ISOLATED POLYNUCLEOTIDES EXPRESSING OR MODULATING MICRORNAS OR TARGETS OF SAME, TRANSGENIC PLANTS COMPRISING SAME AND USES THEREOF

Disclosed are isolated polynucleotides expressing or modulating microRNAs or targets. Further disclosed are transgenic plants comprising an isolated polynucleotide expressing or modulating microRNAs or target for improving nitrogen use efficiency, abiotic stress tolerance, biomass, vigor or yield of a plant. The sequences of microRNAs and targets to be modulated are also disclosed.

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Description
RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 14/376,879, filed Aug. 6, 2014, which is a U.S. National Phase of International Application No. PCT/IL2013/050112, filed Feb. 6, 2013, which claims the benefit of U.S. Provisional Application No. 61/595,213, filed Feb. 6, 2012, all of which are incorporated herein by reference in their entireties.

SEQUENCE LISTING STATEMENT

The ASCII file, entitled, Sequence Listing P34395US02.TXT, created on Nov. 30, 2018 comprising 18,694,144 bytes, submitted concurrently with the filing of this application is incorporated herein by reference.

FIELD AND BACKGROUND OF THE INVENTION

The present invention, in some embodiments thereof, relates to isolated polynucleotides expressing or modulating microRNAs or targets of same, transgenic plants comprising same and uses thereof in improving nitrogen use efficiency, abiotic stress tolerance, biomass, vigor or yield of a plant.

Consumption of soybean for food production is increasing worldwide because of its reported beneficial health effects. Soybean is also viewed as an attractive crop for the production of biodiesel. Importantly, it has the ability to fix atmospheric nitrogen, which in turn may cut the input of nitrogen fertilizer that often accounts for the single largest energy input in agriculture.

With a growing world population, increasing demand for food, fuel and fiber, and a changing climate, agriculture faces unprecedented challenges. In general, shortage in water supply is one of the most severe global agricultural problems affecting plant growth and crop yield. Excessive efforts are made to alleviate the harmful effects of desertification of the world's arable land. Farmers are seeking advanced, biotechnology-based solutions to enable them to obtain stable high yields and give them the potential to reduce irrigation costs or to grow crops in areas where potable water is a limiting factor. It should be noted that improved abiotic stress (ABST) tolerance will confer plants with improved vigor also under non-stress conditions, resulting in crops having improved biomass and/or yield.

ABST is a collective term for numerous extreme environmental parameters such as drought, high or low salinity, high or low temperature/light, and nutrient imbalances. The major agricultural crops (corn, rice, wheat, canola and soybean) account for over half of total human caloric intake, giving their overall yield and quality vast importance. ABST causes more than 50% yield loss of the above mentioned major crops. Among the various ABSTs, drought is the major factor that limits crop productivity worldwide. Short-term conditions of reduced environmental water content typically occur during the life cycle of most crop plants. Although most plants have evolved strategies to survive these conditions, when the severity and duration of drought become too great, major alterations to the plant metabolism take place. As a result, the plant development, growth and yield profoundly diminish. Furthermore, drought is associated with increased susceptibility to various diseases. ABST-induced dehydration or osmotic stress, in the form of reduced availability of water and disruption of turgor pressure, cause irreversible cellular damage. A water-limiting environment at various plant developmental stages may activate various physiological changes.

In soybean, drought, for instance, reduces yield by approximately 40%, with the most critical period for water deprivation being the flowering stage and the period following flowering. Water deficit, salinity and low/high temperatures are stresses that cause plant cellular dehydration, due to transpiration rate that exceeds water uptake. Water use efficiency (WUE), defined as the amount of biomass accumulated per unit of water used, plays an important role in determining a plant's ability to tolerate drought stress. The higher the WUE of a plant, the higher the crop productivity and total biomass yield under drought conditions. Thus, efforts are made worldwide to increase the WUE of the most important crops and reach the best yield performance under extreme water deficiency conditions.

Studies have shown that plant adaptations to drought and other 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. However, generation of transgenic plants expressing full-length genes is typically hampered by the selection of optimal regulatory sequences and identification of those rare transformation events that exhibit sufficient levels of gene products expression.

SUMMARY OF THE INVENTION

According to an aspect of some embodiments of the present invention there is provided a method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11940-11955, 11959-11961, wherein the RNAi molecule regulates abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

According to an aspect of some embodiments of the present invention there is provided a method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957 or 11958, wherein the nucleic acid sequence is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

According to an aspect of some embodiments of the present invention there is provided a transgenic plant exogenously expressing a polynucleotide having a nucleic acid sequence at least 90% identical to SEQ ID NOs: SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957 or 11958, wherein the nucleic acid sequence is capable of regulating abiotic stress tolerance of the plant.

According to some embodiments of the invention, the exogenous polynucleotide encodes a precursor of the nucleic acid sequence.

According to some embodiments of the invention, the precursor of the nucleic acid sequence is at least 60% identical to SEQ ID NO: 174-201, 220-235, 256-259, 2087-3910, 3911, 11910-11939, 11615, 11956, 11957 or 11958.

According to some embodiments of the invention, the precursor of the nucleic acid sequence is at least 60% identical to SEQ ID NO: 174-201, 220-235, 256-259, 2087-3910, 3911, 11875-11904, 11910-11939, 11615, 11956, 11957 or 11958.

According to some embodiments of the invention, the exogenous polynucleotide encodes a mature miRNA.

According to some embodiments of the invention, the exogenous polynucleotide is selected from the group consisting of SEQ ID NO: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957 or 11958.

According to an aspect of some embodiments of the present invention there is provided a nucleic acid construct comprising a nucleic acid sequence being at least 90% identical to SEQ ID NO: 139, 1-201, 202-235, 236-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957, 11958, 11940-11955, 11905-11909, 11959-11961, wherein the nucleic acid sequence is capable of regulating abiotic stress tolerance of a plant and wherein the nucleic acid sequence is under the regulation of a cis-acting regulatory element.

According to some embodiments of the invention, the nucleic acid sequence is selected from the group consisting of SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957 or 11958.

According to some embodiments of the invention, the nucleic acid sequence is selected from the group consisting of SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11959-11961, 11940-11955.

According to an aspect of some embodiments of the present invention there is provided a transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278 11905-11909, 11940-11955, 11959-11961.

According to an aspect of some embodiments of the present invention there is provided a transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 139, 1-201, 202-235, 236-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957, 11958, 11905-11909, 11940-11955, 11959-11961.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence selected from the group consisting of SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11940-11955, 11959-11961.

According to an aspect of some embodiments of the present invention there is provided a transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11940-11955, 11959-11961.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence selected from the group consisting of SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11940-11955, 11959-11961.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence selected from the group consisting of SEQ ID NOs: 139, 1-201, 202-235, 236-3910, 3911, 3953-5114, 5117-6277, 6278, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957, 11958, 11905-11909, 11940-11955, 11959-11961.

According to an aspect of some embodiments of the present invention there is provided an isolated polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence selected from the group consisting of SEQ ID NOs: 139, 1-201, 202-235, 236-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957, 11958, 11905-11909, 11940-11955, 11959-11961.

According to some embodiments of the invention, the polynucleotide encodes a miRNA-Resistant Target as set forth in SEQ ID NO: 11258-11359.

According to some embodiments of the invention, the polynucleotide encodes a miRNA-Resistant Target as set forth in SEQ ID NO: 11091-11257.

According to some embodiments of the invention, the isolated polynucleotide encodes a target mimic as set forth in SEQ ID NO: 11564-11613.

According to some embodiments of the invention, the polynucleotide encodes a target mimic as set forth in SEQ ID NO: 11437-11513.

According to an aspect of some embodiments of the present invention there is provided a nucleic acid construct comprising the isolated polynucleotide under the regulation of a cis-acting regulatory element.

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

According to an aspect of some embodiments of the present invention there is provided a method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide encoding a polypeptide having an amino acid sequence at least 80% homologous or identical to SEQ ID NOs: 9591-10364, wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

According to an aspect of some embodiments of the present invention there is provided a transgenic plant exogenously expressing a polynucleotide encoding a polypeptide having an amino acid sequence at least 80% homologous or identical to SEQ ID NOs: 9591-10364, wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a nucleic acid construct comprising a polynucleotide encoding a polypeptide having an amino acid sequence at least 80% homologous to SEQ ID NOs: 9591-10364, wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant, and wherein the polynucleotide is under a transcriptional control of a cis-acting regulatory element.

According to some embodiments of the invention, the polynucleotide is selected from the group consisting of SEQ ID NO: 10365-10963.

According to some embodiments of the invention, the polypeptide is selected from the group consisting of SEQ ID NO: 9591-10364.

According to some embodiments of the invention, the cis-acting regulatory element comprises a promoter.

According to some embodiments of the invention, the promoter comprises a tissue-specific promoter.

According to some embodiments of the invention, the tissue-specific promoter comprises a root specific promoter.

According to some embodiments of the invention, the method further comprises growing the plant under limiting nitrogen conditions.

According to some embodiments of the invention, the method further comprises growing the plant under abiotic stress.

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

According to some embodiments of the invention, the plant is a monocotyledon.

According to some embodiments of the invention, the plant is a dicotyledon.

According to an aspect of some embodiments of the present invention there is provided a method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide which downregulates an activity or expression of a polypeptide having an amino acid sequence at least 80% homologous or identical to SEQ ID NOs: 6315-8129, wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

According to an aspect of some embodiments of the present invention there is provided a transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a polypeptide having an amino acid sequence at least 80% homologous or identical to SEQ ID NOs: 6315-8129, wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant.

According to an aspect of some embodiments of the present invention there is provided a nucleic acid construct comprising a polynucleotide which downregulates an activity or expression of a polypeptide having an amino acid sequence at least 80% homologous to SEQ ID NOs: 6315-8129, wherein the polypeptide is capable of regulating abiotic stress tolerance of a plant, the nucleic acid sequence being under the regulation of a cis-acting regulatory element.

According to some embodiments of the invention, the polynucleotide acts by a mechanism selected from the group consisting of sense suppression, antisense suppression, ribozyme inhibition, gene disruption.

According to some embodiments of the invention, the cis-acting regulatory element comprises a promoter.

According to some embodiments of the invention, the promoter comprises a tissue-specific promoter.

According to some embodiments of the invention, the tissue-specific promoter comprises a root specific promoter.

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 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 a plasmid map of the binary vector pORE-E1 used for plant transformation according to some embodiments of the invention.

FIG. 2 is a schematic illustration of a plasmid map of the binary vector pORE-E2 used for plant transformation according to some embodiments of the invention.

FIG. 3 is a schematic illustration of a plasmid map of the binary vector pORE-E3 used for plant transformation according to some embodiments of the invention.

DESCRIPTION OF SPECIFIC EMBODIMENTS OF THE INVENTION

The present invention, in some embodiments thereof, relates to isolated polynucleotides expressing or modulating microRNAs or targets of same, transgenic plants comprising same and uses thereof in improving nitrogen use efficiency, abiotic stress tolerance, biomass, vigor or yield 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.

Environmental stresses represent the most limiting factors for agricultural productivity. Apart from biotic stress caused by plant pathogens, there are a number of abiotic stresses such as extremes in temperature, drought, salinity, heavy metals and radiation which all have detrimental effects on plant growth and yield. Abiotic stresses lead to dehydration or osmotic stress through reduced availability of water for vital cellular functions and maintenance of turgor pressure. Stomata closure, reduced supply of CO2 and slower rate of biochemical reactions during prolonged periods of dehydration, high light intensity, high and low temperatures lead to high production of Reactive Oxygen Intermediates (ROI) in the chloroplasts causing irreversible cellular damage and photo inhibition.

Understanding the molecular mechanism for providing protection against biotic and abiotic stresses may lead to the identification of genes associated with stress tolerance. Optimum homeostasis is always a key to living organisms for adjusted environments.

While reducing the present invention to practice, the present inventors have uncovered dsRNA sequences that are differentially expressed in soy plants grown under abiotic stress conditions including, salt stress, heat stress and drought, versus soy plants grown under optimal conditions (see Example 1 of the Examples section which follows). Following extensive experimentation and screening, the present inventors have uncovered miRNA sequences that are upregulated or downregulated in leaf samples, and suggest using same or sequences controlling same in the generation of transgenic plants having improved abiotic stress tolerance.

Each of the above mechanisms may affect water uptake as well as salt absorption and therefore embodiments of the invention further relate to enhancement of abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

Example 5 of the Examples section below, validates the present results by showing that some miRs (e.g., gma-miR4376-5p, zma-miR396b-3p, aly-miR396b-3p, gma-miR156g, ma-miRf10687-akr-omolog gma-miR159d, aly-miR396b-3p, gma-miR4416a, aly-miR396a-3p, zma-miR396b-3p, gma-miR4412-3p, csi-miR162-5p, ath-miRf10279-akr) according to specific embodiment of the invention are indeed differentially expressed under abiotic stress conditions as was initially identified by microarray analysis. The present inventors were also capable of generating transgenic plants which overexpress the indicated miRs (see Example 7).

Thus, according to an aspect of the invention there is provided a method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide having a nucleic acid sequence at least 80%, 85%, 90% or 95% identical to SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 11616, 11615, 2087-3910, 3911, 11910-11939, 11874-11904, 11956, 11957 or 11958 wherein the nucleic acid sequence is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

According to a specific embodiment the exogenous polynucleotide has a nucleic acid sequence at least 90% identical to SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 11616, 11615, 2087-3910, 3911, 11910-11939, 11874-11904, 11956, 11957 or 11958.

According to a specific embodiment the exogenous polynucleotide has a nucleic acid sequence at least 95% identical to SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 11616, 11615, 2087-3910, 3911, 11910-11939, 11874-11904, 11956, 11957 or 11958.

According to a specific embodiment the exogenous polynucleotide has a nucleic acid sequence as set forth in SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 11616, 11615, 2087-3910, 3911, 11910-11939, 11874-11904, 11956, 11957 or 11958.

The phrase “abiotic stress” as used herein refers to any adverse effect on metabolism, growth, viability and/or reproduction of a plant. Abiotic stress can be induced by any of suboptimal environmental growth conditions such as, for example, water deficit or drought, flooding, freezing, low or high temperature, strong winds, heavy metal toxicity, anaerobiosis, high or low nutrient levels (e.g. nutrient deficiency), high or low salt levels (e.g. salinity), atmospheric pollution, high or low light intensities (e.g. insufficient light) or UV irradiation. Abiotic stress may be a short term effect (e.g. acute effect, e.g. lasting for about a week) or alternatively may be persistent (e.g. chronic effect, e.g. lasting for example 10 days or more). The present invention contemplates situations in which there is a single abiotic stress condition or alternatively situations in which two or more abiotic stresses occur.

According to an exemplary embodiment the abiotic stress refers to salinity.

According to another exemplary embodiment the abiotic stress refers to drought.

According to another exemplary embodiment the abiotic stress refers to a temperature stress.

As used herein the phrase “abiotic stress tolerance” refers to the ability of a plant to endure an abiotic stress without exhibiting substantial physiological or physical damage (e.g. alteration in metabolism, growth, viability and/or reproducibility of the plant).

As used herein the phrase “nitrogen use efficiency (NUE)” refers to a measure of crop production per unit of nitrogen fertilizer input. Fertilizer use efficiency (FUE) is a measure of NUE. Crop production can be measured by biomass, vigor or yield. The plant's nitrogen use efficiency is typically a result of an alteration in at least one of the uptake, spread, absorbance, accumulation, relocation (within the plant) and use of nitrogen absorbed by the plant. Improved NUE is with respect to that of a non-transgenic plant (i.e., lacking the transgene of the transgenic plant) of the same species and of the same developmental stage and grown under the same conditions.

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 optimal plant metabolism, growth, reproduction and/or viability.

As used herein the term/phrase “biomass”, “biomass of a plant” or “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. An increase in plant biomass can be in the whole plant or in parts thereof such as aboveground (e.g. harvestable) parts, vegetative biomass, roots and/or seeds or contents thereof (e.g., oil, starch etc.).

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

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

According to an exemplary embodiment the yield is measured by cellulose content, oil content, starch content and the like.

According to another exemplary embodiment the yield is measured by oil content.

According to another exemplary embodiment the yield is measured by protein content.

According to another exemplary embodiment, the yield is measured by seed number per plant or part thereof (e.g., kernel, bean).

A plant yield can be affected by various parameters including, but not limited to, plant biomass; plant vigor; plant 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 (e.g. florets) per panicle (e.g. 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 (e.g. density); number of harvested organs in field; total leaf area; carbon assimilation and carbon partitioning (e.g. 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 term “improving” or “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 25%, at least about 30%, at least about 35%, at least about 40%, at least about 45%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, at least about 90% or greater increase in NUE, in tolerance to abiotic stress, in yield, in biomass or in vigor of a plant, as compared to a native or wild-type plants [i.e., plants not genetically modified to express the biomolecules (polynucleotides) of the invention, e.g., a non-transformed plant of the same species or a transformed plant transformed with a control vector, either of which being of the same developmental stage and grown under the same growth conditions as the transformed plant].

Improved plant NUE 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.

The term “plant” as used herein encompasses whole plants, ancestors and progeny of the plants and plant parts, including seeds, shoots, stems, roots (including tubers), and isolated 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.

As used herein the phrase “plant cell” refers to plant cells which are derived and isolated from disintegrated plant cell tissue or plant cell cultures.

As used herein the phrase “plant cell culture” refers to any type of native (naturally occurring) plant cells, plant cell lines and genetically modified plant cells, which are not assembled to form a complete plant, such that at least one biological structure of a plant is not present. Optionally, the plant cell culture of this aspect of the present invention may comprise a particular type of a plant cell or a plurality of different types of plant cells. It should be noted that optionally plant cultures featuring a particular type of plant cell may be originally derived from a plurality of different types of such plant cells.

Any commercially or scientifically valuable plant is envisaged in accordance with some embodiments of the invention. Plants that are particularly useful in the methods of the invention include all plants which belong to the super family 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., Eucalyptus spp., Euclea schimperi, Eulalia vi/losa, Pagopyrum spp., Feijoa sellowlana, Fragaria spp., Flemingia spp, Freycinetia banksli, Geranium thunbergii, Ginkgo 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., Ornithopus 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 including, but not limited to, cotton, Brassica vegetables, oilseed rape, sesame, olive tree, palm oil, banana, wheat, corn or maize, barley, alfalfa, peanuts, sunflowers, rice, oats, sugarcane, soybean, turf grasses, barley, rye, sorghum, sugar cane, chicory, lettuce, tomato, zucchini, bell pepper, eggplant, cucumber, melon, watermelon, beans, hibiscus, okra, apple, rose, strawberry, chili, garlic, pea, lentil, canola, mums, arabidopsis, broccoli, cabbage, beet, quinoa, spinach, squash, onion, leek, tobacco, potato, sugarbeet, papaya, pineapple, mango, Arabidopsis thaliana, and also plants used in horticulture, floriculture or forestry, such as, but not limited to, poplar, fir, eucalyptus, pine, an ornamental plant, a perennial grass and a forage crop, coniferous plants, moss, algae, as well as other plants listed in World Wide Web (dot) nationmaster (dot) com/encyclopedia/Plantae.

According to a specific embodiment of the present invention, the plant comprises soy.

As used herein, the phrase “exogenous polynucleotide” refers to a heterologous nucleic acid sequence which may not be naturally expressed within the plant or which overexpression [i.e., expression above that found in the control non-transformed plant (e.g., wild type) grown under the same conditions and being of the same developmental stage] 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. It should be noted that the exogenous polynucleotide may comprise a nucleic acid sequence which is identical or partially identical (homologous) to an endogenous nucleic acid sequence of the plant.

As mentioned, the present teachings are based on the identification of miRNA sequences which regulate the tolerance of plants to abiotic stress.

According to some embodiments the exogenous polynucleotide encodes a miRNA or a precursor thereof.

As used herein, the phrase “microRNA (also referred to herein interchangeably as “miRNA” or “miR”) or a precursor thereof” refers to a microRNA (miRNA) molecule acting as a post-transcriptional regulator. Typically, the miRNA molecules are RNA molecules of about 20 to 22 nucleotides in length which can be loaded into a RISC complex and which direct the cleavage of another RNA molecule, wherein the other RNA molecule comprises a nucleotide sequence essentially complementary to the nucleotide sequence of the miRNA molecule.

Typically, a miRNA molecule is processed from a “pre-miRNA” or as used herein a precursor of a pre-miRNA molecule by proteins, such as DCL proteins, present in any plant cell and loaded onto a RISC complex where it can guide the cleavage of the target RNA molecules.

Pre-microRNA molecules are typically processed from pri-microRNA molecules (primary transcripts). The single stranded RNA segments flanking the pre-microRNA are important for processing of the pri-miRNA into the pre-miRNA. The cleavage site appears to be determined by the distance from the stem-ssRNA junction (Han et al. 2006, Cell 125, 887-901, 887-901).

As used herein, a “pre-miRNA” molecule is an RNA molecule of about 100 to about 200 nucleotides, preferably about 100 to about 130 nucleotides which can adopt a secondary structure comprising a double stranded RNA stem and a single stranded RNA loop (also referred to as “hairpin”) and further comprising the nucleotide sequence of the miRNA (and its complement sequence) in the double stranded RNA stem. According to a specific embodiment, the miRNA and its complement are located about 10 to about 20 nucleotides from the free ends of the miRNA double stranded RNA stem. The length and sequence of the single stranded loop region are not critical and may vary considerably, e.g. between 30 and 50 nt in length. The complementarity between the miRNA and its complement need not be perfect and about 1 to 3 bulges of unpaired nucleotides can be tolerated. The secondary structure adopted by an RNA molecule can be predicted by computer algorithms conventional in the art such as mFOLD. The particular strand of the double stranded RNA stem from the pre-miRNA which is released by DCL activity and loaded onto the RISC complex is determined by the degree of complementarity at the 5′ end, whereby the strand which at its 5′ end is the least involved in hydrogen bounding between the nucleotides of the different strands of the cleaved dsRNA stem is loaded onto the RISC complex and will determine the sequence specificity of the target RNA molecule degradation. However, if empirically the miRNA molecule from a particular synthetic pre-miRNA molecule is not functional (because the “wrong” strand is loaded on the RISC complex), it will be immediately evident that this problem can be solved by exchanging the position of the miRNA molecule and its complement on the respective strands of the dsRNA stem of the pre-miRNA molecule. As is known in the art, binding between A and U involving two hydrogen bounds, or G and U involving two hydrogen bounds is less strong that between G and C involving three hydrogen bounds. Exemplary hairpin sequences are provided in Tables 1-8, below.

Naturally occurring miRNA molecules may be comprised within their naturally occurring pre-miRNA molecules but they can also be introduced into existing pre-miRNA molecule scaffolds by exchanging the nucleotide sequence of the miRNA molecule normally processed from such existing pre-miRNA molecule for the nucleotide sequence of another miRNA of interest. The scaffold of the pre-miRNA can also be completely synthetic. Likewise, synthetic miRNA molecules may be comprised within, and processed from, existing pre-miRNA molecule scaffolds or synthetic pre-miRNA scaffolds. Some pre-miRNA scaffolds may be preferred over others for their efficiency to be correctly processed into the designed microRNAs, particularly when expressed as a chimeric gene wherein other DNA regions, such as untranslated leader sequences or transcription termination and polyadenylation regions are incorporated in the primary transcript in addition to the pre-microRNA.

According to the present teachings, the miRNA molecules may be naturally occurring or synthetic.

Thus, the present teachings contemplate expressing an exogenous polynucleotide having a nucleic acid sequence at least 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98% 99% or 100% identical to—NOs: 1-56, 80-125, 11874, 262-2086, 11616, (mature), provided that they regulate ABST.

Alternatively or additionally, the present teachings contemplate expressing an exogenous polynucleotide having a nucleic acid sequence at least 65%, 50%, 75%, 80%, 85%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98% 99% or 100% identical to SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 11616, 11615, 2087-3910, 3911, 11910-11939, 11874-11904, 11956, 11957 or 11958 (mature and precursors Tables 1, 3, 5, 7), provided that they regulate abiotic stress tolerance of the plant.

Tables 1, 3, 5 and 7 below illustrate exemplary miRNA sequences and precursors thereof which over expression are associated with modulation of abiotic stress tolerance. It is noted that Tables 1-17 below are incorporated into the specification and are considered an integral part thereof.

The present invention envisages the use of homologous and orthologous sequences of the above miRNA molecules. At the precursor level use of homologous sequences can be done to a much broader extent. Thus, in such precursor sequences the degree of homology may be lower in all those sequences not including the mature miRNA segment therein.

As used herein, the phrase “stem-loop precursor” refers to stem loop precursor RNA structure from which the miRNA can be processed.

Pre-microRNA molecules are typically processed from pri-microRNA molecules (primary transcripts). The single stranded RNA segments flanking the pre-microRNA are important for processing of the pri-miRNA into the pre-miRNA. The cleavage site appears to be determined by the distance from the stem-ssRNA junction (Han et al. 2006, Cell 125, 887-901, 887-901).

As used herein, a “pre-miRNA” molecule is an RNA molecule of about 100 to about 200 nucleotides, preferably about 100 to about 130 nucleotides which can adopt a secondary structure comprising a double stranded RNA stem and a single stranded RNA loop (also referred to as “hairpin”) and further comprising the nucleotide sequence of the miRNA (and its complement sequence) in the double stranded RNA stem. According to a specific embodiment, the miRNA and its complement are located about 10 to about 20 nucleotides from the free ends of the miRNA double stranded RNA stem. The length and sequence of the single stranded loop region are not critical and may vary considerably, e.g. between 30 and 50 nt in length. The complementarity between the miRNA and its complement need not be perfect and about 1 to 3 bulges of unpaired nucleotides can be tolerated. The secondary structure adopted by an RNA molecule can be predicted by computer algorithms conventional in the art such as mFOLD. The particular strand of the double stranded RNA stem from the pre-miRNA which is released by DCL activity and loaded onto the RISC complex is determined by the degree of complementarity at the 5′ end, whereby the strand which at its 5′ end is the least involved in hydrogen bounding between the nucleotides of the different strands of the cleaved dsRNA stem is loaded onto the RISC complex and will determine the sequence specificity of the target RNA molecule degradation. However, if empirically the miRNA molecule from a particular synthetic pre-miRNA molecule is not functional (because the “wrong” strand is loaded on the RISC complex), it will be immediately evident that this problem can be solved by exchanging the position of the miRNA molecule and its complement on the respective strands of the dsRNA stem of the pre-miRNA molecule. As is known in the art, binding between A and U involving two hydrogen bounds, or G and U involving two hydrogen bounds is less strong that between G and C involving three hydrogen bounds.

Thus, according to a specific embodiment, the exogenous polynucleotide encodes a stem-loop precursor of the nucleic acid sequence. Such a stem-loop precursor can be at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90%, at least about 95% or more identical to SEQ ID NOs: SEQ ID NO: 174-201, 220-235, 256-259, 2087-3910, 3911, 11910-11939, 11615, 11875-11904, 11956, 11957 or 11958 (homologs precursor), provided that it regulates abiotic stress tolerance.

Identity (e.g., percent identity) 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.

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

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.

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.

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: Hypertext Transfer Protocol://World Wide Web (dot) ncbi (dot) nlm (dot) nih (dot) gov. 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 [Hypertext Transfer Protocol://World Wide Web (dot) ebi (dot) ac (dot) uk/Tools/clustalw2/index (dot) html], followed by a neighbor joining tree (Hypertext Transfer Protocol://en (dot) wikipedia (dot) org/wiki/Neighbor-joining) which helps visualizing the clustering.

As mentioned, the present inventors have also identified RNAi sequences which are down regulated under abiotic stress conditions.

Thus, according to an aspect of the invention there is provided a method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide which downregulates an activity or expression of a gene encoding a miRNA molecule having a nucleic acid sequence at least 80%, 85% or preferably 90%, 95% or even 100% identical to the sequence selected from the group consisting of SEQ ID NOs: 57-79, 202-219, 126-161, 236-255, 169-173, 260-261, 3953-5114, 11905-11909, 11940-11955, 11959-11961, 5117-6277 or 6278 (Tables 2, 4, 6 and 8), thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant.

There are various approaches to down regulate miRNA sequences.

As used herein the term “down-regulation” refers to reduced activity or expression of the miRNA (at least 10%, 20%, 30%, 50%, 60%, 70%, 80%, 90% or 100% reduction in activity or expression) as compared to its activity or expression in a plant of the same species and the same developmental stage not expressing the exogenous polynucleotide.

Nucleic acid agents that down-regulate miR activity include, but are not limited to, a target mimic, a micro-RNA resistant gene and a miRNA inhibitor.

The target mimic or micro-RNA resistant target is essentially complementary to the microRNA provided that one or more of following mismatches are allowed:

(a) a mismatch between the nucleotide at the 5′ end of the microRNA and the corresponding nucleotide sequence in the target mimic or micro-RNA resistant target;

(b) a mismatch between any one of the nucleotides in position 1 to position 9 of the microRNA and the corresponding nucleotide sequence in the target mimic or micro-RNA resistant target; or

(c) three mismatches between any one of the nucleotides in position 12 to position 21 of the microRNA and the corresponding nucleotide sequence in the target mimic or micro-RNA resistant target provided that there are no more than two consecutive mismatches.

The target mimic RNA is essentially similar to the target RNA modified to render it resistant to miRNA induced cleavage, e.g. by modifying the sequence thereof such that a variation is introduced in the nucleotide of the target mimic sequence complementary to the nucleotides 10 or 11 of the miRNA resulting in a mismatch.

Alternatively, a microRNA-resistant target may be implemented. Thus, a silent mutation may be introduced in the microRNA binding site of the target gene so that the DNA and resulting RNA sequences are changed in a way that prevents microRNA binding, but the amino acid sequence of the protein is unchanged. Thus, a new sequence can be synthesized instead of the existing binding site, in which the DNA sequence is changed, resulting in lack of miRNA binding to its target.

Tables 14-17 below provide non-limiting examples of target mimics and target resistant sequences that can be used to down-regulate the activity of the miRs of the invention. According to a specific embodiment, the target mimic is listed in any one of the sequences of Table 7. According to a specific embodiment, the mir-resistant target sequence is listed in any one of the sequences of Table 15.

According to a specific embodiment, the target mimic or micro-RNA resistant target is linked to the promoter naturally associated with the pre-miRNA recognizing the target gene and introduced into the plant cell. In this way, the miRNA target mimic or micro-RNA resistant target RNA will be expressed under the same circumstances as the miRNA and the target mimic or micro-RNA resistant target RNA will substitute for the non-target mimic/micro-RNA resistant target RNA degraded by the miRNA induced cleavage.

Non-functional miRNA alleles or miRNA resistant target genes may also be introduced by homologous recombination to substitute the miRNA encoding alleles or miRNA sensitive target genes.

Recombinant expression is effected by cloning the nucleic acid of interest (e.g., miRNA, target gene, silencing agent etc) into a nucleic acid expression construct under the expression of a plant promoter, as further described hereinbelow.

In other embodiments of the invention, synthetic single stranded nucleic acids are used as miRNA inhibitors. A miRNA inhibitor is typically between about 17 to 25 nucleotides in length and comprises a 5′ to 3′ sequence that is at least 90% complementary to the 5′ to 3′ sequence of a mature miRNA. In certain embodiments, a miRNA inhibitor molecule is 17, 18, 19, 20, 21, 22, 23, 24, or 25 nucleotides in length, or any range derivable therein. Moreover, a miRNA inhibitor has a sequence (from 5′ to 3′) that is or is at least 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 99.1, 99.2, 99.3, 99.4, 99.5, 20 99.6, 99.7, 99.8, 99.9 or 100% complementary, or any range derivable therein, to the 5′ to 3′ sequence of a mature miRNA, particularly a mature, naturally occurring miRNA.

While further reducing the present invention to practice, the present inventors have identified gene targets for the differentially expressed miRNA molecules. It is therefore contemplated, that gene targets of those miRNAs that are down regulated during stress should be overexpressed in order to confer tolerance, while gene targets of those miRNAs that are up regulated during stress should be downregulated in the plant in order to confer tolerance.

Thus, according to an aspect of the invention there is provided a method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide encoding a polypeptide having an amino acid sequence at least 80%, 82%, 84%, 85%, 86%, 88%, 90%, 92%, 94%, 95%, 96%, 97%, 98%, 99% or 100% homologous to SEQ ID NOs: 9591-10364 (gene targets of down regulated miRNAs, see Table 10), wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

Nucleic acid sequences (also referred to herein as polynucleotides) of the polypeptides of some embodiments of the invention may be optimized for expression in a specific plant host. 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=1N[(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 (www(dot)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.

Target genes which are contemplated according to the present teachings are provided in the polynucleotide sequences which comprise nucleic acid sequences as set forth in the soy polynucleotides listed in Table 10). However the present teachings also relate to orthologs or homologs at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90%, or at least about 95% or more identical or similar to SEQ ID NO: 10365-10963 (polynucleotides listed in Table 10). Parameters for determining the level of identity are provided hereinbelow.

Alternatively or additionally, target genes which are contemplated according to the present teachings are provided in the polypeptide sequences which comprise amino acid sequences as set forth in the soy polypeptides of Table 10). However the present teachings also relate to orthologs or homologs at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90%, or at least about 95% or more identical or similar to SEQ ID NO: 9591-10364 (Table 10).

As mentioned the present inventors have also identified genes which down-regulation may be done in order to improve their abiotic stress tolerance, NUE, biomass, vigor and yield.

Thus, according to an aspect of the invention there is provided a method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide which downregulates an activity or expression of a polypeptide having an amino acid sequence at least 80%, 85%, 90%, 95%, or 100% homologous to SEQ ID NOs: 6315-8129 (polypeptides of Table 9), wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

Down regulation of activity or expression is by at least 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90% or even complete (100%) loss of activity or expression. Assays for measuring gene expression can be effected at the protein level (e.g., Western blot, ELISA) or at the mRNA level such as by RT-PCR.

According to a specific embodiment the amino acid sequence of the target gene is as set forth in SEQ ID NOs: 6315-8129 of Table 9.

Alternatively or additionally, the amino acid sequence of the target gene is encoded by a polynucleotide sequence as set forth in SEQ ID NOs: 8130-9590 of Table 9.

Examples of polynucleotide downregulating agents that inhibit (also referred to herein as inhibitors or nucleic acid (downregulating) agents) the expression of a target gene are given below.

1. Polynucleotide-Based Inhibition of Gene Expression.

It will be appreciated, that any of these methods when specifically referring to downregulating expression/activity of the target genes can be used, at least in part, to downregulate expression or activity of endogenous RNA molecules.

i. Sense Suppression/Cosuppression

In some embodiments of the invention, inhibition of the expression of target gene may be obtained by sense suppression or cosuppression. For cosuppression, an expression cassette is designed to express an RNA molecule corresponding to all or part of a messenger RNA encoding a target gene in the “sense” orientation. Over-expression of the RNA molecule can result in reduced expression of the native gene. Accordingly, multiple plant lines transformed with the cosuppression expression cassette are screened to identify those that show the greatest inhibition of target gene expression.

The polynucleotide used for cosuppression may correspond to all or part of the sequence encoding the target gene, all or part of the 5′ and/or 3′ untranslated region of a target transcript, or all or part of both the coding sequence and the untranslated regions of a transcript encoding the target gene. In some embodiments where the polynucleotide comprises all or part of the coding region for the target gene, the expression cassette is designed to eliminate the start codon of the polynucleotide so that no protein product will be transcribed.

Cosuppression may be used to inhibit the expression of plant genes to produce plants having undetectable protein levels for the proteins encoded by these genes. See, for example, Broin, et al., (2002) Plant Cell 15:1517-1532. Cosuppression may also be used to inhibit the expression of multiple proteins in the same plant. Methods for using cosuppression to inhibit the expression of endogenous genes in plants are described in Flavell, et al., (1995) Proc. Natl. Acad. Sci. USA 91:3590-3596; Jorgensen, et al., (1996) Plant Mol. Biol. 31:957-973; Johansen and Carrington, (2001) Plant Physiol. 126:930-938; Broin, et al., (2002) Plant Cell 15:1517-1532; Stoutjesdijk, et al., (2002) Plant Physiol. 129:1723-1731; Yu, et al., (2003) Phytochemistry 63:753-763; and U.S. Pat. Nos. 5,035,323, 5,283,185 and 5,952,657; each of which is herein incorporated by reference. The efficiency of cosuppression may be increased by including a poly-dt region in the expression cassette at a position 3′ to the sense sequence and 5′ of the polyadenylation signal. See, US Patent Publication Number 20020058815, herein incorporated by reference. Typically, such a nucleotide sequence has substantial sequence identity to the sequence of the transcript of the endogenous gene, optimally greater than about 65% sequence identity, more optimally greater than about 85% sequence identity, most optimally greater than about 95% sequence identity. See, U.S. Pat. Nos. 5,283,185 and 5,035,323; herein incorporated by reference.

Transcriptional gene silencing (TGS) may be accomplished through use of hpRNA constructs wherein the inverted repeat of the hairpin shares sequence identity with the promoter region of a gene to be silenced. Processing of the hpRNA into short RNAs which can interact with the homologous promoter region may trigger degradation or methylation to result in silencing. (Aufsatz, et al., (2002) PNAS 99(4):16499-16506; Mette, et al., (2000) EMBO J. 19(19):5194-5201)

ii. Antisense Suppression

In some embodiments of the invention, inhibition of the expression of the target gene may be obtained by antisense suppression. For antisense suppression, the expression cassette is designed to express an RNA molecule complementary to all or part of a messenger RNA encoding the target gene. Over-expression of the antisense RNA molecule can result in reduced expression of the native gene. Accordingly, multiple plant lines transformed with the antisense suppression expression cassette are screened to identify those that show the greatest inhibition of target gene expression.

The polynucleotide for use in antisense suppression may correspond to all or part of the complement of the sequence encoding the target gene, all or part of the complement of the 5′ and/or 3′ untranslated region of the target gene transcript, or all or part of the complement of both the coding sequence and the untranslated regions of a transcript encoding the target gene. In addition, the antisense polynucleotide may be fully complementary (i.e., 100% identical to the complement of the target sequence) or partially complementary (i.e., less than 100% identical to the complement of the target sequence) to the target sequence. Antisense suppression may be used to inhibit the expression of multiple proteins in the same plant. Furthermore, portions of the antisense nucleotides may be used to disrupt the expression of the target gene. Generally, sequences of at least 50 nucleotides, 100 nucleotides, 200 nucleotides, 300, 500, 550 or greater may be used. Methods for using antisense suppression to inhibit the expression of endogenous genes in plants are described, for example, in Liu, et al., (2002) Plant Physiol. 129:1732-1753 and U.S. Pat. No. 5,759,829, which is herein incorporated by reference. Efficiency of antisense suppression may be increased by including a poly-dT region in the expression cassette at a position 3′ to the antisense sequence and 5′ of the polyadenylation signal. See, US Patent Publication Number 20020058815.

iii. Double-Stranded RNA Interference

In some embodiments of the invention, inhibition of the expression of a target gene may be obtained by double-stranded RNA (dsRNA) interference. For dsRNA interference, a sense RNA molecule like that described above for cosuppression and an antisense RNA molecule that is fully or partially complementary to the sense RNA molecule are expressed in the same cell, resulting in inhibition of the expression of the corresponding endogenous messenger RNA.

Expression of the sense and antisense molecules can be accomplished by designing the expression cassette to comprise both a sense sequence and an antisense sequence. Alternatively, separate expression cassettes may be used for the sense and antisense sequences. Multiple plant lines transformed with the dsRNA interference expression cassette or expression cassettes are then screened to identify plant lines that show the greatest inhibition of target gene expression. Methods for using dsRNA interference to inhibit the expression of endogenous plant genes are described in Waterhouse, et al., (1998) Proc. Natl. Acad. Sci. USA 95:13959-13965, Liu, et al., (2002) Plant Physiol. 129:1732-1753, and WO 99/59029, WO 99/53050, WO 99/61631, and WO 00/59035.

iv. Hairpin RNA Interference and Intron-Containing Hairpin RNA Interference

In some embodiments of the invention, inhibition of the expression of one or more target gene may be obtained by hairpin RNA (hpRNA) interference or intron-containing hairpin RNA (ihpRNA) interference. These methods are highly efficient at downregulating the expression of endogenous genes. See, Waterhouse and Helliwell, (2003) Nat. Rev. Genet. 5:29-38 and the references cited therein.

