—	15.8	L	21	8.00	L	4
LBY179	91545.4	0.403	0.26	6	—	—	—	8.17	L	6
LBY179	91547.2	—	—	—	14.4	0.13	10	—	—	—
LBY179	91549.1	0.428	0.15	12	16.4	0.02	25	8.32	L	8
LBY152	91286.1	0.426	0.03	12	16.5	0.02	26	8.20	0.05	6
LBY152	91288.2	0.434	0.01	14	16.5	0.07	25	8.17	0.06	6
LBY152	91289.2	—	—	—	15.0	0.19	14	8.04	0.03	4
LBY123	91427.1	0.430	0.25	13	15.6	0.20	19	—	—	—
LBY123	91429.2	0.418	0.03	9	15.6	0.10	19	8.04	0.09	4
LBY123	91429.3	—	—	—	15.2	0.08	16	8.28	L	7
LBY114	91391.2	0.417	0.10	9	—	—	—	—	—	—
LBY114	91393.1	0.395	0.25	4	—	—	—	—	—	—
CONT.	—	0.382	—	—	13.1	—	—	7.72	—	—
LBY200	92754.1	0.385	0.13	10	14.9	0.05	17	7.83	0.21	3
LBY200	92754.3	0.405	L	16	—	—	—	—	—	—
LBY200	92757.1	0.398	0.04	13	—	—	—	—	—	—
LBY200	92757.2	0.377	0.16	8	—	—	—	—	—	—
LBY200	92758.3	0.408	0.08	16	—	—	—	—	—	—
LBY141	92564.1	—	—	—	15.1	0.30	18	—	—	—
LBY141	92565.2	—	—	—	15.0	0.08	17	—	—	—
CONT.	—	0.351	—	—	12.8	—	—	7.59	—	—
LBY203	92839.1	—	—	—	14.6	0.29	16	—	—	—
LBY203	92841.2	—	—	—	15.8	0.14	25	8.16	0.04	7
LBY203	92842.3	0.450	0.08	10	—	—	—	8.09	L	6
LBY180	92576.3	—	—	—	14.8	0.04	17	—	—	—
LBY180	92578.5	0.444	0.20	9	16.2	0.02	28	8.26	L	8
LBY177	92495.1	—	—	—	—	—	—	8.08	0.04	6
LBY177	92497.3	—	—	—	—	—	—	7.88	0.25	3
LBY177	92497.6	—	—	—	15.4	0.09	22	8.14	L	7
LBY144	93059.3	—	—	—	—	—	—	7.99	0.18	5
LBY144	93061.4	—	—	—	16.7	0.03	32	8.43	L	11
LBY144	93061.5	—	—	—	16.9	0.01	34	8.23	0.03	8
LBY144	93061.6	—	—	—	14.9	0.22	18	—	—	—
LBY111	92794.4	0.443	0.16	8	—	—	—	8.01	0.07	5
LBY111	92797.1	0.470	0.11	15	—	—	—	8.02	0.13	5
LBY111	92798.1	—	—	—	—	—	—	8.00	0.08	5
CONT.	—	0.409	—	—	12.6	—	—	7.62	—	—
LBY191	92519.2	—	—	—	19.0	0.04	29	—	—	—
LBY191	92522.1	0.369	0.22	5	—	—	—	—	—	—
LBY1.91	92523.3	0.400	0.01	14	—	—	—	—	—	—
LBY144	93059.3	0.374	0.10	7	—	—	—	—	—	—
LBY111	92797.1	0.382	0.16	9	—	—	—	—	—	—
LBY111	92798.1	0.371	0.28	6	—	—	—	8.09	0.17	4
CONT.	—	0.351	—	—	14.6	—	—	7.74	—	—
LBY78	92311.4	0.425	0.18	1.2	15.2	0.02	22	8.05	0.18	4
LBY78	92312.2	—	—	—	14.0	0.22	12	—	—	—
LBY78	92313.1	—	—	—	—	—	—	8.19	0.07	6
LBY78	92313.5	—	—	—	15.2	0.11	22	—	—	—
LBY31	92344.1	0.423	0.02	11	15.6	0.19	25	8.26	0.05	7
LBY31	92345.4	—	—	—	15.8	0.05	27	8.13	0.13	5
LBY31	92345.6	0.427	0.13	12	—	—	—	—	—	—
LBY31	92347.2	0.415	0.20	9	—	—	—	8.08	0.15	5
LBY175	92179.1	0.427	0.16	12	16.0	0.03	28	8.23	0.05	7
LBY175	92179.3	—	—	—	13.9	0.21	11	—	—	—
LBY175	92181.2	0.441	0.20	16	15.9	0.02	27	8.21	0.05	6
LBY175	92181.3	—	—	—	13.8	0.28	11	8.29	0.08	7
LBY175	92181.4	0.440	0.02	16	15.3	0.04	22	8.06	0.28	4
LBY149	92245.2	—	—	—	13.9	0.21	11	—	—	—
LBY149	92246.3	—	—	—	14.5	0.18	16	8.10	0.15	5
LBY149	92247.1	—	—	—	—	—	—	8.13	0.14	5
LBY140	92265.2	—	—	—	17.2	0.05	37	8.14	0.13	6
LBY140	92265.5	—	—	—	16.5	0.02	32	8.14	0.12	5
LBY140	92268.2	0.410	0.05	8	—	—	—	8.15	0.15	6
LBY116	92136.3	0.409	0.24	8	15.5	0.12	24	8.10	0.19	5
LBY116	92136.4	—	—	—	14.6	0.11	17	8.22	0.05	6
CONT.	—	0.380	—	—	12.5	—	—	7.72	—	—
LBY68	93862.5	—	—	—	16.0	0.24	7	—	—	—
LBY5	93940.2	—	—	—	—	—	—	8.53	0.23	2
LBY34_H2	93856.1	—	—	—	16.6	0.21	11	—	—	—
LBY183	92516.5	—	—	—	15.9	0.28	6	—	—	—
LBY159	92152.3	0.456	0.22	8	16.4	0.18	10	8.56	0.25	9
LBY159	92153.1	—	—	—	17.8	0.17	19	8.56	0.23	2
LBY157	92803.1	—	—	—	18.0	0.25	21	8.59	0.22	3
LBY148	93767.2	—	—	—	16.4	0.24	10	8.69	0.16	4
LBY109	93950.6	—	—	—	—	—	—	8.56	0.28	9
CONT.	—	0.423	—	—	14.9	—	—	8.36	—	—
LBY80	92269.3	—	—	—	10.7	0.01	43	7.41	L	15
LBY80	92270.1	0.356	0.17	10	8.74	0.15	17	6.87	0.03	7
LBY80	92272.2	—	—	—	11.5	L	54	7.37	L	15
LBY80	92273.1	—	—	—	8.88	0.14	19	7.00	0.02	9
LBY185	91497.1	0.363	0.04	12	13.0	L	74	7.44	L	16
LBY185	91497.2	0.358	0.15	11	10.2	0.01	36	6.92	0.03	8
LBY185	91498.2	0.366	0.02	14	13.2	0.02	76	7.64	L	19
LBY185	91499.2	—	—	—	9.26	0.11	24	—	—	—
LBY179	91545.2	—	—	—	12.1	L	62	7.43	L	16
LBY179	91545.4	—	—	—	—	—	—	6.81	0.27	6
LBY179	91547.2	0.369	0.29	14	13.7	0.10	84	7.35	0.06	14
LBY179	91549.1	—	—	—	9.58	L	28	6.91	0.12	8
LBY179	91549.3	—	—	—	12.0	L	61	7.60	L	18
LBY173	91651.2	—	—	—	9.69	0.03	30	6.79	0.09	6
LBY173	91652.1	0.378	0.08	17	15.0	0.01	100	7.70	L	20
LBY173	91652.2	0.358	0.03	11	12.6	L	68	7.07	0.04	10
LBY173	91652.3	0.358	0.18	11	9.59	L	28	7.11	L	11
LBY173	91653.1	—	—	—	11.1	L	49	7.00	0.08	9
LBY153	92249.2	0.339	0.28	5	10.4	0.02	39	7.06	0.05	10
LBY153	92253.2	0.358	0.18	11	—	—	—	—	—	—
LBY121	92290.3	0.358	0.10	11	12.2	L	64	7.60	L	18
LBY121	92290.4	—	—	—	10.6	0.14	41	—	—	—
LBY121	92291.2	0.363	0.20	13	9.37	0.17	25	7.22	0.13	12
LBY121	92291.4	—	—	—	11.0	0.04	47	6.85	0.26	7
CONT.	—	0.323	—	—	7.48	—	—	6.42	—	—
LBY71	93769.3	0.368	0.28	8	—	—	—	—	—	—
LBY68	93862.1	0.365	0.30	7	12.9	0.21	13	7.75	0.07	6
LBY68	93862.4	0.394	0.07	15	—	—	—	8.21	L	12
LBY61	94019.4	—	—	—	13.5	0.22	18	7.60	0.28	4
LBY61	94021.4	—	—	—	13.1	0.17	15	—	—	—
LBY6	94111.3	0.382	0.14	12	—	—	—	—	—	—
LBY52	93946.2	0.427	L	25	12.7	0.27	12	7.81	0.07	7
LBY52	93947.2	0.389	0.02	14	—	—	—	8.05	0.05	10
LBY44	92491.2	0.399	0.04	17	—	—	—	7.96	0.02	9
LBY34_H2	93856.1	0.393	0.09	15	—	—	—	—	—	—
LBY34_H2	93857.1	—	—	—	13.0	0.26	14	—	—	—
LBY34_H2	93857.2	—	—	—	14.4	0.05	26	7.75	0.10	6
LBY34_H2	93857.4	0.374	0.22	10	—	—	—	—	—	—
LBY216	94080.3	0.438	L	28	13.1	0.14	15	7.97	0.01	9
LBY20	94085.1	0.408	0.06	20	14.7	0.06	29	—	—	—
LBY20	94087.3	0.383	0.06	12	—	—	—	8.13	0.02	11
LBY142	93199.1	—	—	—	13.5	0.11	19	7.74	0.18	6
LBY142	93203.4	0.386	0.03	13	15.2	L	34	7.79	0.06	7
CONT.	—	0.341	—	—	11.4	—	—	7.30	—	—
LBY41	91620.4	—	—	—	14.2	0.29	11	—	—	—
LBY41	91621.1	0.425	L	16	15.4	L	20	8.12	0.29	2
LBY41	91621.2	—	—	—	14.4	0.10	12	—	—	—
LBY41	91623.1	—	—	—	14.7	0.01	14	8.25	0.27	4
LBY41	91623.2	0.393	0.29	7	15.7	0.07	23	8.47	0.01	6
LBY173	91651.2	—	—	—	13.8	0.24	8	—	—	—
LBY173	91652.1	0.402	0.25	10	18.5	0.01	44	8.45	0.03	6
LBY173	91652.5	0.434	0.03	18	18.9	L	48	—	—	—
LBY166	91542.5	—	—	—	15.2	0.08	19	—	—	—
LBY166	91544.5	—	—	—	15.9	L	24	8.31	0.02	4
CONT.	—	0.366	—	—	12.8	—	—	7.96	—	—
LBY85	92064.1	0.455	0.09	13	—	—	—	—	—	—
LBY85	92066.2	0.442	0.19	9	—	—	—	—	—	—
LBY85	92066.3	0.468	L	16	18.9	L	22	8.44	0.15	2
LBY85	92066.5	0.474	L	17	—	—	—	—	—	—
LBY85	92068.3	—	—	—	16.6	0.18	8	—	—	—
LBY64	91340.4	0.453	0.05	12	16.3	0.10	6	8.47	0.19	2
LBY64	91342.2	0.454	L	12	—	—	—	—	—	—
LBY64	91342.3	0.454	L	12	16.8	0.27	9	—	—	—
LBY64	91342.6	0.434	0.10	8	—	—	—	—	—	—
LBY46	92200.3	0.432	0.07	7	17.2	0.14	11	—	—	—
LBY46	92201.2	0.450	0.04	11	—	—	—	—	—	—
LBY46	92201.4	0.454	L	12	18.0	0.17	17	8.42	0.13	2
LBY207	92155.1	0.467	0.02	16	17.0	0.17	10	—	—	—
LBY207	92157.3	—	—	—	17.5	0.13	13	—	—	—
LBY207	92158.2	0.516	0.01	28	17.2	0.17	11	—	—	—
LBY185	91497.1	0.464	L	15	17.2	0.30	11	—	—	—
LBY185	91497.2	0.478	L	18	18.8	L	22	—	—	—
LBY185	91498.2	0.470	0.03	16	—	—	—	—	—	—
LBY185	91499.2	0.450	0.05	11	16.9	0.27	10	—	—	—
LBY17	92216.2	0.472	0.08	17	16.5	0.27	7	—	—	—
LBY155	92015.1	0.489	0.02	21	—	—	—	—	—	—
LBY155	92016.4	0.492	L	22	—	—	—	—	—	—
LBY155	92016.7	0.466	L	15	16.9	0.21	10	—	—	—
LBY122	91370.2	0.497	L	23	16.7	0.10	8	—	—	—
LBY122	91371.3	0.422	0.30	5	—	—	—	—	—	—
LBY122	91371.6	0.475	0.12	18	17.6	0.08	14	—	—	—
LBY122	91374.1	0.468	L	16	17.8	0.07	15	—	—	—
CONT.	—	0.404	—	—	15.4	—	—	8.27	—	—
LBY50	91317.3	0.407	0.13	8	—	—	—	—	—	—
LBY50	91318.1	0.403	0.24	7	—	—	—	—	—	—
LBY50	91318.2	0.452	0.03	19	—	—	—	—	—	—
LBY50	91318.4	0.412	0.18	9	—	—	—	—	—	—
LBY24	91220.6	0.425	0.07	12	17.7	0.02	16	8.78	L	9
LBY24	91221.1	0.436	0.02	15	—	—	—	—	—	—
LBY24	91221.2	0.472	0.04	25	19.2	L	25	8.42	0.05	5
LBY24	91223.2	0.404	0.23	7	—	—	—	—	—	—
LBY24	91223.3	0.448	0.01	18	—	—	—	—	—	—
LBY21	90977.1	0.415	0.07	10	—	—	—	—	—	—
LBY21	90978.4	0.430	0.04	14	—	—	—	—	—	—
LBY21	90980.1	0.407	0.11	8	16.8	0.18	9	8.30	0.22	3
LBY161	91292.1	0.451	L	19	16.9	0.24	10	—	—	—
LBY161	91292.3	—	—	—	16.5	0.17	8	8.29	0.20	3
LBY161	91293.3	0.441	0.14	17	19.0	0.03	24	8.62	0.02	7
LBY161	91294.1	—	—	—	—	—	—	8.40	0.08	4
LBY152	91286.1	0.436	L	15	—	—	—	—	—	—
LBY152	91287.1	0.469	L	24	—	—	—	8.27	0.22	3
LBY152	91288.2	0.417	0.13	10	—	—	—	—	—	—
LBY152	91289.2	0.422	0.01	11	—	—	—	—	—	—
LBY15	91143.1	0.432	0.09	14	—	—	—	—	—	—
LBY15	91144.2	0.425	0.19	12	18.3	0.03	19	8.38	0.08	4
LBY15	91144.3	0.418	0.24	11	17.1	0.05	11	8.28	0.23	3
LBY123	91428.2	—	—	—	17.9	L	17	8.28	0.20	3
LBY123	91429.2	—	—	—	18.0	0.06	18	8.26	0.27	3
LBY123	91429.3	—	—	—	17.6	0.10	15	—	—	—
LBY123	91429.6	0.431	0.18	14	18.6	0.09	22	8.37	0.19	4
LBY114	91391.2	0.434	0.05	15	—	—	—	—	—	—
LBY114	91393.1	—	—	—	18.3	0.07	20	—	—	—
LBY114	91393.2	0.404	0.14	7	—	—	—	8.36	0.16	4
CONT.	—	0.379	—	—	15.3	—	—	8.06	—	—
LBY80	92269.3	—	—	—	—	—	—	7.64	0.26	9
LBY80	92269.4	0.410	0.09	11	14.1	0.28	24	—	—	—
LBY80	92270.1	0.422	L	15	14.3	0.02	26	7.93	0.04	6
LBY80	92272.2	—	—	—	—	—	—	7.77	0.05	4
LBY78	92311.3	0.424	0.07	15	—	—	—	8.07	0.02	8
LBY78	92311.4	0.414	0.25	12	—	—	—	—	—	—
LBY78	92312.2	—	—	—	—	—	—	7.77	0.15	4