For hpRNA interference, the expression cassette is designed to express an RNA molecule that hybridizes with itself to form a hairpin structure that comprises a single-stranded loop region and a base-paired stem. The base-paired stem region comprises a sense sequence corresponding to all or part of the endogenous messenger RNA encoding the gene whose expression is to be inhibited, and an antisense sequence that is fully or partially complementary to the sense sequence. Thus, the base-paired stem region of the molecule generally determines the specificity of the RNA interference. hpRNA molecules are highly efficient at inhibiting the expression of endogenous genes, and the RNA interference they induce is inherited by subsequent generations of plants. See, for example, Chuang and Meyerowitz, (2000) Proc. Natl. Acad. Sci. USA 97:5985-5990; Stoutjesdijk, et al., (2002) Plant Physiol. 129:1723-1731; and Waterhouse and Helliwell, (2003) Nat. Rev. Genet. 5:29-38. Methods for using hpRNA interference to inhibit or silence the expression of genes are described, for example, in Chuang and Meyerowitz, (2000) Proc. Natl. Acad. Sci. USA 97:5985-5990; Stoutjesdijk, et al., (2002) Plant Physiol. 129:1723-1731; Waterhouse and Helliwell, (2003) Nat. Rev. Genet. 5:29-38; Pandolfini, et al., BMC Biotechnology 3:7, and US Patent Publication Number 20030175965; each of which is herein incorporated by reference. A transient assay for the efficiency of hpRNA constructs to silence gene expression in vivo has been described by Panstruga, et al., (2003) Mol. Biol. Rep. 30:135-150, herein incorporated by reference.

For ihpRNA, the interfering molecules have the same general structure as for hpRNA, but the RNA molecule additionally comprises an intron that is capable of being spliced in the cell in which the ihpRNA is expressed. The use of an intron minimizes the size of the loop in the hairpin RNA molecule following splicing, and this increases the efficiency of interference. See, for example, Smith, et al., (2000) Nature 507:319-320. In fact, Smith, et al., show 100% suppression of endogenous gene expression using ihpRNA-mediated interference. Methods for using ihpRNA interference to inhibit the expression of endogenous plant genes are described, for example, in Smith, et al., (2000) Nature 507:319-320; Wesley, et al., (2001) Plant J. 27:584, 1-3, 590; Wang and Waterhouse, (2001) Curr. Opin. Plant Biol. 5:156-150; Waterhouse and Helliwell, (2003) Nat. Rev. Genet. 5:29-38; Helliwell and Waterhouse, (2003) Methods 30:289-295, and US Patent Publication Number 20030180955, each of which is herein incorporated by reference.

The expression cassette for hpRNA interference may also be designed such that the sense sequence and the antisense sequence do not correspond to an endogenous RNA. In this embodiment, the sense and antisense sequence flank a loop sequence that comprises a nucleotide sequence corresponding to all or part of the endogenous messenger RNA of the target gene. Thus, it is the loop region that determines the specificity of the RNA interference. See, for example, WO 02/00905, herein incorporated by reference.

v. Amplicon-Mediated Interference

Amplicon expression cassettes comprise a plant virus-derived sequence that contains all or part of the target gene but generally not all of the genes of the native virus. The viral sequences present in the transcription product of the expression cassette allow the transcription product to direct its own replication. The transcripts produced by the amplicon may be either sense or antisense relative to the target sequence (i.e., the messenger RNA for target gene). Methods of using amplicons to inhibit the expression of endogenous plant genes are described, for example, in Angell and Baulcombe, (1997) EMBO J. 16:3675-3685, Angell and Baulcombe, (1999) Plant J. 20:357-362, and U.S. Pat. No. 6,656,805, each of which is herein incorporated by reference.

vi. Ribozymes

In some embodiments, the polynucleotide expressed by the expression cassette of the invention is catalytic RNA or has ribozyme activity specific for the messenger RNA of target gene. Thus, the polynucleotide causes the degradation of the endogenous messenger RNA, resulting in reduced expression of the target gene. This method is described, for example, in U.S. Pat. No. 5,987,071, herein incorporated by reference.

2. Gene Disruption

In some embodiments of the present invention, the activity of a miRNA or a target gene is reduced or eliminated by disrupting the gene encoding the target polypeptide. The gene encoding the target polypeptide may be disrupted by any method known in the art. For example, in one embodiment, the gene is disrupted by transposon tagging. In another embodiment, the gene is disrupted by mutagenizing plants using random or targeted mutagenesis, and selecting for plants that have reduced response regulator activity.

Any of the nucleic acid agents described herein (for overexpression or downregulation of either the target gene or the miRNA) can be provided to the plant as naked RNA or expressed from a nucleic acid expression construct, where it is operably linked to a regulatory sequence.

According to a specific embodiment of the invention, there is provided a nucleic acid construct comprising a nucleic acid sequence encoding a nucleic acid agent (e.g., miRNA or a precursor thereof as described herein, gene target or silencing agent), the nucleic acid sequence being under a transcriptional control of a regulatory sequence such as a tissue specific promoter.

An exemplary nucleic acid construct which can be used for plant transformation include, the pORE E2 binary vector (FIG. 1) in which the relevant nucleic acid sequence is ligated under the transcriptional control of a promoter.

A coding nucleic acid sequence is “operably linked” or “transcriptionally 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. Thus, the regulatory sequence controls the transcription of the miRNA or precursor thereof, gene target or silencing agent.

The term “regulatory sequence”, as used herein, means any DNA, that is involved in driving transcription and controlling (i.e., regulating) the timing and level of transcription of a given DNA sequence, such as a DNA coding for a miRNA, precursor or inhibitor of same. For example, a 5′ regulatory region (or “promoter region”) is a DNA sequence located upstream (i.e., 5′) of a coding sequence and which comprises the promoter and the 5′-untranslated leader sequence. A 3′ regulatory region is a DNA sequence located downstream (i.e., 3′) of the coding sequence and which comprises suitable transcription termination (and/or regulation) signals, including one or more polyadenylation signals.

For the purpose of the invention, the promoter is a plant-expressible promoter. As used herein, the term “plant-expressible promoter” means a DNA sequence which is capable of controlling (initiating) transcription in a plant cell. This includes any promoter of plant origin, but also any promoter of non-plant origin which is capable of directing transcription in a plant cell, i.e., certain promoters of viral or bacterial origin. Thus, any suitable promoter sequence can be used by the nucleic acid construct of the present invention. According to some embodiments of the invention, the promoter is a constitutive promoter, a tissue-specific promoter or an inducible promoter (e.g. an abiotic stress-inducible promoter).

Suitable constitutive promoters include, for example, hydroperoxide lyase (HPL) promoter, CaMV 35S promoter (Odell et al, Nature 313:810-812, 1985); Arabidopsis At6669 promoter (see PCT Publication No. W004081173A2); Arabidopsis new At6669 promoter; maize Ubi 1 (Christensen et al., Plant Sol. Biol. 18:675-689, 1992); rice actin (McElroy et al., Plant Cell 2:163-171, 1990); pEMU (Last et al, Theor. Appl. Genet. 81 :584, 1-3, 588, 1991); CaMV 19S (Nilsson et al, Physiol. Plant 100:456-462, 1997); GOS2 (de Pater et al, Plant J November; 2(6):837-44, 1992); ubiquitin (Christensen et al, Plant MoI. Biol. 18: 675-689, 1992); Rice cyclophilin (Bucholz et al, Plant MoI Biol. 25(5):837-43, 1994); Maize H3 histone (Lepetit et al, MoI. Gen. Genet. 231 : 276-285, 1992); Actin 2 (An et al, Plant J. 10(l); 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 [such as described, for example, by 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 MoI. Biol. 23:1129-1138, 1993; and Matsuoka et al., Proc. Natl. Acad. Sci. USA 90:9586-9590, 1993], seed-preferred promoters [e.g., from seed specific genes (Simon, et al., Plant MoI. Biol. 5. 191, 1985; Scofield, et al., J. Biol. Chem. 262: 12202, 1987; Baszczynski, et al., Plant MoI. Biol. 14: 633, 1990), Brazil Nut albumin (Pearson' et al., Plant MoI. Biol. 18: 235-245, 1992), legumin (Ellis, et al. Plant MoI. Biol. 10: 203-214, 1988), Glutelin (rice) (Takaiwa, et al., MoI. Gen. Genet. 208: 15-22, 1986; Takaiwa, et al., FEBS Letts. 221: 43-47, 1987), Zein (Matzke et al., Plant MoI Biol, 143)323-32 1990), napA (Stalberg, et al., Planta 199: 515-519, 1996), Wheat SPA (Albanietal, Plant Cell, 9: 171-184, 1997), sunflower oleosin (Cummins, et al, Plant MoI. Biol. 19: 873-876, 1992)1, endosperm specific promoters [e.g., wheat LMW and HMW, glutenin-1 (MoI Gen Genet 216:81-90, 1989; NAR 17:461-2), wheat a, b and g gliadins (EMBO3: 1409-15, 1984), Barley 1trl promoter, barley Bl, 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), Synthetic promoter (Vicente-Carbajosa et al., Plant J. 13: 629-640, 1998), rice prolamin NRP33, rice-globulin GIb-I (Wu et al., Plant Cell Physiology 39(8) 885-889, 1998), rice alpha-globulin REB/OHP-1 (Nakase et al. Plant MoI. 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), sorghum gamma-kafirin (PMB 32:1029-35, 1996); e.g., the Napin promoter], embryo specific promoters [e.g., rice OSH1 (Sato et al, Proc. Natl. Acad. Sci. USA, 93: 8117-8122), KNOX (Postma-Haarsma et al, Plant MoI. Biol. 39:257-71, 1999), rice oleosin (Wu et at, J. Biochem., 123:386, 1998)1, and flower-specific promoters [e.g., AtPRP4, chalene synthase (chsA) (Van der Meer, et al., Plant MoI. Biol. 15, 95-109, 1990), LAT52 (Twell et al., MoI. Gen Genet. 217:240-245; 1989), apetala-3]. Also contemplated are root-specific promoters such as the ROOTP promoter described in Vissenberg K, et al. Plant Cell Physiol. 2005 January; 46(1):192-200.

The nucleic acid construct of some embodiments of the invention can further include an appropriate selectable marker and/or an origin of replication.

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.

When naked RNA or DNA is introduced into a cell, the polynucleotides may be synthesized using any method known in the art, including either enzymatic syntheses or solid-phase syntheses. These are especially useful in the case of short polynucleotide sequences with or without modifications as explained above. Equipment and reagents for executing solid-phase synthesis are commercially available from, for example, Applied Biosystems. Any other means for such synthesis may also be employed; the actual synthesis of the oligonucleotides is well within the capabilities of one skilled in the art and can be accomplished via established methodologies as detailed in, for example: Sambrook, J. and Russell, D. W. (2001), “Molecular Cloning: A Laboratory Manual”; Ausubel, R. M. et al., eds. (1994, 1989), “Current Protocols in Molecular Biology,” Volumes I-III, John Wiley & Sons, Baltimore, Md.; Perbal, B. (1988), “A Practical Guide to Molecular Cloning,” John Wiley & Sons, New York; and Gait, M. J., ed. (1984), “Oligonucleotide Synthesis”; utilizing solid-phase chemistry, e.g. cyanoethyl phosphoramidite followed by deprotection, desalting, and purification by, for example, an automated trityl-on method or HPLC.

There are various methods of introducing foreign genes into both monocotyledonous and dicotyledonous plants (Potrykus, L, Annu. Rev. Plant. Physiol, Plant. MoI. 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 (e.g., T-DNA using Agrobacterium tumefaciens or Agrobacterium rhizogenes); see for example, 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 Arntzen, 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.

According to a specific embodiment of the present invention, the exogenous polynucleotide is introduced into the plant by infecting the plant with bacteria, such as using a floral dip transformation method (as described in further detail in Example 7, of the Examples section which follows).

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. For this reason 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. 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 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.

Although stable transformation is presently preferred, transient transformation of leaf cells, meristematic cells or the whole plant is also envisaged by the present invention.

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), Galon 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 Tatlor, Eds. “Plant Virology Protocols: From Virus Isolation to Transgenic Resistance (Methods in Molecular Biology (Humana Pr), VoI 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 proteins 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 nucleic acid is provided in which the native coat protein coding sequence has been deleted from a viral nucleic acid, 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 nucleic acid, and ensuring a systemic infection of the host by the recombinant plant viral nucleic acid, has been inserted. Alternatively, the coat protein gene may be inactivated by insertion of the non-native nucleic acid sequence within it, such that a protein is produced. The recombinant plant viral nucleic acid may contain one or more additional non-native subgenomic promoters. Each non-native subgenomic promoter is capable of transcribing or expressing adjacent genes or nucleic acid sequences in the plant host and incapable of recombination with each other and with native subgenomic promoters. Non-native (foreign) nucleic acid 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 nucleic acid sequence is included. The non-native nucleic acid 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 nucleic acid 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 nucleic acid 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 nucleic acid. 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 nucleic acid sequences may be inserted adjacent to 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 nucleic acid 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 nucleic acid to produce a recombinant plant virus. The recombinant plant viral nucleic acid or recombinant plant virus is used to infect appropriate host plants. The recombinant plant viral nucleic acid is capable of replication in the host, systemic spread in the host, and transcription or expression of foreign gene(s) (isolated nucleic acid) in the host to produce the desired sequence.

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

A technique for introducing exogenous nucleic acid 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 nucleic acid is introduced via particle bombardment into the cells with the aim of introducing at least one exogenous nucleic acid molecule into the chloroplasts. The exogenous nucleic acid is selected such that it gets integrated into the chloroplast's genome via homologous recombination which is readily effected by enzymes inherent to the chloroplast. To this end, the exogenous nucleic acid includes, in addition to a gene of interest, at least one nucleic acid stretch which is derived from the chloroplast's genome. In addition, the exogenous nucleic acid 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 nucleic acid. 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.

Regardless of the method of transformation, propagation or regeneration, the present invention also contemplates a transgenic plant exogenously expressing the polynucleotide/nucleic acid agent of the invention.

According to a specific embodiment, the transgenic plant exogenously expresses a polynucleotide having a nucleic acid sequence at least, 80%, 85%, 90%, 95% or even 100% identical to SEQ ID NOs: 1-56, 11874, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910 11616, 11615, 11910-11939, 11956-11958, 11875-11904 or 3911 (Tables 1, 3, 5 and 7), wherein the nucleic acid sequence is capable of regulating abiotic stress tolerance of the plant.

According to further embodiments, the exogenous polynucleotide encodes a precursor of the nucleic acid sequence.

According to yet further embodiments, the stem-loop precursor is at least 60%, 65% , 70%, 75%, 80%, 85%, 90%, 95% or even 100% identical to SEQ ID NOs: 1-56, 11874, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910 11616, 11615, 11910-11939, 11956-11958, 11875-11904 or 3911 (Tables 1, 3, 5 and 7). More specifically the exogenous polynucleotide is selected from the group consisting of SEQ ID NO: 1-56, 11874, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910 11616, 11615, 11910-11939, 11956-11958, 11875-11904 or 3911 (precursor and mature sequences of upregulated Tables 1, 3, 5 and 7).

Alternatively, there is provided a transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a gene encoding a miRNA molecule having a nucleic acid sequence selected from the group consisting of SEQ ID NOs: 57-79, 202-219, 126-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 11905-11909, 11940-11955, 11959-11961 or 6278 (downregulated Tables 2, 4, 6, 8) or homologs thereof which are at least at least 80%, 85%, 90% or 95% identical to SEQ ID NOs: : 57-79, 202-219, 126-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 11905-11909, 11940-11955, 11959-11961 or 6278 (downregulated Tables 2, 4, 6 and 8).

More specifically, the transgenic plant expresses the nucleic acid agent of Tables 14 or 16. Alternatively, the transgenic plant expresses the nucleic acid agent of Tables 15 or 17.

It will be appreciated that the present teachings also relate to nucleic acid constructs and transgenic plants expressing same which comprise a nucleic acid sequence at least 80%, 85%, 90%, 95% or even 100% identical to SEQ ID NOs: : 57-79, 202-219, 126-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 11905-11909, 11940-11955, 11959-11961 or 6278 (Tables 2, 4, 6 and 8), wherein the nucleic acid sequence is capable of regulating abiotic stress tolerance of the plant.

Alternatively or additionally there is provided a transgenic plant exogenously expressing a polynucleotide encoding a polypeptide having an amino acid sequence at least 80%, 85%, 90%, 95% or even 100% homologous to SEQ ID NOs: 9591-10364 (polypeptides of Table 10), wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant.

Alternatively or additionally there is provided a transgenic plant exogenously expressing a polynucleotide encoding a polypeptide having an amino acid sequence at least 80%, 85%, 90%, 95% or even 100% homologous to SEQ ID NOs: 6315-8129 (polypeptides of Table 9), wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant.

Alternatively or additionally there is provided a transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a polypeptide having an amino acid sequence at least 80%, 85%, 90%, 95% or even 100% homologous to SEQ ID NOs: 6315-10963 (targets of Tables 9 and 10), wherein the polypeptide is capable of regulating abiotic stress tolerance of the plant.

Also contemplated are hybrids of the above described transgenic plants. A “hybrid plant” refers to a plant or a part thereof resulting from a cross between two parent plants, wherein one parent is a genetically engineered plant of the invention (transgenic plant expressing an exogenous miRNA sequence or a precursor thereof). Such a cross can occur naturally by, for example, sexual reproduction, or artificially by, for example, in vitro nuclear fusion. Methods of plant breeding are well-known and within the level of one of ordinary skill in the art of plant biology.

Since abiotic stress tolerance, nitrogen use efficiency as well as yield, vigor or biomass of the plant can involve multiple genes acting additively or in synergy (see, for example, in Quesda et al., Plant Physiol. 130:951-063, 2002), the invention also envisages expressing a plurality of exogenous polynucleotides in a single host plant to thereby achieve superior effect on the efficiency of nitrogen use, yield, vigor and biomass of the plant.

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. 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 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 yield or tolerance traits as described above, using conventional plant breeding techniques.

Expression of the miRNAs of the present invention or precursors thereof can be qualified using methods which are well known in the art such as those involving gene amplification e.g., PCR or RT-PCR or Northern blot or in-situ hybridization.

According to some embodiments of the invention, the plant expressing the exogenous polynucleotide(s) is grown under stress (nitrogen or abiotic) or normal conditions (e.g., biotic conditions and/or conditions with sufficient water, nutrients such as nitrogen and fertilizer). Such conditions, which depend on the plant being grown, are known to those skilled in the art of agriculture, and are further, described above.

According to some embodiments of the invention, the method further comprises growing the plant expressing the exogenous polynucleotide(s) under abiotic stress or nitrogen limiting conditions. Non-limiting examples of abiotic stress conditions include, water deprivation, drought, excess of water (e.g., flood, waterlogging), freezing, low temperature, high temperature, strong winds, heavy metal toxicity, anaerobiosis, nutrient deficiency, nutrient excess, salinity, atmospheric pollution, intense light, insufficient light, or UV irradiation, etiolation and atmospheric pollution.

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

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-m 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., tolerance to abiotic stress). 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, 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 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 of the invention can be 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; and (b) evaluating a trait of a plant as compared to a wild type plant of the same type; thereby evaluating the trait of the plant.

Thus, the effect of the transgene (the exogenous polynucleotide) on different plant characteristics may be determined any method known to one of ordinary skill in the art.

Thus, for example, tolerance to limiting nitrogen conditions may be compared in transformed plants {i.e., expressing the transgene) compared to non-transformed (wild type) plants exposed to the same stress conditions (other stress conditions are contemplated as well, e.g. water deprivation, salt stress e.g. salinity, suboptimal temperature osmotic stress, and the like), using the following assays.

Methods of qualifying plants as being tolerant or having improved tolerance to abiotic stress or limiting nitrogen levels are well known in the art and are further described hereinbelow.

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 millimolar (mM, nitrogen deficient conditions) or 10, 6-9 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 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.

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 Cdmediated reduction of NO3to 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.

Tolerance to abiotic stress (e.g. tolerance to drought or salinity) can be evaluated by determining the differences in physiological and/or physical condition, including but not limited to, vigor, growth, size, or root length, or specifically, leaf color or leaf area size of the transgenic plant compared to a non-modified plant of the same species grown under the same conditions. Other techniques for evaluating tolerance to abiotic stress include, but are not limited to, measuring chlorophyll fluorescence, photosynthetic rates and gas exchange rates. Further assays for evaluating tolerance to abiotic stress are provided hereinbelow and in the Examples section which follows.

Drought tolerance assay—Soil-based drought screens are performed with plants overexpressing the polynucleotides detailed above. Seeds from control Arabidopsis plants, or other transgenic plants overexpressing nucleic acid of the invention are germinated and transferred to pots. Drought stress is obtained after irrigation is ceased. 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.

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 drought stress tolerant plants

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 with added salt), or by culturing the plants in a hyperosmotic growth medium [e.g., 50 Murashige-Skoog medium (MS medium) with added salt]. 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, 150 mM, 300 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 chlorosis 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 PEG 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 experiments, the medium is supplemented for example with 50 mM, 100 mM, 200 mM NaCl or 15%, 20% or 25% PEG.

Cold stress tolerance—One way to analyze cold stress is as follows. 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 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—One way to measure heat stress tolerance is 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.

The biomass, vigor and yield of the plant can also be evaluated using any method known to one of ordinary skill in the art. Thus, for example, plant vigor can be calculated by the increase in growth parameters such as leaf area, fiber length, rosette diameter, plant fresh weight, oil content, seed yield and the like per time.

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.

Thus, the present invention is of high agricultural value for increasing tolerance of plants to nitrogen deficiency or abiotic stress as well as promoting the yield, biomass and vigor of commercially desired crops.

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.

In a further aspect the invention, the transgenic plants of the present invention or parts thereof are comprised in a food or feed product (e.g., dry, liquid, paste). A food or feed product is any ingestible preparation containing the transgenic plants, or parts thereof, of the present invention, or preparations made from these plants. Thus, the plants or preparations are suitable for human (or animal) consumption, i.e. the transgenic plants or parts thereof are more readily digested. Feed products of the present invention further include an oil or a beverage adapted for animal consumption.

It will be appreciated that the transgenic plants, or parts thereof, of the present invention may be used directly as feed products or alternatively may be incorporated or mixed with feed products for consumption. Furthermore, the food or feed products may be processed or used as is. Exemplary feed products comprising the transgenic plants, or parts thereof, include, but are not limited to, grains, cereals, such as oats, e.g. black oats, barley, wheat, rye, sorghum, corn, vegetables, leguminous plants, especially soybeans, root vegetables and cabbage, or green forage, such as grass or hay.

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.

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.

Example 1 Differential Expression of miRNAs in Soybean Plant Under Abiotic Stress Versus Optimal Conditions

Plant Material

Glycine max seeds (soy) were obtained from Taam-Teva shop (Israel). Plants were grown at 28° C. under a 16 hours light:8 hours dark regime. 5

Drought Induction

Plants were grown under standard conditions as described above until seedlings were four weeks old. Next, plants were divided into two groups: control plants were irrigated with tap water twice a week and drought-treated plants received no irrigation. The experiment continued for five days, after which plants were harvested for RNA extraction.

Salt Induction

For salinity induction, irrigation with regular water was substituted by irrigation with 300 mM NaCl solution in the stress group, for an overall of 3 irrigations for a ten-day period.

Heat Shock Induction

For induction of heat shock, the stress group plants were exposed to a high temperature (37° C.) for one hour.

Total RNA Extraction

Total RNA of leaf samples from eight biological repeats were extracted using the mirVana™ kit (Ambion, Austin, Tex.) by pooling tissues from 2-4 plants to one biological repeat. RNA analysis was performed on plant tissue samples from both experimental and control groups.

Microarray Design

Custom microarrays were manufactured by Agilent Technologies by in situ synthesis. A microarray based on Sanger version 16 was designed and consisted of a total 4602 non-redundant DNA 45-nucleotide long probes for all known plant small RNAs, with 1875 sequences (40.7%) from miRBase (http://wwwDOTmirbaseDOTorg/indexDOTshtml) and 2678 sequences (58DOT2%) from PMRD (http://bioinformaticsDOTcauDOTeduDOTcn/PMRD/), with each probe being printed in triplicate. Control and spike probes account for the remaining sequences on the microarray.

Results

Wild type soybean plants were allowed to grow at standard, optimal conditions or stress conditions for a period of time as specified above, at the end of which they were evaluated for stress tolerance. Three to four plants from each group were grouped as a biological repeat. Four to eight biological repeats were obtained for each group, and RNA was extracted from leaf tissue. The expression level of the soybean small RNAs was analyzed by high throughput microarray to identify small RNAs that were differentially expressed between the experimental groups.

Tables 1-6 below present sequences that were found to be differentially expressed in soybean grown under drought conditions (lasting five days), high salt conditions (lasting ten days) or heat shock conditions (lasting one hour), compared to optimal growth conditions. To clarify, the sequence of an up-regulated miRNA is induced under stress conditions and the sequence of a down-regulated miRNA is repressed under stress conditions.

TABLE 1 Differentially Expressed (Up-regulated) Small RNAs in Soybean Plants Growing under Drought (5 days) versus Optimal Conditions. miR Mature Sequence Name (SEQ ID NO) Stem Loop Sequence (SEQ ID NO) p-value Fold-Change ahy- AGGATTCTGTATT ACAATAGAAGGATTCTGTATTAAC 5.90E−06 1.97 (+) miR3514- AACGGTGGA (1) GGTGGACATGATTTATCTCGTTTTT 5p AAAGATATCTTTGCATTTCATATGA GATTTAAAGTTTTTATTGGTAATAT AAATCTCACATGAAATTTAAATTTA TATTTTAAAGTTAAGATAAAGTCAT GTCACCGTTAATACAGAATCCTTCA ATTATATTTAGTCAGGGG (174) aly- AGAAGAGGTACAA AAGTGCTACAAGAATGTATAGTCT 1.10E−05 1.88 (+) miR831- GGAGATGAGA (2) TAGAGTCTCAAGAAGAGGTACAAG 5p GAGATGAGAAGTGAATCACTGAAA CAAGTGGTTCTGGTTTGTGGATCAG TATGGTTTACCCAAAACACGTGTTT GGTGCTTCACTTCTAAACTCCTCGT ACTCTTCTTGGGATTCTATGACTTA CACTTGTTGATTT (175) aqc- TTTGGACTGAAGG GGAGTCTTTCCAGCCCAAAACAGC 3.00E−03 1.51 (+) miR159 GAGCTCTA (3) TTCTTGATCTTCTTGAAAACTTCTG TTTGGACTGAAGGGAGCTCTAA (176) ath- TTGACAGAAGATA GTGTTGACAGAAGATAGAGAGCAC 1.00E−03 1.70 (+) miR157a GAGAGCAC (4) AGATGATGAGATACAATTCGGAGC ATGTTCTTTGCATCTTACTCCTTTGT GCTCTCTAGCCTTCTGTCATCACC (177) ath- TTTGGATTGAAGG GGAAGAGCTCCTTGAAGTTCAATG 6.80E−03 1.63 (+) miR159b GAGCTCTT (5) GAGGGTTTAGCAGGGTGAAGTAAA GCTGCTAAGCTATGGATCCCATAA GCCTTATCAAATTCAATATAATTGA TGATAAGGTTTTTTTTATGGATGCC ATATCTCAGGAGCTTTCACTTACCC CTTTAATGGCTTCACTCTTCTTTGG ATTGAAGGGAGCTCTTCATCTCTC (178) ath- TTTGGATTGAAGG GTGTAACAGAAGGAGCTCCCTTCC 1.20E−03 1.65 (+) miR159c GAGCTCCT (6) TCCAAAACGAAGAGGACAAGATTT GAGGAACTAAAATGCAGAATCTAA GAGTTCATGTCTTCCTCATAGAGAG TGCGCGGTGTTAAAAGCTTGAAGA AAGCACACTTTAAGGGGATTGCAC GACCTCTTAGATTCTCCCTCTTTCT CTACATATCATTCTCTTCTCTTCGTT TGGATTGAAGGGAGCTCCTTTTCTT CTTC (179) ath- CACCGGTGGAGGA GGACTTCTCATCTTCTTTCTTAGCC 2.00E−08 2.09 (+) miRf10068- GTGAGAG (7) GCCGGTGCTCCAGCTCCACCACCG akr TGTCCTCCAACATTACCGTGGCTTC CAGTTCCACCGGTGGAGGAGTGAG AGTGGGAAGTTT (11875) ath- ATCGAAGGAGATG GATTTCTCGTCCTCCGGCAATCCTT 1.90E−05 1.90 (+) miRf10240- GAGGACG (8) CGAACTCATCTTCATCCCAGTAATC akr GAAGGAGATGGAGGACGAAGGCTT C (11876) ath- AAGAAGGAGGAA CTCTAGATCTCAACAGGTTTCCTCC 2.30E−07 2.19 (+) miRf10451- CAACCTGTTG (9) TCCTTCTTTCTATTTAGCTACTTGGT akr TTCAATTGTTTCAAGCCTAGGTAAG CATATGTAAAAAAGAGACAATTGA AACCAAGTAACTAAATAGAAAGAA GGAGGAACAACCTGTTGAGATCTA GAG (11877) ath- TTAGCTGAAGAAG TTTGTTTGTTTAGCTGAAGAAGCAG 3.70E−06 1.84 (+) miRf10687- CAGAGGAG (10) AGGAGTCGGCATTGGGGCACAGTC akr ACTCATCGATGCTGCAATGGGTAA GTCCTCTGCATACTTTTGCTGAGAT AGGAATAGA (11878) ath- TGCAGTTCCTGGA GGTGCCGCTGCAGTTCCTGGAGGT 1.30E−08 2.49 (+) miRf10701- GGTGGAGGA (11) GGAGGAGGTGGTGGTGGGGCCACT akr GCAGCTCTTGGAGGTGGAGGCGGT GGAGGTGGAGCCGCTATAGTTGTT GGAAGTGGAGGAGGTGGCGGTGGT GGT (11879) ath- CTTGTGGAGAGGA TTGTAATTTCTTGTGGAGAGGAAG 7.80E−08 2.10 (+) miRf10751- AGCAAGA (12) CAAGAGGATGTGCTTGGTTGTGGA akr AATATAGGGCCCTTAAAATATATT CATCGTATTCACTCACATAACAAA AATTCCACAAGTAAGCACATCATC TTGCTTCCTCCACAAGAAATTACAA ath- (11880) miRf10924- TGAGGCGTATCAG TGAGGCGTATCAGGAGGTAGTGTT 5.70E−04 1.73 (+) akr GAGGTAGT (13) CTTGGTGGGACAATTTGTGTTGTAT GTTTCA (11881) ath- GAGGTTTGCGATG GATGTTGGAGGTTTGCGATGAGAA 1.80E−04 1.60 (+) miRf11021- AGAAAGAG (14) AGAGATTGGCCGGAAGAATTATCA akr GCCATCAACATCGAGATTGTGAGA TAATCGGAAGACCTGTAATTGTGA AGGTAACTCTTTCTCATCTGCAAAT CTCAACTGTC (11882) ath- TCATCGGAGAAAC TTGTCTCTGTTCATCGGAGAAACAG 1.30E−07 2.78 (+) miRf11037- AGAGGAGC (15) AGGAGCAAGACGTTTCAAACGGTT akr CTTGGCTCATAATTTGCTTCTCTGT TACCTTGGATGACAAGAAAGACAA (11883) ath- GGAAGAGGCAGTG AGGGAGCCAGGGAAGAGGCAGTG 2.20E−03 1.56 (+) miRf11042- CATGGGTA (16) CATGGGTAGAGACAAAACAGAGTC akr GTTTAATGTTTTAGTAAACTCAATC CATGCTCTGCTTGTTCCCTGTCTCT CT (11884) ath- TTTCTTGTGGAGG TTGTAATTTCTTGTGGAGGAAGCA 8.60E−11 3.85 (+) miRf11045- AAGCAAGAT (17) AGATGATGTGCTTACTTGTGGAATT akr TTTGTTATGTGAGTGAATACGATGA ATATATTTTAAGGGCCCTATATTTC CACAACCAAGCACATCCTCTTGCTT CCTCTCCACAAGAAATTACAA (11885) csi- TTGTAGAGAAAGA ATAAAGATGATGATGACAATGAAT 1.80E−04 1.68 (+) miR3946 GAAGAGAGCAC TTTGTAGAGAAAGAGAAGAGAGCA (18) CAAACTTTTTGCTGAAAGTAGCTTT GATTCGATGTGTATCGGTTCATAGA TAATGAGTTTTCAAGTCTATTTTAA TAGAATACTAAAAGTTAGCTCTAA AAATC (180) gma- ACAGAAGATAGAG TGAACAATATCTTGAACAGTTTGTT 2.00E−04 1.76 (+) miR156g AGCACAG (19) GACAGAAGATAGAGAGCACAGGT GATCATACCCAAAAAAGCTTTTGT GTGTGAGCAGTTTTGTGCTCTCTAT CTTCTGTCAATGTACTTCTCA (181) gma- TGACAGAAGACTA TGACAGAAGACTAGAGAGCACAAA 3.90E−04 1.58 (+) miR157c GAGAGCAC (20) GGAGTGAGATGCCATTCCCTTTCAT GCATTTCATCATCAGTGCTCTCTAT CTTCTGTCAA (182) gma- TTTGGATTGAAGG AATTAAAGGGGATTATGAAGTGGA 8.40E−03 1.59 (+) miR159a- GAGCTCTA (21) GCTCCTTGAAGTCCAATTGAGGAT 3p CTTACTGGGTGAATTGAGCTGCTTA GCTATGGATCCCACAGTTCTACCCA TCAATAAGTGCTTTTGTGGTAGTCT TGTGGCTTCCATATTTGGGGAGCTT CATTTGCCTTTATAGTATTAACCTT CTTTGGATTGAAGGGAGCTCTACA CCCTTCTCTTCTTTTCT (183) iba- TTGACAGAAGATA TTGACAGAAGATAGAGAGCATGCT 6.40E−04 1.60 (+) miR157 GAGAGCAT (22) AGAAATTACATTGATAAGCTATGT GGTTCAGAGACCAATCTTCTTATGA GTTCCAATAAGGAGTTGGTTTGTCC CCCCACTGGTATTATGTCTTCAGGT TGACCCTTCACCATGAGAATCATAT GTAATTCTCCGGCGGCGCTCATTGT GACCTGCCAATCGCCTCCGGCAAC TCCTCTTAGCTTCATCAAACTGGGC TAATTCATGAAACCTGCTGCATTGC TGACAGAAGCGCTGTTGAACTCCA TTTATAAGTACT (184) mdm- GGAATGGGCTGTT GAGAAGAGGGAAAGGGAGATTGG 1.50E−04 1.62 (+) miR482a- TGGGAACA (23) AGCTGCTGGAAGTTTTAGGAATGG 5p GCTGTTTGGGAACAAGGAAATTAC CACAATAATTGTCTTGTGGGGTTTC TTCCCAAGCCCGCCCATTCCTATGA TTTCCAGCTGTTCCTCCCTTTCCCTT GTCTC (185) mtr- TCAAAGGGAGGTG TTTATTTTTTTTACACTAAGATACT 2.20E−07 2.64 (+) miR2119 TGGAGTAG (24) CCCTACTTTCCTTTGATTGGAAATA AAGAGAGACAAAAAGGTAAATTTA ATTTCTCTTCTTATGTCAATCAAAG GGAGGTGTGGAGTAGGGTGTAAAA AGTAAA (186) osa- ATTGGATTGAAGG GATGAAGAAGAAGAGCTCCCTTTC 1.40E−03 1.67 (+) miR159e GAGCTCCT (25) GATCCAATTCAGGAGAGGAAGTGG TAGGATGCAGCTGCCGGTTCATGG ATACCTCTGGAGTGCAGGGCAAAT AGTCCTACCCTTTCATGGGTTTGCA TGACTCGGGAGATGAACCCGCCAT TGTCTTCCTCTATTGATTGGATTGA AGGGAGCTCCTCTAGCTACAT (187) osa- CTTGGATTGAAGG GAAGAAGAAGACGAGCTCCCTTCG 5.10E−03 1.75 (+) miR159f GAGCTCTA (26) ATCCAATCCAGGAGAGGAAGTGGT AGGATGCAGCTGCCGGTTCATGGA TACCTCTGCAGTGCATGTCGTAGGC TTGCACTTGCATGGGTTTGCATGAC CCGGGAGATGAACCCACCATTGTC TTCCTCTTATGCTTGGATTGAAGGG AGCTCTACACCTCTCTC (188) osa- GAGAGGAGGACG TCCCGTCATCGCTGCCGGCAAAGG 3.90E−04 1.63 (+) miR1858a GAGTGGGGC (27) GAGGGGGGGTGCCGCAACAAGGA GAGGAGGACGGAGTGGGGCGAGT GGAGCGTCAAAGGGGATGTCATCG CCGCCGAATCTGCTCGTGGGACAT CCCCTTCGATGCTCCACTCGCCCCA ATCCGTCCTCCTCTCCTTGTTGCGG CACCCCCCTTCGCTGGCAGCGACG ACGGCCTC (189) osa- TATGGATGGAGGT CCATAATCATCTATTAGTACAGTGG 7.80E−10 4.36 (+) miR1874- GTAACCCGATG TGAAGACATAGGGCTACTACACCA 3p (28) TCCATAAGGGTTCGAATCTTCGATG TGCCTAGATAGGGTACAGTTGGAT CCCATATGGATGGAGGTGTAACCC GATGCCTTTTACAAATAGATGGTTA TTTT (190) osa- GTGTTTGGTTTAG TCCAACCCATCCCACCTCGTCCCCA 5.50E−06 1.91 (+) miR1879 GGATGAGGTGG AACCAAACACATGCACGCAAATGG (29) CTTGTTGAGGAATAAACATCTTGCT CCCTTGCATTCTAAACTATGATATT CTTCAAGCATATGTGTTTGGTTTAG GGATGAGGTGGGATGGGTTAGGTC CA (191 (ATCCAACCCATCCCACCTCGTCCC CAAACCAAACACATGCACGCAAAT GGCTTGTTGAGGAATAAACATCTT GCTCCCTTGCATTCTAAACTATGAT ATTCTTCAAGCATATGTGTTTGGTT TAGGGATGAGGTGGGATGGGTTAG GTCCA (201) osa- CCTGTGACGTTGG CTGCGAGCCTCCAGCAGCGGCACA 1.90E−11 7.36 (+) miRf10839- TGAAGGTG (30) GGAGGAGGCCATTGCAGCTGTCAA akr GGACGTTGAGAAACTCGCACTTGG GCAGGAAGGGGAGCGAGGGGTCA ACAAACGGGCGGCCTTCCCCTGTG ACGTTGGTGAAGGTGTCGGAG (11886) osa- GGTTTGCCGGAGT CCAGCCATCCCTCTAGAGCCGGCG 7.70E−07 2.11 (+) miRf11013- TGGAGGAGA (31) AACTCCTCCCCTCCCCCCTCCCCCT akr TCCACTCCCACCCCACCCCACCCCG GGACCCTAACCCGTAGGGTCCTCG CCGGCGCCAGAGAAGAAGAGGTTT GCCGGAGTTGGAGGAGATGACATG G (11887) osa- AGGGATTTTGGAA TATAATATAAGGGATTTTGGAAGG 1.20E−06 1.64 (+) miRf11352- GGAGGTGACA (32) AGGTGACATATTCTAGGACTATGT akr ATCTGGATCCAGAGATACTAGGAT GTGTTACCTCCCTCTAAAATCCCTT ATATTATG (11888) osa- GGTGGAGGTGGAG GGTGGAGGTGGAGGTGGAGCTGTG 7.60E−09 2.57 (+) miRf11355- CTGTGCCAAA (33) CCAAATAGGCCCTGAGTTGTATGC akr ACCACCAGTTCAACCCAATAGCTT AAGGGTCTGCTTGGCACAGCTCCA GCTCCACGCAGCC (11889) osa- CATCGGTGTTGGA CATCGGTGTTGGAGGTGGCGGGGA 2.70E−06 2.10 (+) miRf11595- GGTGGC (34) CGAGGTGCTTCTCTAGAGCGGTGC akr CACTACTGCCACCACCGTGGAATT GACGAGGCACAATGCCCACCTCAC CCTCCGCTGCCACTCTGCTGCCACC GATG (11890) osa- AAACCGTGCAAAG TTACTTAAACCGTGCAAAGGAGGT 1.50E−09 4.07 (+) miRf11649- GAGGTCCC (35) CCCATGGCAGTATTTGCACCCGTTT akr TTACTAACGTGGCATCCTGTTGTAC GGTTTTTTTTGACGCAAATACTGCC ATGGGACCTCTTTTGCATGGTTTGA GTAA (11891) osa- ACGCGGAGGAGGT GCACGCGGAGGAGGTGGTGTTCTC 2.80E−04 1.51 (+) miRf11829- GGTGTTCT (36) GCCGGAGTACGAGGAGTTCGCCGT akr CAGGAACGCCGCCCTCTGCGTCC (11892) ppt- GTAGCTTAGCGAG GATTCATGTAATTATTGTTAACCTC 6.90E−13 12.97 (+) miR895 GTGTTGGTA (37) TTTGTGTTCCGAGCTTTTATGATTG GTAGCTTAGCGAGGTGTTGGTATG ATACCAATCCCTGGTTTGCTTGTTC CTAATTGAGTTATGCTTGCACTCAA ATCTAGGGGAGCGGTATTTTGGCT CACTCGCAATGCTTTCATGTACCCT TCCCGCATTATGAGTGCCACTTGGC TCCATGGTGTGATATATAAGTTTC (192) psi- CTTGGATTGAAGG TGGAGCTCCCTTCAGTCCAACCAA 9.90E−04 1.60 (+) miR159 GAGCTCCA (38) AGCTTGTGCGGCGGTGGTTCAGCT GCTGATTCATGCATTCGACTGCCCT GTCCGTGACTTTCCAGCAGCCTGA ATCAATCAATCTATCTCCATGACAG GATAGTGGTGTGCATGACGCAGGA GATGTATTGTCACTGGACACGCATT CCTTGGATTGAAGGGAGCTCCA (193) pta- CAGAAGATAGAGA GATGACAGAAGATAGAGAGCACAT 3.50E−04 1.58 (+) miR156a GCACATC (39) CCGCTCACATGCCGGGACTCTGCG TTTGAGGTGTATGTGGTCTCCATGA TTCTGTCATC (194) pta- CAGAAGATAGAGA GATGACAGAAGATAGAGAGCACA 1.80E−04 1.65 (+) miR156b GCACAAC (40) ACCGCTCAGATGCCGGCACTCTGC GTTTGAGGTGTATGTGCTCTCGTTG ATTTTGTCATC (195) ptc- TGGTGCACCTGGT CTAGTTCCGGAGCCCGGTGAACTTT 7.40E−06 2.02 (+) miRf10148- GGTGGAG (41) ATCACCACTTCCTGCTCCTCTTGGC akr AAGCTTCCAGGTGGAGGAGGTGGA CGAGGTGGTCCACCAGGTGGAGGA GGTGGTGGTGGTGGTGCACCTGGT GGTGGAGGTGG (11893) ptc- TCCTTTGGGGAGA ATGGTTGGAGAAGCTTCCGATCTC 1.70E−06 1.88 (+) miRf10226- TGGAGAGCTT (42) CCTCAAAGGCTTCCTCTATAATTGC akr CTTACATGATGGCATTAGTGGACTC CTTTGGGGAGATGGAGAGCTTACT CCCCAT (11894) ptc- TTGGATTGAAGGG GGGAGTGGAGCTCCTTGAAGTCCA 6.60E−03 1.65 (+) miRf10271- AGCTCTAA (43) ATAGAGGTTCTTGCTGGGTAGATT akr AAGCTGCTAAGCTATGGATCCACA GTCCTATCTATCAACCGAAGGATA GGTTTGCGGCTTGCATATCTCAGGA GCTTTATTGCCTAATGTTAGATCCC TTTTTGGATTGAAGGGAGCTCTAA ACCC (11895) ptc- TTTGGAAAGCAAG TATACATATATCTCACTTGCTTTCT 2.70E−06 2.38 (+) miRf10300- TGAGGTG (44) CAACTATCTCACTTTTCTTTTCAGA akr TTTCAAAAAAACGACATCATGAGA CAGTTTGGAAAGCAAGTGAGGTGT GTGTATA (11896) ptc- TTGGGGAGCTGGA TGACGGATTCGGAGAACAGCTGTC 1.20E−04 3.58 (+) miRf10522- CTCTGGA (45) GGTGTTGATGGTGGCTGTGGGCAG akr AGGACATTTCAGAATTTGGGGAGC TGGACTCTGGAGCAGTGG (11897) ptc- GTTGGGCTTGCTG TCTGCTTCGGGTGGCAGGTCTGGC 8.80E−07 2.47 (+) miRf10619- CTGGAGGA (46) GGTTGTAGAGGGGGCAGCGACGTT akr GATGATCTTCGCTCCTGTTGGTTGC CGTGGCGGTTGGGCTTGCTGCTGG AGGAAGA (11898) ptc- CAGAAGATAGAGA GTTGACAGAAGATAGAGAGCACTG 3.20E−04 1.70 (+) miRf10985- GCACTGA (47) ACGATGAAATGCATGGAGCTTAAT akr TGCATCTCACTCCTTTGTGCTCTCT AGTCTTCTGTCATC (11899) ptc- CTTGGTGAATGGT TGGGACAGCTTGGTGAATGGTTGG 3.70E−07 1.84 (+) miRf11757- TGGGAGGAAT (48) GAGGAATGTCTTTAATGTGGTTATG akr CATCAGTGAAACTCTAGTAAGATT CTCTGTCCACTCCTCTGCATCCGGC ACTTCTCTTAACCGTGCACCTGCTT TAACCA (11900) ptc- CCCAACTTGGAGG GCGTCCAGACCCAACTTGGAGGTG 8.30E−04 1.73 (+) miRf11844- TGGGTGTGG (49) GGTGTGGACGCGTCCAACCCCAAG akr TTGGGCGTGGATGCGTCCAGGCCT AATTTCGAGTTGGGCGTAGACGC (11901) ptc- GAAAGTGTGGAGA ACTTTTCTACGAAAGTGTGGAGAA 4.30E−07 2.28 (+) miRf11847- AGGTTGCC (50) GGTTGCCCCTAAAAAATCTTTTATG akr GCGACTTTCTCGACATTTTGGTAGA AAAGT (11902) ptc- GGCAGAGCATGGA CGGGGAACAGGCAGAGCATGGATG 5.90E−05 3.96 (+) miRf11855- TGGAGCTA (51) GAGCTACTAACAGAAGTACTTGTT akr TTGGCTCTACCCATGCACTGCCTCT TCCCTG (11903) sbi- TTTGGATTGAAGG AGCGAAGCTCCTATCATTCCAATG 1.20E−02 1.59 (+) miR159a GAGCTCTG (52) AAGGGCCCTTTTCATGGGTGGTTCC GCTGCTCGTTCATGGTTCCCACTAT CCTATCTCATCATGTATGTGTGTAT GTACTCTAGAGGGCCCGAGAAGAG ATTCATGTGGTCGTCAGTCTTTGAG ATAGGCTTGTGGTTTGCATGACCG AGGAGCTGCACCGTCCCCTTGCTG GCCGCTCTTTGGATTGAAGGGAGC TCTGCA (196) smo- TGGAAAAAGGAG GCCCATGAACAAGAGTGCACCCCC 7.50E−10 3.98 (+) miR1103- GTGCATTCTTGT TTTCCAATCGGTTAAAGGTCTTAGG 3p (53) ATAGTTGGAGTTTAAGCGTCCTTGG GTTTGAATAGTACTGGGCTGGGTG ACCTCCCGGGAAGTCCAAATTCAG GAGCTTACATTAACCCCAAGTATTC CAAAACGCTTAATCGATTGGAAAA AGGAGGTGCATTCTTGTTCATAGG CCC (197) smo- CTGACAGAAGATA TGGACTGCTGCTGACAGAAGATAG 2.50E−04 1.62 (+) m1R156b GAGAGCAC (54) AGAGCACAGACGTTTGGCTGCAAG AGCGGAATCCATATCCAGCAGCTC TGCGTTCGTGCTCTCTATTCTTCTG TCATCAATCTTTCGA (198) tae- CGGTTGGGCTGTA CATTCGGATTCGCCATCATACGTCC 7.90E−05 2.99 (+) miR2003 TGATGGCGA (55) AACCGTGCATTTGATATGCATATAT ATGCATCACGAGCAACGGTTGGGC TGTATGATGGCGATACCGATTG (199) zma- TGGGAGATGAAGG AGTGGGAGATGAAGGAGCCTTGCA 7.80E−06 2.19 (+) miR482- AGCCTT (11874) TCGATGTCACCGCCGGAGGAGCGC 5p TCGCCTTCTTCGCGCACCGCCGCAA TAGCCGCCCTCGGACCCCTCGCCTC GCTCTTCCTTGTTCCTCCCATTTT (11904) * NA = not available