LBY78	92313.5	—	—	—	14.5	0.01	28	7.97	0.15	6
LBY53	92414.1	—	—	—	13.1	0.16	16	7.77	0.07	4
LBY53	92418.1	0.406	0.06	10	—	—	—	8.03	0.02	7
LBY153	92249.2	—	—	—	12.9	L	14	7.61	0.29	2
LBY153	92252.2	—	—	—	13.3	0.25	17	8.07	0.10	8
LBY149	92246.3	0.422	0.01	15	15.7	L	39	8.33	L	11
LBY121	92291.2	—	—	—	13.4	0.08	18	—	—	—
CONT.	—	0.368	—	—	11.3	—	—	7.48	—	—
LBY76	92642.1	—	—	—	16.3	0.29	15	—	—	—
LBY70	92684.2	—	—	—	16.8	0.10	19	—	—	—
LBY70	92685.5	0.450	0.04	15	17.4	0.11	23	8.07	0.24	4
LBY70	92686.3	—	—	—	16.1	0.24	13	—	—	—
LBY227	92851.1	0.449	0.01	15	—	—	—	8.23	0.08	7
LBY227	92853.1	0.428	0.30	10	—	—	—	—	—	—
LBY159	92152.1	0.432	0.18	11	16.2	0.16	14	—	—	—
LBY159	92153.1	—	—	—	16.8	0.29	19	8.03	0.26	4
LBY156	92294.1	—	—	—	15.6	0.29	10	—	—	—
LBY156	92294.3	—	—	—	—	—	—	8.20	0.11	6
LBY145	92605.1	0.422	0.23	8	—	—	—	—	—	—
LBY145	92606.2	0.433	0.03	11	16.8	0.09	18	8.15	0.13	5
LBY145	92608.4	—	—	—	15.9	0.20	12	—	—	—
CONT.	—	0.390	—	—	14.2	—	—	7.72	—	—
LBY92	93921.2	—	—	—	36.6	L	139	8.93	L	7
LBY92	93923.3	—	—	—	35.1	L	129	8.67	0.07	4
LBY6	94110.2	—	—	—	17.9	0.25	17	8.52	0.27	2
LBY20	94084.1	—	—	—	18.7	0.23	22	8.71	0.19	5
LBY20	94087.1	0.427	0.25	8	—	—	—	—	—	—
LBY148	93765.1	—	—	—	17.2	0.06	12	—	—	—
LBY148	93768.1	0.433	0.15	9	—	—	—	—	—	—
LBY106_H3	93916.1	0.426	0.24	7	17.1	0.13	12	—	—	—
LBY106_H3	93918.1	—	—	—	17.9	0.07	17	—	—	—
CONT.	—	0.397	—	—	15.3	—	—	8.32	—	—
LBY50	91317.3	—	—	—	15.6	0.04	17	7.96	0.18	4
LBY24	91221.2	0.438	0.17	7	16.6	0.05	25	8.02	0.16	5
LBY21	90980.1	0.439	0.25	8	15.7	0.25	18	—	—	—
LBY161	91294.1	—	—	—	—	—	—	8.09	0.09	6
LBY15	91144.1	—	—	—	14.8	0.18	11	8.03	0.12	5
LBY15	91144.2	—	—	—	—	—	—	8.12	0.07	6
CONT.	—	0.408	—	—	13.3	—	—	7.63	—	—
LBY53	92414.1	—	—	—	—	—	—	8.35	0.18	4
LBY53	92415.1	0.466	0.03	12	—	—	—	—	—	—
LBY53	92416.1	—	—	—	16.2	0.15	17	8.33	0.14	3
LBY53	92418.1	—	—	—	16.2	0.15	17	—	—	—
LBY31	92344.1	0.450	0.20	9	15.8	0.13	15	—	—	—
LBY31	92344.2	—	—	—	17.2	0.05	24	8.33	0.07	3
LBY31	92347.1	—	—	—	15.4	0.14	11	—	—	—
LBY208	92358.1	0.454	0.11	10	—	—	—	—	—	—
LBY208	92358.2	0.439	0.29	6	—	—	—	—	—	—
LBY207	92154.1	—	—	—	16.6	0.24	20	—	—	—
LBY207	92155.1	—	—	—	15.7	0.03	13	—	—	—
LBY207	92157.3	0.461	0.01	11	18.8	0.02	36	8.37	0.05	4
LBY207	92158.2	0.448	0.19	8	15.1	0.15	9	—	—	—
LBY175	92179.1	—	—	—	16.8	0.14	21	—	—	—
LBY175	92181.3	0.462	0.05	12	17.6	0.13	27	8.38	0.07	4
LBY175	92181.4	—	—	—	16.3	0.09	18	—	—	—
LBY140	92265.2	0.452	0.08	9	16.2	0.05	17	8.39	0.04	4
LBY140	92265.5	—	—	—	15.8	0.26	14	—	—	—
LBY140	92266.3	—	—	—	16.6	0.04	20	8.30	0.27	3
LBY116	92136.1	—	—	—	16.3	0.09	18	—	—	—
LBY116	92136.3	—	—	—	17.3	0.09	25	—	—	—
LBY116	92136.4	—	—	—	18.0	0.12	30	—	—	—
LBY116	92138.6	0.439	0.24	6	—	—	—	—	—	—
CONT.	—	0.414	—	—	13.8	—	—	8.05	—	—
LBY181	92479.3	—	—	—	15.1	L	32	—	—	—
LBY181	92482.1	0.345	0.22	3	—	—	—	—	—	—
LBY167	92770.4	—	—	—	14.1	0.18	24	—	—	—
LBY167	92773.1	—	—	—	13.7	0.15	20	—	—	—
LBY157	92802.2	—	—	—	14.2	0.06	24	—	—	—
LBY157	92802.3	0.389	0.08	16	17.4	0.07	53	—	—	—
LBY157	92803.1	—	—	—	14.3	0.02	25	—	—	—
LBY157	92803.2	—	—	—	14.9	0.10	30	—	—	—
CONT.	—	0.334	—	—	11.4	—	—	—	—	—
LBY41	91620.4	—	—	—	19.1	0.02	17	8.67	L	4
LBY41	91621.2	—	—	—	18.9	0.13	16	—	—	—
LBY41	91623.2	0.431	0.16	7	—	—	—	8.45	0.23	1
LBY186	91655.4	—	—	—	18.4	0.05	13	—	—	—
LBY186	91657.1	—	—	—	19.2	0.09	18	8.80	L	6
LBY186	91659.1	—	—	—	18.8	0.07	15	8.51	0.26	9
LBY186	91659.3	—	—	—	19.9	0.06	22	—	—	—
LBY166	91544.3	—	—	—	—	—	—	8.51	0.14	2
CONT.	—	0.404	—	—	16.3	—	—	8.33	—	—
LBY85	92064.1	—	—	—	—	—	—	8.17	0.17	3
LBY85	92066.3	0.387	0.30	7	—	—	—	—	—	—
LBY85	92066.5	—	—	—	16.6	0.07	21	8.13	0.24	3
LBY64	91340.4	—	—	—	—	—	—	8.13	0.20	3
LBY64	91342.3	0.383	0.25	6	—	—	—	8.19	0.18	4
LBY64	91342.6	—	—	—	—	—	—	8.10	0.27	2
LBY46	92200.3	0.392	0.19	8	—	—	—	—	—	—
LBY46	92201.2	0.395	0.02	9	17.7	L	28	8.24	0.08	4
LBY46	92201.4	0.386	0.10	7	17.8	0.01	29	8.14	0.28	3
LBY17	92214.1	—	—	—	—	—	—	8.13	0.23	3
LBY17	92216.3	—	—	—	15.9	0.13	15	8.16	0.19	3
LBY17	92216.4	—	—	—	15.6	0.17	14	8.45	0.01	7
LBY155	92014.2	—	—	—	15.0	0.25	9	—	—	—
LBY155	92015.1	0.389	0.19	7	14.9	0.26	8	8.19	0.14	4
LBY122	91371.2	0.394	0.10	9	15.3	0.15	11	—	—	—
LBY122	91371.3	—	—	—	15.4	0.13	12	8.30	0.05	5
LBY122	91371.4	0.382	0.25	5	—	—	—	—	—	—
LBY122	91371.6	0.378	0.24	4	16.1	0.18	17	—	—	—
LBY122	91374.1	—	—	—	15.4	0.16	12	8.10	0.26	3
CONT.	—	0.362	—	—	13.8	—	—	7.90	—	—

Table 271. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value, L—p<0.01.

TABLE 272
Genes showing improved plant performance at Low Nitrogen growth conditions under
regulation of At6669 promoter
		RGR Of Roots	RGR Of Root
	RGR Of Leaf Area	Coverage	Length
			P-	%		P-	%		P-	%
Gene Name	Event #	Ave.	Val.	Incr.	Ave.	Val.	Incr.	Ave.	Val.	Incr.
LBY186	91657.1	—	—	—	2.15	0.02	33	0.879	0.01	14
LBY186	91659.1	—	—	—	2.02	0.02	25	0.830	0.15	8
LBY186	91659.2	—	—	—	1.87	0.15	16	0.894	L	16
LBY186	91659.3	0.0406	L	22	2.37	L	46	0.871	0.05	13
LBY186	91659.4	—	—	—	—	—	—	0.871	0.02	13
LBY179	91545.2	—	—	—	1.95	0.06	20	0.865	0.02	12
LBY179	91545.4	0.0365	0.14	9	—	—	—	—	—	—
LBY179	91547.2	—	—	—	—	—	—	0.831	0.15	8
LBY179	91549.1	0.0379	0.07	14	2.03	0.01	25	0.883	0.02	15
LBY152	91286.1	0.0363	0.12	9	2.03	0.02	25	0.870	0.02	13
LBY152	91288.2	0.0381	0.02	14	2.02	0.03	25	—	—	—
LBY152	91289.2	—	—	—	1.86	0.20	15	0.882	L	15
LBY123	91427.1	0.0388	0.08	16	1.92	0.12	19	0.839	0.13	9
LBY123	91429.2	0.0360	0.13	8	1.93	0.07	19	0.854	0.07	11
LBY123	91429.3	0.0359	0.13	8	1.87	0.14	15	0.842	0.13	9
LBY114	91391.1	—	—	—	—	—	—	0.828	0.27	8
LBY114	91391.2	0.0381	0.03	14	—	—	—	—	—	—
LBY114	91393.1	0.0371	0.06	11	—	—	—	—	—	—
CONT.	—	0.0334	—	—	1.62	—	—	0.769	—	—
LBY200	92754.1	—	—	—	1.78	0.13	17	—	—	—
LBY200	92754.3	0.0339	0.03	18	—	—	—	—	—	—
LBY200	92757.1	0.0322	0.18	13	—	—	—	—	—	—
LBY200	92758.3	0.0349	0.03	22	—	—	—	—	—	—
LBY141	92564.1	—	—	—	1.86	0.13	22	0.834	L	32
LBY141	92565.2	—	—	—	1.84	0.11	21	0.721	0.10	14
LBY141	92566.3	—	—	—	—	—	—	0.756	0.03	19
CONT.	—	0.0286	—	—	1.52	—	—	0.634	—	—
LBY203	92839.1	—	—	—	1.76	0.14	18	—	—	—
LBY203	92841.2	—	—	—	1.89	0.04	26	—	—	—
LBY203	92842.3	0.0390	0.05	18	—	—	—	—	—	—
LBY180	92576.3	—	—	—	1.78	0.08	19	0.745	0.29	7
LBY180	92578.5	—	—	—	1.94	L	30	0.756	0.26	9
LBY177	92495.1	—	—	—	—	—	—	0.746	0.28	7
LBY177	92497.6	—	—	—	1.85	0.04	24	—	—	—
LBY144	93061.4	—	—	—	2.00	L	33	—	—	—
LBY144	93061.5	—	—	—	2.05	L	36	0.773	0.15	11
LBY144	93061.6	—	—	—	1.80	0.09	20	—	—	—
LBY111	92797.1	0.0398	0.09	20	—	—	—	—	—	—
CONT.	—	0.0331	—	—	1.50	—	—	0.695	—	—
LBY203	92842.3	0.0355	0.02	20	—	—	—	—	—	—
LBY191	92519.2	—	—	—	2.34	0.04	31	—	—	—
LBY191	92523.3	0.0331	0.06	12	—	—	—	—	—	—
LBY167	92772.1	—	—	—	—	—	—	0.809	0.17	8
LBY144	93059.3	0.0322	0.12	8	—	—	—	—	—	—
LBY144	93061.5	0.0318	0.23	7	—	—	—	—	—	—
LBY111	92797.1	0.0333	0.05	12	—	—	—	—	—	—
LBY111	92798.1	0.0316	0.26	6	—	—	—	0.798	0.19	7
CONT.	—	0.0297	—	—	1.79	—	—	0.748	—	—
LBY78	92311.4	—	—	—	1.81	0.07	21	—	—	—
LBY78	92312.2	—	—	—	1.70	0.26	13	—	—	—
LBY78	92313.5	0.0365	0.15	16	1.84	0.08	23	—	—	—
LBY31	92344.1	—	—	—	1.86	0.08	24	—	—	—
LBY31	92345.4	—	—	—	1.89	0.05	26	—	—	—
LBY31	92347.2	0.0362	0.14	15	—	—	—	—	—	—
LBY175	92179.1	—	—	—	1.93	0.02	29	—	—	—
LBY175	92179.3	—	—	—	1.70	0.28	13	—	—	—
LBY175	92181.2	—	—	—	1.92	0.02	28	—	—	—
LBY175	92181.4	—		—	1.83	0.08	22	—	—	—
LBY149	92246.3	—	—	—	1.75	0.17	16	—	—	—
LBY149	92247.1	—	—	—	—	—	—	0.820	0.28	14
LBY140	92265.2	—	—	—	2.08	L	39	—	—	—
LBY140	92265.5	—	—	—	1.97	0.01	31	—	—	—
LBY140	92268.2	—	—	—	—	—	—	0.846	0.16	18
LBY116	92136.3	—	—	—	1.88	0.06	25	—	—	—
LBY116	92136.4	—	—	—	1.78	0.11	19	0.834	0.21	16
CONT.	—	0.0315	—	—	1.50	—	—	0.720	—	—
LBY201	93927.1	0.0399	0.22	8	—	—	—	—	—	—
LBY159	92152.3	—	—	—	2.09	0.29	11	0.917	0.06	7
LBY159	92153.1	—	—	—	2.25	0.10	19	—	—	—
LBY157	92803.1	—	—	—	2.29	0.10	21	0.910	0.07	7
LBY148	93768.1	—	—	—	—	—	—	0.909	0.18	7
LBY109	93950.1	—	—	—	—	—	—	0.906	0.21	6
LBY109	93950.6	—	—	—	—	—	—	0.937	0.02	10
CONT.	—	0.0370	—	—	1.89	—	—	0.853	—	—
LBY80	92269.3	—	—	—	1.27	L	42	0.634	0.21	9
LBY80	92269.4	0.0270	0.28	6	—	—	—	—	—	—
LBY80	92270.1	0.0296	0.05	16	1.03	0.13	15	—	—	—
LBY80	92272.2	—	—	—	1.37	L	53	0.638	0.07	10
LBY80	92273.1	—	—	—	1.05	0.08	18	—	—	—
LBY185	91497.1	0.0275	0.15	8	1.56	L	74	0.655	0.07	13
LBY185	91497.2	0.0277	0.26	9	1.22	L	36	0.622	0.14	7
LBY185	91498.2	0.0280	0.12	10	1.57	L	76	0.687	0.01	18
LBY185	91499.2	—	—	—	1.11	0.03	24	0.608	0.24	5
LBY185	91499.3	—	—	—	1.02	0.30	14	0.634	0.24	9
LBY179	91545.2	—	—	—	1.45	L	62	0.675	0.02	16
LBY179	91547.2	—	—	—	1.67	L	87	0.708	0.03	22
LBY179	91549.1	—	—	—	1.14	L	28	0.642	0.12	11
LBY179	91549.3	—	—	—	1.46	L	63	0.735	L	27
LBY173	91651.2	—	—	—	1.16	L	30	0.664	0.03	14
LBY173	91652.1	—	—	—	1.82	L	103	0.767	L	32
LBY173	91652.2	—	—	—	1.51	L	69	0.663	0.04	14
LBY173	91652.3	0.0298	0.14	17	1.15	L	28	0.668	L	15
LBY173	91653.1	—	—	—	1.35	L	51	0.685	0.02	18
LBY153	92249.2	—	—	—	1.24	L	39	0.625	0.25	8
LBY153	92253.2	0.0281	0.21	11	1.02	0.30	14	—	—	—
LBY121	92290.3	0.0293	0.04	15	1.48	L	66	0.710	L	22
LBY121	92290.4	—	—	—	1.28	L	43	0.692	0.12	19
LBY121	92291.2	0.0296	0.11	17	1.12	0.05	25	0.659	0.13	14
LBY121	92291.4	—	—	—	1.34	L	50	0.684	0.02	18
LBY121	92293.2	—	—	—	—	—	—	0.622	0.24	7
CONT.	—	0.0254	—	—	0.893	—	—	0.580	—	—
LBY71	93769.3	0.0355	0.25	16	—	—	—	—	—	—
LBY68	93862.1	—	—	—	—	—	—	0.806	0.21	10
LBY68	93862.4	0.0412	L	35	—	—	—	0.832	0.16	14
LBY61	94019.4	—	—	—	1.81	0.22	19	—	—	—
LBY61	94021.4	—	—	—	1.78	0.23	17	—	—	—
LBY6	94111.3	0.0362	0.16	18	—	—	—	—	—	—
LBY52	93944.1	0.0379	0.08	24	—	—	—	—	—	—
LBY52	93946.2	0.0406	0.01	33	—	—	—	0.841	0.09	15
LBY52	93947.2	0.0375	0.06	23	—	—	—	0.875	0.03	20
LBY44	92491.2	0.0388	0.04	27	—	—	—	0.841	0.08	15
LBY34_H2	93856.1	0.0385	0.06	26	—	—	—	—	—	—
LBY34_H2	93857.1	—	—	—	1.77	0.28	16	0.805	0.18	10
LBY34_H2	93857.2	—	—	—	1.96	0.04	29	—	—	—
LBY216	94080.3	0.0420	L	37	1.79	0.21	18	0.877	0.02	20
LBY216	94082.2	0.0345	0.29	13	—	—	—	—	—	—
LBY20	94085.1	0.0356	0.22	16	1.99	0.05	31	0.842	0.09	15
LBY20	94087.3	0.0393	0.02	29	—	—	—	0.924	L	27
LBY181	92480.1	—	—	—	—	—	—	0.861	0.04	18
LBY142	93199.1	0.0367	0.14	20	1.81	0.18	19	—	—	—
LBY142	93203.4	—	—	—	2.06	0.02	35	0.796	0.27	9
CONT.	—	0.0306	—	—	1.52	—	—	0.730	—	—
LBY41	91621.1	0.0379	0.04	15	1.90	0.06	21	—	—	—
LBY41	91621.2	—	—	—	1.79	0.26	13	0.875	0.14	8
LBY41	91623.1	—	—	—	1.81	0.17	15	—	—	—
LBY41	91623.2	—	—	—	1.95	0.06	24	0.919	L	14
LBY173	91652.1	—	—	—	2.28	L	45	0.920	0.01	14
LBY173	91652.5	—	—	—	2.34	L	49	0.930	0.02	15
LBY173	91653.1	—	—	—	—	—	—	0.871	0.21	8
LBY166	91542.5	—	—	—	1.89	0.10	20	0.912	0.02	13
LBY166	91544.3	—	—	—	—	—	—	0.862	0.26	6
LBY166	91544.4	—	—	—	—	—	—	0.876	0.12	8
LBY166	91544.5	—	—	—	1.98	0.04	26	0.967	L	19
CONT.	—	0.0329	—	—	1.57	—	—	0.810	—	—
LBY85	92064.1	0.0389	0.05	19	—	—	—	—	—	—
LBY85	92066.2	0.0374	0.14	14	—	—	—	—	—	—
LBY85	92066.3	0.0362	0.23	11	2.28	L	22	—	—	—
LBY85	92066.5	0.0404	L	24	—	—	—	—	—	—
LBY85	92068.3	—	—	—	2.03	0.25	8	—	—	—
LBY64	91340.4	0.0392	0.03	20	—	—	—	—	—	—
LBY64	91342.2	0.0395	0.02	21	—	—	—	—	—	—
LBY64	91342.3	0.0366	0.17	12	—	—	—	—	—	—