TABLE 2 Differentially Expressed (Down-regulated) Small RNAs in Soybean Plants Growing under Drought (5 days) versus Optimal Conditions. Mature miR Sequence Fold- Name (SEQ ID NO:) Stem Loop Sequence (SEQ ID NO:) p-Value Change aly- GTTCAATAAA TCTACGTGACCCTCTCTGTATTCTTCCACAGCTTTCT 7.20E−08 2.93 (−) miR396a- GCTGTGGGAA TGAACTGCAAAACTTCTTCAGATTTGTTTTTTTTAT 3p G (57) ATATATGTCTTACGCATAAAATAGTGTTTTTGTTCA CATCTCTGCTCGATTGATTTGCGGTTCAATAAAGCT GTGGGAAGATACGGACAGAGTCAAAGA (202) aly- GCTCAAGAAA GAAGAAGAAGAAGAAGATCCTGGTCATATTTTTCC 2.10E−08 4.25 (−) miR396b- GCTGTGGGAA ACAGCTTTCTTGAACTTTCTTTTTCATTTCCATTGTT 3p A (58) TTTTTTTTTCTAAACCAAAAAAAAAGATCTCTAAAA TTTAGCATTTTGGAAACAAAGAAGAAGCTCAAGAA AGCTGTGGGAAAACATGACAATTCAGGGTTTTACT CCATTGATTC (203) bdi- ATTGAGTGCA GCAAAGGCATCATTGAGTGCAGCGTTGATGAACAG 1.60E−02 1.73 (−) miR2508 GCGTTGATGA GGGCCAGGCGACCGGCGGCCGGTCCGGTTCGGTTC AC (59) ACCGGCGCTGCACACAGTGACGCCCTTGC (204) ctr- TTGAGCCGCG ATCGACGGTTGAAGGGGAGAGTTGTAAAATGAAAT 7.00E−04 1.90 (−) miR171 TCAATATCTC CATCAAGGTATTGGCGCGCCTCAATTTAAAGACGT C (60) GGTTAAATGGGCATGATTAGCCATGTATTTTCATTG AGCCGCGTCAATATCTCCTTAATTATTTTGTAACTC TCTCCTCTATATCCTCGCCTTCGGTATGCAGCTGCT CCTCGATACATATGAGGATTCAGAAACAGACAAAG GCGGTAGAAGTAATCTTCATCAATATTATTGAAGC AGGAAACATAACGGCAAGTTTTAAGACCCGTTTGG GGCATGTGGGGTCTCATTTTGATGTTAATGAAGTGA AAACTTGTATTTTCCCTCAAACATTCACTCACTCCA GGCCGGCAGGAACAAC (205) gma- TCTCATTCCA CAGTGTTTGGCAGAGGTGTATGGAGTGAGAGAAGG 3.20E−03 1.61 (−) miR1507a TACATCGTCT GAAAGGGTATTTTCCGATTCTGTCGTTACTCTCTTC GA (61) CCTCTCTCATTCCATACATCGTCTGACGAACGTATC (206) gma- AGCTGCTTAG GGGTGAATTGAGCTGCTTAGCTATGGATCCCACAG 7.30E−07 2.63 (−) miR159d CTATGGATCC TTCTACCCATCAATAAGTGCTTTTGTGGTAGTCTTG C (62) TGGCTTCCATATCTGGGGAGCTTCATTTGCCT (207) gma- AAGAAAGCT GGTCATGCTTTTCCACAGCTTTCTTGAACTTCTTAT 8.90E−06 2.12 (−) miR396d GTGGGAGAAT GCATCTTATATCTCTCCACTTCCAGCATTTTAAGCC ATGGC (63) CTAGAAGCTCAAGAAAGCTGTGGGAGAATATGGCA A(208) gma- AAGTGATGAC TTGTTAGTTGCCTTTCGTTAAGTGATGACGTGGTAG 2.10E−03 1.86 (−) miR4371b GTGGTAGACG ACGGAGTGCCGTGTCATTATGCCTTGTCACAGACA GAGT (64) CCTCATTGCTACATCATCACCGCTAATGATATGGCA CTGACGTGTTAGTGATTGGTGTGATGACGTGACACT CTATCTGCCACATCATCACCTAACGGAAGACAACT AACGA (209) gma- TACGCAGGAG AAGGTTTGCTACGCAGGAGAGATGACGCTGTCCCT 6.10E−05 2.57 (−) miR4376- AGATGACGCT TGCACCCATCCTAGCTTCCCTTGAGTAGGTAAGAGC 5p GT (65) AAGGCCAGCCAGCATCATATCTCCTGCATAGTAAA CCTT (210) gma- ACGGGTCGCT CTTTGATCTGGGTGAGAGAAACGCGTATCGATGGA 1.40E−03 3.07 (−) miR4416a CTCACCTAGG TTGGGTTCAGTTCTGGTCTCACACGGTTTGTTCTAA (66) CAATTTGTACTGACTGTGTTTTGATCGATACGGGTC GCTCTCACCTAGGCCAGAGTTGC (211) gma- TCTTCCCAAT TCAGAATTTGTGGGAATGGGCTGATTGGGAAGCAA 1.30E−05 2.05 (−) miR482a- TCCGCCCATT TGTGTGCTGGTGCAATGCATTTAATTTCTTCCCAAT 3p CCTA (67) TCCGCCCATTCCTATGATTTCTGA (212) gma- TATGGGGGGA GGTATGGGGGGATTGGGAAGGAATATCCATAAGCA 3.20E−08 1.71 (−) miR482b- TTGGGAAGGA AAATATGCTATTTCTTCCCTACACCTCCCATACC 5p AT (68) (213) gso- TCGGCAAGTT AGCCAAGGAUGACUUGCCGGCAUUAGCCAAGUGA 1.20E−05 2.46 (−) miR169g* GGCCTTGGCT AUGAGCAUCAUAUAUAUAUAUAUAUAUAUAUAU (69) GACUCAUGUUCUUGUCGGCAAGUUGGCCUUGGCU (11905) gso- TCTTCCCTAC GGGGAAGGCATGGGTATGGGGGGATTGGGAAGGA 1.60E−02 1.74 (−) miR482a ACCTCCCATA ATATCCATAAGCAAAATATGCTATTTCTTCCCTACA C (70) CCTCCCATACCACTGTTTTTCCT (214) osa- GTCTTATAAC TACTACCTCCATTTCAGGTTATAAGACTTTCTAGTG 2.10E−02 1.84 (−) miRf11996- CTGAAACGGG TTGCTCACATTCATATATATGTTAATAAATTCATTA akr GG (71) ACATATAGAAAGTCTTATAACCTGAAACGGGGGAA GTA (11906) ppt- TCGGACCAGG GCCGAGAACAGAGATTGTGTAGCTCAGCTGTAAGG 2.20E−05 1.77 (−) miR166m CATCATTCCT AATGTGGCATGGCTCGATGCTGTTTGAGCATGTCA T (72) AGTTCAGCCTCGGACCAGGCATCATTCCTTTCATCT CAGTTACACATTTGACATCCAGGA (215) pta- CCGGACCAGG ACCAATCGAATCCGGACCAGGCTTCATCCCAGGCA 8.30E−04 1.59 (−) miR166c CTTCATCCCA TCTGGACCCAATCGACAGCAGCTCCTTTAGCCTTTG G (73) AAAGGAACTCTGTCAAGGTCTCCTCTGCTATAGAC AGGAGTCCAGCGGGGCTAGCATCTCTTGGGGGATG CTGAGGTGTTGGATTATGTTGGT (216) ptc- TCGGACCAGG TAAGGTTGAGAGGAACGCTGTCTGGGTCGAGGTCA 4.70E−05 1.77 (−) miR166p CTCCATTCCT TGGAGGCCATGATTATACATAAATGGCATTATCTG T (74) ATGACAGCCCAGATAATCGATGCACCTGTCTTGAA CCTAAATGATTCTCGGACCAGGCTCCATTCCTTCCA ACCAT (217) ptc- AAGATGGAG GTGTGTGAGCAAGATGGAGAAGCAGGGCACGTGC 6.10E−04 1.56 (−) miRf11079- AAGCAGGGC ACTACTAACTCATGCACACAGAGAGGGAGACGCAT akr ACGTGC (75) TTCTTGCTGGAGTTACGAGTTACGACTCTTACCTAC TATTGATTTTGTTAGCTCCAGTGAGTTAGTTATTCA TGTGCCTGTCTTCCTCATCATGATCACTAC (11907) ptc- CAAGGCTCTG CTTGGTCATCAAGGCTCTGATACCATGTCAAAGAA 1.70E−05 1.81 (−) miRf11396- ATACCATGTC TCATATTTTGAGACCTTATCTAACAGCTTAAGCTAT akr AA (76) TGGGTTGAGATGGTTCCTTGACATGATATCAGAGC CTTGATGACGAAG (11908) ptc- CAAGGCTCTG GCTTGGTCATCAAGGCTCTGATACCATGTTAAAGA 2.30E−04 1.63 (−) miRf11669- ATACCATGTT ACCATCTCAACCTAATACCATGTTAGAGAATAATA akr (77) TAAATCATATCTAGAGACTTTACCTAACAGCTTAAG CTATTGGCCTATTGGATTAGTATGGTTCTTTGACAT GGTATCAGAGCCTTGATAACCAAGT (11909) vvi- TTGGCATTCT ACAGAGTTTATTGGCATTCTGTCCACCTCCCATCTC 6.70E−03 1.55 (−) miR394b GTCCACCTCC TTGAAAATCTCTCTTTTCTCTCTGTGGAGGTGGGCA (78) TACTGCCAACCAAGCTCTGTT (218) zma- GTTCAATAAA AGATGGCCTTCTTTGTGATCTTCCACAGCTTTCTTG 2.10E−08 4.76 (−) miR396b- GCTGTGGGAA AACTGCATCTCTCAGAGGAGCGGCAGCTTCAACTC 3p A (79) CTCCACCCGCATCAGCAGGTGCATGCAGTTCAATA AAGCTGTGGGAAACTGCAGAGAGAGGCCAG (219)

TABLE 3 Differentially Expressed (Up-regulated) Small RNAs in Soybean Plants Growing under High Salt (10 days) versus Optimal Conditions. Mature Sequence (SEQ miR Name ID NO:) Stem Loop Sequence (SEQ ID NO:) p-Value Fold-Change ppt-miR895 GTAGCTTAGC GATTCATGTAATTATTGTTAACCTCTTTGTG 7.20E−10 9.36 (+) GAGGTGTTGG TTCCGAGCTTTTATGATTGGTAGCTTAGCGA TA (80) GGTGTTGGTATGATACCAATCCCTGGTTTGC TTGTTCCTAATTGAGTTATGCTTGCACTCAA ATCTAGGGGAGCGGTATTTTGGCTCACTCG CAATGCTTTCATGTACCCTTCCCGCATTATG AGTGCCACTTGGCTCCATGGTGTGATATAT AAGTTTC (220) ptc- TTTGGAAAGC TATACATATATCTCACTTGCTTTCTCAACTA 1.40E−07 6.02 (+) miRf10300- AAGTGAGGTG TCTCACTTTTCTTTTCAGATTTCAAAAAAAC akr (81) GACATCATGAGACAGTTTGGAAAGCAAGTG AGGTGTGTGTATA (11910) osa- CCTGTGACGTT CTGCGAGCCTCCAGCAGCGGCACAGGAGGA 6.20E−09 5.21 (+) miRf10839- GGTGAAGGTG GGCCATTGCAGCTGTCAAGGACGTTGAGAA akr (82) ACTCGCACTTGGGCAGGAAGGGGAGCGAG GGGTCAACAAACGGGCGGCCTTCCCCTGTG ACGTTGGTGAAGGTGTCGGAG (11911 smo- TGGAAAAAGG GCCCATGAACAAGAGTGCACCCCCTTTCCA 6.50E−08 5.20 (+) miR1103-3p AGGTGCATTCT ATCGGTTAAAGGTCTTAGGATAGTTGGAGT TGT (83) TTAAGCGTCCTTGGGTTTGAATAGTACTGG GCTGGGTGACCTCCCGGGAAGTCCAAATTC AGGAGCTTACATTAACCCCAAGTATTCCAA AACGCTTAATCGATTGGAAAAAGGAGGTGC ATTCTTGTTCATAGGCCC (221) osa- AAACCGTGCA TTACTTAAACCGTGCAAAGGAGGTCCCATG 9.70E−08 5.10 (+) miRf11649- AAGGAGGTCC GCAGTATTTGCACCCGTTTTTACTAACGTGG akr C (84) CATCCTGTTGTACGGTTTTTTTTGACGCAAA TACTGCCATGGGACCTCTTTTGCATGGTTTG AGTAA (11912) osa-miR1874- TATGGATGGA CCATAATCATCTATTAGTACAGTGGTGAAG 6.50E−09 4.75 (+) 3p GGTGTAACCC ACATAGGGCTACTACACCATCCATAAGGGT GATG (85) TCGAATCTTCGATGTGCCTAGATAGGGTAC AGTTGGATCCCATATGGATGGAGGTGTAAC CCGATGCCTTTTACAAATAGATGGTTATTTT (222) ptc- GTTGGGCTTGC TCTGCTTCGGGTGGCAGGTCTGGCGGTTGT 2.00E−08 3.70 (+) miRf10619- TGCTGGAGGA AGAGGGGGCAGCGACGTTGATGATCTTCGC akr (86) TCCTGTTGGTTGCCGTGGCGGTTGGGCTTGC TGCTGGAGGAAGA (11913) osa- GCTGGAGGAT GCCGGCTAGTACAATCGAATCCACTAGCAC 7.50E−08 3.48 (+) miRf10362- GCGACGGTGC CGAGGCTTGGGTCACTAGATCCCGTGGCCC akr T (87) TAGCCTAATTGCTGGAGGATGCGACGGTGC TTGTGAGC (11914) ahy-miR3514- AGGATTCTGT ACAATAGAAGGATTCTGTATTAACGGTGGA 2.40E−08 3.43 (+) 5p ATTAACGGTG CATGATTTATCTCGTTTTTAAAGATATCTTT GA (88) GCATTTCATATGAGATTTAAAGTTTTTATTG GTAATATAAATCTCACATGAAATTTAAATTT ATATTTTAAAGTTAAGATAAAGTCATGTCA CCGTTAATACAGAATCCTTCAATTATATTTA GTCAGGGG (223) mtr-miR2119 TCAAAGGGAG TTTATTTTTTTTACACTAAGATACTCCCTAC 2.00E−07 2.89 (+) GTGTGGAGTA TTTCCTTTGATTGGAAATAAAGAGAGACAA G (89) AAAGGTAAATTTAATTTCTCTTCTTATGTCA ATCAAAGGGAGGTGTGGAGTAGGGTGTAA AAAGTAAA (224) osa- GGTGGAGGTG GGTGGAGGTGGAGGTGGAGCTGTGCCAAAT 2.40E−07 2.85 (+) miRf11355- GAGCTGTGCC AGGCCCTGAGTTGTATGCACCACCAGTTCA akr AAA (90) ACCCAATAGCTTAAGGGTCTGCTTGGCACA GCTCCAGCTCCACGCAGCC (11915) osa- CATCGGTGTTG CATCGGTGTTGGAGGTGGCGGGGACGAGGT 8.90E−06 2.77 (+) miRf11595- GAGGTGGC GCTTCTCTAGAGCGGTGCCACTACTGCCAC akr (91) CACCGTGGAATTGACGAGGCACAATGCCCA CCTCACCCTCCGCTGCCACTCTGCTGCCACC GATG (11916) ptc- CCCAACTTGG GCGTCCAGACCCAACTTGGAGGTGGGTGTG 1.20E−05 2.75 (+) miRf11844- AGGTGGGTGT GACGCGTCCAACCCCAAGTTGGGCGTGGAT akr GG (92) GCGTCCAGGCCTAATTTCGAGTTGGGCGTA GACGC (11916) ptc- GAAAGTGTGG ACTTTTCTACGAAAGTGTGGAGAAGGTTGC 2.50E−06 2.70 (+) miRf11847- AGAAGGTTGC CCCTAAAAAATCTTTTATGGCGACTTTCTCG akr C (93) ACATTTTGGTAGAAAAGT (11917) ath- TTTCTTGTGGA TTGTAATTTCTTGTGGAGGAAGCAAGATGA 4.40E−07 2.59 (+) miRf11045- GGAAGCAAGA TGTGCTTACTTGTGGAATTTTTGTTATGTGA akr T (94) GTGAATACGATGAATATATTTTAAGGGCCC TATATTTCCACAACCAAGCACATCCTCTTGC TTCCTCTCCACAAGAAATTACAA (11918) 8.90E−07 2.51 (+) ath- GTGGGAGGAC AAACATGTGGGAGGACTCCAAGTGTGGTTA miRf10702- TCCAAGTGTG TATCCTCGGTATTATCTCGATGTGAACCACA akr (95) CTTGGAGTCCTCCCACATGTTT (11919) ath- TGCAGTTCCTG GGTGCCGCTGCAGTTCCTGGAGGTGGAGGA 1.40E−06 2.40 (+) miRf10701- GAGGTGGAGG GGTGGTGGTGGGGCCACTGCAGCTCTTGGA akr A (96) GGTGGAGGCGGTGGAGGTGGAGCCGCTATA GTTGTTGGAAGTGGAGGAGGTGGCGGTGGT GGT (11920) osa-miR1869 TGAGAACAAT AAGGAACACCTGAGAACAATAGGCATGGG 2.20E−05 2.27 (+) AGGCATGGGA AGGTATTGGGAAAACACAGGAACATATTGT GGTA (97) GACCCCTAATTTTAAAGGGAAATAATGGTT GAGGCTTTCCTCCATGTTCCCATGCCTAATG CTCTTAGGTGCTCTTTTT (225) ptc- TGGTGCACCT CTAGTTCCGGAGCCCGGTGAACTTTATCAC 2.80E−05 2.22 (+) miRf10148- GGTGGTGGAG CACTTCCTGCTCCTCTTGGCAAGCTTCCAGG akr (98) TGGAGGAGGTGGACGAGGTGGTCCACCAG GTGGAGGAGGTGGTGGTGGTGGTGCACCTG GTGGTGGAGGTGG (11921) osa-miR1879 GTGTTTGGTTT TCCAACCCATCCCACCTCGTCCCCAAACCA 5.80E−05 2.21 (+) AGGGATGAGG AACACATGCACGCAAATGGCTTGTTGAGGA TGG (99) ATAAACATCTTGCTCCCTTGCATTCTAAACT ATGATATTCTTCAAGCATATGTGTTTGGTTT AGGGATGAGGTGGGATGGGTTAGGTCCA (226) (ATCCAACCCATCCCACCTCGTCCCCAAACC AAACACATGCACGCAAATGGCTTGTTGAGG AATAAACATCTTGCTCCCTTGCATTCTAAAC TATGATATTCTTCAAGCATATGTGTTTGGTT TAGGGATGAGGTGGGATGGGTTAGGTCCA (235) ath- GGTGGTGGAA TAGGGAATATCTTGATCTTTCCACCATCTAC 4.90E−06 2.21 (+) miRf10148- AGATCAAGAT AAAGAATAAAAAAAAAGCTTCCAATATTAC akr (100) TAGGTATTTGGTGGTGGAAAGATCAAGATA TTCCTTA (11922) osa- GGTTTGCCGG CCAGCCATCCCTCTAGAGCCGGCGAACTCC 4.70E−06 2.21 (+) miRf11013- AGTTGGAGGA TCCCCTCCCCCCTCCCCCTTCCACTCCCACC akr GA (101) CCACCCCACCCCGGGACCCTAACCCGTAGG GTCCTCGCCGGCGCCAGAGAAGAAGAGGTT TGCCGGAGTTGGAGGAGATGACATGG (11923) ath- ATGGTGGTAC TCCTCGACTTCCTGGTAGAGTGGTGTGATCG 8.60E−05 2.18 (+) miRf10209- TCGGCCAGGT AGTGATGGTCAGGTGTGGAGGTGATGATAC akr GGT (102) TCGACCAGGTGGTCAAGTGAAGTGATCAAG TGACTCTCATGGTGGTACTCGGCCAGGTGG TCGAGTGG (11924) ath- TGAGGCGTAT TGAGGCGTATCAGGAGGTAGTGTTCTTGGT 1.50E−04 2.18 (+) miRf10924- CAGGAGGTAG GGGACAATTTGTGTTGTATGTTTCA (11925) akr T (103) ppt-miR1220a TTCCGGTGGTG ACTTCTTGCACTCCTCTATCTCCCTCGGCAC 1.90E−06 2.15 (+) AGGAAGATAG CTGCACAGTGATTTTCTCAATATCTTCACGT (104) TGGTGGCCACGTTCGAACATATCCCATGCG GGCAACTCCGGCGTAGGTGTACACGGCCAG CGTTGCTTACCATCTGGAGGATACCCTTGCT CAAACCTACGACTCTGTTCCGGTGGTGAGG AAGATAGAGGAGTTCAAGAAGT (227) osa- CGCGCCGACG CGCCGTCTCCCTCGCCGTCGCCGGCGTCGCC 5.40E−06 2.12 (+) miRf11341- ATGACGGTGG GGAGATGACGAGAAGACGTGCCCCGGCGC akr AGT (105) GCCGACGATGACGGTGGAGTCGGCG (11926) osa- AGGGATTTTG TATAATATAAGGGATTTTGGAAGGAGGTGA 2.30E−06 2.11 (+) miRf11352- GAAGGAGGTG CATATTCTAGGACTATGTATCTGGATCCAG akr ACA (106) AGATACTAGGATGTGTTACCTCCCTCTAAA ATCCCTTATATTATG (11927) osa-miR2055 TTTCCTTGGGA AGAAGATGGAGGCACCAGCCCAAGGAAAC 7.20E−04 2.09 (+) AGGTGGTTTC ACAGACATTGACACGCAATTCAAGGAGAAG (107) ATTGCGTCCTACTTTTTCCTTGGGAAGGTGG TTTCTCTTCT (228) ath- ATCGAAGGAG GATTTCTCGTCCTCCGGCAATCCTTCGAACT 9.80E−07 2.03 (+) miRf10240- ATGGAGGACG CATCTTCATCCCAGTAATCGAAGGAGATGG akr (108) AGGACGAAGGCTTC (11928) ath- CACCGGTGGA GGACTTCTCATCTTCTTTCTTAGCCGCCGGT 6.30E−07 1.99 (+) miRf10068- GGAGTGAGAG GCTCCAGCTCCACCACCGTGTCCTCCAACAT akr (109) TACCGTGGCTTCCAGTTCCACCGGTGGAGG AGTGAGAGTGGGAAGTTT (11929) ghr-miR2950 TGGTGTGCAG CATGGGTTTATGTTATATTCCATCTCTTGCA 5.70E−06 1.98 (+) GGGGTGGAAT CACTGGACTAGCCAGCTTTTTGTTGGCTTCA A (110) GCTTCAGGTTGGTGTGCAGGGGGTGGAATA CATCATTGATATCATG (229) ath- ACTTGGGTGG TGGTAAGTGATAATCATTACCACCCAAGCT 7.90E−04 1.98 (+) miRf10368- TGCTGATTAT AACATTCAAACCAAAAACCAGTTTAAGTTA akr (111) ACTTGGGTGGTGCTGATTATCACTTGTCG (11930) ath- GGTGGTGAAG GGCGGTGGTGAAGAAGCATGGTTTGGAAAT 9.30E−05 1.93 (+) miRf10763- AAGCATGGTT CTCACAGCCTGGATTAGAGCCATATGAAGG akr (112) GCTCACATGGGAGATGACCAAGAAAAGAG ACGACACTGAAGTCCACAAGTTAGAATTAT ATAGTGAAGTTTCTACATTATTTTCTCACCA CCGCT (11931) ptc- CATCTAGGTG TCTTACCATTGGACCACCTACTAGATGATTA 4.30E−04 1.92 (+) miRf10734- GTGGTCCAGT AAAACTACATCATCTAACCATCTAGGTGGT akr G (113) GGTCCAGTGGTAAGA (11932) osa- ACGCGGAGGA GCACGCGGAGGAGGTGGTGTTCTCGCCGGA 4.10E−05 1.90 (+) miRf11829- GGTGGTGTTCT GTACGAGGAGTTCGCCGTCAGGAACGCCGC akr (114) CCTCTGCGTCC (11933) zma-miR482- TGGGAGATGA AGTGGGAGATGAAGGAGCCTTGCATCGATG 4.20E−05 1.88 (+) 5p AGGAGCCTT TCACCGCCGGAGGAGCGCTCGCCTTCTTCG (115) CGCACCGCCGCAATAGCCGCCCTCGGACCC CTCGCCTCGCTCTTCCTTGTTCCTCCCATTTT (230) osa- TGGAAAGTTG ATGTGATGGAGATGCGATGGAAAGTTGGGA 1.30E−05 1.86 (+) miR1850.1 GGAGATTGGG GATTGGGGGAAGTTGTGTGTGAACTAAACG G (116) TGGATTGGGGCCCTGTTTAGTTCACATCAAT CTTCCTCCAAATTCCCAACTTTTCATCACAT CACAATCACAT (231) osa-miR1881 AATGTTATTGT AACCAAGTTAAAATGCTCATAGGTATGAAC 2.00E−03 1.76 (+) AGCGTGGTGG AAGCATCAATGTTATTGTAGCGTGGTGGTG TGT (117) TGACCTCTGTGCACGTAAGCTTGAGGCAGC AAGTTCGACTCCTTCAAAAGGAAGATTTGT ACCGCTGGGGAAGTGCCAGAAGAAAAGAA CAAGGAAGACTTGCTAGCAGGACAAAAGG ACGGTAAACTTGGAAAAAAAAAGGTCCAG AAGAAAAGAACAAAGAAGAACTGCTTGAA GGAGTCGAACTTGCTACCTCAAGCTTGCGT GCACATAGGTCACACCACTACGCTACAATA ACGTTGATGCTTGTTCAGACCTGTGAGCATT TTAACTTGGTT (232) ptc- TCCTTTGGGGA ATGGTTGGAGAAGCTTCCGATCTCCCTCAA 9.60E−05 1.74 (+) miRf10226- GATGGAGAGC AGGCTTCCTCTATAATTGCCTTACATGATGG akr TT (118) CATTAGTGGACTCCTTTGGGGAGATGGAGA GCTTACTCCCCAT (11934) ptc- CTTGGTGAAT TGGGACAGCTTGGTGAATGGTTGGGAGGAA 3.90E−05 1.73 (+) miRf11757- GGTTGGGAGG TGTCTTTAATGTGGTTATGCATCAGTGAAAC akr AAT (119) TCTAGTAAGATTCTCTGTCCACTCCTCTGCA TCCGGCACTTCTCTTAACCGTGCACCTGCTT TAACCA (11935) ath- GAGGTTTGCG GATGTTGGAGGTTTGCGATGAGAAAGAGAT 1.50E−03 1.66 (+) miRf11021- ATGAGAAAGA TGGCCGGAAGAATTATCAGCCATCAACATC akr G (120) GAGATTGTGAGATAATCGGAAGACCTGTAA TTGTGAAGGTAACTCTTTCTCATCTGCAAAT CTCAACTGTC (11936) ath- TGGCGGTGGA GTGGATACTGTTCTGGTGGAGGATACTTCA 6.50E−04 1.65 (+) miRf10633- TACTTCTTGAT CCGGCGGATGAGGGTAAGTCTTGATCGGTG akr CGG (121) GTGGATACTTCACCGGTGGATGCTCGTATG GTGGCGGTGGATACTTCTTGATCGGTGGTG GATAC (11937) ptc- TTGGCGGTGA GAGAAACGCTCTAATTAATCATCGTTATGC 1.90E−04 1.63 (+) miRf10132- TTGAACGGAG CACGTGTCTATTTACGGATAACGCAACGCT akr GGT (122) ACTAAATCGCGAATTTTAGTTTGAGTGGAA GATCTTGGCCGTTGGATTGGCGGTGATTGA ACGGAGGGTTGATC (11938) ptc- CAACTTAGAG GCCCTTAACCAACTTAGAGTTGGGGGTGGG 5.20E−03 1.61 (+) miRf11315- TTGGGGGTGG CACGTCATGGGTCAACCTAGGGTTGGTCTC akr (123) GGACTCGCCCTTGCTCAACTTAGAGTTGGG TACGGGC (11939) aly-miR831- AGAAGAGGTA AAGTGCTACAAGAATGTATAGTCTTAGAGT 1.60E−03 1.61 (+) 5p CAAGGAGATG CTCAAGAAGAGGTACAAGGAGATGAGAAG AGA (124) TGAATCACTGAAACAAGTGGTTCTGGTTTG TGGATCAGTATGGTTTACCCAAAACACGTG TTTGGTGCTTCACTTCTAAACTCCTCGTACT CTTCTTGGGATTCTATGACTTACACTTGTTG ATTT (233) csi-miR3948 TGGAGTGGGA AGGAGTGTGGAGTGGGAGTGGGAGTAGGG 7.10E−05 1.55 (+) GTGGGAGTAG TGTTTACTTAGACTAAATGAAAGTATGGAT GGTG (125) TATCAATCAGAATCCTAATTATTTGTTTACT TTGTCTTGGATTGGGAGTAAATTATTTTAAA TTATAATTTTATCCTTATGTACAAAATTATA A (234)