LBY64	91342.6	0.0372	0.11	14	—	—	—	—	—	—
LBY46	92200.3	—	—	—	2.07	0.17	11	—	—	—
LBY46	92201.2	0.0378	0.09	16	—	—	—	—	—	—
LBY46	92201.4	0.0382	0.07	17	2.19	0.06	17	—	—	—
LBY46	92202.1	—	—	—	—	—	—	0.850	0.23	7
LBY207	92155.1	0.0386	0.06	18	2.05	0.22	9	—	—	—
LBY207	92157.3	—	—	—	2.14	0.08	14	—	—	—
LBY207	92158.2	0.0413	0.03	26	2.07	0.19	10	—	—	—
LBY185	91497.1	—	—	—	2.07	0.22	11	—	—	—
LBY185	91497.2	—	—	—	2.28	L	22	—	—	—
LBY185	91498.2	0.0390	0.04	20	—	—	—	0.854	0.20	8
LBY185	91499.2	0.0368	0.27	13	2.06	0.27	10	—	—	—
LBY17	92216.2	0.0397	0.05	22	—	—	—	—	—	—
LBY155	92015.1	0.0406	0.02	24	—	—	—	—	—	—
LBY155	92016.4	0.0397	0.03	21	—	—	—	—	—	—
LBY155	92016.5	0.0377	0.14	16	—	—	—	—	—	—
LBY155	92016.7	0.0383	0.05	17	2.05	0.24	9	—	—	—
LBY122	91370.2	0.0396	0.02	21	2.01	0.27	7	—	—	—
LBY122	91371.2	0.0368	0.22	13	—	—	—	—	—	—
LBY122	91371.6	0.0382	0.14	17	2.13	0.07	14	—	—	—
LBY122	91374.1	0.0402	0.01	23	2.16	0.04	15	—	—	—
CONT.	—	0.0327	—	—	1.87	—	—	0.792	—	—
LBY50	91318.2	0.0400	0.09	18	—	—	—	—	—	—
LBY24	91220.6	—	—	—	2.11	0.04	16	0.795	0.25	12
LBY24	91221.1	0.0377	0.25	11	—	—	—	—	—	—
LBY24	91221.2	0.0404	0.12	19	2.30	L	27	—	—	—
LBY24	91223.3	0.0404	0.06	19	—	—	—	—	—	—
LBY21	90977.1	0.0374	0.25	10	—	—	—	—	—	—
LBY21	90978.4	0.0384	0.18	13	—	—	—	—	—	—
LBY21	90980.1	—	—	—	2.00	0.21	10	—	—	—
LBY161	91292.1	0.0412	0.02	22	2.01	0.24	11	—	—	—
LBY161	91292.3	—	—	—	1.97	0.27	9	0.791	0.23	11
LBY161	91293.3	—	—	—	2.22	0.02	22	—	—	—
LBY152	91286.1	0.0397	0.06	17	—	—	—	—	—	—
LBY152	91287.1	0.0404	0.04	19	—	—	—	—	—	—
LBY152	91289.2	0.0378	0.24	12	—	—	—	—	—	—
LBY15	91143.4	—	—	—	—	—	—	0.790	0.22	11
LBY15	91144.2	0.0378	0.27	12	2.16	0.03	19	—	—	—
LBY15	91144.3	—	—	—	2.04	0.13	12	—	—	—
LBY123	91428.2	—	—	—	2.15	0.03	18	0.782	0.29	10
LBY123	91429.2	—	—	—	2.15	0.04	19	—	—	—
LBY123	91429.3	—	—	—	2.13	0.07	17	—	—	—
LBY123	91429.6	—	—	—	2.24	0.02	23	—	—	—
LBY114	91391.1	—	—	—	—	—	—	0.783	0.22	10
LBY114	91391.2	0.0389	0.14	15	—	—	—	—	—	—
LBY114	91393.1	—	—	—	2.23	0.03	23	0.845	0.03	19
LBY114	91393.2	—	—	—	2.02	0.24	11	0.827	0.10	16
CONT.	—	0.0338	—	—	1.82	—	—	0.711	—	—
LBY80	92269.2	—	—	—	1.51	0.28	9	—	—	—
LBY80	92269.4	—	—	—	1.72	0.07	24	—	—	—
LBY80	92270.1	0.0356	0.26	9	1.74	L	25	—	—	—
LBY78	92311.3	0.0380	0.08	16	1.53	0.30	11	0.785	0.23	8
LBY78	92313.5	—	—	—	1.77	L	28	—	—	—
LBY53	92414.1	—	—	—	1.61	0.07	16	—	—	—
LBY53	92418.1	0.0366	0.12	12	1.52	0.25	10	—	—	—
LBY153	92249.2	—	—	—	1.59	0.06	15	—	—	—
LBY153	92252.2	—	—	—	1.63	0.09	18	0.799	0.23	10
LBY149	92246.3	—	—	—	1.94	L	40	0.847	0.02	16
LBY121	92291.2	—	—	—	1.64	0.05	18	—	—	—
LBY121	92291.4	—	—	—	1.65	0.19	19	—	—	—
LBY121	92293.2	—	—	—	—	—	—	0.781	0.22	7
CONT.	—	0.0327	—	—	1.39	—	—	0.728	—	—
LBY76	92642.1	—	—	—	1.99	0.29	15	—	—	—
LBY70	92684.2	—	—	—	2.08	0.17	19	—	—	—
LBY70	92685.5	0.0375	0.18	15	2.13	0.13	23	—	—	—
LBY159	92150.4	—	—	—	—	—	—	0.862	0.12	13
LBY159	92152.1	—	—	—	1.98	0.28	14	—	—	—
LBY159	92153.1	—	—	—	2.06	0.21	19	—	—	—
LBY156	92294.1	—	—	—	—	—	—	0.838	0.24	10
LBY145	92605.1	0.0365	0.28	12	—	—	—	—	—	—
LBY145	92606.2	0.0364	0.23	12	2.05	0.18	18	—	—	—
CONT.	—	0.0325	—	—	1.74	—	—	0.762	—	—
LBY92	93921.2	—	—	—	4.54	L	142	0.973	0.01	21
LBY92	93923.3	—	—	—	4.35	L	132	0.877	0.24	9
LBY6	94110.2	—	—	—	2.21	0.18	18	—	—	—
LBY20	94084.1	—	—	—	2.30	0.13	23	0.880	0.23	10
LBY20	94085.1	—	—	—	2.15	0.28	15	0.904	0.10	13
LBY148	93765.1	—	—	—	2.10	0.26	12	—	—	—
LBY148	93768.1	0.0391	0.30	13	—	—	—	—	—	—
LBY106_H3	93916.1	—	—	—	2.10	0.30	12	—	—	—
LBY106_H3	93918.1	—	—	—	2.21	0.17	18	0.905	0.11	13
CONT.	—	0.0347	—	—	1.87	—	—	0.803	—	—
LBY50	91317.3	0.0387	0.21	10	1.92	0.10	19	0.803	0.27	9
LBY50	91318.4	0.0376	0.29	7	—	—	—	—	—	—
LBY24	91221.2	—	—	—	2.04	0.04	26	—	—	—
LBY21	90979.2	—	—	—	—	—	—	0.804	0.25	9
LBY21	90980.1	—	—	—	1.92	0.18	19	—	—	—
LBY161	91294.1	0.0379	0.26	7	—	—	—	0.804	0.24	9
LBY15	91144.1	—	—	—	1.81	0.30	12	—	—	—
LBY15	91144.2	—	—	—	—	—	—	0.830	0.10	12
CONT.	—	0.0353	—	—	1.61	—	—	0.738	—	—
LBY53	92416.1	—	—	—	2.00	0.12	18	0.841	0.06	10
LBY53	92418.1	—	—	—	1.97	0.13	17	—	—	—
LBY31	92344.1	—	—	—	1.92	0.20	14	—	—	—
LBY31	92344.2	—	—	—	2.11	0.03	24	—	—	—
LBY31	92347.1	—	—	—	1.88	0.28	11	—	—	—
LBY208	92358.1	0.0397	0.15	13	—	—	—	—	—	—
LBY207	92154.1	—	—	—	2.03	0.13	20	0.844	0.14	10
LBY207	92155.1	—	—	—	1.91	0.15	13	—	—	—
LBY207	92157.3	—	—	—	2.28	L	35	—	—	—
LBY207	92158.2	0.0382	0.29	9	—	—	—	—	—	—
LBY175	92179.1	—	—	—	2.07	0.07	22	0.819	0.17	7
LBY175	92181.3	—	—	—	2.13	0.03	26	—	—	—
LBY175	92181.4	—	—	—	2.00	0.09	18	0.835	0.09	9
LBY140	92265.2	0.0381	0.28	9	1.96	0.10	16	—	—	—
LBY140	92265.5	—	—	—	1.93	0.19	14	—	—	—
LBY140	92266.3	—	—	—	2.03	0.06	20	—	—	—
LBY116	92136.1	—	—	—	2.00	0.09	18	0.809	0.28	6
LBY116	92136.3	—	—	—	2.13	0.03	26	0.853	0.05	11
LBY116	92136.4	—	—	—	2.23	0.03	32	0.920	L	20
LBY116	92138.6	—	—	—	1.91	0.25	13	—	—	—
CONT.	—	0.0351	—	—	1.69	—	—	0.766	—	—
LBY181	92479.3	—	—	—	1.86	L	35	0.797	0.02	12
LBY167	92770.4	—	—	—	1.73	0.06	26	—	—	—
LBY167	92772.2	—	—	—	1.56	0.28	13	—	—	—
LBY167	92773.1	—	—	—	1.68	0.08	22	0.766	0.10	8
LBY167	92773.4	—	—	—	1.55	0.28	12	—	—	—
LBY157	92802.2	—	—	—	1.74	0.02	26	0.750	0.21	6
LBY157	92802.3	—	—	—	2.14	L	55	—	—	—
LBY157	92803.1	—	—	—	1.75	0.02	27	0.759	0.11	7
LBY157	92803.2	—	—	—	1.82	0.02	32	0.754	0.27	6
CONT.	—	—	—	—	1.38	—	—	0.709	—	—
LBY41	91620.4	—	—	—	2.29	0.05	18	—	—	—
LBY41	91621.2	—	—	—	2.32	0.05	19	0.854	0.07	15
LBY186	91655.4	—	—	—	2.26	0.07	16	0.811	0.25	10
LBY186	91657.1	—	—	—	2.32	0.04	19	0.846	0.12	14
LBY186	91659.1	—	—	—	2.27	0.07	17	0.816	0.27	10
LBY186	91659.3	—	—	—	2.41	0.01	24	0.830	0.20	12
LBY186	91659.4	—	—	—	—	—	—	0.878	0.03	19
LBY166	91542.4	—	—	—	—	—	—	0.876	0.03	18
LBY166	91542.5	—	—	—	—	—	—	0.853	0.07	15
LBY166	91544.3	—	—	—	—	—	—	0.886	0.02	20
LBY166	91544.4	—	—	—	—	—	—	0.879	0.03	19
LBY166	91544.5	—	—	—	—	—	—	0.953	L	29
CONT.	—	—	—	—	1.94	—	—	0.740	—	—
LBY85	92066.2	0.0347	0.10	10	—	—	—	0.805	0.25	8
LBY85	92066.3	—	—	—	1.93	0.23	15	0.824	0.15	10
LBY85	92066.5	—	—	—	2.03	0.07	21	—	—	—
LBY64	91340.4	—	—	—	—	—	—	0.811	0.22	8
LBY64	91342.3	0.0342	0.17	9	—	—	—	—	—	—
LBY46	92200.3	—	—	—	1.91	0.26	14	—	—	—
LBY46	92201.2	—	—	—	2.17	0.01	30	0.821	0.14	10
LBY46	92201.4	—	—	—	2.20	0.01	31	0.836	0.11	12
LBY17	92215.4	—	—	—	—	—	—	0.820	0.14	10
LBY17	92216.3	—	—	—	1.95	0.16	16	—	—	—
LBY17	92216.4	—	—	—	1.91	0.25	14	0.805	0.28	8
LBY155	92014.2	—	—	—	—	—	—	0.808	0.22	8
LBY155	92015.1	0.0355	0.07	13	—	—	—	0.804	0.27	7
LBY122	91371.2	0.0343	0.19	9	1.87	0.27	12	—	—	—
LBY122	91371.3	—	—	—	1.90	0.22	13	0.832	0.09	11
LBY122	91371.4	0.0346	0.15	10	—	—	—	—	—	—
LBY122	91371.6	—	—	—	1.96	0.16	17	—	—	—
LBY122	91374.1	—	—	—	1.90	0.24	13	0.839	0.07	12
CONT.	—	0.0315	—	—	1.68	—	—	0.748	—	—