TABLE 4 Differentially Expressed (Down-regulated) Small RNAs in Soybean Plants Growing under High Salt (10 days) versus Optimal Conditions. Mature Sequence miR Name (SEQ ID NO:) Stem Loop Sequence (SEQ ID NO:) p-Value Fold-Change aly-miR160c-3p GCGTACAAGGAG CATATAATAGTTTGTCGTCGTTATGCCTGGCT 7.60E−04 1.59 (−) CCAAGCATG CCCTGTATGCCACGAGTGGATACCGATTTTGT (126) TATAAAATCGGCTGCCGGTGGCGTACAAGGA GCCAAGCATGACCATAAGCATATG (236) aly-miR396a-3p GTTCAATAAAGCT TCTACGTGACCCTCTCTGTATTCTTCCACAGC 1.20E−09 5.50 (−) GTGGGAAG (127) TTTCTTGAACTGCAAAACTTCTTCAGATTTGT TTTTTTTATATATATGTCTTACGCATAAAATA GTGTTTTTGTTCACATCTCTGCTCGATTGATT TGCGGTTCAATAAAGCTGTGGGAAGATACGG ACAGAGTCAAAGA (237) aly-miR396b-3p GCTCAAGAAAGC GAAGAAGAAGAAGAAGATCCTGGTCATATTT 9.00E−07 3.80 (−) TGTGGGAAA TTCCACAGCTTTCTTGAACTTTCTTTTTCATTT (128) CCATTGTTTTTTTTTTTCTAAACCAAAAAAAA AGATCTCTAAAATTTAGCATTTTGGAAACAA AGAAGAAGCTCAAGAAAGCTGTGGGAAAAC ATGACAATTCAGGGTTTTACTCCATTGATTC (238) ath-miRf10197- CACTCGACCAAG GGTGAAGACACTCGACCTCGTGGTCGAGTGA 2.90E−07 3.71 (−) akr GGGGTCGAGTGA TGTGATCGAGTGGTGGTCAGAAGATGGAGAT (129) GAAGTCACTCGACCAAGGGGGTCGAGTGATG TGATC (11940 ath-miRf10239- CGCCTTGCATCAA TCGGGCTCGGATTCGCTTGGTGCAGGTCGGG 1.00E−03 2.17 (−) akr CTGAATC (130) AACCAATTCGGCTGACACAGCCTCGTGACTT TTAAACCTTTATTGGTTTGTGAGCAGGGATTG GATCCCGCCTTGCATCAACTGAATCGGATCC TCGA (11941) ath-miRf10279- ACTCAGCCTGGG TGATGGTGATACTCGACATCCAGGTAGAGTG 7.80E−06 4.99 (−) akr GGTCGAGTGAT ATGAGGTCGAGTAGAGGTCTGGCAATGGGAT (131) GAAGTCACTCAGCCTGGGGGTCGAGTGATGT GATCG (11942) bna-miR2111b- TAATCTGCATCCT GCACTTGATGAGGAACTGGTAATCTGCATCC 4.40E−04 2.55 (−) 5p GAGGTTTA (132) TGAGGTTTAAAAATACATAGGCACATGCAAA TGTGTGTATTATAGTTTTTAATCCTCGGGATA CAGATTACCTCTTCCTTTTACTGAA (239) bra-miR160a-3p GCGTATGAGGAG TATGTGTAGTTGTATAAGATGTGTATGCCTGG 1.90E−04 1.94 (−) CCATGCATA (133) CTCCCTGTATGCCATCCTCTAAGCTCATCGAC CATTGATGACCTCCGTGAATGGCGTATGAGG AGCCATGCATATTTTCATATACATTTACATAC (240 csi-miR162-5p TGGAGGCAGCGG AAACTGTTTACACTGATCTGTGCTGCTGATAA 1.60E−03 1.95 (−) TTCATCGATC ATCTTAATTTTTTTTTTTGAATTTTTATTTAAC (134) AGAAAATAGAGAGAGTGAAGTCACTGGAGG CAGCGGTTCATCGATCACTTTGTGCAAATTTT GTTGTGAAAAATAACACAAAATACATGAATC GATCGATAAACCTCTGCATCCAGCGCTCACT CCAACTCTATTC (241) gma-miR1524 CGAGTCCGAGGA GCGACTTATTGGAGTTCATTCTTCGCACTCTC 3.30E−03 1.73 (−) AGGAACTCC TCGGAAACCACTTGTTTCCAATCATCTAATCA (135) GACGATAGCAGACTCAAGAAAGACGTTTCCT TCCCAGATCCTTCTAGACCATTTGCAAACCGT CTCCTTCCCCGAATCCATTCTCCAAACCCTCG ATCCTTGAGGAGCTCCACCACCGTGACGGCG CTCCGGTCTCCGCCGTCAATTGTGCCGTCGCG GTGGAGCATGAGCGTCTTCATGAGTCTGAAA GGGAATTATAGGAACTACTTTCCTGATTAGG TTATTGGAAACAAGTGGTTTCCGAGTCCGAG GAAGGAACTCCAACGCCCAAC (242) gma-miR159d AGCTGCTTAGCTA GGGTGAATTGAGCTGCTTAGCTATGGATCCC 3.20E−06 3.24 (−) TGGATCCC (136) ACAGTTCTACCCATCAATAAGTGCTTTTGTGG TAGTCTTGTGGCTTCCATATCTGGGGAGCTTC ATTTGCCT (243) gma-miR2119 TCAAAGGGAGTT ATACTTCATTTTTTATACTTTAATTTCCTCTAT 2.70E−03 1.54 (−) GTAGGGGAA ACCTCACTTTTATTGGAGAAAAAAGAGAATA (137) GAAAATAGTGGATTTCTCTTCTTTTTTTCAAT CAAAGGGAGTTGTAGGGGAAAGTTTAGAAA ATGGCGTGT (244) gma-miR396d AAGAAAGCTGTG GGTCATGCTTTTCCACAGCTTTCTTGAACTTC 4.60E−08 2.76 (−) GGAGAATATGGC TTATGCATCTTATATCTCTCCACTTCCAGCAT (138) TTTAAGCCCTAGAAGCTCAAGAAAGCTGTGG GAGAATATGGCAA (245) gma-miR4412- AGTGGCGTAGAT AACTGTTGCGGGTATCTTTGCCTCTGAAGGA 9.80E−05 3.03 (−) 3p CCCCACAAC (139) AAGTTGTGCCTATTATTATGGCTTATTGCTTT AGTGGCGTAGATCCCCACAACAGTT (246) gma-miR4416a ACGGGTCGCTCTC CTTTGATCTGGGTGAGAGAAACGCGTATCGA 9.20E−06 4.30 (−) ACCTAGG (140) TGGATTGGGTTCAGTTCTGGTCTCACACGGTT TGTTCTAACAATTTGTACTGACTGTGTTTTGA TCGATACGGGTCGCTCTCACCTAGGCCAGAG TTGC (247) gma-miR482b- TATGGGGGGATT GGTATGGGGGGATTGGGAAGGAATATCCATA 2.30E−10 2.74 (−) 5p GGGAAGGAAT AGCAAAATATGCTATTTCTTCCCTACACCTCC (141) CATACC (248) osa-miR162a TCGATAAACCTCT GGTGATGCCTGGGCGCAGTGGTTTATCGATC 4.00E−04 1.52 (−) GCATCCAG (142) CCTTCCCTGCCTTGTGGCGCTGATCCAGGAGC GGCGAATTTCTTTGAGAGGGTGTTCTTTTTTT TTCTTCCTTTTGGTCCTTGTTGCAGCCAACGA CAACGCGGGAATCGATCGATAAACCTCTGCA TCCAGTTCTCGCC (249) osa-miR1846e CAACGAGGAGGC CGCATCCGCCAACGAGGAGGCCGGGACCACC 4.30E−04 1.90 (−) CGGGACCA (143) GGATCCGGTGACTCCGGCCTCCTCGCCGGCA GATCCGG (250) osa-miR2104 GCGGCGAGGGGA ACGGGCGCTCACGGTGGCTTCGACCCTCGTC 3.90E−02 1.51 (−) TGCGAGCGTG TCGGCCGCGTGCGGTAGTGCGGGAGGCATGC (144) CGTGTGTACCGGCGGCGAGGGGATGCGAGCG TGAGTGCCTCGG (251) osa-miRf10849- TGGACTGTTTGGG GCTGGACTGTTTGGGGGAGCTTCTGATTTTGG 1.80E−03 1.52 (−) akr GGAGCTTCT (145) GAGAAACGGCTATAGCTAGAAGCTCCCCGAA ACAGGCCCAAC (11943) osa-miRf11415- GAGAGCAGGATG GAAGAGGCAGAGAGCAGGATGCAGCCAAGG 6.70E−03 1.55 (−) akr CAGCCAAGG ATGACTTGCCGGCCGGCGATGGCCGACGGCG (146) AGGTTAATTAATTGGCCGGAGACTGGCAGTC CTTCTCTGTTGATCCGGCAAGTTTGTCCTTGG CTACACCTTGCTCTCTTCTCGTC (11944) osa-miRf11996- GTCTTATAACCTG TACTACCTCCATTTCAGGTTATAAGACTTTCT 7.20E−03 2.01 (−) akr AAACGGGGG AGTGTTGCTCACATTCATATATATGTTAATAA (147) ATTCATTAACATATAGAAAGTCTTATAACCT GAAACGGGGGAAGTA (11945) ppt-miR533b-5p GAGCTGTCCAGG GGAGGACCGATATGGAGAGCTGTCCAGGCTG 7.90E−04 3.23 (−) CTGTGAGGG TGAGGGGAGCACTCGTATTCTTTTGACCTTTG (148) CTAGAAGAGGGAATACAGCGCTCTCCCTCAC AGTCTGTACAGCTCTCTGTATCTCTTCCTCT (252) ptc-miRf10007- CATTGACAGGGA TTGCTGTGGTGAGTTTCCCTGTCAGTGCTCAC 3.90E−02 1.77 (−) akr AACTCACCA (149) TACGATATTTAATGAAGAAGAAAAATAAAGC AAGAGATAAAAAAGGCATTTCCTCGATTCAG ATTTCAGGGTGCAGCATTGCATTGAGCATTG ACAGGGAAACTCACCACGGCAA (11946) ptc-miRf10976- TGGGAACGTGGC GCCCTGTTTGGGAACGTGGCTGTGGCTACAC 2.30E−04 1.81 (−) akr TGTGGCTA (150) TGATGCTTCTGGTTTGGAAATGGAGGTGCAA CTGAAGTTATGGGAACGTTCCCAAACAGGGC (11947) ptc-miRf11018- CTGCAAACCTAA CTGCAAACCTAAGGGAGCGGTTTTGCAGACC 1.10E−02 1.79 (−) akr GGGAGCGG (151) CCAAGCGCACAAGTCTGCAGACCCGCTCGCT TGGGTCTGCAG (11948) ptc-miRf11079- AAGATGGAGAAG GTGTGTGAGCAAGATGGAGAAGCAGGGCAC 2.30E−05 2.43 (−) akr CAGGGCACGTGC GTGCACTACTAACTCATGCACACAGAGAGGG (152) AGACGCATTTCTTGCTGGAGTTACGAGTTAC GACTCTTACCTACTATTGATTTTGTTAGCTCC AGTGAGTTAGTTATTCATGTGCCTGTCTTCCT CATCATGATCACTAC (11949) ptc-miRf11324- CTTGTCGCAGGA TTGGGGGTTTCTTGTCGCAGGAGAGATGGCG 5.90E−05 1.73 (−) akr GAGATGGCGCT CTAGCTAACCATGGTCATATCATATATATCAT (153) ATGGCAAGTATTACTTGCTCTTTGTATGTATC AGCTGTAAAGATAGCTCAGCTAAAGCCATCC TCCTGCGACTGGACACCCTGCAA (11950) ptc-miRf11396- CAAGGCTCTGAT CTTGGTCATCAAGGCTCTGATACCATGTCAA 4.10E−04 1.51 (−) akr ACCATGTCAA AGAATCATATTTTGAGACCTTATCTAACAGCT (154) TAAGCTATTGGGTTGAGATGGTTCCTTGACAT GATATCAGAGCCTTGATGACGAAG (11951) ptc-miRf11953- GTAATCTGCATCC AGGATTGGGTAATCTGCATCCTGAGGTTTGG 1.90E−04 2.74 (−) akr TGAGGTT (155) ATCACCACATGTTTTGATCTAGTCCTTGGGTT GCAGATTACCTCTTCCT (11952) ptc-miRf12069- GGAGGGGCTGCA CTTGGGCCAGGAGGGGCTGCAAGACCCAAGT 3.90E−07 3.81 (−) akr AGACCCAAG GACTTGGGTCTGCGCTCTTGCCACACCCAAG (156) CAACTTGGGTCAGACGCCCTTCCAAGCCCCA AG (11953) ptc-miRf12389- GTCGACCTGGCG TGAGTCGACCTGGCGAGTCAACCGGGTTTGA 1.00E−02 1.75 (−) akr AGTCAACCGGG TTGTTTTTTTATCCTTGCTAGTCTTTCACCTTA (157) CTAGGACCGGTCCAGCCACCGGGTTAATCGA GTCCCGGGTTGACTTGCTGGGCCGTCTGG (11954) vvi-miR2111-5p  TAATCTGCATCCT GCAATATTGGGTCAGGATCGGGTAATCTGCA 3.10E−04 2.82 (−) GAGGTCTA (158) TCCTGAGGTCTAGATAAGTATATCTCCGTTGC AGCTAGTCCTCTGGTTGCAGATTACTTCTTCC TCACTGCCAATGC (253) zma-miR167u TGAAGCTGCCAC TGAAGCTGCCACATGATCTGATGACGCAGAG 2.20E−05 1.57 (−) ATGATCTG (159) TCATGCATATGCATTGCATCCAGCAAGCTCC ATGCGTGCGTGCATGGCCGAATGGCCGAAGA GACTAGCTAGTCCATCTCTCCAAGGCCATCC ACGTGTGAGAATTCAATTCCTCGTGGATCAG ATCAGGCTGTTGTTGACAACTGCATGCCGCA CCTGCACTACAGCAACCCAAGGCATAGGTAG CTAGCTAGGTTTCGGTGGTCAGATCAGATCA GGCTGGCAGCTTCA (254) zma-miR396b- GTTCAATAAAGCT AGATGGCCTTCTTTGTGATCTTCCACAGCTTT 7.90E−09 6.05 (−) 3p GTGGGAAA (160) CTTGAACTGCATCTCTCAGAGGAGCGGCAGC TTCAACTCCTCCACCCGCATCAGCAGGTGCA TGCAGTTCAATAAAGCTGTGGGAAACTGCAG AGAGAGGCCAG (255) zma-miR398a- GGGGCGAACTGA GGGGGCGAACUGAGAACACAUGAGAAUAAU 3.00E−04 1.89 (−) 5p GAACACATG GAGAUGAGAUUGCUCGCCUCGCGGUACGGU (161) UCGUGCUGGCCUGGACCACCGUCGUCGCCG UUCAUCUUGUACGCAUAAUAAUGCUGCAUG UGUUCUCAGGUCGCCCCCGC (11955)

TABLE 5 Differentially Expressed (Up-regulated) Small RNAs in Soybean Plants Growing under Heat Shock (1 hour) versus Optimal Conditions. Mature Sequence (SEQ miR Name ID NO:) Stem Loop Sequence (SEQ ID NO:) p-Value Fold-Change aly-miR831- AGAAGAGGTACAAGG AAGTGCTACAAGAATGTATAGTCTTAGAG 4.20E−05 1.73 (+) 5p AGATGAGA (162) TCTCAAGAAGAGGTACAAGGAGATGAGA AGTGAATCACTGAAACAAGTGGTTCTGGT TTGTGGATCAGTATGGTTTACCCAAAACA CGTGTTTGGTGCTTCACTTCTAAACTCCTC GTACTCTTCTTGGGATTCTATGACTTACAC TTGTTGATTT (256) ath- TTAGCTGAAGAAGCA TTTGTTTGTTTAGCTGAAGAAGCAGAGGA 2.10E−05 1.76(+) miRf10687- GAGGAG (163) GTCGGCATTGGGGCACAGTCACTCATCGA akr TGCTGCAATGGGTAAGTCCTCTGCATACTT TTGCTGAGATAGGAATAGA (11956) ath- GAGGTTTGCGATGAG GATGTTGGAGGTTTGCGATGAGAAAGAGA 2.10E−07 1.82 (+) miRf11021- AAAGAG (164) TTGGCCGGAAGAATTATCAGCCATCAACA akr TCGAGATTGTGAGATAATCGGAAGACCTG TAATTGTGAAGGTAACTCTTTCTCATCTGC AAATCTCAACTGTC (11957) far-miR1134 CGACAACAACAACAA ACGGCAATCCCAGCTTCAACGGGCCGGTG 2.80E−04 1.63 (+) GAAGAAGAG (165) CCAGGCGTGCCTCCCGGCGATGCCCATCG GTCGCCGACGCCTCCTAGCACGCCAGCTG GCTCACAAGGTGTCTCTCCCGGCGGCGAC AACAACAACAAGAAGAAGAGATCAGGTC TGGTGCTGGCTACTACCATCCCGGTCTCA GTCAGTGTGGTGGCGCTCATCTCGCTGGG TGCCGTGCTGCTCTTCCGCAAGAAAAACA ACGGGTCCG (257) osa- TTGGCCTCGTCGAAGA TCTCGTTCTTGGAGAGGCCCTTGCCGACCT 1.90E−06 2.01 (+) miRf10105- AGGAGA (166) TGGCGATGCGCTTGCCGGCCCTGGACCAG akr CGGGACGCCGCGGTCTCCTGCTTGGCCTC GTCGAAGAAGGAGA (11958) pab- TGGCGCTAGAAGGAG AAATGGCGCTAGAAGGAGGGCCTGAAAA 6.60E−05 1.68 (+) miR3711 GGCCT (167) TTATTAATGGCACGAGGCAGTCGTAAGAC TCCTCCACCACCCAACCACTCACCTATAGT GAAAAGAAGTCATTAAAATGATAACATCA CCCCTCAAATAGAACCA (258) zma- TGGGAGATGAAGGAG AGTGGGAGATGAAGGAGCCTTGCATCGAT 8.20E−07 2.05 (+) miR482-5p CCTT (168) GTCACCGCCGGAGGAGCGCTCGCCTTCTT CGCGCACCGCCGCAATAGCCGCCCTCGGA CCCCTCGCCTCGCTCTTCCTTGTTCCTCCC ATTTT (259)

TABLE 6 Differentially Expressed (Down-regulated) Small RNAs in Soybean Plants Growing under Heat Shock (1 hour) versus Optimal Conditions. Mature Sequence miR Name (SEQ ID NO:) Stem Loop Sequence (SEQ ID NO:) p-Value Fold-Change ath-miRf10279- ACTCAGCCTGGGG TGATGGTGATACTCGACATCCAGGTAGA 1.30E−02 2.56 (−) akr GTCGAGTGAT (169) GTGATGAGGTCGAGTAGAGGTCTGGCAA TGGGATGAAGTCACTCAGCCTGGGGGTC GAGTGATGTGATCG (11959) csi-miR162-5p TGGAGGCAGCGGT AAACTGTTTACACTGATCTGTGCTGCTG 4.10E−05 1.71 (−) TCATCGATC (170) ATAAATCTTAATTTTTTTTTTTGAATTTTT ATTTAACAGAAAATAGAGAGAGTGAAG TCACTGGAGGCAGCGGTTCATCGATCAC TTTGTGCAAATTTTGTTGTGAAAAATAA CACAAAATACATGAATCGATCGATAAAC CTCTGCATCCAGCGCTCACTCCAACTCTA TTC (260) gma-miR4412- AGTGGCGTAGATC AACTGTTGCGGGTATCTTTGCCTCTGAA 1.60E−05 1.81 (−) 3p CCCACAAC (171) GGAAAGTTGTGCCTATTATTATGGCTTAT TGCTTTAGTGGCGTAGATCCCCACAACA GTT (261) osa-miRf10151- TGGCTATATTTTGG GTATACTACCTCCGTCCCAAAATATAGC 3.60E−03 2.06 (−) akr GACGGAG (172) CACTTTTAGATTCATAAACAAAAGTGGC TATATTTTGGGACGGAGGGAGTATAT (11960) ptc-miRf12069- GGAGGGGCTGCAA CTTGGGCCAGGAGGGGCTGCAAGACCCA 1.90E−03 2.03 (−) akr GACCCAAG (173) AGTGACTTGGGTCTGCGCTCTTGCCACA CCCAAGCAACTTGGGTCAGACGCCCTTC CAAGCCCCAAG (11961)

Example 2 Identification of Homologous and Orthologous Sequences of Differential Small RNAs Associated with Enhanced Abiotic Stress Tolerance

The miRNA sequences of the invention that were either down- or up-regulated under abiotic stress conditions were examined for homologous and orthologous sequences using the miRBase database (http://wwwDOTmirbaseDOTorg/) and the Plant MicroRNA Database (PMRD, http://bioinformaticsDOTcauDOTeduDOTcn/PMRD). The mature miRNA sequences that are homologous or orthologous to the soy miRNAs listed in Tables 1-6 above, were found using miRNA public databases, having at least 75% identity of the entire mature miRNA length of the original soy sequence listed in Tables 1-6 and are summarized in Tables 7-8 below.