Table 272. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”—p-value. L—p<0.01.

Results from T1 Plants

Tables 273-275 summarize the observed phenotypes of transgenic plants expressing the gene constructs using the TC-T1 Assays (seedling analysis of T1 plants).

The genes presented in Tables 273-275 showed a significant improvement in plant biomass and root development since they produced a higher biomass (dry weight. Table 273), a larger leaf and root biomass (leaf area, root length and root coverage) (Table 274), and a higher relative growth rate of leaf area, and root coverage (Table 275) when grown under normal growth conditions, compared to control plants grown under identical growth conditions. Plants producing larger root biomass have better possibilities to absorb larger amount of nitrogen from soil. Plants producing larger leaf biomass have better ability to produce assimilates. The genes were cloned under the regulation of a constitutive promoter (At6669; SEQ ID NO: 10654). The evaluation of each gene was performed by testing the performance of different number of events. Some of the genes were evaluated in more than one seedling assay. This second experiment confirmed the significant increment in leaf and root performance. Event with p-value<0.1 was considered statistically significant.

TABLE 273
Genes showing improved plant performance at Normal
growth conditions under regulation of At6669 promoter
Gene	Dry Weight [mg]	Fresh Weight [mg]
Name	Ave.	P-Val.	% Incr.	Ave.	P-Val.	% Incr.
LBY92	12.1	0.02	61	238.5	0.03	39
LBY20	9.92	L	31	—	—	—
CONT.	7.56	—	—	171.3	—	—
LBY86	—	—	—	138.1	0.14	17
LBY170	9.18	0.17	11	131.9	0.24	12
CONT.	8.26	—	—	117.7	—	—
LBY92	12.2	0.15	26	231.9	0.10	37
LBY92	12.6	0.04	31	212.5	0.10	25
LBY92	14.3	L	48	262.3	L	55
CONT.	9.66	—	—	169.8	—	—

Table 273. “CONT.”=Control; “Ave.”=Average; “% Incr.”=% increment; “p-val.”=p-value, L=p<0.01.

TABLE 274
Genes showing improved plant performance at Normal
growth conditions under regulation of At6669 promoter
		Roots
	Leaf Area [cm2]	Coverage [cm2]	Roots Length [cm]
Gene			%			%			%
Name	Ave.	P-Val.	Incr.	Ave.	P-Val.	Incr.	Ave.	P-Val.	Incr.
LBY4	—	—	—	11.3	0.21	15	—	—	—
CONT.	—	—	—	9.88	—	—	—	—	—
LBY92	1.10	0.02	48	17.4	0.01	143	7.47	0.10	9
LBY6	—	—	—	8.76	0.11	22	—	—	—
LBY216	0.868	0.24	16	10.1	0.05	41	7.84	0.02	15
LBY20	0.870	L	16	9.37	0.04	31	—	—	—
LBY106_H3	—	—	—	9.55	0.02	33	7.76	L	13
CONT.	0.748	—	—	7.17	—	—	6.84	—	—
LBY3	—	—	—	10.6	0.20	11	—	—	—
CONT.	—	—	—	9.49	—	—	—	—	—
LBY92	0.973	0.09	19	19.6	0.02	87	8.09	0.22	6
LBY92	1.05	L	28	16.1	L	53	—	—	—
LBY92	1.16	L	42	20.2	L	92	8.37	0.05	10
CONT.	0.818	—	—	10.5	—	—	7.61	—	—
LGN62_H2	0.847	L	48	11.6	L	53	7.76	0.26	6
CONT.	0.574	—	—	7.57	—	—	7.34	—	—

Table 274. “CONT.”=Control; “Ave.”=Average; “% Incr.”=% increment; “p-val.”=p-value, L=p<0.01.