TABLE 7 Summary of Homologs/Orthologs to Small RNAs which are up-regulated in Abiotic Stress in Soybean Plants. Homolog Sequence (SEQ % Homolog stem-loop Mir Name Homolog Name ID NO:) Identity sequence (SEQ ID NO:) far- tae-miR1134 CAACAACAACAAGAAG 0.88 2087 miR1134 AAGAAGAT (262) mtr- gma-miR2119 TCAAAGGGAGTTGTAGG 0.76 2088 miR2119 GGAA (263) pvu-miR2119 TCAAAGGGAGTTGTAGG 0.76 2089 GGAA (264) ppt- ppt-miR1220b TTCCGGTGGTGAGGAAG 1 2090 miR1220a ATAG (265) aqc- acb-miR159 TTGGACTGAAGGGAGCT 0.86 2091 miR159 CCCT (266) aha-miR159 TTGGACTGAAGGGAGCT 0.86 2092 CCCT (267) ahi-miR159 TTGGACTGAAGGGAGCT 0.86 2093 CCCT (268) ahy-miR159 TTTGGATTGAAGGGAGC 0.95 2094 TCTA (269) aly-miR159a TTTGGATTGAAGGGAGC 0.95 2095 TCTA (270) aly-miR159b TTTGGATTGAAGGGAGC 0.9 2096 TCTT (271) aly-miR159c TTTGGATTGAAGGGAGC 0.86 2097 TCCT (272) ape-miR159 TTGGACTGAAGGGAGCT 0.86 2098 CCCT (273) ath-miR159a TTTGGATTGAAGGGAGC 0.95 2099 TCTA (274) ath-miR159b TTTGGATTGAAGGGAGC 0.9 2100 TCTT (275) ath-miR159c TTTGGATTGAAGGGAGC 0.86 2101 TCCT (276) bdi-miR159 CTTGGATTGAAGGGAGC 0.86 2102 TCT (277) bna-miR159 TTTGGATTGAAGGGAGC 0.95 2103 TCTA (278) bra-miR159a TTTGGATTGAAGGGAGC 0.95 2104 TCTA (279) bvl-miR159 TTGGACTGAAGGGAGCT 0.86 2105 CCCT (280) cmi-miR159 TTGGACTGAAGGGAGCT 0.86 2106 CCCT (281) cor-miR159 TTGGACTGAAGGGAGCT 0.86 2107 CCCT (282) crb-miR159 TTGGACTGAAGGGAGCT 0.86 2108 CCCT (283) csi-miR159 TTTGGATTGAAGGGAGC 0.95 2109 TCTA (284) dso-miR159 TTGGACTGAAGGGAGCT 0.86 2110 CCCT (285) ech-miR159 TTGGACTGAAGGGAGCT 0.86 2111 CCCT (286) fal-miR159 TTGGACTGAAGGGAGCT 0.86 2112 CCCT (287) far-miR159 TTTGGATTGAAGGGAGC 0.9 2113 TCTG (288) gma-miR159a-3p TTTGGATTGAAGGGAGC 0.95 2114 TCTA (289) gma-miR159b ATTGGAGTGAAGGGAGC 0.86 2115 TCCA (290) gma-miR159c ATTGGAGTGAAGGGAGC 0.81 2116 TCCG (291) hvu-miR159a TTTGGATTGAAGGGAGC 0.9 2117 TCTG (292) hvu-miR159b TTTGGATTGAAGGGAGC 0.9 2118 TCTG (293) hvv-miR159a TTTGGATTGAAGGGAGC 0.9 2119 TCTG (294) hvv-miR159b TTTGGATTGAAGGGAGC 0.9 2120 TCTG (295) ltu-miR159 TTTGGATTGAAGGGAGC 0.95 2121 TCTA (296) mma-miR159 TTGGACTGAAGGGAGCT 0.86 2122 CCCT (297) mtr-miR159a TTTGGATTGAAGGGAGC 0.95 2123 TCTA (298) mtr-miR159b ATTGAATTGAAGGGAGC 0.67 2124 AACT (299) mtr-miR159c TTTGGATTGAAGGGAGC 0.95 2125 TCTA (300) nof-miR159 TTGGACTGAAGGGAGCT 0.86 2126 CCCT (301) oru-miR159 TTTGGATTGAAGGGAGC 0.9 2127 TCTG (302) osa-miR159a TTTGGATTGAAGGGAGC 0.9 2128 TCTG (303) osa-miR159a.1 TTTGGATTGAAGGGAGC 0.9 2129 TCTG (304) osa-miR159b TTTGGATTGAAGGGAGC 0.9 2130 TCTG (305) osa-miR159c ATTGGATTGAAGGGAGC 0.86 2131 TCCA (306) osa-miR159d ATTGGATTGAAGGGAGC 0.81 2132 TCCG (307) osa-miR159e ATTGGATTGAAGGGAGC 0.81 2133 TCCT (308) osa-miR159f CTTGGATTGAAGGGAGC 0.9 2134 TCTA (309) osa-miR159m TTTGGATTGAAGGGAGC 0.9 2135 TCTG (310) pgl-miR159 TTTGGATTGAAGGGAGC 0.9 2136 TCTG (311) psi-miR159 CTTGGATTGAAGGGAGC 0.86 2137 TCCA (312) pta-miR159a TTGGATTGAAGGGAGCT 0.86 2138 CCA (313) pta-miR159b TTGGATTGAAGAGAGCT 0.76 2139 CCC (314) pta-miR159c CTTGGATTGAAGGGAGC 0.81 2140 TCCC (315) ptc-miR159a TTTGGATTGAAGGGAGC 0.95 2141 TCTA (316) ptc-miR159b TTTGGATTGAAGGGAGC 0.95 2142 TCTA (317) ptc-miR159c TTTGGATTGAAGGGAGC 0.95 2143 TCTA (318) ptc-miR159d CTTGGATTGAAGGGAGC 0.81 2144 TCCT (319) ptc-miR159e CTTGGGGTGAAGGGAGC 0.76 2145 TCCT (320) ptc-miR159f ATTGGAGTGAAGGGAGC 0.86 2146 TCGA (321) pvu-miR159 TTTGGATTGAAGGGAGC 0.95 2147 TCTA (322) pvu-miR159a.1 TTTGGATTGAAGGGAGC 0.95 2148 TCTA (323) rco-miR159 TTTGGATTGAAGGGAGC 0.95 2149 TCTA (324) rin-miR159 TTGGACTGAAGGGAGCT 0.86 2150 CCCT (325) sar-miR159 TTTGGATTGAAGGGAGC 0.9 2151 TCTG (326) sbi-miR159a TTTGGATTGAAGGGAGC 0.9 2152 TCTG (327) sbi-miR159b CTTGGATTGAAGGGAGC 0.81 2153 TCCT (328) sly-miR159 TTTGGATTGAAGGGAGC 0.95 2154 TCTA (329) smo-miR159 CTTGGATTGAAGGGAGC 0.81 2155 TCCC (330) sof-miR159a TTTGGATTGAAGGGAGC 0.9 2156 TCTG (331) sof-miR159b TTTGGATTGAAGGGAGC 0.9 2157 TCTG (332) sof-miR159c CTTGGATTGAAGGGAGC 0.81 2158 TCCT (333) sof-miR159d TTTGGATTGAAGGGAGC 0.9 2159 TCTG (334) sof-miR159e TTTGGATTGAAAGGAGC 0.86 2160 TCTT (335) spr-miR159 TTTGGATTGAAGGGAGC 0.9 2161 TCTG (336) ssp-miR159a TTTGGATTGAAGGGAGC 0.9 2162 TCTG (337) svi-miR159 TTGGACTGAAGGGAGCT 0.86 2163 CCCT (338) tae-miR159a TTTGGATTGAAGGGAGC 0.9 2164 TCTG (339) tae-miR159b TTTGGATTGAAGGGAGC 0.9 2165 TCTG (340) tar-miR159 TTGGACTGAAGGGAGCT 0.86 2166 CCCT (341) vvi-miR159a CTTGGAGTGAAGGGAGC 0.86 2167 TCTC (342) vvi-miR159b CTTGGAGTGAAGGGAGC 0.86 2168 TCTC (343) vvi-miR159c TTTGGATTGAAGGGAGC 0.95 2169 TCTA (344) zma-miR159a TTTGGATTGAAGGGAGC 0.9 2170 TCTG (345) zma-miR159b TTTGGATTGAAGGGAGC 0.9 2171 TCTG (346) zma-miR159c CTTGGATTGAAGGGAGC 0.81 2172 TCCT (347) zma-miR159d CTTGGATTGAAGGGAGC 0.81 2173 TCCT (348) zma-miR159e ATTGGTTTGAAGGGAGC 0.81 2174 TCCA (349) zma-miR159f TTTGGATTGAAGGGAGC 0.9 2175 TCTG (350) zma-miR159g TTTGGAGTGAAGGGAGT 0.86 2176 TCTG (351) zma-miR159h TTTGGAGTGAAGGGAGC 0.9 2177 TCTG (352) zma-miR159i TTTGGAGTGAAGGGAGC 0.9 2178 TCTG (353) zma-miR159j TTTGGATTGAAGGGAGC 0.9 2179 TCTG (354) zma-miR159k TTTGGATTGAAGGGAGC 0.9 2180 TCTG (355) zma-miR159m TTTGGATTGAAGGGAGC 0.9 2181 TCTG (356) ath- acb-miR159 TTGGACTGAAGGGAGCT 0.81 2182 miR159b CCCT (357) aha-miR159 TTGGACTGAAGGGAGCT 0.81 2183 CCCT (358) ahi-miR159 TTGGACTGAAGGGAGCT 0.81 2184 CCCT (359) ahy-miR159 TTTGGATTGAAGGGAGC 0.95 2185 TCTA (360) aly-miR159a TTTGGATTGAAGGGAGC 0.95 2186 TCTA (361) aly-miR159b TTTGGATTGAAGGGAGC 1 2187 TCTT (362) aly-miR159c TTTGGATTGAAGGGAGC 0.95 2188 TCCT (363) ape-miR159 TTGGACTGAAGGGAGCT 0.81 2189 CCCT (364) aqc-miR159 TTTGGACTGAAGGGAGC 0.9 2190 TCTA (365) ath-miR159a TTTGGATTGAAGGGAGC 0.95 2191 TCTA (366) ath-miR159c TTTGGATTGAAGGGAGC 0.95 2192 TCCT (367) bdi-miR159 CTTGGATTGAAGGGAGC 0.9 2193 TCT (368) bna-miR159 TTTGGATTGAAGGGAGC 0.95 2194 TCTA (369) bra-miR159a TTTGGATTGAAGGGAGC 0.95 2195 TCTA (370) bvl-miR159 TTGGACTGAAGGGAGCT 0.81 2196 CCCT (371) cmi-miR159 TTGGACTGAAGGGAGCT 0.81 2197 CCCT (372) cor-miR159 TTGGACTGAAGGGAGCT 0.81 2198 CCCT (373) crb-miR159 TTGGACTGAAGGGAGCT 0.81 2199 CCCT (374) csi-miR159 TTTGGATTGAAGGGAGC 0.95 2200 TCTA (375) dso-miR159 TTGGACTGAAGGGAGCT 0.81 2201 CCCT (376) ech-miR159 TTGGACTGAAGGGAGCT 0.81 2202 CCCT (377) fal-miR159 TTGGACTGAAGGGAGCT 0.81 2203 CCCT (378) far-miR159 TTTGGATTGAAGGGAGC 0.95 2204 TCTG (379) gma-miR159a-3p TTTGGATTGAAGGGAGC 0.95 2205 TCTA (380) gma-miR159b ATTGGAGTGAAGGGAGC 0.81 2206 TCCA (381) gma-miR159c ATTGGAGTGAAGGGAGC 0.81 2207 TCCG (382) hvu-miR159a TTTGGATTGAAGGGAGC 0.95 2208 TCTG (383) hvu-miR159b TTTGGATTGAAGGGAGC 0.95 2209 TCTG (384) hvv-miR159a TTTGGATTGAAGGGAGC 0.95 2210 TCTG (385) hvv-miR159b TTTGGATTGAAGGGAGC 0.95 2211 TCTG (386) ltu-miR159 TTTGGATTGAAGGGAGC 0.95 2212 TCTA (387) mma-miR159 TTGGACTGAAGGGAGCT 0.81 2213 CCCT (388) mtr-miR159a TTTGGATTGAAGGGAGC 0.95 2214 TCTA (389) mtr-miR159b ATTGAATTGAAGGGAGC 0.76 2215 AACT (390) mtr-miR159c TTTGGATTGAAGGGAGC 0.95 2216 TCTA (391) nof-miR159 TTGGACTGAAGGGAGCT 0.81 2217 CCCT (392) oru-miR159 TTTGGATTGAAGGGAGC 0.95 2218 TCTG (393) osa-miR159a TTTGGATTGAAGGGAGC 0.95 2219 TCTG (394) osa-miR159a.1 TTTGGATTGAAGGGAGC 0.95 2220 TCTG (395) osa-miR159b TTTGGATTGAAGGGAGC 0.95 2221 TCTG (396) osa-miR159c ATTGGATTGAAGGGAGC 0.86 2222 TCCA (397) osa-miR159d ATTGGATTGAAGGGAGC 0.86 2223 TCCG (398) osa-miR159e ATTGGATTGAAGGGAGC 0.9 2224 TCCT (399) osa-miR159f CTTGGATTGAAGGGAGC 0.9 2225 TCTA (400) osa-miR159m TTTGGATTGAAGGGAGC 0.95 2226 TCTG (401) pgl-miR159 TTTGGATTGAAGGGAGC 0.95 2227 TCTG (402) psi-miR159 CTTGGATTGAAGGGAGC 0.86 2228 TCCA (403) pta-miR159a TTGGATTGAAGGGAGCT 0.86 2229 CCA (404) pta-miR159b TTGGATTGAAGAGAGCT 0.81 2230 CCC (405) pta-miR159c CTTGGATTGAAGGGAGC 0.86 2231 TCCC (406) ptc-miR159a TTTGGATTGAAGGGAGC 0.95 2232 TCTA (407) ptc-miR159b TTTGGATTGAAGGGAGC 0.95 2233 TCTA (408) ptc-miR159c TTTGGATTGAAGGGAGC 0.95 2234 TCTA (409) ptc-miR159d CTTGGATTGAAGGGAGC 0.9 2235 TCCT (410) ptc-miR159e CTTGGGGTGAAGGGAGC 0.81 2236 TCCT (411) ptc-miR159f ATTGGAGTGAAGGGAGC 0.81 2237 TCGA (412) pvu-miR159 TTTGGATTGAAGGGAGC 0.95 2238 TCTA (413) pvu-miR159a.1 TTTGGATTGAAGGGAGC 0.95 2239 TCTA (414) rco-miR159 TTTGGATTGAAGGGAGC 0.95 2240 TCTA (415) rin-miR159 TTGGACTGAAGGGAGCT 0.81 2241 CCCT (416) sar-miR159 TTTGGATTGAAGGGAGC 0.95 2242 TCTG (417) sbi-miR159a TTTGGATTGAAGGGAGC 0.95 2243 TCTG (418) sbi-miR159b CTTGGATTGAAGGGAGC 0.9 2244 TCCT (419) sly-miR159 TTTGGATTGAAGGGAGC 0.95 2245 TCTA (420) smo-miR159 CTTGGATTGAAGGGAGC 0.86 2246 TCCC (421) sof-miR159a TTTGGATTGAAGGGAGC 0.95 2247 TCTG (422) sof-miR159b TTTGGATTGAAGGGAGC 0.95 2248 TCTG (423) sof-miR159c CTTGGATTGAAGGGAGC 0.9 2249 TCCT (424) sof-miR159d TTTGGATTGAAGGGAGC 0.95 2250 TCTG (425) sof-miR159e TTTGGATTGAAAGGAGC 0.95 2251 TCTT (426) spr-miR159 TTTGGATTGAAGGGAGC 0.95 2252 TCTG (427) ssp-miR159a TTTGGATTGAAGGGAGC 0.95 2253 TCTG (428) svi-miR159 TTGGACTGAAGGGAGCT 0.81 2254 CCCT (429) tae-miR159a TTTGGATTGAAGGGAGC 0.95 2255 TCTG (430) tae-miR159b TTTGGATTGAAGGGAGC 0.95 2256 TCTG (431) tar-miR159 TTGGACTGAAGGGAGCT 0.81 2257 CCCT (432) vvi-miR159a CTTGGAGTGAAGGGAGC 0.86 2258 TCTC (433) vvi-miR159b CTTGGAGTGAAGGGAGC 0.86 2259 TCTC (434) vvi-miR159c TTTGGATTGAAGGGAGC 0.95 2260 TCTA (435) zma-miR159a TTTGGATTGAAGGGAGC 0.95 2261 TCTG (436) zma-miR159b TTTGGATTGAAGGGAGC 0.95 2262 TCTG (437) zma-miR159c CTTGGATTGAAGGGAGC 0.9 2263 TCCT (438) zma-miR159d CTTGGATTGAAGGGAGC 0.9 2264 TCCT (439) zma-miR159e ATTGGTTTGAAGGGAGC 0.81 2265 TCCA (440) zma-miR159f TTTGGATTGAAGGGAGC 0.95 2266 TCTG (441) zma-miR159g TTTGGAGTGAAGGGAGT 0.86 2267 TCTG (442) zma-miR159h TTTGGAGTGAAGGGAGC 0.9 2268 TCTG (443) zma-miR159i TTTGGAGTGAAGGGAGC 0.9 2269 TCTG (444) zma-miR159j TTTGGATTGAAGGGAGC 0.95 2270 TCTG (445) zma-miR159k TTTGGATTGAAGGGAGC 0.95 2271 TCTG (446) zma-miR159m TTTGGATTGAAGGGAGC 0.95 2272 TCTG (447) ath- acb-miR159 TTGGACTGAAGGGAGCT 0.86 2273 miR159c CC CT (448) aha-miR159 TTGGACTGAAGGGAGCT 0.86 2274 CCCT (449) ahi-miR159 TTGGACTGAAGGGAGCT 0.86 2275 CCCT (450) ahy-miR159 TTTGGATTGAAGGGAGC 0.9 2276 TCTA (451) aly-miR159a TTTGGATTGAAGGGAGC 0.9 2277 TCTA (452) aly-miR159b TTTGGATTGAAGGGAGC 0.95 2278 TCTT (453) aly-miR159c TTTGGATTGAAGGGAGC 1 2279 TCCT (454) ape-miR159 TTGGACTGAAGGGAGCT 0.86 2280 CCCT (455) aqc-miR159 TTTGGACTGAAGGGAGC 0.86 2281 TCTA (456) ath-miR159a TTTGGATTGAAGGGAGC 0.9 2282 TCTA (457) ath-miR159b TTTGGATTGAAGGGAGC 0.95 2283 TCTT (458) bdi-miR159 CTTGGATTGAAGGGAGC 0.86 2284 TCT (459) bna-miR159 TTTGGATTGAAGGGAGC 0.9 2285 TCTA (460) bra-miR159a TTTGGATTGAAGGGAGC 0.9 2286 TCTA (461) bvl-miR159 TTGGACTGAAGGGAGCT 0.86 2287 CCCT (462) cmi-miR159 TTGGACTGAAGGGAGCT 0.86 2288 CCCT (463) cor-miR159 TTGGACTGAAGGGAGCT 0.86 2289 CCCT (464) crb-miR159 TTGGACTGAAGGGAGCT 0.86 2290 CCCT (465) csi-miR159 TTTGGATTGAAGGGAGC 0.9 2291 TCTA (466) dso-miR159 TTGGACTGAAGGGAGCT 0.86 2292 CCCT (467) ech-miR159 TTGGACTGAAGGGAGCT 0.86 2293 CCCT (468) fal-miR159 TTGGACTGAAGGGAGCT 0.86 2294 CCCT (469) far-miR159 TTTGGATTGAAGGGAGC 0.9 2295 TCTG (470) gma-miR159a-3p TTTGGATTGAAGGGAGC 0.9 2296 TCTA (471) gma-miR159b ATTGGAGTGAAGGGAGC 0.86 2297 TCCA (472) gma-miR159c ATTGGAGTGAAGGGAGC 0.86 2298 TCCG (473) hvu-miR159a TTTGGATTGAAGGGAGC 0.9 2299 TCTG (474) hvu-miR159b TTTGGATTGAAGGGAGC 0.9 2300 TCTG (475) hvv-miR159a TTTGGATTGAAGGGAGC 0.9 2301 TCTG (476) hvv-miR159b TTTGGATTGAAGGGAGC 0.9 2302 TCTG (477) ltu-miR159 TTTGGATTGAAGGGAGC 0.9 2303 TCTA (478) mma-miR159 TTGGACTGAAGGGAGCT 0.86 2304 CCCT (479) mtr-miR159a TTTGGATTGAAGGGAGC 0.9 2305 TCTA (480) mtr-miR159b ATTGAATTGAAGGGAGC 0.81 2306 AACT (481) mtr-miR159c TTTGGATTGAAGGGAGC 0.9 2307 TCTA (482) nof-miR159 TTGGACTGAAGGGAGCT 0.86 2308 CCCT (483) oru-miR159 TTTGGATTGAAGGGAGC 0.9 2309 TCTG (484) osa-miR159a TTTGGATTGAAGGGAGC 0.9 2310 TCTG (485) osa-miR159a.1 TTTGGATTGAAGGGAGC 0.9 2311 TCTG (486) osa-miR159b TTTGGATTGAAGGGAGC 0.9 2312 TCTG (487) osa-miR159c ATTGGATTGAAGGGAGC 0.9 2313 TCCA (488) osa-miR159d ATTGGATTGAAGGGAGC 0.9 2314 TCCG (489) osa-miR159e ATTGGATTGAAGGGAGC 0.95 2315 TCCT (490) osa-miR159f CTTGGATTGAAGGGAGC 0.86 2316 TCTA (491) osa-miR159m TTTGGATTGAAGGGAGC 0.9 2317 TCTG (492) pgl-miR159 TTTGGATTGAAGGGAGC 0.9 2318 TCTG (493) psi-miR159 CTTGGATTGAAGGGAGC 0.9 2319 TCCA (494) pta-miR159a TTGGATTGAAGGGAGCT 0.9 2320 CCA (495) pta-miR159b TTGGATTGAAGAGAGCT 0.86 2321 CCC (496) pta-miR159c CTTGGATTGAAGGGAGC 0.9 2322 TCCC (497) ptc-miR159a TTTGGATTGAAGGGAGC 0.9 2323 TCTA (498) ptc-miR159b TTTGGATTGAAGGGAGC 0.9 2324 TCTA (499) ptc-miR159c TTTGGATTGAAGGGAGC 0.9 2325 TCTA (500) ptc-miR159d CTTGGATTGAAGGGAGC 0.95 2326 TCCT (501) ptc-miR159e CTTGGGGTGAAGGGAGC 0.86 2327 TCCT (502) ptc-miR159f ATTGGAGTGAAGGGAGC 0.81 2328 TCGA (503) pvu-miR159 TTTGGATTGAAGGGAGC 0.9 2329 TCTA (504) pvu-miR159a.1 TTTGGATTGAAGGGAGC 0.9 2330 TCTA (505) rco-miR159 TTTGGATTGAAGGGAGC 0.9 2331 TCTA (506) rin-miR159 TTGGACTGAAGGGAGCT 0.86 2332 CCCT (507) sar-miR159 TTTGGATTGAAGGGAGC 0.9 2333 TCTG (508) sbi-miR159a TTTGGATTGAAGGGAGC 0.9 2334 TCTG (509) sbi-miR159b CTTGGATTGAAGGGAGC 0.95 2335 TCCT (510) sly-miR159 TTTGGATTGAAGGGAGC 0.9 2336 TCTA (511) smo-miR159 CTTGGATTGAAGGGAGC 0.9 2337 TCCC (512) sof-miR159a TTTGGATTGAAGGGAGC 0.9 2338 TCTG (513) sof-miR159b TTTGGATTGAAGGGAGC 0.9 2339 TCTG (514) sof-miR159c CTTGGATTGAAGGGAGC 0.95 2340 TCCT (515) sof-miR159d TTTGGATTGAAGGGAGC 0.9 2341 TCTG (516) sof-miR159e TTTGGATTGAAAGGAGC 0.9 2342 TCTT (517) spr-miR159 TTTGGATTGAAGGGAGC 0.9 2343 TCTG (518) ssp-miR159a TTTGGATTGAAGGGAGC 0.9 2344 TCTG (519) svi-miR159 TTGGACTGAAGGGAGCT 0.86 2345 CCCT (520) tae-miR159a TTTGGATTGAAGGGAGC 0.9 2346 TCTG (521) tae-miR159b TTTGGATTGAAGGGAGC 0.9 2347 TCTG (522) tar-miR159 TTGGACTGAAGGGAGCT 0.86 2348 CCCT (523) vvi-miR159a CTTGGAGTGAAGGGAGC 0.81 2349 TCTC (524) vvi-miR159b CTTGGAGTGAAGGGAGC 0.81 2350 TCTC (525) vvi-miR159c TTTGGATTGAAGGGAGC 0.9 2351 TCTA (526) zma-miR159a TTTGGATTGAAGGGAGC 0.9 2352 TCTG (527) zma-miR159b TTTGGATTGAAGGGAGC 0.9 2353 TCTG (528) zma-miR159c CTTGGATTGAAGGGAGC 0.95 2354 TCCT (529) zma-miR159d CTTGGATTGAAGGGAGC 0.95 2355 TCCT (530) zma-miR159e ATTGGTTTGAAGGGAGC 0.86 2356 TCCA (531) zma-miR159f TTTGGATTGAAGGGAGC 0.9 2357 TCTG (532) zma-miR159g TTTGGAGTGAAGGGAGT 0.81 2358 TCTG (533) zma-miR159h TTTGGAGTGAAGGGAGC 0.86 2359 TCTG (534) zma-miR159i TTTGGAGTGAAGGGAGC 0.86 2360 TCTG (535) zma-miR159j TTTGGATTGAAGGGAGC 0.9 2361 TCTG (536) zma-miR159k TTTGGATTGAAGGGAGC 0.9 2362 TCTG (537) zma-miR159m TTTGGATTGAAGGGAGC 0.9 2363 TCTG (538) ath- gma-miRf10687- TTAGCCGCAGAGGCAGA 0.86 11615 miRf10687- alcr-homolog GGAG (11616) akr ghr- vvi-miR2950* TGGTGTGCACGGGATGG 0.9 2364 miR2950 AATA (539) gma- ahy-miR156a TGACAGAAGAGAGAGA 0.85 2365 miR156g GCAC (540) ahy-miR156b-5p TTGACAGAAGATAGAGA 0.9 2366 GCAC (541) ahy-miR 156c TTGACAGAAGAGAGAG 0.85 2367 AGCAC (542) aly-miR156a TGACAGAAGAGAGTGA 0.8 2368 GCAC (543) aly-miR156b TGACAGAAGAGAGTGA 0.8 2369 GCAC (544) aly-miR156c TGACAGAAGAGAGTGA 0.8 2370 GCAC (545) aly-miR156d TGACAGAAGAGAGTGA 0.8 2371 GCAC (546) aly-miR156e TGACAGAAGAGAGTGA 0.8 2372 GCAC (547) aly-miR156f TGACAGAAGAGAGTGA 0.8 2373 GCAC (548) aly-miR156g CGACAGAAGAGAGTGA 0.8 2374 GCAC (549) aly-miR156h TGACAGAAGAAAGAGA 0.85 2375 GCAC (550) aqc-miR156a TGACAGAAGATAGAGA 0.9 2376 GCAC (551) aqc-miR156b TGACAGAAGATAGAGA 0.9 2377 GCAC (552) ath-miR156a TGACAGAAGAGAGTGA 0.8 2378 GCAC (553) ath-miR156b TGACAGAAGAGAGTGA 0.8 2379 GCAC (554) ath-miR156c TGACAGAAGAGAGTGA 0.8 2380 GCAC (555) ath-miR156d TGACAGAAGAGAGTGA 0.8 2381 GCAC (556) ath-miR156e TGACAGAAGAGAGTGA 0.8 2382 GCAC (557) ath-miR156f TGACAGAAGAGAGTGA 0.8 2383 GCAC (558) ath-miR156g CGACAGAAGAGAGTGA 0.8 2384 GCAC (559) ath-miR156h TGACAGAAGAAAGAGA 0.85 2385 GCAC (560) bdi-miR156 TGACAGAAGAGAGAGA 0.9 2386 GCACA (561) bdi-miR156b TGACAGAAGAGAGTGA 0.8 2387 GCAC (562) bdi-miR156c TGACAGAAGAGAGTGA 0.8 2388 GCAC (563) bdi-miR156d TGACAGAAGAGAGTGA 0.8 2389 GCAC (564) bna-miR156a TGACAGAAGAGAGTGA 0.85 2390 GCACA (565) bna-miR156b TTGACAGAAGATAGAGA 0.9 2391 GCAC (566) bna-miR156c TTGACAGAAGATAGAGA 0.9 2392 GCAC (567) csi-miR156 TGACAGAAGAGAGTGA 0.8 2393 GCAC (568) ctr-miR156 TGACAGAAGAGAGTGA 0.8 2394 GCAC (569) far-miR156a TGACAGAAGAGAGAGA 0.9 2395 GCACA (570) far-miR156b TTGACAGAAGAGAGAG 0.85 2396 AGCAC (571) ghr-miR156a TGACAGAAGAGAGTGA 0.8 2397 GCAC (572) ghr-miR156b TGACAGAAGAGAGTGA 0.8 2398 GCAC (573) ghr-miR156c TGTCAGAAGAGAGTGAG 0.75 2399 CAC (574) ghr-miR156d TGACAGAAGAGAGTGA 0.8 2400 GCAC (575) gma-miR156a TGACAGAAGAGAGTGA 0.8 2401 GCAC (576) gma-miR156b TGACAGAAGAGAGAGA 0.9 2402 GCACA (577) gma-miR156c TTGACAGAAGATAGAGA 0.9 2403 GCAC (578) gma-miR156d TTGACAGAAGATAGAGA 0.9 2404 GCAC (579) gma-miR156e TTGACAGAAGATAGAGA 0.9 2405 GCAC (580) gma-miR156f TTGACAGAAGAGAGAG 0.9 2406 AGCACA (581) hvu-miR156 TGACAGAAGAGAGTGA 0.85 2407 GCACA (582) mtr-miR156 TGACAGAAGAGAGAGA 0.9 2408 GCACA (583) mtr-miR156b TGACAGAAGAGAGTGA 0.8 2409 GCAC (584) mtr-miR156c TGACAGAAGAGAGTGA 0.8 2410 GCAC (585) mtr-miR156d TGACAGAAGAGAGTGA 0.8 2411 GCAC (586) mtr-miR156e TTGACAGAAGATAGAGA 0.9 2412 GCAC (587) mtr-miR156f TTGACAGAAGATAGAGA 0.9 2413 GCAC (588) mtr-miR156g TTGACAGAAGATAGAGG 0.85 2414 GCAC (589) mtr-miR156h TTGACAGAAGATAGAGA 0.9 2415 GCAC (590) mtr-miR156i TGACAGAAGAGAGTGA 0.8 2416 GCAC (591) osa-miR156a TGACAGAAGAGAGTGA 0.8 2417 GCAC (592) osa-miR156b TGACAGAAGAGAGTGA 0.8 2418 GCAC (593) osa-miR156c TGACAGAAGAGAGTGA 0.8 2419 GCAC (594) osa-miR156d TGACAGAAGAGAGTGA 0.8 2420 GCAC (595) osa-miR156e TGACAGAAGAGAGTGA 0.8 2421 GCAC (596) osa-miR156f TGACAGAAGAGAGTGA 0.8 2422 GCAC (597) osa-miR156g TGACAGAAGAGAGTGA 0.8 2423 GCAC (598) osa-miR156h TGACAGAAGAGAGTGA 0.8 2424 GCAC (599) osa-miR156i TGACAGAAGAGAGTGA 0.8 2425 GCAC (600) osa-miR156j TGACAGAAGAGAGTGA 0.8 2426 GCAC (601) osa-miR156k TGACAGAAGAGAGAGA 0.9 2427 GCACA (602) osa-miR156l CGACAGAAGAGAGTGA 0.8 2428 GCATA (603) ppt-miR156a TGACAGAAGAGAGTGA 0.8 2429 GCAC (604) ppt-miR156b TGACAGAAGAGAGTGA 0.8 2430 GCAC (605) ppt-miR156c TGACAGAAGAGAGTGA 0.8 2431 GCAC (606) pta-miR156a CAGAAGATAGAGAGCA 0.9 2432 CATC (607) pta-miR156b CAGAAGATAGAGAGCA 0.9 2433 CAAC (608) ptc-miR156a TGACAGAAGAGAGTGA 0.8 2434 GCAC (609) ptc-miR156b TGACAGAAGAGAGTGA 0.8 2435 GCAC (610) ptc-miR156c TGACAGAAGAGAGTGA 0.8 2436 GCAC (611) ptc-miR156d TGACAGAAGAGAGTGA 0.8 2437 GCAC (612) ptc-miR156e TGACAGAAGAGAGTGA 0.8 2438 GCAC (613) ptc-miR156f TGACAGAAGAGAGTGA 0.8 2439 GCAC (614) ptc-miR156g TTGACAGAAGATAGAGA 0.9 2440 GCAC (615) ptc-miR156h TTGACAGAAGATAGAGA 0.9 2441 GCAC (616) ptc-miR156i TTGACAGAAGATAGAGA 0.9 2442 GCAC (617) ptc-miR156j TTGACAGAAGATAGAGA 0.9 2443 GCAC (618) ptc-miR156k TGACAGAAGAGAGGGA 0.8 2444 GCAC (619) rco-miR156a TGACAGAAGAGAGTGA 0.85 2445 GCACA (620) rco-miR156b TGACAGAAGAGAGTGA 0.85 2446 GCACA (621) rco-miR156c TGACAGAAGAGAGTGA 0.85 2447 GCACA (622) rco-miR156d TGACAGAAGAGAGTGA 0.85 2448 GCACA (623) rco-miR156e TGACAGAAGAGAGAGA 0.9 2449 GCACA (624) rco-miR156f TTGACAGAAGATAGAGA 0.9 2450 GCAC (625) rco-miR156g TTGACAGAAGATAGAGA 0.9 2451 GCAC (626) rco-miR156h TTGACAGAAGATAGAGA 0.9 2452 GCAC (627) sbi-miR156a TGACAGAAGAGAGTGA 0.8 2453 GCAC (628) sbi-miR156b TGACAGAAGAGAGTGA 0.8 2454 GCAC (629) sbi-miR156c TGACAGAAGAGAGTGA 0.8 2455 GCAC (630) sbi-miR156d TGACAGAAGAGAGAGA 0.9 2456 GCACA (631) sbi-miR156e TGACAGAAGAGAGCGA 0.8 2457 GCAC (632) sbi-miR156f TGACAGAAGAGAGTGA 0.8 2458 GCAC (633) sbi-miR156g TGACAGAAGAGAGTGA 0.8 2459 GCAC (634) sbi-miR156h TGACAGAAGAGAGTGA 0.8 2460 GCAC (635) sbi-miR156i TGACAGAAGAGAGTGA 0.8 2461 GCAC (636) sly-miR156a TTGACAGAAGATAGAGA 0.9 2462 GCAC (637) sly-miR156b TTGACAGAAGATAGAGA 0.9 2463 GCAC (638) sly-miR156c TTGACAGAAGATAGAGA 0.9 2464 GCAC (639) smo-miR156a CGACAGAAGAGAGTGA 0.8 2465 GCAC (640) smo-miR156b CTGACAGAAGATAGAG 0.9 2466 AGCAC (641) smo-miR156c TTGACAGAAGAAAGAG 0.85 2467 AGCAC (642) smo-miR156d TTGACAGAAGACAGGG 0.8 2468 AGCAC (643) sof-miR156 TGACAGAAGAGAGTGA 0.8 2469 GCAC (644) ssp-miR156 TGACAGAAGAGAGTGA 0.85 2470 GCACA (645) tae-miR156 TGACAGAAGAGAGTGA 0.85 2471 GCACA (646) tcc-miR156a TGACAGAAGAGAGAGA 0.9 2472 GCACA (647) tcc-miR156b TGACAGAAGAGAGTGA 0.8 2473 GCAC (648) tcc-miR156c TGACAGAAGAGAGTGA 0.8 2474 GCAC (649) tcc-miR156d TGACAGAAGAGAGTGA 0.8 2475 GCAC (650) tcc-miR156e TTGACAGAAGATAGAGA 0.9 2476 GCAC (651) tcc-miR156f TTGACAGAAGATAGAGA 0.9 2477 GCAC (652) tcc-miR156g TGACAGAAGAGAGTGA 0.8 2478 GCAC (653) vvi-miR156a TGACAGAAGAGAGGGA 0.8 2479 GCAC (654) vvi-miR156b TGACAGAAGAGAGTGA 0.8 2480 GCAC (655) vvi-miR156c TGACAGAAGAGAGTGA 0.8 2481 GCAC (656) vvi-miR156d TGACAGAAGAGAGTGA 0.8 2482 GCAC (657) vvi-miR156e TGACAGAGGAGAGTGA 0.75 2483 GCAC (658) vvi-miR156f TTGACAGAAGATAGAGA 0.9 2484 GCAC (659) vvi-miR156g TTGACAGAAGATAGAGA 0.9 2485 GCAC (660) vvi-miR156h TGACAGAAGAGAGAGA 0.8 2486 GCAT (661) vvi-miR156i TTGACAGAAGATAGAGA 0.9 2487 GCAC (662) zma-miR156a TGACAGAAGAGAGTGA 0.8 2488 GCAC (663) zma-miR156b TGACAGAAGAGAGTGA 0.8 2489 GCAC (664) zma-miR156c TGACAGAAGAGAGTGA 0.8 2490 GCAC (665) zma-miR156d TGACAGAAGAGAGTGA 0.8 2491 GCAC (666) zma-miR156e TGACAGAAGAGAGTGA 0.8 2492 GCAC (667) zma-miR156f TGACAGAAGAGAGTGA 0.8 2493 GCAC (668) zma-miR156g TGACAGAAGAGAGTGA 0.8 2494 GCAC (669) zma-miR156h TGACAGAAGAGAGTGA 0.8 2495 GCAC (670) zma-miR156i TGACAGAAGAGAGTGA 0.8 2496 GCAC (671) zma-miR156j TGACAGAAGAGAGAGA 0.9 2497 GCACA (672) zma-miR156k TGACAGAAGAGAGCGA 0.8 2498 GCAC (673) zma-miR156l TGACAGAAGAGAGTGA 0.8 2499 GCAC (674) gma- ahy-miR157a-5p TTGACAGAAGATAGAGA 0.95 2500 miR157c GCAC (675) ahy-miR157k TTGACAGAAGAGAGAG 0.9 2501 AGCAC (676) aly-miR157a TTGACAGAAGATAGAGA 0.95 2502 GCAC (677) aly-miR157b TTGACAGAAGATAGAGA 0.95 2503 GCAC (678) aly-miR157c TTGACAGAAGATAGAGA 0.95 2504 GCAC (679) aly-miR157d TGACAGAAGATAGAGA 0.95 2505 GCAC (680) ath-miR157a TTGACAGAAGATAGAGA 0.95 2506 GCAC (681) ath-miR157b TTGACAGAAGATAGAGA 0.95 2507 GCAC (682) ath-miR157c TTGACAGAAGATAGAGA 0.95 2508 GCAC (683) ath-miR157d TGACAGAAGATAGAGA 0.95 2509 GCAC (684) ath-miR157m TTGACAGAAGAGAGAG 0.9 2510 AGCAC (685) bol-miR157a TTGACAGAAGATAGAGA 0.95 2511 GCAC (686) bra-miR157a TTGACAGAAGATAGAGA 0.95 2512 GCAC (687) can-miR157 TTGACAGAAGAGAGAG 0.9 2513 AGCAC (688) ghr-miR157 ATGACAGAAGAGAGAG 0.9 2514 AGCAC (689) gma-miR157r TTGACAGAAGAGAGAG 0.9 2515 AGCAC (690) gra-miR157a TTGACAGAAGATAGAGA 0.95 2516 GCAC (691) gra-miR157b TTGACAGAAGATAGAGA 0.95 2517 GCAC (692) gra-miR157c TTGACAGAAGAGAGAG 0.9 2518 AGCAC (693) gra-miR157d TTGACAGAAGAGAGAG 0.9 2519 AGCAC (694) han-miR157a TTGACAGAAGATAGAGA 0.95 2520 GCAC (695) han-miR157b TTGACAGAAGAGAGAG 0.9 2521 AGCAC (696) iba-miR157 TTGACAGAAGATAGAGA 0.9 2522 GCAT (697) ini-miR157a TTGACAGAAGATAGAGA 0.9 2523 GCAT (698) ini-miR157b TTGACAGAAGATAGAGA 0.9 2524 GCAT (699) lja-miR157a TTGACAGAAGATAGAGA 0.95 2525 GCAC (700) lja-miR157b TTGACAGAAGAGAGAG 0.9 2526 AGCAC (701) lja-miR157c TTGACAGAAGATAGAGA 0.9 2527 GCAT (702) lsa-miR157 TTGACAGAAGAGAGAG 0.9 2528 AGCAC (703) mtr-miR157 TTGACAGAAGATAGAGG 0.9 2529 GCAC (704) nad-miR157a TTGACAGAAGACAGAG 0.95 2530 AGCAC (705) nad-miR157b TTGACAGAAGACAGAG 0.95 2531 AGCAC (706) nad-miR157c TTGACAGAAGACAGAG 0.95 2532 AGCAC (707) nbe-miR157a TTGACAGAAGAGAGAG 0.9 2533 AGCAC (708) nbe-miR157b TTGACAGAAGAGAGAG 0.9 2534 AGCAC (709) nta-miR157 TTGACAGAAGATAGAGA 0.95 2535 GCAC (710) pam-miR157 TTGACAGAAGAGAGAG 0.9 2536 AGCAC (711) par-miR157 TTGACAGAAGAGAGAG 0.9 2537 AGCAC (712) pco-miR157 TTGACAGAAGATAGAGA 0.9 2538 GCAT (713) pts-miR157 TTGACAGAAGAGAGAG 0.9 2539 AGCAC (714) sbi-miR157 TTGACAGAAGAGAGTGA 0.86 2540 GCAC (715) sin-miR157 TTGACAGAAGAGAGAG 0.9 2541 AGCAC (716) sly-miR157a TTGACAGAAGATAGAGA 0.9 2542 GCAT (717) sly-miR157b TTGACAGAAGATAGAGA 0.9 2543 GCAT (718) sly-miR157c TTGACAGAAGATAGAGA 0.9 2544 GCAT (719) stu-miR157a TTGACAGAAGATAGAGA 0.95 2545 GCAC (720) stu-miR157b TTGACAGAAGAGAGAG 0.9 2546 AGCAC (721) stu-miR157c TTGACAGAAGAGAGAG 0.9 2547 AGCAC (722) zel-miR157 TTGACAGAAGAGAGAG 0.9 2548 AGCAC (723) zma-miR157m TTGACAGAAGAGAGAG 0.9 2549 AGCAC (724) iba- ahy-miR157a-5p TTGACAGAAGATAGAGA 0.95 2550 miR157 GCAC (725) ahy-miR157k TTGACAGAAGAGAGAG 0.9 2551 AGCAC (726) aly-miR157a TTGACAGAAGATAGAGA 0.95 2552 GCAC (727) aly-miR157b TTGACAGAAGATAGAGA 0.95 2553 GCAC (728) aly-miR157c TTGACAGAAGATAGAGA 0.95 2554 GCAC (729) aly-miR157d TGACAGAAGATAGAGA 0.9 2555 GCAC (730) ath-miR157a TTGACAGAAGATAGAGA 0.95 2556 GCAC (731) ath-miR157b TTGACAGAAGATAGAGA 0.95 2557 GCAC (732) ath-miR157c TTGACAGAAGATAGAGA 0.95 2558 GCAC (733) ath-miR157d TGACAGAAGATAGAGA 0.9 2559 GCAC (734) ath-miR157m TTGACAGAAGAGAGAG 0.9 2560 AGCAC (735) bol-miR157a TTGACAGAAGATAGAGA 0.95 2561 GCAC (736) bra-miR157a TTGACAGAAGATAGAGA 0.95 2562 GCAC (737) can-miR157 TTGACAGAAGAGAGAG 0.9 2563 AGCAC (738) ghr-miR157 ATGACAGAAGAGAGAG 0.86 2564 AGCAC (739) gma-miR157c TGACAGAAGACTAGAG 0.9 2565 AGCAC (740) gma-miR157r TTGACAGAAGAGAGAG 0.9 2566 AGCAC (741) gra-miR157a TTGACAGAAGATAGAGA 0.95 2567 GCAC (742) gra-miR157b TTGACAGAAGATAGAGA 0.95 2568 GCAC (743) gra-miR157c TTGACAGAAGAGAGAG 0.9 2569 AGCAC (744) gra-miR157d TTGACAGAAGAGAGAG 0.9 2570 AGCAC (745) han-miR157a TTGACAGAAGATAGAGA 0.95 2571 GCAC (746) han-miR157b TTGACAGAAGAGAGAG 0.9 2572 AGCAC (747) ini-miR157a TTGACAGAAGATAGAGA 1 2573 GCAT (748) ini-miR157b TTGACAGAAGATAGAGA 1 2574 GCAT (749) lja-miR157a TTGACAGAAGATAGAGA 0.95 2575 GCAC (750) lja-miR157b TTGACAGAAGAGAGAG 0.9 2576 AGCAC (751) lja-miR157c TTGACAGAAGATAGAGA 1 2577 GCAT (752) lsa-miR157 TTGACAGAAGAGAGAG 0.9 2578 AGCAC (753) mtr-miR157 TTGACAGAAGATAGAGG 0.9 2579 GCAC (754) nad-miR157a TTGACAGAAGACAGAG 0.9 2580 AGCAC (755) nad-miR157b TTGACAGAAGACAGAG 0.9 2581 AGCAC (756) nad-miR157c TTGACAGAAGACAGAG 0.9 2582 AGCAC (757) nbe-miR157a TTGACAGAAGAGAGAG 0.9 2583 AGCAC (758) nbe-miR157b TTGACAGAAGAGAGAG 0.9 2584 AGCAC (759) nta-miR157 TTGACAGAAGATAGAGA 0.95 2585 GCAC (760) pam-miR157 TTGACAGAAGAGAGAG 0.9 2586 AGCAC (761) par-miR157 TTGACAGAAGAGAGAG 0.9 2587 AGCAC (762) pco-miR157 TTGACAGAAGATAGAGA 1 2588 GCAT (763) pts-miR157 TTGACAGAAGAGAGAG 0.9 2589 AGCAC (764) sbi-miR157 TTGACAGAAGAGAGTGA 0.86 2590 GCAC (765) sin-miR157 TTGACAGAAGAGAGAG 0.9 2591 AGCAC (766) sly-miR157a TTGACAGAAGATAGAGA 1 2592 GCAT (767) sly-miR157b TTGACAGAAGATAGAGA 1 2593 GCAT (768) sly-miR157c TTGACAGAAGATAGAGA 1 2594 GCAT (769) stu-miR157a TTGACAGAAGATAGAGA 0.95 2595 GCAC (770) stu-miR157b TTGACAGAAGAGAGAG 0.9 2596 AGCAC (771) stu-miR157c TTGACAGAAGAGAGAG 0.9 2597 AGCAC (772) zel-miR157 TTGACAGAAGAGAGAG 0.9 2598 AGCAC (773) zma-miR157m TTGACAGAAGAGAGAG 0.9 2599 AGCAC (774) mdm- gma-miR482b-5p TATGGGGGGATTGGGAA 0.62 2600 miR482a- GGAAT (775) 5p mdo-miR482* GGAATGGGCTGTTTGGG 1 2601 AACA (776) pvu-miR482* GGAATGGGCTGATTGGG 0.95 2602 AAGCA (777) osa- acb-miR159 TTGGACTGAAGGGAGCT 0.86 2603 miR159e CC CT (778) aha-miR159 TTGGACTGAAGGGAGCT 0.86 2604 CC CT (779) ahi-miR159 TTGGACTGAAGGGAGCT 0.86 2605 CC CT (780) ahy-miR159 TTTGGATTGAAGGGAGC 0.86 2606 TCTA (781) aly-miR159a TTTGGATTGAAGGGAGC 0.86 2607 TCTA (782) aly-miR159b TTTGGATTGAAGGGAGC 0.9 2608 TCTT (783) aly-miR159c TTTGGATTGAAGGGAGC 0.95 2609 TC CT (784) ape-miR159 TTGGACTGAAGGGAGCT 0.86 2610 CCCT (785) aqc-miR159 TTTGGACTGAAGGGAGC 0.81 2611 TCTA (786) ath-miR159a TTTGGATTGAAGGGAGC 0.86 2612 TCTA (787) ath-miR159b TTTGGATTGAAGGGAGC 0.9 2613 TCTT (788) ath-miR159c TTTGGATTGAAGGGAGC 0.95 2614 TCCT (789) bdi-miR159 CTTGGATTGAAGGGAGC 0.86 2615 TCT (790) bna-miR159 TTTGGATTGAAGGGAGC 0.86 2616 TCTA (791) bra-miR159a TTTGGATTGAAGGGAGC 0.86 2617 TCTA (792) bvl-miR159 TTGGACTGAAGGGAGCT 0.86 2618 CCCT (793) cmi-miR159 TTGGACTGAAGGGAGCT 0.86 2619 CCCT (794) cor-miR159 TTGGACTGAAGGGAGCT 0.86 2620 CCCT (795) crb-miR159 TTGGACTGAAGGGAGCT 0.86 2621 CCCT (796) csi-miR159 TTTGGATTGAAGGGAGC 0.86 2622 TCTA (797) dso-miR159 TTGGACTGAAGGGAGCT 0.86 2623 CCCT (798) ech-miR159 TTGGACTGAAGGGAGCT 0.86 2624 CCCT (799) fal-miR159 TTGGACTGAAGGGAGCT 0.86 2625 CCCT (800) far-miR159 TTTGGATTGAAGGGAGC 0.86 2626 TCTG (801) gma-miR159a-3p TTTGGATTGAAGGGAGC 0.86 2627 TCTA (802) gma-miR159b ATTGGAGTGAAGGGAGC 0.9 2628 TCCA (803) gma-miR159c ATTGGAGTGAAGGGAGC 0.9 2629 TCCG (804) hvu-miR159a TTTGGATTGAAGGGAGC 0.86 2630 TCTG (805) hvu-miR159b TTTGGATTGAAGGGAGC 0.86 2631 TCTG (806) hvv-miR159a TTTGGATTGAAGGGAGC 0.86 2632 TCTG (807) hvv-miR159b TTTGGATTGAAGGGAGC 0.86 2633 TCTG (808) ltu-miR159 TTTGGATTGAAGGGAGC 0.86 2634 TCTA (809) mma-miR159 TTGGACTGAAGGGAGCT 0.86 2635 CCCT (810) mtr-miR159a TTTGGATTGAAGGGAGC 0.86 2636 TCTA (811) mtr-miR159b ATTGAATTGAAGGGAGC 0.86 2637 AACT (812) mtr-miR159c TTTGGATTGAAGGGAGC 0.86 2638 TCTA (813) nof-miR159 TTGGACTGAAGGGAGCT 0.86 2639 CCCT (814) oru-miR159 TTTGGATTGAAGGGAGC 0.86 2640 TCTG (815) osa-miR159a TTTGGATTGAAGGGAGC 0.86 2641 TCTG (816) osa-miR159a.1 TTTGGATTGAAGGGAGC 0.86 2642 TCTG (817) osa-miR159b TTTGGATTGAAGGGAGC 0.86 2643 TCTG (818) osa-miR159c ATTGGATTGAAGGGAGC 0.95 2644 TCCA (819) osa-miR159d ATTGGATTGAAGGGAGC 0.95 2645 TCCG (820) osa-miR159f CTTGGATTGAAGGGAGC 0.86 2646 TCTA (821) osa-miR159m TTTGGATTGAAGGGAGC 0.86 2647 TCTG (822) pgl-miR159 TTTGGATTGAAGGGAGC 0.86 2648 TCTG (823) psi-miR159 CTTGGATTGAAGGGAGC 0.9 2649 TCCA (824) pta-miR159a TTGGATTGAAGGGAGCT 0.9 2650 CCA (825) pta-miR159b TTGGATTGAAGAGAGCT 0.86 2651 CCC (826) pta-miR159c CTTGGATTGAAGGGAGC 0.9 2652 TCCC (827) ptc-miR159a TTTGGATTGAAGGGAGC 0.86 2653 TCTA (828) ptc-miR159b TTTGGATTGAAGGGAGC 0.86 2654 TCTA (829) ptc-miR159c TTTGGATTGAAGGGAGC 0.86 2655 TCTA (830) ptc-miR159d CTTGGATTGAAGGGAGC 0.95 2656 TCCT (831) ptc-miR159e CTTGGGGTGAAGGGAGC 0.86 2657 TCCT (832) ptc-miR159f ATTGGAGTGAAGGGAGC 0.86 2658 TCGA (833) pvu-miR159 TTTGGATTGAAGGGAGC 0.86 2659 TCTA (834) pvu-miR159.2 CTTCCATATCTGGGGAG 0.62 2660 CTTC (835) pvu-miR159a.1 TTTGGATTGAAGGGAGC 0.86 2661 TCTA (836) pvu-miR159a.2 CTTCCATATCTGGGGAG 0.62 2662 CTTC (837) rco-miR159 TTTGGATTGAAGGGAGC 0.86 2663 TCTA (838) rin-miR159 TTGGACTGAAGGGAGCT 0.86 2664 CCCT (839) sar-miR159 TTTGGATTGAAGGGAGC 0.86 2665 TCTG (840) sbi-miR159a TTTGGATTGAAGGGAGC 0.86 2666 TCTG (841) sbi-miR159b CTTGGATTGAAGGGAGC 0.95 2667 TCCT (842) sly-miR159 TTTGGATTGAAGGGAGC 0.86 2668 TCTA (843) smo-miR159 CTTGGATTGAAGGGAGC 0.9 2669 TCCC (844) sof-miR159a TTTGGATTGAAGGGAGC 0.86 2670 TCTG (845) sof-miR159b TTTGGATTGAAGGGAGC 0.86 2671 TCTG (846) sof-miR159c CTTGGATTGAAGGGAGC 0.95 2672 TCCT (847) sof-miR159d TTTGGATTGAAGGGAGC 0.86 2673 TCTG (848) sof-miR159e TTTGGATTGAAAGGAGC 0.86 2674 TCTT (849) spr-miR159 TTTGGATTGAAGGGAGC 0.86 2675 TCTG (850) ssp-miR159a TTTGGATTGAAGGGAGC 0.86 2676 TCTG (851) svi-miR159 TTGGACTGAAGGGAGCT 0.86 2677 CCCT (852) tae-miR159a TTTGGATTGAAGGGAGC 0.86 2678 TCTG (853) tae-miR159b TTTGGATTGAAGGGAGC 0.86 2679 TCTG (854) tar-miR159 TTGGACTGAAGGGAGCT 0.86 2680 CCCT (855) vvi-miR159a CTTGGAGTGAAGGGAGC 0.81 2681 TCTC (856) vvi-miR159b CTTGGAGTGAAGGGAGC 0.81 2682 TCTC (857) vvi-miR159c TTTGGATTGAAGGGAGC 0.86 2683 TCTA (858) zma-miR159a TTTGGATTGAAGGGAGC 0.86 2684 TCTG (859) zma-miR159b TTTGGATTGAAGGGAGC 0.86 2685 TCTG (860) zma-miR159c CTTGGATTGAAGGGAGC 0.95 2686 TCCT (861) zma-miR159d CTTGGATTGAAGGGAGC 0.95 2687 TCCT (862) zma-miR159e ATTGGTTTGAAGGGAGC 0.9 2688 TCCA (863) zma-miR159f TTTGGATTGAAGGGAGC 0.86 2689 TCTG (864) zma-miR159g TTTGGAGTGAAGGGAGT 0.76 2690 TCTG (865) zma-miR159h TTTGGAGTGAAGGGAGC 0.81 2691 TCTG (866) zma-miR159i TTTGGAGTGAAGGGAGC 0.81 2692 TCTG (867) zma-miR159j TTTGGATTGAAGGGAGC 0.86 2693 TCTG (868) zma-miR159k TTTGGATTGAAGGGAGC 0.86 2694 TCTG (869) zma-miR159m