TABLE 275
Genes showing improved plant performance at Normal growth conditions under
regulation of At6669 promoter
		RGR Of
	RGR Of Leaf Area	Roots Coverage	RGR Of Root Length
Gene			%			%			%
Name	Ave.	P-Val.	Incr.	Ave.	P-Val.	Incr.	Ave.	P-Val.	Incr.
LBY4	0.103	0.27	11	1.39	0.19	16	—	—	—
CONT.	0.0928	—	—	1.19	—	—	—	—	—
LBY92	0.116	L	62	2.14	L	148	0.795	0.07	12
LBY6	—	—	—	1.07	0.07	24	—	—	—
LBY216	0.0890	0.05	24	1.21	L	41	0.826	0.02	17
LBY20	0.0888	L	23	1.14	0.02	32	0.760	0.25	8
LBY106_H3	—	—	—	1.15	0.01	33	0.801	0.04	13
CONT.	0.0720	—	—	0.863	—	—	0.707	—	—
LBY3	—	—	—	1.27	0.24	13	—	—	—
CONT.	—	—	—	1.13	—	—	—	—	—
LBY92	0.0980	0.21	15	2.41	L	88	0.849	0.25	12
LBY92	0.106	0.04	24	1.97	L	54	—	—	—
LBY92	0.121	L	41	2.48	L	94	0.879	0.11	16
CONT.	0.0855	—	—	1.28	—	—	0.755	—	—
LGN62_H2	0.0847	L	48	1.41	L	55	0.798	0.06	12
CONT.	0.0573	—	—	0.909	—	—	0.711	—	—

Table 275. “CONT.”—Control; “Ave.”—Average; “% Incr.”=% increment; “p-val.”=p-value, L=p<0.01.

Example 32

Evaluation of Transgenic Brachypodium Nue and Yield Under Low or Normal Nitrogen Fertilization in Greenhouse Assay

Assay 1: Nitrogen Use efficiency measured plant biomass and yield at limited and optimal nitrogen concentration under greenhouse conditions until heading—This assay follows the plant biomass formation and growth (measured by height) of plants which are grown in the greenhouse at limiting and non-limiting (e.g., normal) nitrogen growth conditions. Transgenic Brachypodium seeds are sown in peat plugs. The T, transgenic seedlings are then transplanted to 27.8×11.8×8.5 cm trays filled with peat and perlite in a 1:1 ratio. The trays are irrigated with a solution containing nitrogen limiting conditions, which are achieved by irrigating the plants with a solution containing 3 mM inorganic nitrogen in the form of NH₄NO₃, supplemented with 1 mM KH₂PO₄. 1 mM MgSO₄. 3.6 mM KCl, 2 mM CaCl₂ and microelements, while normal nitrogen levels are achieved by applying a solution of 6 mM inorganic nitrogen also in the form of NH₄NO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄, 2 mM CaCl₂. 3.6 mM KCl and microelements. All plants are grown in the greenhouse until heading. Plant biomass (the above ground tissue) is weighted right after harvesting the shoots (plant fresh weight [FW]). Following, plants are dried in an oven at 70° C. for 48 hours and weighed (plant dry weight [DW]).

Each construct is validated at its T₁ generation. Transgenic plants transformed with a construct conformed by an empty vector carrying the BASTA selectable marker are used as control (FIG. 9B) or with a construct conformed by an empty vector carrying the BASTA and Hygromycin selectable marker (FIG. 13, pQ6sN)).

The plants are analyzed for their overall size, fresh weight and dry matter. Transgenic plants performance is compared to control plants grown in parallel under the same conditions. Mock-transgenic plants with no gene and no promoter at all, are used as control (e.g., FIGS. 9B and 13).

The experiment is planned in blocks and nested randomized plot distribution within them. For each gene of the invention five independent transformation events are analyzed from each construct.

Phenotyping

Plant Fresh and Dry shoot weight—In Heading assays when heading stage has completed (about day 30 from sowing), the plants are harvested and directly weighed for the determination of the plant fresh weight on semi-analytical scales (0.01 gr) (FW) and left to dry at 70° C. in a drying chamber for about 48 hours before weighting to determine plant dry weight (DW).

Time to Heading—In both Seed Maturation and Heading assays heading is defined as the full appearance of the first spikelet in the plant. The time to heading occurrence is defined by the date the heading is completely visible. The time to heading occurrence date is documented for all plants and then the time from planting to heading was calculated. It should be noted that a negative increment (in percentages) when found in time to heading indicates potential for drought avoidance.

Leaf thickness—In Heading assays when minimum 5 plants per plot in at least 90% of the plots in an experiment have been documented at heading, measurement of leaf thickness is performed using a micro-meter on the second leaf below the flag leaf.

Plant Height—In both Seed Maturation and Heading assays once heading is completely visible, the height of the first spikelet is measured from soil level to the bottom of the spikelet.

Tillers number—In Heading assays manual count of tillers is preformed per plant after harvest, before weighing.

These results demonstrate that the polynucleotides of the invention are capable of improving yield and additional valuable important agricultural traits such as increase of biomass, abiotic stress tolerance, nitrogen use efficiency, yield, vigor, fiber yield and/or quality. Thus, transformed plants showing improved fresh and dry weight demonstrate the gene capacity to improve biomass, a key trait of crops for forage and plant productivity; transformed plants showing improvement of seed yield demonstrate the genes capacity to improve plant productivity; transformed plants showing improvement of plot coverage and rosette diameter demonstrate the genes capacity to improve plant drought resistance as they reduce the loss of soil water by simple evaporation and reduce the competition with weeds; hence reduce the need to use herbicides to control weeds. Transformed plants showing improvement of relative growth rate of various organs (leaf and root) demonstrate the gene capacity to promote plant growth and hence shortening the needed growth period and/or alternatively improving the utilization of available nutrients and water leading to increase of land productivity; Transformed plants showing improvement of organ number, as demonstrated by the leaf number parameter, exhibit a potential to improve biomass and yield important for forage and plant productivity; Transformed plants showing increased root length and coverage demonstrate the gene capacity to improve drought resistance and better utilization of fertilizers as the roots can reach larger soil volume; Transformed plants showing improvement of leaf petiole relative area and leaf blade area demonstrate the genes capacity to cope with limited light intensities results from increasing the plant population densities and hence improve land productivity.

Example 33

Evaluation of Transgenic Brachypodium Nue and Yield Under Low or Normal Nitrogen Fertilization in Greenhouse Assay

Assay 2: Nitrogen Use efficiency measured plant biomass and yield at limited and optimal nitrogen concentration under greenhouse conditions until Seed Maturation—This assay follows the plant biomass and yield production of plants that were grown in the greenhouse at limiting and non-limiting nitrogen growth conditions. Transgenic Brachypodium seeds are sown in peat plugs. The T₁ transgenic seedlings are then transplanted to 27.8×11.8×8.5 cm trays filled with peat and perlite in a 1:1 ratio. The trays are irrigated with a solution containing nitrogen limiting conditions, which are achieved by irrigating the plants with a solution containing 3 mM inorganic nitrogen in the form of NH₄NO₃, supplemented with 1 mM KH₂PO₄. 1 mM MgSO₄. 3.6 mM KCl, 2 mM CaCl₂ and microelements, while normal nitrogen levels are achieved by applying a solution of 6 mM inorganic nitrogen also in the form of NH₄NO₃ with 1 mM KH₂PO₄, 1 mM MgSO₄, 2 mM CaCl₂, 3.6 mM KCl and microelements. All plants are grown in the greenhouse until seed maturation. Each construct is validated at its T₁ generation. Transgenic plants transformed with a construct conformed by an empty vector carrying the BASTA selectable marker are used as control (FIG. 9B) or with a construct conformed by an empty vector carrying the BASTA and Hygromycin selectable marker (FIG. 13).

The plants are analyzed for their overall biomass, fresh weight and dry matter, as well as a large number of yield and yield components related parameters. Transgenic plants performance is compared to control plants grown in parallel under the same conditions. Mock-transgenic plants are with no gene and no promoter at all. The experiment is planned in blocks and nested randomized plot distribution within them. For each gene of the invention five independent transformation events are analyzed from each construct.

Phenotyping

Plant Fresh and Dry vegetative weight—In Seed Maturation assays when maturity stage has completed (about day 80 from sowing), the plants are harvested and directly weighed for the determination of the plant fresh weight (FW) and left to dry at 70° C. in a drying chamber for about 48 hours before weighting to determine plant dry weight (DW).

Spikelets Dry weight (SDW)—In Seed Maturation assays when maturity stage has completed (about day 80 from sowing), the spikelets are separated from the biomass, left to dry at 70° C. in a drying chamber for about 48 hours before weighting to determine spikelets dry weight (SDW).

Grain Yield per Plant—In Seed Maturation assays after drying of spikelets for SDW, spikelets are run through production machine, then through cleaning machine, until seeds are produced per plot, then weighed and Grain Yield per Plant is calculated.

Grain Number—In Seed Maturation assays after seeds per plot are produced and cleaned, the seeds are run through a counting machine and counted.

1000 Seed Weight—In Seed Maturation assays after seed production, a fraction is taken from each sample (seeds per plot; ˜0.5 gr), counted and photographed. 1000 seed weight is calculated.

Harvest Index—In Seed Maturation assays after seed production, harvest index is calculated by dividing grain yield and vegetative dry weight.