TTTGGATTGAAGGGAGC 0.86 2695 TCTG (870) osa- acb-miR159 TTGGACTGAAGGGAGCT 0.81 2696 miR159f CCCT (871) aha-miR159 TTGGACTGAAGGGAGCT 0.81 2697 CCCT (872) ahi-miR159 TTGGACTGAAGGGAGCT 0.81 2698 CCCT (873) ahy-miR159 TTTGGATTGAAGGGAGC 0.95 2699 TCTA (874) aly-miR159a TTTGGATTGAAGGGAGC 0.95 2700 TCTA (875) aly-miR159b TTTGGATTGAAGGGAGC 0.9 2701 TCTT (876) aly-miR159c TTTGGATTGAAGGGAGC 0.86 2702 TCCT (877) ape-miR159 TTGGACTGAAGGGAGCT 0.81 2703 CCCT (878) aqc-miR159 TTTGGACTGAAGGGAGC 0.9 2704 TCTA (879) ath-miR159a TTTGGATTGAAGGGAGC 0.95 2705 TCTA (880) ath-miR159b TTTGGATTGAAGGGAGC 0.9 2706 TCTT (881) ath-miR159c TTTGGATTGAAGGGAGC 0.86 2707 TCCT (882) bdi-miR159 CTTGGATTGAAGGGAGC 0.95 2708 TCT (883) bna-miR159 TTTGGATTGAAGGGAGC 0.95 2709 TCTA (884) bra-miR159a TTTGGATTGAAGGGAGC 0.95 2710 TCTA (885) bvl-miR159 TTGGACTGAAGGGAGCT 0.81 2711 CCCT (886) cmi-miR159 TTGGACTGAAGGGAGCT 0.81 2712 CCCT (887) cor-miR159 TTGGACTGAAGGGAGCT 0.81 2713 CCCT (888) crb-miR159 TTGGACTGAAGGGAGCT 0.81 2714 CCCT (889) csi-miR159 TTTGGATTGAAGGGAGC 0.95 2715 TCTA (890) dso-miR159 TTGGACTGAAGGGAGCT 0.81 2716 CCCT (891) ech-miR159 TTGGACTGAAGGGAGCT 0.81 2717 CCCT (892) fal-miR159 TTGGACTGAAGGGAGCT 0.81 2718 CCCT (893) far-miR159 TTTGGATTGAAGGGAGC 0.9 2719 TCTG (894) gma-miR159a-3p TTTGGATTGAAGGGAGC 0.95 2720 TCTA (895) gma-miR159b ATTGGAGTGAAGGGAGC 0.86 2721 TCCA (896) gma-miR159c ATTGGAGTGAAGGGAGC 0.81 2722 TCCG (897) hvu-miR159a TTTGGATTGAAGGGAGC 0.9 2723 TCTG (898) hvu-miR159b TTTGGATTGAAGGGAGC 0.9 2724 TCTG (899) hvv-miR159a TTTGGATTGAAGGGAGC 0.9 2725 TCTG (900) hvv-miR159b TTTGGATTGAAGGGAGC 0.9 2726 TCTG (901) ltu-miR159 TTTGGATTGAAGGGAGC 0.95 2727 TCTA (902) mma-miR159 TTGGACTGAAGGGAGCT 0.81 2728 CCCT (903) mtr-miR159a TTTGGATTGAAGGGAGC 0.95 2729 TCTA (904) mtr-miR159b ATTGAATTGAAGGGAGC 0.71 2730 AACT (905) mtr-miR159c TTTGGATTGAAGGGAGC 0.95 2731 TCTA (906) nof-miR159 TTGGACTGAAGGGAGCT 0.81 2732 CCCT (907) oru-miR159 TTTGGATTGAAGGGAGC 0.9 2733 TCTG (908) osa-miR159a TTTGGATTGAAGGGAGC 0.9 2734 TCTG (909) osa-miR159a.1 TTTGGATTGAAGGGAGC 0.9 2735 TCTG (910) osa-miR159b TTTGGATTGAAGGGAGC 0.9 2736 TCTG (911) osa-miR159c ATTGGATTGAAGGGAGC 0.9 2737 TCCA (912) osa-miR159d ATTGGATTGAAGGGAGC 0.86 2738 TCCG (913) osa-miR159e ATTGGATTGAAGGGAGC 0.86 2739 TCCT (914) osa-miR159m TTTGGATTGAAGGGAGC 0.9 2740 TCTG (915) pgl-miR159 TTTGGATTGAAGGGAGC 0.9 2741 TCTG (916) psi-miR159 CTTGGATTGAAGGGAGC 0.95 2742 TCCA (917) pta-miR159a TTGGATTGAAGGGAGCT 0.9 2743 CCA (918) pta-miR159b TTGGATTGAAGAGAGCT 0.81 2744 CCC (919) pta-miR159c CTTGGATTGAAGGGAGC 0.9 2745 TCCC (920) ptc-miR159a TTTGGATTGAAGGGAGC 0.95 2746 TCTA (921) ptc-miR159b TTTGGATTGAAGGGAGC 0.95 2747 TCTA (922) ptc-miR159c TTTGGATTGAAGGGAGC 0.95 2748 TCTA (923) ptc-miR159d CTTGGATTGAAGGGAGC 0.9 2749 TCCT (924) ptc-miR159e CTTGGGGTGAAGGGAGC 0.81 2750 TCCT (925) ptc-miR159f ATTGGAGTGAAGGGAGC 0.86 2751 TCGA (926) pvu-miR159 TTTGGATTGAAGGGAGC 0.95 2752 TCTA (927) pvu-miR159.2 CTTCCATATCTGGGGAG 0.62 2753 CTTC (928) pvu-miR159a.1 TTTGGATTGAAGGGAGC 0.95 2754 TCTA (929) pvu-miR159a.2 CTTCCATATCTGGGGAG 0.62 2755 CTTC (930) rco-miR159 TTTGGATTGAAGGGAGC 0.95 2756 TCTA (931) rin-miR159 TTGGACTGAAGGGAGCT 0.81 2757 CCCT (932) sar-miR159 TTTGGATTGAAGGGAGC 0.9 2758 TCTG (933) sbi-miR159a TTTGGATTGAAGGGAGC 0.9 2759 TCTG (934) sbi-miR159b CTTGGATTGAAGGGAGC 0.9 2760 TCCT (935) sly-miR159 TTTGGATTGAAGGGAGC 0.95 2761 TCTA (936) smo-miR159 CTTGGATTGAAGGGAGC 0.9 2762 TCCC (937) sof-miR159a TTTGGATTGAAGGGAGC 0.9 2763 TCTG (938) sof-miR159b TTTGGATTGAAGGGAGC 0.9 2764 TCTG (939) sof-miR159c CTTGGATTGAAGGGAGC 0.9 2765 TCCT (940) sof-miR159d TTTGGATTGAAGGGAGC 0.9 2766 TCTG (941) sof-miR159e TTTGGATTGAAAGGAGC 0.86 2767 TCTT (942) spr-miR159 TTTGGATTGAAGGGAGC 0.9 2768 TCTG (943) ssp-miR159a TTTGGATTGAAGGGAGC 0.9 2769 TCTG (944) svi-miR159 TTGGACTGAAGGGAGCT 0.81 2770 CCCT (945) tae-miR159a TTTGGATTGAAGGGAGC 0.9 2771 TCTG (946) tae-miR159b TTTGGATTGAAGGGAGC 0.9 2772 TCTG (947) tar-miR159 TTGGACTGAAGGGAGCT 0.81 2773 CCCT (948) vvi-miR159a CTTGGAGTGAAGGGAGC 0.9 2774 TCTC (949) vvi-miR159b CTTGGAGTGAAGGGAGC 0.9 2775 TCTC (950) vvi-miR159c TTTGGATTGAAGGGAGC 0.95 2776 TCTA (951) zma-miR159a TTTGGATTGAAGGGAGC 0.9 2777 TCTG (952) zma-miR159b TTTGGATTGAAGGGAGC 0.9 2778 TCTG (953) zma-miR159c CTTGGATTGAAGGGAGC 0.9 2779 TCCT (954) zma-miR159d CTTGGATTGAAGGGAGC 0.9 2780 TCCT (955) zma-miR159e ATTGGTTTGAAGGGAGC 0.86 2781 TCCA (956) zma-miR159f TTTGGATTGAAGGGAGC 0.9 2782 TCTG (957) zma-miR159g TTTGGAGTGAAGGGAGT 0.81 2783 TCTG (958) zma-miR159h TTTGGAGTGAAGGGAGC 0.86 2784 TCTG (959) zma-miR159i TTTGGAGTGAAGGGAGC 0.86 2785 TCTG (960) zma-miR159j TTTGGATTGAAGGGAGC 0.9 2786 TCTG (961) zma-miR159k TTTGGATTGAAGGGAGC 0.9 2787 TCTG (962) zma-miR159m TTTGGATTGAAGGGAGC 0.9 2788 TCTG (963) osa- osa-miR1858b GAGAGGAGGACGGAGT 1 2789 miR1858a GGGGC (964) psi- acb-miR159 TTGGACTGAAGGGAGCT 0.86 2790 miR159 CCCT (965) aha-miR159 TTGGACTGAAGGGAGCT 0.86 2791 CCCT (966) ahi-miR159 TTGGACTGAAGGGAGCT 0.86 2792 CCCT (967) ahy-miR159 TTTGGATTGAAGGGAGC 0.9 2793 TCTA (968) aly-miR159a TTTGGATTGAAGGGAGC 0.9 2794 TCTA (969) aly-miR159b TTTGGATTGAAGGGAGC 0.86 2795 TCTT (970) aly-miR159c TTTGGATTGAAGGGAGC 0.9 2796 TCCT (971) ape-miR159 TTGGACTGAAGGGAGCT 0.86 2797 CCCT (972) aqc-miR159 TTTGGACTGAAGGGAGC 0.86 2798 TCTA (973) ath-miR159a TTTGGATTGAAGGGAGC 0.9 2799 TCTA (974) ath-miR159b TTTGGATTGAAGGGAGC 0.86 2800 TCTT (975) ath-miR159c TTTGGATTGAAGGGAGC 0.9 2801 TCCT (976) bdi-miR159 CTTGGATTGAAGGGAGC 0.9 2802 TCT (977) bna-miR159 TTTGGATTGAAGGGAGC 0.9 2803 TCTA (978) bra-miR159a TTTGGATTGAAGGGAGC 0.9 2804 TCTA (979) bvl-miR159 TTGGACTGAAGGGAGCT 0.86 2805 CCCT (980) cmi-miR159 TTGGACTGAAGGGAGCT 0.86 2806 CCCT (981) cor-miR159 TTGGACTGAAGGGAGCT 0.86 2807 CCCT (982) crb-miR159 TTGGACTGAAGGGAGCT 0.86 2808 CCCT (983) csi-miR159 TTTGGATTGAAGGGAGC 0.9 2809 TCTA (984) dso-miR159 TTGGACTGAAGGGAGCT 0.86 2810 CCCT (985) ech-miR159 TTGGACTGAAGGGAGCT 0.86 2811 CCCT (986) fal-miR159 TTGGACTGAAGGGAGCT 0.86 2812 CCCT (987) far-miR159 TTTGGATTGAAGGGAGC 0.86 2813 TCTG (988) gma-miR159a-3p TTTGGATTGAAGGGAGC 0.9 2814 TCTA (989) gma-miR159b ATTGGAGTGAAGGGAGC 0.9 2815 TCCA (990) gma-miR159c ATTGGAGTGAAGGGAGC 0.86 2816 TCCG (991) hvu-miR159a TTTGGATTGAAGGGAGC 0.86 2817 TCTG (992) hvu-miR159b TTTGGATTGAAGGGAGC 0.86 2818 TCTG (993) hvv-miR159a TTTGGATTGAAGGGAGC 0.86 2819 TCTG (994) hvv-miR159b TTTGGATTGAAGGGAGC 0.86 2820 TCTG (995) ltu-miR159 TTTGGATTGAAGGGAGC 0.9 2821 TCTA (996) mma-miR159 TTGGACTGAAGGGAGCT 0.86 2822 CCCT (997) mtr-miR159a TTTGGATTGAAGGGAGC 0.9 2823 TCTA (998) mtr-miR159b ATTGAATTGAAGGGAGC 0.76 2824 AACT (999) mtr-miR159c TTTGGATTGAAGGGAGC 0.9 2825 TCTA (1000) nof-miR159 TTGGACTGAAGGGAGCT 0.86 2826 CCCT (1001) oru-miR159 TTTGGATTGAAGGGAGC 0.86 2827 TCTG (1002) osa-miR159a TTTGGATTGAAGGGAGC 0.86 2828 TCTG (1003 osa-miR159a.1 TTTGGATTGAAGGGAGC 0.86 2829 TCTG (1004) osa-miR159a.2 TTGCATGCCCCAGGAGC 0.62 2830 TGCA (1005) osa-miR159b TTTGGATTGAAGGGAGC 0.86 2831 TCTG (1006) osa-miR159c ATTGGATTGAAGGGAGC 0.95 2832 TCCA (1007) osa-miR159d ATTGGATTGAAGGGAGC 0.9 2833 TCCG (1008) osa-miR159e ATTGGATTGAAGGGAGC 0.9 2834 TCCT (1009) osa-miR159f CTTGGATTGAAGGGAGC 0.95 2835 TCTA (1010) osa-miR159m TTTGGATTGAAGGGAGC 0.86 2836 TCTG (1011) pgl-miR159 TTTGGATTGAAGGGAGC 0.86 2837 TCTG (1012) pta-miR159a TTGGATTGAAGGGAGCT 0.95 2838 CCA (1013) pta-miR159b TTGGATTGAAGAGAGCT 0.86 2839 CCC (1014) pta-miR159c CTTGGATTGAAGGGAGC 0.95 2840 TCCC (1015) ptc-miR159a TTTGGATTGAAGGGAGC 0.9 2841 TCTA (1016) ptc-miR159b TTTGGATTGAAGGGAGC 0.9 2842 TCTA (1017) ptc-miR159c TTTGGATTGAAGGGAGC 0.9 2843 TCTA (1018) ptc-miR159d CTTGGATTGAAGGGAGC 0.95 2844 TCCT (1019) ptc-miR159e CTTGGGGTGAAGGGAGC 0.86 2845 TCCT (1020) ptc-miR159f ATTGGAGTGAAGGGAGC 0.86 2846 TCGA (1021) pvu-miR159 TTTGGATTGAAGGGAGC 0.9 2847 TCTA (1022) pvu-miR159.2 CTTCCATATCTGGGGAG 0.67 2848 CTTC (1023) pvu-miR159a.1 TTTGGATTGAAGGGAGC 0.9 2849 TCTA (1024) pvu-miR159a.2 CTTCCATATCTGGGGAG 0.67 2850 CTTC (1025) rco-miR159 TTTGGATTGAAGGGAGC 0.9 2851 TCTA (1026) rin-miR159 TTGGACTGAAGGGAGCT 0.86 2852 CCCT (1027) sar-miR159 TTTGGATTGAAGGGAGC 0.86 2853 TCTG (1028) sbi-miR159a TTTGGATTGAAGGGAGC 0.86 2854 TCTG (1029) sbi-miR159b CTTGGATTGAAGGGAGC 0.95 2855 TCCT (1030) sly-miR159 TTTGGATTGAAGGGAGC 0.9 2856 TCTA (1031) smo-miR159 CTTGGATTGAAGGGAGC 0.95 2857 TCCC (1032) sof-miR159a TTTGGATTGAAGGGAGC 0.86 2858 TCTG (1033) sof-miR159b TTTGGATTGAAGGGAGC 0.86 2859 TCTG (1034) sof-miR159c CTTGGATTGAAGGGAGC 0.95 2860 TCCT (1035) sof-miR159d TTTGGATTGAAGGGAGC 0.86 2861 TCTG (1036) sof-miR159e TTTGGATTGAAAGGAGC 0.81 2862 TCTT (1037) spr-miR159 TTTGGATTGAAGGGAGC 0.86 2863 TCTG (1038) ssp-miR159a TTTGGATTGAAGGGAGC 0.86 2864 TCTG (1039) svi-miR159 TTGGACTGAAGGGAGCT 0.86 2865 CCCT (1040) tae-miR159a TTTGGATTGAAGGGAGC 0.86 2866 TCTG (1041) tae-miR159b TTTGGATTGAAGGGAGC 0.86 2867 TCTG (1042) tar-miR159 TTGGACTGAAGGGAGCT 0.86 2868 CCCT (1043) vvi-miR159a CTTGGAGTGAAGGGAGC 0.86 2869 TCTC (1044) vvi-miR159b CTTGGAGTGAAGGGAGC 0.86 2870 TCTC (1045) vvi-miR159c TTTGGATTGAAGGGAGC 0.9 2871 TCTA (1046) zma-miR159a TTTGGATTGAAGGGAGC 0.86 2872 TCTG (1047) zma-miR159b TTTGGATTGAAGGGAGC 0.86 2873 TCTG (1048) zma-miR159c CTTGGATTGAAGGGAGC 0.95 2874 TCCT (1049) zma-miR159d CTTGGATTGAAGGGAGC 0.95 2875 TCCT (1050) zma-miR159e ATTGGTTTGAAGGGAGC 0.9 2876 TCCA (1051) zma-miR159f TTTGGATTGAAGGGAGC 0.86 2877 TCTG (1052) zma-miR159g TTTGGAGTGAAGGGAGT 0.76 2878 TCTG (1053) zma-miR159h TTTGGAGTGAAGGGAGC 0.81 2879 TCTG (1054) zma-miR159i TTTGGAGTGAAGGGAGC 0.81 2880 TCTG (1055) zma-miR159j TTTGGATTGAAGGGAGC 0.86 2881 TCTG (1056) zma-miR159k TTTGGATTGAAGGGAGC 0.86 2882 TCTG (1057) zma-miR159m TTTGGATTGAAGGGAGC 0.86 2883 TCTG (1058) pta- ahy-miR156a TGACAGAAGAGAGAGA 0.8 2884 miR156a GCAC (1059) ahy-miR156b-5p TTGACAGAAGATAGAGA 0.85 2885 GCAC (1060) ahy-miR156c TTGACAGAAGAGAGAG 0.8 2886 AGCAC (1061) aly-miR156a TGACAGAAGAGAGTGA 0.75 2887 GCAC (1062) aly-miR156b TGACAGAAGAGAGTGA 0.75 2888 GCAC (1063) aly-miR156c TGACAGAAGAGAGTGA 0.75 2889 GCAC (1064) aly-miR156d TGACAGAAGAGAGTGA 0.75 2890 GCAC (1065) aly-miR156e TGACAGAAGAGAGTGA 0.75 2891 GCAC (1066) aly-miR156f TGACAGAAGAGAGTGA 0.75 2892 GCAC (1067) aly-miR156g CGACAGAAGAGAGTGA 0.75 2893 GCAC (1068) aly-miR156h TGACAGAAGAAAGAGA 0.8 2894 GCAC (1069) aqc-miR156a TGACAGAAGATAGAGA 0.85 2895 GCAC (1070) aqc-miR156b TGACAGAAGATAGAGA 0.85 2896 GCAC (1071) ath-miR156a TGACAGAAGAGAGTGA 0.75 2897 GCAC (1072) ath-miR156b TGACAGAAGAGAGTGA 0.75 2898 GCAC (1073) ath-miR156c TGACAGAAGAGAGTGA 0.75 2899 GCAC (1074) ath-miR156d TGACAGAAGAGAGTGA 0.75 2900 GCAC (1075) ath-miR156e TGACAGAAGAGAGTGA 0.75 2901 GCAC (1076) ath-miR156f TGACAGAAGAGAGTGA 0.75 2902 GCAC (1077) ath-miR156g CGACAGAAGAGAGTGA 0.75 2903 GCAC (1078) ath-miR156h TGACAGAAGAAAGAGA 0.8 2904 GCAC (1079) ath-miR156m TGACAGAAGAGAGAGA 0.8 2905 GCAC (1080) ath-miR156o TGACAGAAGAGAGAGA 0.8 2906 GCAC (1081) ath-miR156p TGACAGAAGAGAGAGA 0.8 2907 GCAC (1082) ath-miR156q TGACAGAAGAGAGAGA 0.8 2908 GCAC (1083) ath-miR156r TGACAGAAGAGAGAGA 0.8 2909 GCAC (1084) ath-miR156s TGACAGAAGAGAGAGA 0.8 2910 GCAC (1085) bdi-miR156 TGACAGAAGAGAGAGA 0.85 2911 GCACA (1086) bdi-miR156b TGACAGAAGAGAGTGA 0.75 2912 GCAC (1087) bdi-miR156c TGACAGAAGAGAGTGA 0.75 2913 GCAC (1088) bdi-miR156d TGACAGAAGAGAGTGA 0.75 2914 GCAC (1089) bna-miR156a TGACAGAAGAGAGTGA 0.8 2915 GCACA (1090) bna-miR156b TTGACAGAAGATAGAGA 0.85 2916 GCAC (1091) bna-miR156c TTGACAGAAGATAGAGA 0.85 2917 GCAC (1092) can-miR156a TGACAGAAGAGAGAGA 0.8 2918 GCAC (1093) can-miR156b TGACAGAAGAGAGGGA 0.75 2919 GCAC (1094) cpt-miR156a TGACAGAAGAGAGTGA 0.75 2920 GCAC (1095) cpt-miR156b TGACAGAAGAGAGAGA 0.8 2921 GCAC (1096) cru-miR156 TGACAGAAGAGAGAGA 0.8 2922 GCAC (1097) csi-miR156 TGACAGAAGAGAGTGA 0.75 2923 GCAC (1098) csi-miR156a TGACAGAAGAGAGAGA 0.8 2924 GCAC (1099) csi-miR156b TGACAGAAGAGAGAGA 0.8 2925 GCAC (1100) ctr-miR156 TGACAGAAGAGAGTGA 0.75 2926 GCAC (1101) eca-miR156 TGACAGAAGAGAGAGA 0.8 2927 GCAC (1102) far-miR156a TGACAGAAGAGAGAGA 0.85 2928 GCACA (1103) far-miR156b TTGACAGAAGAGAGAG 0.8 2929 AGCAC (1104) ghr-miR156a TGACAGAAGAGAGTGA 0.75 2930 GCAC (1105) ghr-miR156b TGACAGAAGAGAGTGA 0.75 2931 GCAC (1106) ghr-miR156c TGTCAGAAGAGAGTGAG 0.75 2932 CAC (1107) ghr-miR156d TGACAGAAGAGAGTGA 0.75 2933 GCAC (1108) gma-miR156a TGACAGAAGAGAGTGA 0.75 2934 GCAC (1109) gma-miR156b TGACAGAAGAGAGAGA 0.85 2935 GCACA (1110) gma-miR156c TTGACAGAAGATAGAGA 0.85 2936 GCAC (1111) gma-miR156d TTGACAGAAGATAGAGA 0.85 2937 GCAC (1112) gma-miR156e TTGACAGAAGATAGAGA 0.85 2938 GCAC (1113) gma-miR156f TTGACAGAAGAGAGAG 0.85 2939 AGCACA (1114) gma-miR156g ACAGAAGATAGAGAGC 0.9 2940 ACAG (1115) gma-miR156h TGACAGAAGAGAGAGA 0.8 2941 GCAC (1116) gma-miR156i TGACAGAAGAGAGAGA 0.8 2942 GCAC (1117) han-miR156 TGACAGAAGAGAGAGA 0.8 2943 GCAC (1118) hvs-miR156 TGACAGAAGAGAGAGA 0.8 2944 GCAC (1119) hvu-miR156 TGACAGAAGAGAGTGA 0.8 2945 GCACA (1120) hvv-miR156a TGACAGAAGAGAGTGA 0.75 2946 GCAC (1121) hvv-miR156b TGACAGAAGAGAGAGA 0.8 2947 GCAC (1122) hvv-miR156c TGACAGAAGAGAGAGA 0.8 2948 GCAC (1123) hvv-miR156d TGACAGAAGAGAGAGA 0.8 2949 GCAC (1124) lja-miR156 TGACAGAAGAGAGAGA 0.8 2950 GCAC (1125) lsa-miR156 TGACAGAAGAGAGAGA 0.8 2951 GCAC (1126) mdo-miR156a TGACAGAAGAGAGAGA 0.8 2952 GCAC (1127) mdo-miR156b TGACAGAAGAGAGAGA 0.8 2953 GCAC (1128) mtr-miR156 TGACAGAAGAGAGAGA 0.85 2954 GCACA (1129) mtr-miR156b TGACAGAAGAGAGTGA 0.75 2955 GCAC (1130) mtr-miR156c TGACAGAAGAGAGTGA 0.75 2956 GCAC (1131) mtr-miR156d TGACAGAAGAGAGTGA 0.75 2957 GCAC (1132) mtr-miR156e TTGACAGAAGATAGAGA 0.85 2958 GCAC (1133) mtr-miR156f TTGACAGAAGATAGAGA 0.85 2959 GCAC (1134) mtr-miR156g TTGACAGAAGATAGAGG 0.8 2960 GCAC (1135) mtr-miR156h TTGACAGAAGATAGAGA 0.85 2961 GCAC (1136) mtr-miR156i TGACAGAAGAGAGTGA 0.75 2962 GCAC (1137) nbe-miR156a TGACAGAAGAGAGAGA 0.8 2963 GCAC (1138) nbe-miR156b TGACAGAAGAGAGAGA 0.8 2964 GCAC (1139) oru-miR156 TGACAGAAGAGAGTGA 0.75 2965 GCAC (1140) osa-miR156a TGACAGAAGAGAGTGA 0.75 2966 GCAC (1141) osa-miR156b TGACAGAAGAGAGTGA 0.75 2967 GCAC (1142) osa-miR156c TGACAGAAGAGAGTGA 0.75 2968 GCAC (1143) osa-miR156d TGACAGAAGAGAGTGA 0.75 2969 GCAC (1144) osa-miR156e TGACAGAAGAGAGTGA 0.75 2970 GCAC (1145) osa-miR156f TGACAGAAGAGAGTGA 0.75 2971 GCAC (1146) osa-miR156g TGACAGAAGAGAGTGA 0.75 2972 GCAC (1147) osa-miR156h TGACAGAAGAGAGTGA 0.75 2973 GCAC (1148) osa-miR156i TGACAGAAGAGAGTGA 0.75 2974 GCAC (1149) osa-miR156j TGACAGAAGAGAGTGA 0.75 2975 GCAC (1150) osa-miR156k TGACAGAAGAGAGAGA 0.85 2976 GCACA (1151) osa-miR156l CGACAGAAGAGAGTGA 0.75 2977 GCATA (1152) osa-miR156m TGACAGAAGAGAGTGA 0.75 2978 GCAC (1153) osa-miR156n TGACAGAAGAGAGTGA 0.75 2979 GCAC (1154) osa-miR156o TGACAGAAGAGAGTGA 0.7 2980 GCAT (1155) osa-miR156p TGACAGAAGAGAGTGA 0.7 2981 GCTC (1156) osa-miR156q TGACAGAACAGAGTGA 0.7 2982 GCAC (1157) osa-miR156r TGACAGAAGAGAGAGA 0.8 2983 GCAC (1158) par-miR156 TGACAGAAGAGAGAGA 0.8 2984 GCAC (1159) ppd-miR156 TGACAGAAGAGAGAGA 0.8 2985 GCAC (1160) ppr-miR156 TGACAGAAGAGAGTGA 0.75 2986 GCAC (1161) ppt-miR156a TGACAGAAGAGAGTGA 0.75 2987 GCAC (1162) ppt-miR156b TGACAGAAGAGAGTGA 0.75 2988 GCAC (1163) ppt-miR156c TGACAGAAGAGAGTGA 0.75 2989 GCAC (1164) pta-miR156b CAGAAGATAGAGAGCA 0.95 2990 CAAC (1165) ptc-miR156a TGACAGAAGAGAGTGA 0.75 2991 GCAC (1166) ptc-miR156b TGACAGAAGAGAGTGA 0.75 2992 GCAC (1167) ptc-miR156c TGACAGAAGAGAGTGA 0.75 2993 GCAC (1168) ptc-miR156d TGACAGAAGAGAGTGA 0.75 2994 GCAC (1169) ptc-miR156e TGACAGAAGAGAGTGA 0.75 2995 GCAC (1170) ptc-miR156f TGACAGAAGAGAGTGA 0.75 2996 GCAC (1171) ptc-miR156g TTGACAGAAGATAGAGA 0.85 2997 GCAC (1172) ptc-miR156h TTGACAGAAGATAGAGA 0.85 2998 GCAC (1173) ptc-miR156i TTGACAGAAGATAGAGA 0.85 2999 GCAC (1174) ptc-miR156j TTGACAGAAGATAGAGA 0.85 3000 GCAC (1175) ptc-miR156k TGACAGAAGAGAGGGA 0.75 3001 GCAC (1176) ptr-miR156 TGACAGAAGAGAGAGA 0.8 3002 GCAC (1177) pts-miR156a TGACAGAAGAGAGTGA 0.7 3003 GCGC (1178) pts-miR156b TGACAGAAGAGAGAGA 0.8 3004 GCAC (1179) pts-miR156c TGACAGAAGAGAGAGA 0.8 3005 GCAC (1180) rco-miR156a TGACAGAAGAGAGTGA 0.8 3006 GCACA (1181) rco-miR156b TGACAGAAGAGAGTGA 0.8 3007 GCACA (1182) rco-miR156c TGACAGAAGAGAGTGA 0.8 3008 GCACA (1183) rco-miR156d TGACAGAAGAGAGTGA 0.8 3009 GCACA (1184) rco-miR156e TGACAGAAGAGAGAGA 0.85 3010 GCACA (1185) rco-miR156f TTGACAGAAGATAGAGA 0.85 3011 GCAC (1186) rco-miR156g TTGACAGAAGATAGAGA 0.85 3012 GCAC (1187) rco-miR156h TTGACAGAAGATAGAGA 0.85 3013 GCAC (1188) sbi-miR156a TGACAGAAGAGAGTGA 0.75 3014 GCAC (1189) sbi-miR156b TGACAGAAGAGAGTGA 0.75 3015 GCAC (1190) sbi-miR156c TGACAGAAGAGAGTGA 0.75 3016 GCAC (1191) sbi-miR156d TGACAGAAGAGAGAGA 0.85 3017 GCACA (1192) sbi-miR156e TGACAGAAGAGAGCGA 0.75 3018 GCAC (1193) sbi-miR156f TGACAGAAGAGAGTGA 0.75 3019 GCAC (1194) sbi-miR156g TGACAGAAGAGAGTGA 0.75 3020 GCAC (1195) sbi-miR156h TGACAGAAGAGAGTGA 0.75 3021 GCAC (1196) sbi-miR156i TGACAGAAGAGAGTGA 0.75 3022 GCAC (1197) sin-miR156 TGACAGAAGAGAGAGA 0.8 3023 GCAC (1198) sly-miR156a TTGACAGAAGATAGAGA 0.85 3024 GCAC (1199) sly-miR156b TTGACAGAAGATAGAGA 0.85 3025 GCAC (1200) sly-miR156c TTGACAGAAGATAGAGA 0.85 3026 GCAC (1201) smo-miR156a CGACAGAAGAGAGTGA 0.75 3027 GCAC (1202) smo-miR156b CTGACAGAAGATAGAG 0.85 3028 AGCAC (1203) smo-miR156c TTGACAGAAGAAAGAG 0.8 3029 AGCAC (1204) smo-miR156d TTGACAGAAGACAGGG 0.75 3030 AGCAC (1205) sof-miR156 TGACAGAAGAGAGTGA 0.75 3031 GCAC (1206) sof-miR156c TGACAGAAGAGAGAGA 0.8 3032 GCAC (1207) sof-miR156d TGACAGAAGAGAGAGA 0.8 3033 GCAC (1208) sof-miR156e TGACAGAAGAGAGAGA 0.8 3034 GCAC (1209) sof-miR156f TGACAGAAGAGAGAGA 0.8 3035 GCAC (1210) sof-miR156g TGACAGAAGAGAGAGA 0.8 3036 GCAC (1211) sof-miR156h TGACAGAAGAGAGAGA 0.8 3037 GCAC (1212) sof-miR156u TGACAGAAGAGAGAGA 0.8 3038 GCAC (1213) spr-miR156 TGACAGAAGAGAGAGA 0.8 3039 GCAC (1214) ssp-miR156 TGACAGAAGAGAGTGA 0.8 3040 GCACA (1215) stu-miR156a TGACAGAAGAGAGTGA 0.75 3041 GCAC (1216) stu-miR156b TGACAGAAGAGAGAGA 0.8 3042 GCAC (1217) stu-miR156c TGACAGAAGAGAGAGA 0.8 3043 GCAC (1218) stu-miR156d TGACAGAAGAGAGAGA 0.8 3044 GCAC (1219) stu-miR156e TGACAGAAGAGAGAGA 0.8 3045 GCAC (1220) tae-miR156 TGACAGAAGAGAGTGA 0.8 3046 GCACA (1221) tae-miR156a TGACAGAAGAGAGAGA 0.8 3047 GCAC (1222) tae-miR156b TGACAGAAGAGAGAGA 0.8 3048 GCAC (1223) tcc-miR156a TGACAGAAGAGAGAGA 0.85 3049 GCACA (1224) tcc-miR156b TGACAGAAGAGAGTGA 0.75 3050 GCAC (1225) tcc-miR156c TGACAGAAGAGAGTGA 0.75 3051 GCAC (1226) tcc-miR156d TGACAGAAGAGAGTGA 0.75 3052 GCAC (1227) tcc-miR156e TTGACAGAAGATAGAGA 0.85 3053 GCAC (1228) tcc-miR156f TTGACAGAAGATAGAGA 0.85 3054 GCAC (1229) tcc-miR156g TGACAGAAGAGAGTGA 0.75 3055 GCAC (1230) tre-miR156 TGACAGAAGAGAGTGA 0.75 3056 GCAC (1231) vvi-miR156a TGACAGAAGAGAGGGA 0.75 3057 GCAC (1232) vvi-miR156b TGACAGAAGAGAGTGA 0.75 3058 GCAC (1233) vvi-miR156c TGACAGAAGAGAGTGA 0.75 3059 GCAC (1234) vvi-miR156d TGACAGAAGAGAGTGA 0.75 3060 GCAC (1235) vvi-miR156e TGACAGAGGAGAGTGA 0.7 3061 GCAC (1236) vvi-miR156f TTGACAGAAGATAGAGA 0.85 3062 GCAC (1237) vvi-miR156g TTGACAGAAGATAGAGA 0.85 3063 GCAC (1238) vvi-miR156h TGACAGAAGAGAGAGA 0.75 3064 GCAT (1239) vvi-miR156i TTGACAGAAGATAGAGA 0.85 3065 GCAC (1240) zel-miR156 TGACAGAAGAGAGAGA 0.8 3066 GCAC (1241) zma-miR156a TGACAGAAGAGAGTGA 0.75 3067 GCAC (1242) zma-miR156b TGACAGAAGAGAGTGA 0.75 3068 GCAC (1243) zma-miR156c TGACAGAAGAGAGTGA 0.75 3069 GCAC (1244) zma-miR156d TGACAGAAGAGAGTGA 0.75 3070 GCAC (1245) zma-miR156e TGACAGAAGAGAGTGA 0.75 3071 GCAC (1246) zma-miR156f TGACAGAAGAGAGTGA 0.75 3072 GCAC (1247) zma-miR156g TGACAGAAGAGAGTGA 0.75 3073 GCAC (1248) zma-miR156h TGACAGAAGAGAGTGA 0.75 3074 GCAC (1249) zma-miR156i TGACAGAAGAGAGTGA 0.75 3075 GCAC (1250) zma-miR156j TGACAGAAGAGAGAGA 0.85 3076 GCACA (1251) zma-miR156k TGACAGAAGAGAGCGA 0.75 3077 GCAC (1252) zma-miR156l TGACAGAAGAGAGTGA 0.75 3078 GCAC (1253) zma-miR156m TGACAGAAGAGAGTGA 0.75 3079 GCAC (1254) zma-miR156n TGACAGAAGAGAGTGA 0.75 3080 GCAC (1255) zma-miR156o TGACAGAAGAGAGTGA 0.75 3081 GCAC (1256) zma-miR156p TGACAGAAGAGAGAGA 0.8 3082 GCAC (1257) zma-miR156q TGACAGAAGAGAGAGA 0.8 3083 GCAC (1258) zma-miR156r TGACAGAAGAGAGTGG 0.7 3084 GCAC (1259) pta- ahy-miR156a TGACAGAAGAGAGAGA 0.8 3085 miR156b GCAC (1260) ahy-miR156b-5p TTGACAGAAGATAGAGA 0.85 3086 GCAC (1261) ahy-miR156c TTGACAGAAGAGAGAG 0.8 3087 AGCAC (1262) aly-miR156a TGACAGAAGAGAGTGA 0.75 3088 GCAC (1263) aly-miR156b TGACAGAAGAGAGTGA 0.75 3089 GCAC (1264) aly-miR156c TGACAGAAGAGAGTGA 0.75 3090 GCAC (1265) aly-miR156d TGACAGAAGAGAGTGA 0.75 3091 GCAC (1266) aly-miR156e TGACAGAAGAGAGTGA 0.75 3092 GCAC (1267) aly-miR156f TGACAGAAGAGAGTGA 0.75 3093 GCAC (1268) aly-miR156g CGACAGAAGAGAGTGA 0.75 3094 GCAC (1269) aly-miR156h TGACAGAAGAAAGAGA 0.8 3095 GCAC (1270) aqc-miR156a TGACAGAAGATAGAGA 0.85 3096 GCAC (1271) aqc-miR156b TGACAGAAGATAGAGA 0.85 3097 GCAC (1272) ath-miR156a TGACAGAAGAGAGTGA 0.75 3098 GCAC (1273) ath-miR156b TGACAGAAGAGAGTGA 0.75 3099 GCAC (1274) ath-miR156c TGACAGAAGAGAGTGA 0.75 3100 GCAC (1275) ath-miR156d TGACAGAAGAGAGTGA 0.75 3101 GCAC (1276) ath-miR156e TGACAGAAGAGAGTGA 0.75 3102 GCAC (1277) ath-miR156f TGACAGAAGAGAGTGA 0.75 3103 GCAC (1278) ath-miR156g CGACAGAAGAGAGTGA 0.75 3104 GCAC (1279) ath-miR156h TGACAGAAGAAAGAGA 0.8 3105 GCAC (1280) ath-miR156m TGACAGAAGAGAGAGA 0.8 3106 GCAC (1281) ath-miR156o TGACAGAAGAGAGAGA 0.8 3107 GCAC (1282) ath-miR156p TGACAGAAGAGAGAGA 0.8 3108 GCAC (1283) ath-miR156q TGACAGAAGAGAGAGA 0.8 3109 GCAC (1284) ath-miR156r TGACAGAAGAGAGAGA 0.8 3110 GCAC (1285) ath-miR156s TGACAGAAGAGAGAGA 0.8 3111 GCAC (1286) bdi-miR156 TGACAGAAGAGAGAGA 0.85 3112 GCACA (1287) bdi-miR156b TGACAGAAGAGAGTGA 0.75 3113 GCAC (1288) bdi-miR156c TGACAGAAGAGAGTGA 0.75 3114 GCAC (1289) bdi-miR156d TGACAGAAGAGAGTGA 0.75 3115 GCAC (1290) bna-miR156a TGACAGAAGAGAGTGA 0.8 3116 GCACA (1291) bna-miR156b TTGACAGAAGATAGAGA 0.85 3117 GCAC (1292) bna-miR156c TTGACAGAAGATAGAGA 0.85 3118 GCAC (1293) can-miR156a TGACAGAAGAGAGAGA 0.8 3119 GCAC (1294) can-miR156b TGACAGAAGAGAGGGA 0.75 3120 GCAC (1295) cpt-miR156a TGACAGAAGAGAGTGA 0.75 3121 GCAC (1296) cpt-miR156b TGACAGAAGAGAGAGA 0.8 3122 GCAC (1297) cru-miR156 TGACAGAAGAGAGAGA 0.8 3123 GCAC (1298) csi-miR156 TGACAGAAGAGAGTGA 0.75 3124 GCAC (1299) csi-miR156a TGACAGAAGAGAGAGA 0.8 3125 GCAC (1300) csi-miR156b TGACAGAAGAGAGAGA 0.8 3126 GCAC (1301) ctr-miR156 TGACAGAAGAGAGTGA 0.75 3127 GCAC (1302) eca-miR156 TGACAGAAGAGAGAGA 0.8 3128 GCAC (1303) far-miR156a TGACAGAAGAGAGAGA 0.85 3129 GCACA (1304) far-miR156b TTGACAGAAGAGAGAG 0.8 3130 AGCAC (1305) ghr-miR156a TGACAGAAGAGAGTGA 0.75 3131 GCAC (1306) ghr-miR156b TGACAGAAGAGAGTGA 0.75 3132 GCAC (1307) ghr-miR156c TGTCAGAAGAGAGTGAG 0.75 3133 CAC (1308) ghr-miR156d TGACAGAAGAGAGTGA 0.75 3134 GCAC (1309) gma-miR156a TGACAGAAGAGAGTGA 0.75 3135 GCAC (1310) gma-miR156b TGACAGAAGAGAGAGA 0.85 3136 GCACA (1311) gma-miR156c TTGACAGAAGATAGAGA 0.85 3137 GCAC (1312) gma-miR156d TTGACAGAAGATAGAGA 0.85 3138 GCAC (1313) gma-miR156e TTGACAGAAGATAGAGA 0.85 3139 GCAC (1314) gma-miR156f TTGACAGAAGAGAGAG 0.85 3140 AGCACA (1315) gma-miR156g ACAGAAGATAGAGAGC 0.9 3141 ACAG (1316) gma-miR156h TGACAGAAGAGAGAGA 0.8 3142 GCAC (1317) gma-miR156i TGACAGAAGAGAGAGA 0.8 3143 GCAC (1318) han-miR156 TGACAGAAGAGAGAGA 0.8 3144 GCAC (1319) hvs-miR156 TGACAGAAGAGAGAGA 0.8 3145 GCAC (1320) hvu-miR156 TGACAGAAGAGAGTGA 0.8 3146 GCACA (1321) hvv-miR156a TGACAGAAGAGAGTGA 0.75 3147 GCAC (1322) hvv-miR156b TGACAGAAGAGAGAGA 0.8 3148 GCAC (1323) hvv-miR156c TGACAGAAGAGAGAGA 0.8 3149 GCAC (1324) hvv-miR156d TGACAGAAGAGAGAGA 0.8 3150 GCAC (1325) lja-miR156 TGACAGAAGAGAGAGA 0.8 3151 GCAC (1326) lsa-miR156 TGACAGAAGAGAGAGA 0.8 3152 GCAC (1327) mdo-miR156a TGACAGAAGAGAGAGA 0.8 3153 GCAC (1328) mdo-miR156b TGACAGAAGAGAGAGA 0.8 3154 GCAC (1329) mtr-miR156 TGACAGAAGAGAGAGA 0.85 3155 GCACA (1330) mtr-miR156b TGACAGAAGAGAGTGA 0.75 3156 GCAC (1331) mtr-miR156c TGACAGAAGAGAGTGA 0.75 3157 GCAC (1332) mtr-miR156d TGACAGAAGAGAGTGA 0.75 3158 GCAC (1333) mtr-miR156e TTGACAGAAGATAGAGA 0.85 3159 GCAC (1334) mtr-miR156f TTGACAGAAGATAGAGA 0.85 3160 GCAC (1335) mtr-miR156g TTGACAGAAGATAGAGG 0.8 3161 GCAC (1336) mtr-miR156h TTGACAGAAGATAGAGA 0.85 3162 GCAC (1337) mtr-miR156i TGACAGAAGAGAGTGA 0.75 3163 GCAC (1338) nbe-miR156a TGACAGAAGAGAGAGA 0.8 3164 GCAC (1339) nbe-miR156b TGACAGAAGAGAGAGA 0.8 3165 GCAC (1340) oru-miR156 TGACAGAAGAGAGTGA 0.75 3166 GCAC (1341) osa-miR156a TGACAGAAGAGAGTGA 0.75 3167 GCAC (1342) osa-miR156b TGACAGAAGAGAGTGA 0.75 3168 GCAC (1343) osa-miR156c TGACAGAAGAGAGTGA 0.75 3169 GCAC (1344) osa-miR156d TGACAGAAGAGAGTGA 0.75 3170 GCAC (1345) osa-miR156e TGACAGAAGAGAGTGA 0.75 3171 GCAC (1346) osa-miR156f TGACAGAAGAGAGTGA 0.75 3172 GCAC (1347) osa-miR156g TGACAGAAGAGAGTGA 0.75 3173 GCAC (1348) osa-miR156h TGACAGAAGAGAGTGA 0.75 3174 GCAC (1349) osa-miR156i TGACAGAAGAGAGTGA 0.75 3175 GCAC (1350) osa-miR156j TGACAGAAGAGAGTGA 0.75 3176 GCAC (1351) osa-miR156k TGACAGAAGAGAGAGA 0.85 3177 GCACA (1352) osa-miR156l CGACAGAAGAGAGTGA 0.75 3178 GCATA (1353) osa-miR156m TGACAGAAGAGAGTGA 0.75 3179 GCAC (1354) osa-miR156n TGACAGAAGAGAGTGA 0.75 3180 GCAC (1355) osa-miR156o TGACAGAAGAGAGTGA 0.7 3181 GCAT (1356) osa-miR156p TGACAGAAGAGAGTGA 0.7 3182 GCTC (1357) osa-miR156q TGACAGAACAGAGTGA 0.7 3183 GCAC (1358) osa-miR156r TGACAGAAGAGAGAGA 0.8 3184 GCAC (1359) par-miR156 TGACAGAAGAGAGAGA 0.8 3185 GCAC (1360) ppd-miR156 TGACAGAAGAGAGAGA 0.8 3186 GCAC (1361) ppr-miR156 TGACAGAAGAGAGTGA 0.75 3187 GCAC (1362) ppt-miR156a TGACAGAAGAGAGTGA 0.75 3188 GCAC (1363) ppt-miR156b TGACAGAAGAGAGTGA 0.75 3189 GCAC (1364) ppt-miR156c TGACAGAAGAGAGTGA 0.75 3190 GCAC (1365) pta-miR156a CAGAAGATAGAGAGCA 0.95 3191 CATC (1366) ptc-miR156a TGACAGAAGAGAGTGA 0.75 3192 GCAC (1367) ptc-miR156b TGACAGAAGAGAGTGA 0.75 3193 GCAC (1368) ptc-miR156c TGACAGAAGAGAGTGA 0.75 3194 GCAC (1369) ptc-miR156d TGACAGAAGAGAGTGA 0.75 3195 GCAC (1370) ptc-miR156e TGACAGAAGAGAGTGA 0.75 3196 GCAC (1371) ptc-miR156f TGACAGAAGAGAGTGA 0.75 3197 GCAC (1372) ptc-miR156g TTGACAGAAGATAGAGA 0.85 3198 GCAC (1373) ptc-miR156h TTGACAGAAGATAGAGA 0.85 3199 GCAC (1374) ptc-miR156i TTGACAGAAGATAGAGA 0.85 3200 GCAC (1375) ptc-miR156j TTGACAGAAGATAGAGA 0.85 3201 GCAC (1376) ptc-miR156k TGACAGAAGAGAGGGA 0.75 3202 GCAC (1377) ptr-miR156 TGACAGAAGAGAGAGA 0.8 3203 GCAC (1378) pts-miR156a TGACAGAAGAGAGTGA 0.7 3204 GCGC (1379) pts-miR156b TGACAGAAGAGAGAGA 0.8 3205 GCAC (1380) pts-miR156c TGACAGAAGAGAGAGA 0.8 3206 GCAC (1381) rco-miR156a TGACAGAAGAGAGTGA 0.8 3207 GCACA (1382) rco-miR156b TGACAGAAGAGAGTGA 0.8 3208 GCACA (1383) rco-miR156c TGACAGAAGAGAGTGA 0.8 3209 GCACA (1384) rco-miR156d TGACAGAAGAGAGTGA 0.8 3210 GCACA (1385) rco-miR156e TGACAGAAGAGAGAGA 0.85 3211 GCACA (1386) rco-miR156f TTGACAGAAGATAGAGA 0.85 3212 GCAC (1387) rco-miR156g TTGACAGAAGATAGAGA 0.85 3213 GCAC (1388) rco-miR156h TTGACAGAAGATAGAGA 0.85 3214 GCAC (1389) sbi-miR156a TGACAGAAGAGAGTGA 0.75 3215 GCAC (1390) sbi-miR156b TGACAGAAGAGAGTGA 0.75 3216 GCAC (1391) sbi-miR156c TGACAGAAGAGAGTGA 0.75 3217 GCAC (1392) sbi-miR156d TGACAGAAGAGAGAGA 0.85 3218 GCACA (1393) sbi-miR156e TGACAGAAGAGAGCGA 0.75 3219 GCAC (1394) sbi-miR156f TGACAGAAGAGAGTGA 0.75 3220 GCAC (1395) sbi-miR156g TGACAGAAGAGAGTGA 0.75 3221 GCAC (1396) sbi-miR156h TGACAGAAGAGAGTGA 0.75 3222 GCAC (1397) sbi-miR156i TGACAGAAGAGAGTGA 0.75 3223 GCAC (1398) sin-miR156 TGACAGAAGAGAGAGA 0.8 3224 GCAC (1399) sly-miR156a TTGACAGAAGATAGAGA 0.85 3225 GCAC (1400) sly-miR156b TTGACAGAAGATAGAGA 0.85 3226 GCAC (1401) sly-miR156c TTGACAGAAGATAGAGA 0.85 3227 GCAC (1402) smo-miR156a CGACAGAAGAGAGTGA 0.75 3228 GCAC (1403) smo-miR156b CTGACAGAAGATAGAG 0.85 3229 AGCAC (1404) smo-miR156c TTGACAGAAGAAAGAG 0.8 3230 AGCAC (1405) smo-miR156d TTGACAGAAGACAGGG 0.75 3231 AGCAC (1406) sof-miR156 TGACAGAAGAGAGTGA 0.75 3232 GCAC (1407) sof-miR156c TGACAGAAGAGAGAGA 0.8 3233 GCAC (1408) sof-miR156d TGACAGAAGAGAGAGA 0.8 3234 GCAC (1409) sof-miR156e TGACAGAAGAGAGAGA 0.8 3235 GCAC (1410) sof-miR156f TGACAGAAGAGAGAGA 0.8 3236 GCAC (1411) sof-miR156g TGACAGAAGAGAGAGA 0.8 3237 GCAC (1412) sof-miR156h TGACAGAAGAGAGAGA 0.8 3238 GCAC (1413) sof-miR156u TGACAGAAGAGAGAGA 0.8 3239 GCAC (1414) spr-miR156 TGACAGAAGAGAGAGA 0.8 3240 GCAC (1415) ssp-miR156 TGACAGAAGAGAGTGA 0.8 3241 GCACA (1416) stu-miR156a TGACAGAAGAGAGTGA 0.75 3242 GCAC (1417) stu-miR156b TGACAGAAGAGAGAGA 0.8 3243 GCAC (1418) stu-miR156c TGACAGAAGAGAGAGA 0.8 3244 GCAC (1419) stu-miR156d TGACAGAAGAGAGAGA 0.8 3245 GCAC (1420) stu-miR156e TGACAGAAGAGAGAGA 0.8 3246 GCAC (1421) tae-miR156 TGACAGAAGAGAGTGA 0.8 3247 GCACA (1422) tae-miR156a TGACAGAAGAGAGAGA 0.8 3248 GCAC (1423) tae-miR156b TGACAGAAGAGAGAGA 0.8 3249 GCAC (1424) tcc-miR156a TGACAGAAGAGAGAGA 0.85 3250 GCACA (1425) tcc-miR156b TGACAGAAGAGAGTGA 0.75 3251 GCAC (1426) tcc-miR156c TGACAGAAGAGAGTGA 0.75 3252 GCAC (1427) tcc-miR156d TGACAGAAGAGAGTGA 0.75 3253 GCAC (1428) tcc-miR156e TTGACAGAAGATAGAGA 0.85 3254 GCAC (1429) tcc-miR156f TTGACAGAAGATAGAGA 0.85 3255 GCAC (1430) tcc-miR156g TGACAGAAGAGAGTGA 0.75 3256 GCAC (1431) tre-miR156 TGACAGAAGAGAGTGA 0.75 3257 GCAC (1432) vvi-miR156a TGACAGAAGAGAGGGA 0.75 3258 GCAC (1433) vvi-miR156b TGACAGAAGAGAGTGA 0.75 3259 GCAC (1434) vvi-miR156c TGACAGAAGAGAGTGA 0.75 3260 GCAC (1435) vvi-miR156d TGACAGAAGAGAGTGA 0.75 3261 GCAC (1436) vvi-miR156e TGACAGAGGAGAGTGA 0.7 3262 GCAC (1437) vvi-miR156f TTGACAGAAGATAGAGA 0.85 3263 GCAC (1438) vvi-miR156g TTGACAGAAGATAGAGA 0.85 3264 GCAC (1439) vvi-miR156h TGACAGAAGAGAGAGA 0.75 3265 GCAT (1440) vvi-miR156i TTGACAGAAGATAGAGA 0.85 3266 GCAC (1441) zel-miR156 TGACAGAAGAGAGAGA 0.8 3267 GCAC (1442) zma-miR156a TGACAGAAGAGAGTGA 0.75 3268 GCAC (1443) zma-miR156b TGACAGAAGAGAGTGA 0.75 3269 GCAC (1444) zma-miR156c TGACAGAAGAGAGTGA 0.75 3270 GCAC (1445) zma-miR156d TGACAGAAGAGAGTGA 0.75 3271 GCAC (1446) zma-miR156e TGACAGAAGAGAGTGA 0.75 3272 GCAC (1447) zma-miR156f TGACAGAAGAGAGTGA 0.75 3273 GCAC (1448) zma-miR156g TGACAGAAGAGAGTGA 0.75 3274 GCAC (1449) zma-miR156h TGACAGAAGAGAGTGA 0.75 3275 GCAC (1450) zma-miR156i TGACAGAAGAGAGTGA 0.75 3276 GCAC (1451) zma-miR156j TGACAGAAGAGAGAGA 0.85 3277 GCACA (1452) zma-miR156k TGACAGAAGAGAGCGA 0.75 3278 GCAC (1453) zma-miR156l TGACAGAAGAGAGTGA 0.75 3279 GCAC (1454) zma-miR156m TGACAGAAGAGAGTGA 0.75 3280 GCAC (1455) zma-miR156n TGACAGAAGAGAGTGA 0.75 3281 GCAC (1456) zma-miR156o TGACAGAAGAGAGTGA 0.75 3282 GCAC (1457) zma-miR156p TGACAGAAGAGAGAGA 0.8 3283 GCAC (1458) zma-miR156q TGACAGAAGAGAGAGA 0.8 3284 GCAC (1459) zma-miR156r TGACAGAAGAGAGTGG 0.7 3285 GCAC (1460) ptc- ahy-miR159 TTTGGATTGAAGGGAGC 0.95 3286 miRf10271- TCTA (1461) akr aly-miR159a TTTGGATTGAAGGGAGC 0.95 3287 TCTA (1462) aly-miR159b TTTGGATTGAAGGGAGC 0.9 3288 TCTT (1463) aqc-miR159 TTTGGACTGAAGGGAGC 0.9 3289 TCTA (1464) ath-miR159a TTTGGATTGAAGGGAGC 0.95 3290 TCTA (1465) ath-miR159b TTTGGATTGAAGGGAGC 0.9 3291 TCTT (1466) bdi-miR159 CTTGGATTGAAGGGAGC 0.9 3292 TCT (1467) bna-miR159 TTTGGATTGAAGGGAGC 0.95 3293 TCTA (1468) bra-miR159a TTTGGATTGAAGGGAGC 0.95 3294 TCTA (1469) csi-miR159 TTTGGATTGAAGGGAGC 0.95 3295 TCTA (1470) far-miR159 TTTGGATTGAAGGGAGC 0.9 3296 TCTG (1471) gma-miR159a-3p TTTGGATTGAAGGGAGC 0.95 3297 TCTA (1472) hvu-miR159a TTTGGATTGAAGGGAGC 0.9 3298 TCTG (1473) hvu-miR159b TTTGGATTGAAGGGAGC 0.9 3299 TCTG (1474) mtr-miR159a TTTGGATTGAAGGGAGC 0.95 3300 TCTA (1475) osa-miR159a.1 TTTGGATTGAAGGGAGC 0.9 3301 TCTG (1476) osa-miR159b TTTGGATTGAAGGGAGC 0.9 3302 TCTG (1477) osa-miR159c