Time to Heading—In both Seed Maturation and Heading assays heading is defined as the full appearance of the first spikelet in the plant. The time to heading occurrence is defined by the date the heading is completely visible. The time to heading occurrence date is documented for all plants and then the time from planting to heading was calculated.

Leaf thickness—In Heading assays when minimum 5 plants per plot in at least 90% of the plots in an experiment have been documented at heading, measurement of leaf thickness is performed using a micro-meter on the second leaf below the flag leaf.

Grain filling period—In Seed Maturation assays maturation is defined by the first color-break of spikelet+stem on the plant, from green to yellow/brown.

Plant Height—In both Seed Maturation and Heading assays once heading is completely visible, the height of the first spikelet is measured from soil level to the bottom of the spikelet.

Tillers number—In Heading assays manual count of tillers is preformed per plant after harvest, before weighing.

Number of reproductive heads per plant—In Heading assays manual count of heads per plant is performed.

Statistical analyses—To identify genes conferring significantly improved tolerance to abiotic stresses, the results obtained from the transgenic plants are compared to those obtained from control plants. To identify outperforming genes and constructs, results from the independent transformation events tested are analyzed separately. Data is analyzed using Student's t-test and results are considered significant if the p value is less than 0.1. The JMP statistics software package was used (Version 5.2.1, SAS Institute Inc., Cary, N.C., USA).

Although the invention has been described in conjunction with specific embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, it is intended to embrace all such alternatives, modifications and variations that fall within the spirit and broad scope of the appended claims.

All publications, patents and patent applications mentioned in this specification are herein incorporated in their entirety by reference into the specification, to the same extent as if each individual publication, patent or patent application was specifically and individually indicated to be incorporated herein by reference. In addition, citation or identification of any reference in this application shall not be construed as an admission that such reference is available as prior art to the present invention. To the extent that section headings are used, they should not be construed as necessarily limiting.

LENGTHY TABLES
The patent application contains a lengthy table section. A copy of the table is available in electronic form from the USPTO web site (). An electronic copy of the table will also be available from the USPTO upon request and payment of the fee set forth in 37 CFR 1.19(b)(3).

Claims

1. A method of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant, comprising over-expressing within the plant, a polypeptide comprising an amino acid sequence at least 80% identical to SEQ ID NO: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629, thereby increasing the yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of the plant.

2. The method of claim 1, wherein said polypeptide is selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

3. A method of producing a crop comprising growing a crop plant over-expressing a polypeptide comprising an amino acid sequence at least 80% homologous to the amino acid sequence selected from the group consisting of SEQ ID NOs: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629, wherein the crop plant is derived from plants which over-express said polypeptide and which have been selected for increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and/or increased abiotic stress tolerance as compared to a wild type plant of the same species which is grown under the same growth conditions, and the crop plant having the increased yield, increased growth rate, increased biomass, increased vigor, increased oil content, increased seed yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, increased nitrogen use efficiency, and/or increased abiotic stress tolerance, thereby producing the crop.

4-6. (canceled)

7. A nucleic acid construct comprising an isolated polynucleotide comprising a nucleic acid sequence encoding a polypeptide which comprises an amino acid sequence at least 80% homologous to the amino acid sequence set forth in SEQ ID NO: 552-633, 635-725, 727-773, 775-780, 782-786, 789-885, 887-889, 891-897, 6029-7467, 7481, 7487, 7498-7499, 7501-7503, 7512-7513, 7515, 7517, 7522, 7525, 7529, 7533-7534, 7539-7541, 7545, 7549, 7552, 7555-7556, 7558, 7563, 7576, 7579, 7588, 7590, 7592-7593, 7595, 7609-7612, 7614-7615, 7620, 7624, 7627, 7631, 7633, 7637, 7639, 7643-7644, 7647, 7649, 7651, 7653-7658, 7660, 7662, 7664, 7666, 7672-7673, 7677-7678, 7680-7681, 7683-7684, 7688-7690, 7692, 7694, 7699-7703, 7705-7706, 7709-7711, 7716-7719, 7721-7723, 7726-7732, 7736-7738, 7740-7742, 7745, 7747-7748, 7751, 7758, 7760-7762, 7765-7766, 7769, 7773, 7777-7781, 7783-7785, 7787-7789, 7791, 7795-7800, 7802-7811, 7813, 7815-8160, 8162, 8164-8853, 8855-9215, 9238-9749, 9751-9803, 9805-9818, 9828, 9935-9968, 9970-9971, 9973-10187, 10189, 10191-10585, 10600-10605, 10609-10628 or 10629 and a promoter for directing transcription of said nucleic acid sequence in a host cell, wherein said promoter is heterologous to said isolated polynucleotide, wherein said amino acid sequence is capable of increasing yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance of a plant.

8. The nucleic acid construct of claim 7, wherein said amino acid sequence is selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

9. The nucleic acid construct of claim 7, wherein said nucleic acid sequence, at least 80% identical to SEQ ID NOs: 1-82, 84-174, 176-222, 224-229, 231-235, 238-302, 304-387, 389-473, 475-519, 521-526, 528-532, 535-551, 898-2468, 2485, 2492-2493, 2495, 2507-2508, 2510-2512, 2523-2524, 2526, 2528, 2533, 2537, 2541, 2545-2546, 2551-2553, 2557, 2564, 2567, 2573-2574, 2576-2577, 2583, 2594, 2599, 2602, 2611, 2613-2614, 2616-2617, 2619, 2635-2638, 2640-2642, 2648, 2652, 2655, 2660, 2662, 2666, 2668, 2673-2674, 2677, 2679, 2681, 2683-2688, 2691, 2693, 2695-2698, 2700, 2707-2708, 2713-2714, 2716-2717, 2719-2720, 2724-2726, 2728, 2730-2731, 2736-2742, 2744-2746, 2751-2753, 2757, 2759-2762, 2764-2766, 2769-2776, 2780-2783, 2785-2788, 2791, 2793-2795, 2798, 2805, 2807-2808, 2812, 2814-2815, 2818-2820, 2823, 2829, 2834-2838, 2840-2842, 2844-2846, 2848, 2852-2858, 2860-2872, 2874, 2876-3244, 3246, 3248-4015, 4017-4426, 4449-5012, 5015-5071, 5073-5090, 5101, 5255, 5267-5304, 5306-5307, 5309-5539, 5541, 5543-5976, 5994-5999, 6003-6027 or 6028.

10. The nucleic acid construct of claim 7, wherein said nucleic acid sequence is selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

11-13. (canceled)

14. A plant cell transformed with the nucleic acid construct of claim 7.

15-16. (canceled)

17. The method of claim 3, wherein said polypeptide is encoded by a nucleic acid sequence selected from the group consisting of SEQ ID NOs: 1-551, 898-6027 and 6028.

18. (canceled)

19. The method of claim 3, wherein said amino acid sequence is selected from the group consisting of SEQ ID NOs: 552-773, 775-780, 782-786, 789-885, 887-897, 6029-7781, 7783-9818, 9820-9823, 9827-9828, 9840-9841, 9849, 9852-9854, 9856, 9858-9859, 9867, 9870, 9872, 9874-9875, 9881, 9883-9885, 9887, 9891, 9893, 9896, 9898-9902, 9904, 9906-9908, 9911, 9915, 9917, 9919, 9921-9922, 9924-9926, 9929, 9933-10585, 10589, 10593, 10599-10605, 10607-10628 and 10629.

20. The plant cell of claim 14, wherein said plant cell forms part of a plant.

21. The method of claim 1, further comprising growing the plant expressing said exogenous polynucleotide under the abiotic stress.

22. The method of claim 1, wherein said abiotic stress is selected from the group consisting of salinity, drought, osmotic stress, water deprivation, flood, etiolation, low temperature, high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency, nitrogen deficiency, nutrient excess, atmospheric pollution and UV irradiation.

23. The method claim 1, wherein the yield comprises seed yield or oil yield.

24. A transgenic plant comprising the nucleic acid construct of claim 7.

25. The method of claim 1, further comprising growing the plant expressing said exogenous polynucleotide under nitrogen-limiting conditions.

26. (canceled)

27. A method of growing a crop, the method comprising seeding seeds and/or planting plantlets of a plant transformed with the nucleic acid construct of claim 7, wherein the plant is derived from plants which have been transformed with said exogenous polynucleotide and which have been selected for at least one trait selected from the group consisting of: increased nitrogen use efficiency, increased abiotic stress tolerance, increased biomass, increased growth rate, increased vigor, increased yield, increased fiber yield, increased fiber quality, increased fiber length, increased photosynthetic capacity, and increased oil content as compared to a non-transformed plant which is grown under the same growth conditions, thereby growing the crop.

28-30. (canceled)

31. The method of claim 1, further comprising selecting a plant having an increased yield, growth rate, biomass, vigor, oil content, seed yield, fiber yield, fiber quality, fiber length, photosynthetic capacity, nitrogen use efficiency, and/or abiotic stress tolerance as compared to the wild type plant of the same species which is grown under the same growth conditions.

32-33. (canceled)

34. The method of claim 31, wherein said selecting is performed under non-stress conditions.

35. The method of claim 31, wherein said selecting is performed under abiotic stress conditions.