ATTGGATTGAAGGGAGC 0.9 3303 TCCA (1478) osa-miR159f CTTGGATTGAAGGGAGC 0.95 3304 TCTA (1479) pta-miR159a TTGGATTGAAGGGAGCT 0.9 3305 CCA (1480) ptc-miR159a TTTGGATTGAAGGGAGC 0.95 3306 TCTA (1481) ptc-miR159b TTTGGATTGAAGGGAGC 0.95 3307 TCTA (1482) ptc-miR159c TTTGGATTGAAGGGAGC 0.95 3308 TCTA (1483) pvu-miR159a.1 TTTGGATTGAAGGGAGC 0.95 3309 TCTA (1484) rco-miR159 TTTGGATTGAAGGGAGC 0.95 3310 TCTA (1485) sbi-miR159a TTTGGATTGAAGGGAGC 0.9 3311 TCTG (1486) sly-miR159 TTTGGATTGAAGGGAGC 0.95 3312 TCTA (1487) sof-miR159a TTTGGATTGAAGGGAGC 0.9 3313 TCTG (1488) sof-miR159b TTTGGATTGAAGGGAGC 0.9 3314 TCTG (1489) sof-miR159d TTTGGATTGAAGGGAGC 0.9 3315 TCTG (1490) ssp-miR159a TTTGGATTGAAGGGAGC 0.9 3316 TCTG (1491) tae-miR159a TTTGGATTGAAGGGAGC 0.9 3317 TCTG (1492) tae-miR159b TTTGGATTGAAGGGAGC 0.9 3318 TCTG (1493) vvi-miR159c TTTGGATTGAAGGGAGC 0.95 3319 TCTA (1494) zma-miR159a TTTGGATTGAAGGGAGC 0.9 3320 TCTG (1495) zma-miR159b TTTGGATTGAAGGGAGC 0.9 3321 TCTG (1496) zma-miR159f TTTGGATTGAAGGGAGC 0.9 3322 TCTG (1497) zma-miR159j TTTGGATTGAAGGGAGC 0.9 3323 TCTG (1498) zma-miR159k TTTGGATTGAAGGGAGC 0.9 3324 TCTG (1499) ptc- gma-miR156g ACAGAAGATAGAGAGC 0.9 3325 miRf10985- ACAG (1500) akr ath- ahy-miR156a TGACAGAAGAGAGAGA 0.9 3326 miR157a GCAC (1501) ahy-miR156b-5p TTGACAGAAGATAGAGA 1 3327 GCAC (1502) ahy-miR156c TTGACAGAAGAGAGAG 0.95 3328 AGCAC (1503) aly-miR156a TGACAGAAGAGAGTGA 0.86 3329 GCAC (1504) aly-miR156b TGACAGAAGAGAGTGA 0.86 3330 GCAC (1505) aly-miR156c TGACAGAAGAGAGTGA 0.86 3331 GCAC (1506) aly-miR156d TGACAGAAGAGAGTGA 0.86 3332 GCAC (1507) aly-miR156e TGACAGAAGAGAGTGA 0.86 3333 GCAC (1508) aly-miR156f TGACAGAAGAGAGTGA 0.86 3334 GCAC (1509) aly-miR156g CGACAGAAGAGAGTGA 0.81 3335 GCAC (1510) aly-miR156h TGACAGAAGAAAGAGA 0.9 3336 GCAC (1511) aqc-miR156a TGACAGAAGATAGAGA 0.95 3337 GCAC (1512) aqc-miR156b TGACAGAAGATAGAGA 0.95 3338 GCAC (1513) ath-miR156a TGACAGAAGAGAGTGA 0.86 3339 GCAC (1514) ath-miR156b TGACAGAAGAGAGTGA 0.86 3340 GCAC (1515) ath-miR156c TGACAGAAGAGAGTGA 0.86 3341 GCAC (1516) ath-miR156d TGACAGAAGAGAGTGA 0.86 3342 GCAC (1517) ath-miR156e TGACAGAAGAGAGTGA 0.86 3343 GCAC (1518) ath-miR156f TGACAGAAGAGAGTGA 0.86 3344 GCAC (1519) ath-miR156g CGACAGAAGAGAGTGA 0.81 3345 GCAC (1520) ath-miR156h TGACAGAAGAAAGAGA 0.9 3346 GCAC (1521) ath-miR156m TGACAGAAGAGAGAGA 0.9 3347 GCAC (1522) ath-miR156o TGACAGAAGAGAGAGA 0.9 3348 GCAC (1523) ath-miR156p TGACAGAAGAGAGAGA 0.9 3349 GCAC (1524) ath-miR156q TGACAGAAGAGAGAGA 0.9 3350 GCAC (1525) ath-miR156r TGACAGAAGAGAGAGA 0.9 3351 GCAC (1526) ath-miR156s TGACAGAAGAGAGAGA 0.9 3352 GCAC (1527) bdi-miR156 TGACAGAAGAGAGAGA 0.9 3353 GCACA (1528) bdi-miR156b TGACAGAAGAGAGTGA 0.86 3354 GCAC (1529) bdi-miR156c TGACAGAAGAGAGTGA 0.86 3355 GCAC (1530) bdi-miR156d TGACAGAAGAGAGTGA 0.86 3356 GCAC (1531) bna-miR156a TGACAGAAGAGAGTGA 0.86 3357 GCACA (1532) bna-miR156b TTGACAGAAGATAGAGA 1 3358 GCAC (1533) bna-miR156c TTGACAGAAGATAGAGA 1 3359 GCAC (1534) can-miR156a TGACAGAAGAGAGAGA 0.9 3360 GCAC (1535) can-miR156b TGACAGAAGAGAGGGA 0.86 3361 GCAC (1536) cpt-miR156a TGACAGAAGAGAGTGA 0.86 3362 GCAC (1537) cpt-miR156b TGACAGAAGAGAGAGA 0.9 3363 GCAC (1538) cru-miR156 TGACAGAAGAGAGAGA 0.9 3364 GCAC (1539) csi-miR156 TGACAGAAGAGAGTGA 0.86 3365 GCAC (1540) csi-miR156a TGACAGAAGAGAGAGA 0.9 3366 GCAC (1541) csi-miR156b TGACAGAAGAGAGAGA 0.9 3367 GCAC (1542) ctr-miR156 TGACAGAAGAGAGTGA 0.86 3368 GCAC (1543) eca-miR156 TGACAGAAGAGAGAGA 0.9 3369 GCAC (1544) far-miR156a TGACAGAAGAGAGAGA 0.9 3370 GCACA (1545) far-miR156b TTGACAGAAGAGAGAG 0.95 3371 AGCAC (1546) ghr-miR156a TGACAGAAGAGAGTGA 0.86 3372 GCAC (1547) ghr-miR156b TGACAGAAGAGAGTGA 0.86 3373 GCAC (1548) ghr-miR156c TGTCAGAAGAGAGTGAG 0.81 3374 CAC (1549) ghr-miR156d TGACAGAAGAGAGTGA 0.86 3375 GCAC (1550) gma-miR156a TGACAGAAGAGAGTGA 0.86 3376 GCAC (1551) gma-miR156b TGACAGAAGAGAGAGA 0.9 3377 GCACA (1552) gma-miR156c TTGACAGAAGATAGAGA 1 3378 GCAC (1553) gma-miR156d TTGACAGAAGATAGAGA 1 3379 GCAC (1554) gma-miR156e TTGACAGAAGATAGAGA 1 3380 GCAC (1555) gma-miR156f TTGACAGAAGAGAGAG 0.95 3381 AGCACA (1556) gma-miR156g ACAGAAGATAGAGAGC 0.86 3382 ACAG (1557) gma-miR156h TGACAGAAGAGAGAGA 0.9 3383 GCAC (1558) gma-miR156i TGACAGAAGAGAGAGA 0.9 3384 GCAC (1559) han-miR156 TGACAGAAGAGAGAGA 0.9 3385 GCAC (1560) hvs-miR156 TGACAGAAGAGAGAGA 0.9 3386 GCAC (1561) hvu-miR156 TGACAGAAGAGAGTGA 0.86 3387 GCACA (1562) hvv-miR156a TGACAGAAGAGAGTGA 0.86 3388 GCAC (1563) hvv-miR156b TGACAGAAGAGAGAGA 0.9 3389 GCAC (1564) hvv-miR156c TGACAGAAGAGAGAGA 0.9 3390 GCAC (1565) hvv-miR156d TGACAGAAGAGAGAGA 0.9 3391 GCAC (1566) lja-miR156 TGACAGAAGAGAGAGA 0.9 3392 GCAC (1567) lsa-miR156 TGACAGAAGAGAGAGA 0.9 3393 GCAC (1568) mdo-miR156a TGACAGAAGAGAGAGA 0.9 3394 GCAC (1569) mdo-miR156b TGACAGAAGAGAGAGA 0.9 3395 GCAC (1570) mtr-miR156 TGACAGAAGAGAGAGA 0.9 3396 GCACA (1571) mtr-miR156b TGACAGAAGAGAGTGA 0.86 3397 GCAC (1572) mtr-miR156c TGACAGAAGAGAGTGA 0.86 3398 GCAC (1573) mtr-miR156d TGACAGAAGAGAGTGA 0.86 3399 GCAC (1574) mtr-miR156e TTGACAGAAGATAGAGA 1 3400 GCAC (1575) mtr-miR156f TTGACAGAAGATAGAGA 1 3401 GCAC (1576) mtr-miR156g TTGACAGAAGATAGAGG 0.95 3402 GCAC (1577) mtr-miR156h TTGACAGAAGATAGAGA 1 3403 GCAC (1578) mtr-miR156i TGACAGAAGAGAGTGA 0.86 3404 GCAC (1579) nbe-miR156a TGACAGAAGAGAGAGA 0.9 3405 GCAC (1580) nbe-miR156b TGACAGAAGAGAGAGA 0.9 3406 GCAC (1581) oru-miR156 TGACAGAAGAGAGTGA 0.86 3407 GCAC (1582) osa-miR156a TGACAGAAGAGAGTGA 0.86 3408 GCAC (1583) osa-miR156b TGACAGAAGAGAGTGA 0.86 3409 GCAC (1584) osa-miR156c TGACAGAAGAGAGTGA 0.86 3410 GCAC (1585) osa-miR156d TGACAGAAGAGAGTGA 0.86 3411 GCAC (1586) osa-miR156e TGACAGAAGAGAGTGA 0.86 3412 GCAC (1587) osa-miR156f TGACAGAAGAGAGTGA 0.86 3413 GCAC (1588) osa-miR156g TGACAGAAGAGAGTGA 0.86 3414 GCAC (1589) osa-miR156h TGACAGAAGAGAGTGA 0.86 3415 GCAC (1590) osa-miR156i TGACAGAAGAGAGTGA 0.86 3416 GCAC (1591) osa-miR156j TGACAGAAGAGAGTGA 0.86 3417 GCAC (1592) osa-miR156k TGACAGAAGAGAGAGA 0.9 3418 GCACA (1593) osa-miR156l CGACAGAAGAGAGTGA 0.76 3419 GCATA (1594) osa-miR156m TGACAGAAGAGAGTGA 0.86 3420 GCAC (1595) osa-miR156n TGACAGAAGAGAGTGA 0.86 3421 GCAC (1596) osa-miR156o TGACAGAAGAGAGTGA 0.81 3422 GCAT (1597) osa-miR156p TGACAGAAGAGAGTGA 0.81 3423 GCTC (1598) osa-miR156q TGACAGAACAGAGTGA 0.81 3424 GCAC (1599) osa-miR156r TGACAGAAGAGAGAGA 0.9 3425 GCAC (1600) par-miR156 TGACAGAAGAGAGAGA 0.9 3426 GCAC (1601) pga-miR156a GATCCTAGAGCCCTTGA 0.38 3427 GCC (1602) ppd-miR156 TGACAGAAGAGAGAGA 0.9 3428 GCAC (1603) ppr-miR156 TGACAGAAGAGAGTGA 0.86 3429 GCAC (1604) ppt-miR156a TGACAGAAGAGAGTGA 0.86 3430 GCAC (1605) ppt-miR156b TGACAGAAGAGAGTGA 0.86 3431 GCAC (1606) ppt-miR156c TGACAGAAGAGAGTGA 0.86 3432 GCAC (1607) pta-miR156a CAGAAGATAGAGAGCA 0.81 3433 CATC (1608) pta-miR156b CAGAAGATAGAGAGCA 0.81 3434 CAAC (1609) ptc-miR156a TGACAGAAGAGAGTGA 0.86 3435 GCAC (1610) ptc-miR156b TGACAGAAGAGAGTGA 0.86 3436 GCAC (1611) ptc-miR156c TGACAGAAGAGAGTGA 0.86 3437 GCAC (1612) ptc-miR156d TGACAGAAGAGAGTGA 0.86 3438 GCAC (1613) ptc-miR156e TGACAGAAGAGAGTGA 0.86 3439 GCAC (1614) ptc-miR156f TGACAGAAGAGAGTGA 0.86 3440 GCAC (1615) ptc-miR156g TTGACAGAAGATAGAGA 1 3441 GCAC (1616) ptc-miR156h TTGACAGAAGATAGAGA 1 3442 GCAC (1617) ptc-miR156i TTGACAGAAGATAGAGA 1 3443 GCAC (1618) ptc-miR156j TTGACAGAAGATAGAGA 1 3444 GCAC (1619) ptc-miR156k TGACAGAAGAGAGGGA 0.86 3445 GCAC (1620) ptr-miR156 TGACAGAAGAGAGAGA 0.9 3446 GCAC (1621) pts-miR156a TGACAGAAGAGAGTGA 0.81 3447 GCGC (1622) pts-miR156b TGACAGAAGAGAGAGA 0.9 3448 GCAC (1623) pts-miR156c TGACAGAAGAGAGAGA 0.9 3449 GCAC (1624) rco-miR156a TGACAGAAGAGAGTGA 0.86 3450 GCACA (1625) rco-miR156b TGACAGAAGAGAGTGA 0.86 3451 GCACA (1626) rco-miR156c TGACAGAAGAGAGTGA 0.86 3452 GCACA (1627) rco-miR156d TGACAGAAGAGAGTGA 0.86 3453 GCACA (1628) rco-miR156e TGACAGAAGAGAGAGA 0.9 3454 GCACA (1629) rco-miR156f TTGACAGAAGATAGAGA 1 3455 GCAC (1630) rco-miR156g TTGACAGAAGATAGAGA 1 3456 GCAC (1631) rco-miR156h TTGACAGAAGATAGAGA 1 3457 GCAC (1632) sbi-miR156a TGACAGAAGAGAGTGA 0.86 3458 GCAC (1633) sbi-miR156b TGACAGAAGAGAGTGA 0.86 3459 GCAC (1634) sbi-miR156c TGACAGAAGAGAGTGA 0.86 3460 GCAC (1635) sbi-miR156d TGACAGAAGAGAGAGA 0.9 3461 GCACA (1636) sbi-miR156e TGACAGAAGAGAGCGA 0.86 3462 GCAC (1637) sbi-miR156f TGACAGAAGAGAGTGA 0.86 3463 GCAC (1638) sbi-miR156g TGACAGAAGAGAGTGA 0.86 3464 GCAC (1639) sbi-miR156h TGACAGAAGAGAGTGA 0.86 3465 GCAC (1640) sbi-miR156i TGACAGAAGAGAGTGA 0.86 3466 GCAC (1641) sin-miR156 TGACAGAAGAGAGAGA 0.9 3467 GCAC (1642) sly-miR156a TTGACAGAAGATAGAGA 1 3468 GCAC (1643) sly-miR156b TTGACAGAAGATAGAGA 1 3469 GCAC (1644) sly-miR156c TTGACAGAAGATAGAGA 1 3470 GCAC (1645) smo-miR156a CGACAGAAGAGAGTGA 0.81 3471 GCAC (1646) smo-miR156b CTGACAGAAGATAGAG 0.95 3472 AGCAC (1647) smo-miR156c TTGACAGAAGAAAGAG 0.95 3473 AGCAC (1648) smo-miR156d TTGACAGAAGACAGGG 0.9 3474 AGCAC (1649) sof-miR156 TGACAGAAGAGAGTGA 0.86 3475 GCAC (1650) sof-miR156c TGACAGAAGAGAGAGA 0.9 3476 GCAC (1651) sof-miR156d TGACAGAAGAGAGAGA 0.9 3477 GCAC (1652) sof-miR156e TGACAGAAGAGAGAGA 0.9 3478 GCAC (1653) sof-miR156f TGACAGAAGAGAGAGA 0.9 3479 GCAC (1654) sof-miR156g TGACAGAAGAGAGAGA 0.9 3480 GCAC (1655) sof-miR156h TGACAGAAGAGAGAGA 0.9 3481 GCAC (1656) sof-miR156u TGACAGAAGAGAGAGA 0.9 3482 GCAC (1657) spr-miR156 TGACAGAAGAGAGAGA 0.9 3483 GCAC (1658) ssp-miR156 TGACAGAAGAGAGTGA 0.86 3484 GCACA (1659) stu-miR156a TGACAGAAGAGAGTGA 0.86 3485 GCAC (1660) stu-miR156b TGACAGAAGAGAGAGA 0.9 3486 GCAC (1661) stu-miR156c TGACAGAAGAGAGAGA 0.9 3487 GCAC (1662) stu-miR156d TGACAGAAGAGAGAGA 0.9 3488 GCAC (1663) stu-miR156e TGACAGAAGAGAGAGA 0.9 3489 GCAC (1664) tae-miR156 TGACAGAAGAGAGTGA 0.86 3490 GCACA (1665) tae-miR156a TGACAGAAGAGAGAGA 0.9 3491 GCAC (1666) tae-miR156b TGACAGAAGAGAGAGA 0.9 3492 GCAC (1667) tcc-miR156a TGACAGAAGAGAGAGA 0.9 3493 GCACA (1668) tcc-miR156b TGACAGAAGAGAGTGA 0.86 3494 GCAC (1669) tcc-miR156c TGACAGAAGAGAGTGA 0.86 3495 GCAC (1670) tcc-miR156d TGACAGAAGAGAGTGA 0.86 3496 GCAC (1671) tcc-miR156e TTGACAGAAGATAGAGA 1 3497 GCAC (1672) tcc-miR156f TTGACAGAAGATAGAGA 1 3498 GCAC (1673) tcc-miR156g TGACAGAAGAGAGTGA 0.86 3499 GCAC (1674) tre-miR156 TGACAGAAGAGAGTGA 0.86 3500 GCAC (1675) vvi-miR156a TGACAGAAGAGAGGGA 0.86 3501 GCAC (1676) vvi-miR156b TGACAGAAGAGAGTGA 0.86 3502 GCAC (1677) vvi-miR156c TGACAGAAGAGAGTGA 0.86 3503 GCAC (1678) vvi-miR156d TGACAGAAGAGAGTGA 0.86 3504 GCAC (1679) vvi-miR156e TGACAGAGGAGAGTGA 0.81 3505 GCAC (1680) vvi-miR156f TTGACAGAAGATAGAGA 1 3506 GCAC (1681) vvi-miR156g TTGACAGAAGATAGAGA 1 3507 GCAC (1682) vvi-miR156h TGACAGAAGAGAGAGA 0.86 3508 GCAT (1683) vvi-miR156i TTGACAGAAGATAGAGA 1 3509 GCAC (1684) zel-miR156 TGACAGAAGAGAGAGA 0.9 3510 GCAC (1685) zma-miR156a TGACAGAAGAGAGTGA 0.86 3511 GCAC (1686) zma-miR156b TGACAGAAGAGAGTGA 0.86 3512 GCAC (1687) zma-miR156c TGACAGAAGAGAGTGA 0.86 3513 GCAC (1688) zma-miR156d TGACAGAAGAGAGTGA 0.86 3514 GCAC (1689) zma-miR156e TGACAGAAGAGAGTGA 0.86 3515 GCAC (1690) zma-miR156f TGACAGAAGAGAGTGA 0.86 3516 GCAC (1691) zma-miR156g TGACAGAAGAGAGTGA 0.86 3517 GCAC (1692) zma-miR156h TGACAGAAGAGAGTGA 0.86 3518 GCAC (1693) zma-miR156i TGACAGAAGAGAGTGA 0.86 3519 GCAC (1694) zma-miR156j TGACAGAAGAGAGAGA 0.9 3520 GCACA (1695) zma-miR156k TGACAGAAGAGAGCGA 0.86 3521 GCAC (1696) zma-miR156l TGACAGAAGAGAGTGA 0.86 3522 GCAC (1697) zma-miR156m TGACAGAAGAGAGTGA 0.86 3523 GCAC (1698) zma-miR156n TGACAGAAGAGAGTGA 0.86 3524 GCAC (1699) zma-miR156o TGACAGAAGAGAGTGA 0.86 3525 GCAC (1700) zma-miR156p TGACAGAAGAGAGAGA 0.9 3526 GCAC (1701) zma-miR156q TGACAGAAGAGAGAGA 0.9 3527 GCAC (1702) zma-miR156r TGACAGAAGAGAGTGG 0.81 3528 GCAC (1703) smo- ahy-miR156a TGACAGAAGAGAGAGA 0.9 3529 miR156b GCAC (1704) ahy-miR156b-5p TTGACAGAAGATAGAGA 0.95 3530 GCAC (1705) ahy-miR156c TTGACAGAAGAGAGAG 0.9 3531 AGCAC (1706) aly-miR156a TGACAGAAGAGAGTGA 0.86 3532 GCAC (1707) aly-miR156b TGACAGAAGAGAGTGA 0.86 3533 GCAC (1708) aly-miR156c TGACAGAAGAGAGTGA 0.86 3534 GCAC (1709) aly-miR156d TGACAGAAGAGAGTGA 0.86 3535 GCAC (1710) aly-miR156e TGACAGAAGAGAGTGA 0.86 3536 GCAC (1711) aly-miR156f TGACAGAAGAGAGTGA 0.86 3537 GCAC (1712) aly-miR156g CGACAGAAGAGAGTGA 0.81 3538 GCAC (1713) aly-miR156h TGACAGAAGAAAGAGA 0.9 3539 GCAC (1714) aqc-miR156a TGACAGAAGATAGAGA 0.95 3540 GCAC (1715) aqc-miR156b TGACAGAAGATAGAGA 0.95 3541 GCAC (1716) ath-miR156a TGACAGAAGAGAGTGA 0.86 3542 GCAC (1717) ath-miR156b TGACAGAAGAGAGTGA 0.86 3543 GCAC (1718) ath-miR156c TGACAGAAGAGAGTGA 0.86 3544 GCAC (1719) ath-miR156d TGACAGAAGAGAGTGA 0.86 3545 GCAC (1720) ath-miR156e TGACAGAAGAGAGTGA 0.86 3546 GCAC (1721) ath-miR156f TGACAGAAGAGAGTGA 0.86 3547 GCAC (1722) ath-miR156g CGACAGAAGAGAGTGA 0.81 3548 GCAC (1723) ath-miR156h TGACAGAAGAAAGAGA 0.9 3549 GCAC (1724) ath-miR156m TGACAGAAGAGAGAGA 0.9 3550 GCAC (1725) ath-miR156o TGACAGAAGAGAGAGA 0.9 3551 GCAC (1726) ath-miR156p TGACAGAAGAGAGAGA 0.9 3552 GCAC (1727) ath-miR156q TGACAGAAGAGAGAGA 0.9 3553 GCAC (1728) ath-miR156r TGACAGAAGAGAGAGA 0.9 3554 GCAC (1729) ath-miR156s TGACAGAAGAGAGAGA 0.9 3555 GCAC (1730) bdi-miR156 TGACAGAAGAGAGAGA 0.9 3556 GCACA (1731) bdi-miR156b TGACAGAAGAGAGTGA 0.86 3557 GCAC (1732) bdi-miR156c TGACAGAAGAGAGTGA 0.86 3558 GCAC (1733) bdi-miR156d TGACAGAAGAGAGTGA 0.86 3559 GCAC (1734) bna-miR156a TGACAGAAGAGAGTGA 0.86 3560 GCACA (1735) bna-miR156b TTGACAGAAGATAGAGA 0.95 3561 GCAC (1736) bna-miR156c TTGACAGAAGATAGAGA 0.95 3562 GCAC (1737) can-miR156a TGACAGAAGAGAGAGA 0.9 3563 GCAC (1738) can-miR156b TGACAGAAGAGAGGGA 0.86 3564 GCAC (1739) cpt-miR156a TGACAGAAGAGAGTGA 0.86 3565 GCAC (1740) cpt-miR156b TGACAGAAGAGAGAGA 0.9 3566 GCAC (1741) cru-miR156 TGACAGAAGAGAGAGA 0.9 3567 GCAC (1742) csi-miR156 TGACAGAAGAGAGTGA 0.86 3568 GCAC (1743) csi-miR156a TGACAGAAGAGAGAGA 0.9 3569 GCAC (1744) csi-miR156b TGACAGAAGAGAGAGA 0.9 3570 GCAC (1745) ctr-miR156 TGACAGAAGAGAGTGA 0.86 3571 GCAC (1746) eca-miR156 TGACAGAAGAGAGAGA 0.9 3572 GCAC (1747) far-miR156a TGACAGAAGAGAGAGA 0.9 3573 GCACA (1748) far-miR156b TTGACAGAAGAGAGAG 0.9 3574 AGCAC (1749) ghr-miR156a TGACAGAAGAGAGTGA 0.86 3575 GCAC (1750) ghr-miR156b TGACAGAAGAGAGTGA 0.86 3576 GCAC (1751) ghr-miR156c TGTCAGAAGAGAGTGAG 0.81 3577 CAC (1752) ghr-miR156d TGACAGAAGAGAGTGA 0.86 3578 GCAC (1753) gma-miR156a TGACAGAAGAGAGTGA 0.86 3579 GCAC (1754) gma-miR156b TGACAGAAGAGAGAGA 0.9 3580 GCACA (1755) gma-miR156c TTGACAGAAGATAGAGA 0.95 3581 GCAC (1756) gma-miR156d TTGACAGAAGATAGAGA 0.95 3582 GCAC (1757) gma-miR156e TTGACAGAAGATAGAGA 0.95 3583 GCAC (1758) gma-miR156f TTGACAGAAGAGAGAG 0.9 3584 AGCACA (1759) gma-miR156g ACAGAAGATAGAGAGC 0.86 3585 ACAG (1760) gma-miR156h TGACAGAAGAGAGAGA 0.9 3586 GCAC (1761) gma-miR156i TGACAGAAGAGAGAGA 0.9 3587 GCAC (1762) han-miR156 TGACAGAAGAGAGAGA 0.9 3588 GCAC (1763) hvs-miR156 TGACAGAAGAGAGAGA 0.9 3589 GCAC (1764) hvu-miR156 TGACAGAAGAGAGTGA 0.86 3590 GCACA (1765) hvv-miR156a TGACAGAAGAGAGTGA 0.86 3591 GCAC (1766) hvv-miR156b TGACAGAAGAGAGAGA 0.9 3592 GCAC (1767) hvv-miR156c TGACAGAAGAGAGAGA 0.9 3593 GCAC (1768) hvv-miR156d TGACAGAAGAGAGAGA 0.9 3594 GCAC (1769) lja-miR156 TGACAGAAGAGAGAGA 0.9 3595 GCAC (1770) lsa-miR156 TGACAGAAGAGAGAGA 0.9 3596 GCAC (1771) mdo-miR156a TGACAGAAGAGAGAGA 0.9 3597 GCAC (1772) mdo-miR156b TGACAGAAGAGAGAGA 0.9 3598 GCAC (1773) mtr-miR156 TGACAGAAGAGAGAGA 0.9 3599 GCACA (1774) mtr-miR156b TGACAGAAGAGAGTGA 0.86 3600 GCAC (1775) mtr-miR156c TGACAGAAGAGAGTGA 0.86 3601 GCAC (1776) mtr-miR156d TGACAGAAGAGAGTGA 0.86 3602 GCAC (1777) mtr-miR156e TTGACAGAAGATAGAGA 0.95 3603 GCAC (1778) mtr-miR156f TTGACAGAAGATAGAGA 0.95 3604 GCAC (1779) mtr-miR156g TTGACAGAAGATAGAGG 0.9 3605 GCAC (1780) mtr-miR156h TTGACAGAAGATAGAGA 0.95 3606 GCAC (1781) mtr-miR156i TGACAGAAGAGAGTGA 0.86 3607 GCAC (1782) nbe-miR156a TGACAGAAGAGAGAGA 0.9 3608 GCAC (1783) nbe-miR156b TGACAGAAGAGAGAGA 0.9 3609 GCAC (1784) oru-miR156 TGACAGAAGAGAGTGA 0.86 3610 GCAC (1785) osa-miR156a TGACAGAAGAGAGTGA 0.86 3611 GCAC (1786) osa-miR156b TGACAGAAGAGAGTGA 0.86 3612 GCAC (1787) osa-miR156c TGACAGAAGAGAGTGA 0.86 3613 GCAC (1788) osa-miR156d TGACAGAAGAGAGTGA 0.86 3614 GCAC (1789) osa-miR156e TGACAGAAGAGAGTGA 0.86 3615 GCAC (1790) osa-miR156f TGACAGAAGAGAGTGA 0.86 3616 GCAC (1791) osa-miR156g TGACAGAAGAGAGTGA 0.86 3617 GCAC (1792) osa-miR156h TGACAGAAGAGAGTGA 0.86 3618 GCAC (1793) osa-miR156i TGACAGAAGAGAGTGA 0.86 3619 GCAC (1794) osa-miR156j TGACAGAAGAGAGTGA 0.86 3620 GCAC (1795) osa-miR156k TGACAGAAGAGAGAGA 0.9 3621 GCACA (1796) osa-miR156l CGACAGAAGAGAGTGA 0.76 3622 GCATA (1797) osa-miR156m TGACAGAAGAGAGTGA 0.86 3623 GCAC (1798) osa-miR156n TGACAGAAGAGAGTGA 0.86 3624 GCAC (1799) osa-miR156o TGACAGAAGAGAGTGA 0.81 3625 GCAT (1800) osa-miR156p TGACAGAAGAGAGTGA 0.81 3626 GCTC (1801) osa-miR156q TGACAGAACAGAGTGA 0.81 3627 GCAC (1802) osa-miR156r TGACAGAAGAGAGAGA 0.9 3628 GCAC (1803) par-miR156 TGACAGAAGAGAGAGA 0.9 3629 GCAC (1804) ppd-miR156 TGACAGAAGAGAGAGA 0.9 3630 GCAC (1805) ppr-miR156 TGACAGAAGAGAGTGA 0.86 3631 GCAC (1806) ppt-miR156a TGACAGAAGAGAGTGA 0.86 3632 GCAC (1807) ppt-miR156b TGACAGAAGAGAGTGA 0.86 3633 GCAC (1808) ppt-miR156c TGACAGAAGAGAGTGA 0.86 3634 GCAC (1809) pta-miR156a CAGAAGATAGAGAGCA 0.81 3635 CATC (1810) pta-miR156b CAGAAGATAGAGAGCA 0.81 3636 CAAC (1811) ptc-miR156a TGACAGAAGAGAGTGA 0.86 3637 GCAC (1812) ptc-miR156b TGACAGAAGAGAGTGA 0.86 3638 GCAC (1813) ptc-miR156c TGACAGAAGAGAGTGA 0.86 3639 GCAC (1814) ptc-miR156d TGACAGAAGAGAGTGA 0.86 3640 GCAC (1815) ptc-miR156e TGACAGAAGAGAGTGA 0.86 3641 GCAC (1816) ptc-miR156f TGACAGAAGAGAGTGA 0.86 3642 GCAC (1817) ptc-miR156g TTGACAGAAGATAGAGA 0.95 3643 GCAC (1818) ptc-miR156h TTGACAGAAGATAGAGA 0.95 3644 GCAC (1819) ptc-miR156i TTGACAGAAGATAGAGA 0.95 3645 GCAC (1820) ptc-miR156j TTGACAGAAGATAGAGA 0.95 3646 GCAC (1821) ptc-miR156k TGACAGAAGAGAGGGA 0.86 3647 GCAC (1822) ptr-miR156 TGACAGAAGAGAGAGA 0.9 3648 GCAC (1823) pts-miR156a TGACAGAAGAGAGTGA 0.81 3649 GCGC (1824) pts-miR156b TGACAGAAGAGAGAGA 0.9 3650 GCAC (1825) pts-miR156c TGACAGAAGAGAGAGA 0.9 3651 GCAC (1826) rco-miR156a TGACAGAAGAGAGTGA 0.86 3652 GCACA (1827) rco-miR156b TGACAGAAGAGAGTGA 0.86 3653 GCACA (1828) rco-miR156c TGACAGAAGAGAGTGA 0.86 3654 GCACA (1829) rco-miR156d TGACAGAAGAGAGTGA 0.86 3655 GCACA (1830) rco-miR156e TGACAGAAGAGAGAGA 0.9 3656 GCACA (1831) rco-miR156f TTGACAGAAGATAGAGA 0.95 3657 GCAC (1832) rco-miR156g TTGACAGAAGATAGAGA 0.95 3658 GCAC (1833) rco-miR156h TTGACAGAAGATAGAGA 0.95 3659 GCAC (1834) sbi-miR156a TGACAGAAGAGAGTGA 0.86 3660 GCAC (1835) sbi-miR156b TGACAGAAGAGAGTGA 0.86 3661 GCAC (1836) sbi-miR156c TGACAGAAGAGAGTGA 0.86 3662 GCAC (1837) sbi-miR156d TGACAGAAGAGAGAGA 0.9 3663 GCACA (1838) sbi-miR156e TGACAGAAGAGAGCGA 0.86 3664 GCAC (1839) sbi-miR156f TGACAGAAGAGAGTGA 0.86 3665 GCAC (1840) sbi-miR156g TGACAGAAGAGAGTGA 0.86 3666 GCAC (1841) sbi-miR156h TGACAGAAGAGAGTGA 0.86 3667 GCAC (1842) sbi-miR156i TGACAGAAGAGAGTGA 0.86 3668 GCAC (1843) sin-miR156 TGACAGAAGAGAGAGA 0.9 3669 GCAC (1844) sly-miR156a TTGACAGAAGATAGAGA 0.95 3670 GCAC (1845) sly-miR156b TTGACAGAAGATAGAGA 0.95 3671 GCAC (1846) sly-miR156c TTGACAGAAGATAGAGA 0.95 3672 GCAC (1847) smo-miR156a CGACAGAAGAGAGTGA 0.81 3673 GCAC (1848) smo-miR156c TTGACAGAAGAAAGAG 0.9 3674 AGCAC (1849) smo-miR156d TTGACAGAAGACAGGG 0.86 3675 AGCAC (1850) sof-miR156 TGACAGAAGAGAGTGA 0.86 3676 GCAC (1851) sof-miR156c TGACAGAAGAGAGAGA 0.9 3677 GCAC (1852) sof-miR156d TGACAGAAGAGAGAGA 0.9 3678 GCAC (1853) sof-miR156e TGACAGAAGAGAGAGA 0.9 3679 GCAC (1854) sof-miR156f TGACAGAAGAGAGAGA 0.9 3680 GCAC (1855) sof-miR156g TGACAGAAGAGAGAGA 0.9 3681 GCAC (1856) sof-miR156h TGACAGAAGAGAGAGA 0.9 3682 GCAC (1857) sof-miR156u TGACAGAAGAGAGAGA 0.9 3683 GCAC (1858) spr-miR156 TGACAGAAGAGAGAGA 0.9 3684 GCAC (1859) ssp-miR156 TGACAGAAGAGAGTGA 0.86 3685 GCACA (1860) stu-miR156a TGACAGAAGAGAGTGA 0.86 3686 GCAC (1861) stu-miR156b TGACAGAAGAGAGAGA 0.9 3687 GCAC (1862) stu-miR156c TGACAGAAGAGAGAGA 0.9 3688 GCAC (1863) stu-miR156d TGACAGAAGAGAGAGA 0.9 3689 GCAC (1864) stu-miR156e TGACAGAAGAGAGAGA 0.9 3690 GCAC (1865) tae-miR156 TGACAGAAGAGAGTGA 0.86 3691 GCACA (1866) tae-miR156a TGACAGAAGAGAGAGA 0.9 3692 GCAC (1867) tae-miR156b TGACAGAAGAGAGAGA 0.9 3693 GCAC (1868) tcc-miR156a TGACAGAAGAGAGAGA 0.9 3694 GCACA (1869) tcc-miR156b TGACAGAAGAGAGTGA 0.86 3695 GCAC (1870) tcc-miR156c TGACAGAAGAGAGTGA 0.86 3696 GCAC (1871) tcc-miR156d TGACAGAAGAGAGTGA 0.86 3697 GCAC (1872) tcc-miR156e TTGACAGAAGATAGAGA 0.95 3698 GCAC (1873) tcc-miR156f TTGACAGAAGATAGAGA 0.95 3699 GCAC (1874) tcc-miR156g TGACAGAAGAGAGTGA 0.86 3700 GCAC (1875) tre-miR156 TGACAGAAGAGAGTGA 0.86 3701 GCAC (1876) vvi-miR156a TGACAGAAGAGAGGGA 0.86 3702 GCAC (1877) vvi-miR156b TGACAGAAGAGAGTGA 0.86 3703 GCAC (1878) vvi-miR156c TGACAGAAGAGAGTGA 0.86 3704 GCAC (1879) vvi-miR156d TGACAGAAGAGAGTGA 0.86 3705 GCAC (1880) vvi-miR156e TGACAGAGGAGAGTGA 0.81 3706 GCAC (1881) vvi-miR156f TTGACAGAAGATAGAGA 0.95 3707 GCAC (1882) vvi-miR156g TTGACAGAAGATAGAGA 0.95 3708 GCAC (1883) vvi-miR156h TGACAGAAGAGAGAGA 0.86 3709 GCAT (1884) vvi-miR156i TTGACAGAAGATAGAGA 0.95 3710 GCAC (1885) zel-miR156 TGACAGAAGAGAGAGA 0.9 3711 GCAC (1886) zma-miR156a TGACAGAAGAGAGTGA 0.86 3712 GCAC (1887) zma-miR156b TGACAGAAGAGAGTGA 0.86 3713 GCAC (1888) zma-miR156c TGACAGAAGAGAGTGA 0.86 3714 GCAC (1889) zma-miR156d TGACAGAAGAGAGTGA 0.86 3715 GCAC (1890) zma-miR156e TGACAGAAGAGAGTGA 0.86 3716 GCAC (1891) zma-miR156f TGACAGAAGAGAGTGA 0.86 3717 GCAC (1892) zma-miR156g TGACAGAAGAGAGTGA 0.86 3718 GCAC (1893) zma-miR156h TGACAGAAGAGAGTGA 0.86 3719 GCAC (1894) zma-miR156i TGACAGAAGAGAGTGA 0.86 3720 GCAC (1895) zma-miR156j TGACAGAAGAGAGAGA 0.9 3721 GCACA (1896) zma-miR156k TGACAGAAGAGAGCGA 0.86 3722 GCAC (1897) zma-miR156l TGACAGAAGAGAGTGA 0.86 3723 GCAC (1898) zma-miR156m TGACAGAAGAGAGTGA 0.86 3724 GCAC (1899) zma-miR156n TGACAGAAGAGAGTGA 0.86 3725 GCAC (1900) zma-miR156o TGACAGAAGAGAGTGA 0.86 3726 GCAC (1901) zma-miR156p TGACAGAAGAGAGAGA 0.9 3727 GCAC (1902) zma-miR156q TGACAGAAGAGAGAGA 0.9 3728 GCAC (1903) zma-miR156r TGACAGAAGAGAGTGG 0.81 3729 GCAC (1904) gma- acb-miR159 TTGGACTGAAGGGAGCT 0.81 3730 miR159a- CCCT (1905) 3p aha-miR159 TTGGACTGAAGGGAGCT 0.81 3731 CCCT (1906) ahi-miR159 TTGGACTGAAGGGAGCT 0.81 3732 CCCT (1907) ahy-miR159 TTTGGATTGAAGGGAGC 1 3733 TCTA (1908) aly-miR159a TTTGGATTGAAGGGAGC 1 3734 TCTA (1909) aly-miR159b TTTGGATTGAAGGGAGC 0.95 3735 TCTT (1910) aly-miR159c TTTGGATTGAAGGGAGC 0.9 3736 TCCT (1911) ape-miR159 TTGGACTGAAGGGAGCT 0.81 3737 CCCT (1912) aqc-miR159 TTTGGACTGAAGGGAGC 0.95 3738 TCTA (1913) ath-miR159a TTTGGATTGAAGGGAGC 1 3739 TCTA (1914) ath-miR159b TTTGGATTGAAGGGAGC 0.95 3740 TCTT (1915) ath-miR159c TTTGGATTGAAGGGAGC 0.9 3741 TCCT (1916) bdi-miR159 CTTGGATTGAAGGGAGC 0.9 3742 TCT (1917) bna-miR159 TTTGGATTGAAGGGAGC 1 3743 TCTA (1918) bra-miR159a TTTGGATTGAAGGGAGC 1 3744 TCTA (1919) bvl-miR159 TTGGACTGAAGGGAGCT 0.81 3745 CCCT (1920) cmi-miR159 TTGGACTGAAGGGAGCT 0.81 3746 CCCT (1921) cor-miR159 TTGGACTGAAGGGAGCT 0.81 3747 CCCT (1922) crb-miR159 TTGGACTGAAGGGAGCT 0.81 3748 CCCT (1923) csi-miR159 TTTGGATTGAAGGGAGC 1 3749 TCTA (1924) dso-miR159 TTGGACTGAAGGGAGCT 0.81 3750 CCCT (1925) ech-miR159 TTGGACTGAAGGGAGCT 0.81 3751 CCCT (1926) fal-miR159 TTGGACTGAAGGGAGCT 0.81 3752 CCCT (1927) far-miR159 TTTGGATTGAAGGGAGC 0.95 3753 TCTG (1928) gma-miR159b ATTGGAGTGAAGGGAGC 0.86 3754 TCCA (1929) gma-miR159c ATTGGAGTGAAGGGAGC 0.81 3755 TCCG (1930) hvu-miR159a TTTGGATTGAAGGGAGC 0.95 3756 TCTG (1931) hvu-miR159b TTTGGATTGAAGGGAGC 0.95 3757 TCTG (1932) hvv-miR159a TTTGGATTGAAGGGAGC 0.95 3758 TCTG (1933) hvv-miR159b TTTGGATTGAAGGGAGC 0.95 3759 TCTG (1934) ltu-miR159 TTTGGATTGAAGGGAGC 1 3760 TCTA (1935) mma-miR159 TTGGACTGAAGGGAGCT 0.81 3761 CCCT (1936) mtr-miR159a TTTGGATTGAAGGGAGC 1 3762 TCTA (1937) mtr-miR159b ATTGAATTGAAGGGAGC 0.71 3763 AACT (1938) mtr-miR159c TTTGGATTGAAGGGAGC 1 3764 TCTA (1939) nof-miR159 TTGGACTGAAGGGAGCT 0.81 3765 CCCT (1940) oru-miR159 TTTGGATTGAAGGGAGC 0.95 3766 TCTG (1941) osa-miR159a TTTGGATTGAAGGGAGC 0.95 3767 TCTG (1942) osa-miR159a.1 TTTGGATTGAAGGGAGC 0.95 3768 TCTG (1943) osa-miR159b TTTGGATTGAAGGGAGC 0.95 3769 TCTG (1944) osa-miR159c ATTGGATTGAAGGGAGC 0.9 3770 TCCA (1945) osa-miR159d ATTGGATTGAAGGGAGC 0.86 3771 TCCG (1946) osa-miR159e ATTGGATTGAAGGGAGC 0.86 3772 TCCT (1947) osa-miR159f CTTGGATTGAAGGGAGC 0.95 3773 TCTA (1948) osa-miR159m TTTGGATTGAAGGGAGC 0.95 3774 TCTG (1949) pgl-miR159 TTTGGATTGAAGGGAGC 0.95 3775 TCTG (1950) psi-miR159 CTTGGATTGAAGGGAGC 0.9 3776 TCCA (1951) pta-miR159a TTGGATTGAAGGGAGCT 0.9 3777 CCA (1952) pta-miR159b TTGGATTGAAGAGAGCT 0.81 3778 CCC (1953) pta-miR159c CTTGGATTGAAGGGAGC 0.86 3779 TCCC (1954) ptc-miR159a TTTGGATTGAAGGGAGC 1 3780 TCTA (1955) ptc-miR159b TTTGGATTGAAGGGAGC 1 3781 TCTA (1956) ptc-miR159c TTTGGATTGAAGGGAGC 1 3782 TCTA (1957) ptc-miR159d CTTGGATTGAAGGGAGC 0.86 3783 TCCT (1958) ptc-miR159e CTTGGGGTGAAGGGAGC 0.76 3784 TCCT (1959) ptc-miR159f ATTGGAGTGAAGGGAGC 0.86 3785 TCGA (1960) pvu-miR159 TTTGGATTGAAGGGAGC 1 3786 TCTA (1961) pvu-miR159a.1 TTTGGATTGAAGGGAGC 1 3787 TCTA (1962) rco-miR159 TTTGGATTGAAGGGAGC 1 3788 TCTA (1963) rin-miR159 TTGGACTGAAGGGAGCT 0.81 3789 CCCT (1964) sar-miR159 TTTGGATTGAAGGGAGC 0.95 3790 TCTG (1965) sbi-miR159a TTTGGATTGAAGGGAGC 0.95 3791 TCTG (1966) sbi-miR159b CTTGGATTGAAGGGAGC 0.86 3792 TCCT (1967) sly-miR159 TTTGGATTGAAGGGAGC 1 3793 TCTA (1968) smo-miR159 CTTGGATTGAAGGGAGC 0.86 3794 TCCC (1969) sof-miR159a TTTGGATTGAAGGGAGC 0.95 3795 TCTG (1970) sof-miR159b TTTGGATTGAAGGGAGC 0.95 3796 TCTG (1971) sof-miR159c CTTGGATTGAAGGGAGC 0.86 3797 TCCT (1972) sof-miR159d TTTGGATTGAAGGGAGC 0.95 3798 TCTG (1973) sof-miR159e TTTGGATTGAAAGGAGC 0.9 3799 TCTT (1974) spr-miR159 TTTGGATTGAAGGGAGC 0.95 3800 TCTG (1975) ssp-miR159a TTTGGATTGAAGGGAGC 0.95 3801 TCTG (1976) svi-miR159 TTGGACTGAAGGGAGCT 0.81 3802 CCCT (1977) tae-miR159a TTTGGATTGAAGGGAGC 0.95 3803 TCTG (1978) tae-miR159b TTTGGATTGAAGGGAGC 0.95 3804 TCTG (1979) tar-miR159 TTGGACTGAAGGGAGCT 0.81 3805 CCCT (1980) vvi-miR159a CTTGGAGTGAAGGGAGC 0.86 3806 TCTC (1981) vvi-miR159b CTTGGAGTGAAGGGAGC 0.86 3807 TCTC (1982) vvi-miR159c TTTGGATTGAAGGGAGC 1 3808 TCTA (1983) zma-miR159a TTTGGATTGAAGGGAGC 0.95 3809 TCTG (1984) zma-miR159b TTTGGATTGAAGGGAGC 0.95 3810 TCTG (1985) zma-miR159c CTTGGATTGAAGGGAGC 0.86 3811 TCCT (1986) zma-miR159d CTTGGATTGAAGGGAGC 0.86 3812 TCCT (1987) zma-miR159e ATTGGTTTGAAGGGAGC 0.86 3813 TCCA (1988) zma-miR159f TTTGGATTGAAGGGAGC 0.95 3814 TCTG (1989) zma-miR159g TTTGGAGTGAAGGGAGT 0.86 3815 TCTG (1990) zma-miR159h TTTGGAGTGAAGGGAGC 0.9 3816 TCTG (1991) zma-miR159i TTTGGAGTGAAGGGAGC 0.9 3817 TCTG (1992) zma-miR159j TTTGGATTGAAGGGAGC 0.95 3818 TCTG (1993) zma-miR159k TTTGGATTGAAGGGAGC 0.95 3819 TCTG (1994) zma-miR159m TTTGGATTGAAGGGAGC 0.95 3820 TCTG (1995) sbi- acb-miR159 TTGGACTGAAGGGAGCT 0.81 3821 miR159a CCCT (1996) aha-miR159 TTGGACTGAAGGGAGCT 0.81 3822 CCCT (1997) ahi-miR159 TTGGACTGAAGGGAGCT 0.81 3823 CCCT (1998) ahy-miR159 TTTGGATTGAAGGGAGC 0.95 3824 TCTA (1999) aly-miR159a TTTGGATTGAAGGGAGC 0.95 3825 TCTA (2000) aly-miR159b TTTGGATTGAAGGGAGC 0.95 3826 TCTT (2001) aly-miR159c TTTGGATTGAAGGGAGC 0.9 3827 TCCT (2002) ape-miR159 TTGGACTGAAGGGAGCT 0.81 3828 CCCT (2003) aqc-miR159 TTTGGACTGAAGGGAGC 0.9 3829 TCTA (2004) ath-miR159a TTTGGATTGAAGGGAGC 0.95 3830 TCTA (2005) ath-miR159b TTTGGATTGAAGGGAGC 0.95 3831 TCTT (2006) ath-miR159c TTTGGATTGAAGGGAGC 0.9 3832 TCCT (2007) bdi-miR159 CTTGGATTGAAGGGAGC 0.9 3833 TCT (2008) bna-miR159 TTTGGATTGAAGGGAGC 0.95 3834 TCTA (2009) bra-miR159a TTTGGATTGAAGGGAGC 0.95 3835 TCTA (2010) bvl-miR159 TTGGACTGAAGGGAGCT 0.81 3836 CCCT (2011) cmi-miR159 TTGGACTGAAGGGAGCT 0.81 3837 CCCT (2012) cor-miR159 TTGGACTGAAGGGAGCT 0.81 3838 CCCT (2013) crb-miR159 TTGGACTGAAGGGAGCT 0.81 3839 CCCT (2014) csi-miR159 TTTGGATTGAAGGGAGC 0.95 3840 TCTA (2015) dso-miR159 TTGGACTGAAGGGAGCT 0.81 3841 CCCT (2016) ech-miR159 TTGGACTGAAGGGAGCT 0.81 3842 CCCT (2017) fal-miR159 TTGGACTGAAGGGAGCT 0.81 3843 CCCT (2018) far-miR159 TTTGGATTGAAGGGAGC 1 3844 TCTG (2019) gma-miR159a-3p TTTGGATTGAAGGGAGC 0.95 3845 TCTA (2020) gma-miR159b ATTGGAGTGAAGGGAGC 0.81 3846 TCCA (2021) gma-miR159c ATTGGAGTGAAGGGAGC 0.86 3847 TCCG (2022) hvu-miR159a TTTGGATTGAAGGGAGC 1 3848 TCTG (2023) hvu-miR159b TTTGGATTGAAGGGAGC 1 3849 TCTG (2024) hvv-miR159a TTTGGATTGAAGGGAGC 1 3850 TCTG (2025) hvv-miR159b TTTGGATTGAAGGGAGC 1 3851 TCTG (2026) ltu-miR159 TTTGGATTGAAGGGAGC 0.95 3852 TCTA (2027) mma-miR159 TTGGACTGAAGGGAGCT 0.81 3853 CCCT (2028) mtr-miR159a TTTGGATTGAAGGGAGC 0.95 3854 TCTA (2029) mtr-miR159b ATTGAATTGAAGGGAGC 0.71 3855 AACT (2030) mtr-miR159c TTTGGATTGAAGGGAGC 0.95 3856 TCTA (2031) nof-miR159 TTGGACTGAAGGGAGCT 0.81 3857 CCCT (2032) oru-miR159 TTTGGATTGAAGGGAGC 1 3858 TCTG (2033) osa-miR159a TTTGGATTGAAGGGAGC 1 3859 TCTG (2034) osa-miR159a.1 TTTGGATTGAAGGGAGC 1 3860 TCTG (2035) osa-miR159b TTTGGATTGAAGGGAGC 1 3861 TCTG (2036) osa-miR159c ATTGGATTGAAGGGAGC 0.86 3862 TCCA (2037) osa-miR159d ATTGGATTGAAGGGAGC 0.9 3863 TCCG (2038) osa-miR159e ATTGGATTGAAGGGAGC 0.86 3864 TCCT (2039) osa-miR159f CTTGGATTGAAGGGAGC 0.9 3865 TCTA (2040) osa-miR159m TTTGGATTGAAGGGAGC 1 3866 TCTG (2041) pgl-miR159 TTTGGATTGAAGGGAGC 1 3867 TCTG (2042) psi-miR159 CTTGGATTGAAGGGAGC 0.86 3868 TCCA (2043) pta-miR159a TTGGATTGAAGGGAGCT 0.86 3869 CCA (2044) pta-miR159b TTGGATTGAAGAGAGCT 0.81 3870 CCC (2045) pta-miR159c CTTGGATTGAAGGGAGC 0.86 3871 TCCC (2046) ptc-miR159a TTTGGATTGAAGGGAGC 0.95 3872 TCTA (2047) ptc-miR159b TTTGGATTGAAGGGAGC 0.95 3873 TCTA (2048) ptc-miR159c TTTGGATTGAAGGGAGC 0.95 3874 TCTA (2049) ptc-miR159d CTTGGATTGAAGGGAGC 0.86 3875 TCCT (2050) ptc-miR159e CTTGGGGTGAAGGGAGC 0.76 3876 TCCT (2051) ptc-miR159f ATTGGAGTGAAGGGAGC 0.81 3877 TCGA (2052) pvu-miR159 TTTGGATTGAAGGGAGC 0.95 3878 TCTA (2053) pvu-miR159a.1 TTTGGATTGAAGGGAGC 0.95 3879 TCTA (2054) rco-miR159 TTTGGATTGAAGGGAGC 0.95 3880 TCTA (2055) rin-miR159 TTGGACTGAAGGGAGCT 0.81 3881 CCCT (2056) sar-miR159 TTTGGATTGAAGGGAGC 1 3882 TCTG (2057) sbi-miR159b CTTGGATTGAAGGGAGC 0.86 3883 TCCT (2058) sly-miR159 TTTGGATTGAAGGGAGC 0.95 3884 TCTA (2059) smo-miR159 CTTGGATTGAAGGGAGC 0.86 3885 TCCC (2060) sof-miR159a TTTGGATTGAAGGGAGC 1 3886 TCTG (2061) sof-miR159b TTTGGATTGAAGGGAGC 1 3887 TCTG (2062) sof-miR159c CTTGGATTGAAGGGAGC 0.86 3888 TCCT (2063) sof-miR159d TTTGGATTGAAGGGAGC 1 3889 TCTG (2064) sof-miR159e TTTGGATTGAAAGGAGC 0.9 3890 TCTT (2065) spr-miR159 TTTGGATTGAAGGGAGC 1 3891 TCTG (2066) ssp-miR159a TTTGGATTGAAGGGAGC 1 3892 TCTG (2067) svi-miR159 TTGGACTGAAGGGAGCT 0.81 3893 CCCT (2068) tae-miR159a TTTGGATTGAAGGGAGC 1 3894 TCTG (2069) tae-miR159b TTTGGATTGAAGGGAGC 1 3895 TCTG (2070) tar-miR159 TTGGACTGAAGGGAGCT 0.81 3896 CCCT (2071) vvi-miR159a CTTGGAGTGAAGGGAGC 0.86 3897 TCTC (2072) vvi-miR159b CTTGGAGTGAAGGGAGC 0.86 3898 TCTC (2073) vvi-miR159c TTTGGATTGAAGGGAGC 0.95 3899 TCTA (2074) zma-miR159a TTTGGATTGAAGGGAGC 1 3900 TCTG (2075) zma-miR159b TTTGGATTGAAGGGAGC 1 3901 TCTG (2076) zma-miR159c CTTGGATTGAAGGGAGC 0.86 3902 TCCT (2077) zma-miR159d CTTGGATTGAAGGGAGC 0.86 3903 TCCT (2078) zma-miR159e ATTGGTTTGAAGGGAGC 0.81 3904 TCCA (2079) zma-miR159f TTTGGATTGAAGGGAGC 1 3905 TCTG (2080) zma-miR159g TTTGGAGTGAAGGGAGT 0.9 3906 TCTG (2081) zma-miR159h TTTGGAGTGAAGGGAGC 0.95 3907 TCTG (2082) zma-miR159i TTTGGAGTGAAGGGAGC 0.95 3908 TCTG (2083) zma-miR159j TTTGGATTGAAGGGAGC 1 3909 TCTG (2084) zma-miR159k TTTGGATTGAAGGGAGC 1 3910 TCTG (2085) zma-miR159m TTTGGATTGAAGGGAGC 1 3911 TCTG (2086)

TABLE 8 Summary of Homologs/Orthologs to Small RNAs which are down- regulated in Abiotic Stress in Soybean Plants. Homolog % Homolog Stem- Mir Name Name Homolog Sequence (SEQ ID NO:) Identity loop Sequence aly-miR396a- aly- GCTCAAGAAAGCTGTGGGAAA 0.86 5117 3p miR396b-3p (3953) csi-miR396c TTCAAGAAATCTGTGGGAAG 0.86 5118 (3954) gma- AAGAAAGCTGTGGGAGAATATGGC 0.67 5119 miR396d (3955) osa- GTTCAAGAAAGCCCATGGAAA 0.71 5120 miR396e* (3956) osa- ATGGTTCAAGAAAGCCCATGGAAA 0.71 5121 miR396e-3p (3957) osa- GTTCAAGAAAGTCCTTGGAAA 0.71 5122 miR396f* (3958) osa- ATAGTTCAAGAAAGTCCTTGGAAA 0.71 5123 miR396f-3p (3959) zma- GTTCAATAAAGCTGTGGGAAA 0.95 5124 miR396a* (3960) zma- GTTCAATAAAGCTGTGGGAAA 0.95 5125 miR396b-3p (3961) zma- GGTCAAGAAAGCCGTGGGAAG 0.86 5126 miR396e* (3962) zma- GGTCAAGAAAGCTGTGGGAAG 0.9 5127 miR396f* (3963) zma- GTTCAAGAAAGCTGTGGAAGA 0.81 5128 miR396g* (3964) aly-miR396b- aly- GTTCAATAAAGCTGTGGGAAG 0.86 5129 3p miR396a-3p (3965) csi-miR396c TTCAAGAAATCTGTGGGAAG 0.81 5130 (3966) gma- AAGAAAGCTGTGGGAGAATATGGC 0.76 5131 miR396d (3967) osa- GTTCAAGAAAGCCCATGGAAA 0.76 5132 miR396e* (3968) osa- ATGGTTCAAGAAAGCCCATGGAAA 0.76 5133 miR396e-3p (3969) osa- GTTCAAGAAAGTCCTTGGAAA 0.76 5134 miR396f* (3970) osa- ATAGTTCAAGAAAGTCCTTGGAAA 0.76 5135 miR396f-3p (3971) zma- GTTCAATAAAGCTGTGGGAAA 0.9 5136 miR396a* (3972) zma- GTTCAATAAAGCTGTGGGAAA 0.9 5137 miR396b-3p (3973) zma- GGTCAAGAAAGCCGTGGGAAG 0.86 5138 miR396e* (3974) zma- GGTCAAGAAAGCTGTGGGAAG 0.9 5139 miR396f* (3975) zma- GTTCAAGAAAGCTGTGGAAGA 0.86 5140 miR396g* (3976) ath- aly- CCCGCCTTGCATCAACTGAAT 0.95 5141 miRf10239- miR168a* (3977) alcr bna- aly- TAATCTGCATCCTGAGGTTTA 1 5142 miR2111b-5p miR2111a (3978) aly- TAATCTGCATCCTGAGGTTTA 1 5143 miR2111b (3979) ath- TAATCTGCATCCTGAGGTTTA 1 5144 miR2111a (3980) ath- TAATCTGCATCCTGAGGTTTA 1 5145 miR2111b (3981) bna- TAATCTGCATCCTGAGGTTTA 1 5146 miR2111a (3982) bra- TAATCTGCATCCTGAGGTTTA 1 5147 miR2111a (3983) bra- TAATCTGCATCCTGAGGTTTA 1 5148 miR2111b (3984) lja-miR2111 TAATCTGCATCCTGAGGTTTA (3985) 1 5149 mtr- TAATCTGCATCCTGAGGTTTA (3986) 1 5150 miR2111a mtr- TAATCTGCATCCTGAGGTTTA (3987) 1 5151 miR2111b mtr- TAATCTGCATCCTGAGGTTTA (3988) 1 5152 miR2111c mtr- TAATCTGCATCCTGAGGTTTA (3989) 1 5153 miR2111d mtr- TAATCTGCATCCTGAGGTTTA (3990) 1 5154 miR2111e mtr- TAATCTGCATCCTGAGGTTTA (3991) 1 5155 miR2111f mtr- TAATCTGCATCCTGAGGTTTA (3992) 1 5156 miR2111h mtr- TAATCTGCATCCTGAGGTTTA (3993) 1 5157 miR2111i mtr- TAATCTGCATCCTGAGGTTTA (3994) 1 5158 miR2111j mtr- TAATCTGCATCCTGAGGTTTA (3995) 1 5159 miR2111k mtr- TAATCTGCATCCTGAGGTTTA (3996) 1 5160 miR2111l mtr- TAATCTGCATCCTGAGGTTTA (3997) 1 5161 miR2111m mtr- TAATCTGCATCCTGAGGTTTA (3998) 1 5162 miR2111n mtr- TAATCTGCATCCTGAGGTTTA (3999) 1 5163 miR2111o mtr- TAATCTGCATCCTGAGGTTTA (4000) 1 5164 miR2111p mtr- TAATCTGCATCCTGAGGTTTA (4001) 1 5165 miR2111q mtr- TAATCTGCATCCTGAGGTTTA (4002) 1 5166 miR2111r mtr- TAATCTGCATCCTGAGGTTTA (4003) 1 5167 miR2111s tcc-miR2111 TAATCTGCATCCTGAGGTTTA (4004) 1 5168 vvi- TAATCTGCATCCTGAGGTCTA (4005) 0.95 5169 miR2111-5p csi-miR162- aly- GGAGGCAGCGGTTCATCGATC (4006) 0.95 5170 5p miR162a* aly- GGAGGCAGCGGTTCATCGATC (4007) 0.95 5171 miR162b* zma- GGGCGCAGTGGTTTATCGATC (4008) 0.77 5172 miR162* gma-miR396d aly- GCTCAAGAAAGCTGTGGGAAA 0.67 5173 miR396b-3p (4009) zma- GTTCAATAAAGCTGTGGGAAA 0.63 5174 miR396a* (4010) zma- GTTCAATAAAGCTGTGGGAAA 0.63 5175 miR396b-3p (4011) zma- GGTCAAGAAAGCTGTGGGAAG 0.63 5176 miR396f* (4012) zma- GTTCAAGAAAGCTGTGGAAGA 0.67 5177 miR396g* (4013) gma- aqc-miR482a TCTTGCCGACTCCTCCCATACC 0.71 5178 miR482a-3p (4014) aqc- TCTTGCCGACTCCTCCCATACC 0.71 5179 miR482b (4015) aqc-miR482c TCTTGCCGACTCCTCCCATACC 0.71 5180 (4016) csi-miR482a TCTTCCCTATGCCTCCCATTCC (4017) 0.79 5181 csi-miR482b TCTTGCCCACCCCTCCCATTCC 0.71 5182 (4018) csi-miR482c TTCCCTAGTCCCCCTATTCCTA (4019) 0.75 5183 ghr-miR482a TCTTTCCTACTCCTCCCATACC (4020) 0.71 5184 ghr-miR482b TCTTGCCTACTCCACCCATGCC 0.71 5185 (4021) gma-miR482 TCTTCCCAATTCCGCCCATTCCTA 1 5186 (4022) gra-miR482 TCTTTCCAATTCCTCCCATTCC (4023) 0.83 5187 gso-miR482a TCTTCCCTACACCTCCCATAC (4024) 0.67 5188 gso- TCTTCCCTACACCTCCCATAC (4025) 0.67 5189 miR482b mdm- TCTTCCCAAGCCCGCCCATTCC 0.83 5190 miR482 (4026) mdo-miR482 TCTTCCCAAGCCCGCCCATTCC 0.83 5191 (4027) pab- TCTTCCCTACTCCTCCCATTCC (4028) 0.79 5192 miR482a pab- TCTTCCCTATTCCTCCCATTCC (4029) 0.83 5193 miR482b pab- TCTTTCCTACTCCTCCCATTCC (4030) 0.75 5194 miR482c pta-miR482a TCTTCCCTACTCCTCCCATTCC (4031) 0.79 5195 pta-miR482b TCTTCCCTACTCCTCCCATTCC (4032) 0.79 5196 pta-miR482c TCTTCCCTATTCCTCCCATT (4033) 0.75 5197 pta-miR482d TCCTCCCTACTCCTCCCATT (4034) 0.67 5198 ptc- TCTTGCCTACTCCTCCCATT (4035) 0.67 5199 miR482.2 pvu-miR482 TCTTCCCAATTCCGCCCATTCC 0.92 5200 (4036) sly-miR482 TTTCCAATTCCACCCATTCCTA 0.83 5201 (4037) vvi-miR482 TCTTTCCTACTCCTCCCATTCC (4038) 0.75 5202 zma-miR482 TCTTCCTTGTTCCTCCCATT (4039) 0.67 5203 gma- pvu- GGAATGGGCTGATTGGGAAGCA 0.73 5204 miR482b-5p miR482* (4040) gso- aly- GGCAAGTTGTCCTTGGCTACA (4041) 0.85 5205 miR169g* miR169a* aly- GGCAAGTTGTCCTTCGGCTACA 0.85 5206 miR169b* (4042) aly- GGCAAGTCATCTCTGGCTATG (4043) 0.65 5207 miR169c* aly- GCAAGTTGACCTTGGCTCTGT (4044) 0.8 5208 miR169d* aly- GCAAGTTGACCTTGGCTCTGT (4045) 0.8 5209 miR169e* aly- GCAAGTTGACCTTGGCTCTGC (4046) 0.8 5210 miR169f* aly- GCAAGTTGACCTTGGCTCTGT (4047) 0.8 5211 miR169g* aly-miR169h TAGCCAAGGATGACTTGCCTG (4048) 0.65 5212 aly- GGCAGTCTCCTTGGCTATT (4049) 0.65 5213 miR169h* aly-miR169i TAGCCAAGGATGACTTGCCTG (4050) 0.65 5214 aly- GGCAGTCTCCTTGGATATC (4051) 0.6 5215 miR169i* aly-miR169j TAGCCAAGGATGACTTGCCTG (4052) 0.65 5216 aly- GGCAGTCTCCTTGGCTATC (4053) 0.65 5217 miR169j* aly-miR169k TAGCCAAGGATGACTTGCCTG (4054) 0.65 5218 aly- GGCAGTCTCCTTGGCTATC (4055) 0.65 5219 miR169k* aly-miR169l TAGCCAAGGATGACTTGCCTG (4056) 0.65 5220 aly- GGCAGTCTCCTTGGCTATC (4057) 0.65 5221 miR1691* aly- TAGCCAAGGATGACTTGCCTG (4058) 0.65 5222 miR169m aly- GGCAGTCTTCTTGGCTATC (4059) 0.6 5223 miR169m* aly-miR169n TAGCCAAAGATGACTTGCCTG (4060) 0.6 5224 aly- GGCAGTCTCTTTGGCTATC (4061) 0.6 5225 miR169n* aqc-miR169a TAGCCAAGGATGACTTGCCTA (4062) 0.65 5226 aqc- TAGCCAAGGATGACTTGCCTG (4063) 0.65 5227 miR169b ath- TCCGGCAAGTTGACCTTGGCT (4064) 0.9 5228 miR169g* ath-miR169h TAGCCAAGGATGACTTGCCTG (4065) 0.65 5229 ath-miR169i TAGCCAAGGATGACTTGCCTG (4066) 0.65 5230 ath-miR169j TAGCCAAGGATGACTTGCCTG (4067) 0.65 5231 ath-miR169k TAGCCAAGGATGACTTGCCTG (4068) 0.65 5232 ath-miR169l TAGCCAAGGATGACTTGCCTG (4069) 0.65 5233 ath- TAGCCAAGGATGACTTGCCTG (4070) 0.65 5234 miR169m ath-miR169n TAGCCAAGGATGACTTGCCTG (4071) 0.65 5235 bdi-miR169b TAGCCAAGGATGACTTGCCGG (4072) 0.6 5236 bdi-miR169d TAGCCAAGAATGACTTGCCTA (4073) 0.65 5237 bdi-miR169e TAGCCAAGGATGACTTGCCTG (4074) 0.65 5238 bdi-miR169g TAGCCAAGGATGACTTGCCTG (4075) 0.65 5239 bdi-miR169h TAGCCAAGGATGACTTGCCTA (4076) 0.65 5240 bdi-miR169i CCAGCCAAGAATGGCTTGCCTA 0.6 5241 (4077) bdi-miR169j TAGCCAGGAATGGCTTGCCTA (4078) 0.6 5242 bdi-miR169k TAGCCAAGGATGATTTGCCTGT 0.6 5243 (4079) bna- TAGCCAAGGATGACTTGCCTA (4080) 0.65 5244 miR169c bna- TAGCCAAGGATGACTTGCCTA (4081) 0.65 5245 miR169d bna- TAGCCAAGGATGACTTGCCTA (4082) 0.65 5246 miR169e bna-miR169f TAGCCAAGGATGACTTGCCTA (4083) 0.65 5247 bna- TAGCCAAGGATGACTTGCCTGC 0.65 5248 miR169g (4084) bna- TAGCCAAGGATGACTTGCCTGC 0.65 5249 miR169h (4085) bna-miR169i TAGCCAAGGATGACTTGCCTGC 0.65 5250 (4086) bna-miR169j TAGCCAAGGATGACTTGCCTGC 0.65 5251 (4087) bna- TAGCCAAGGATGACTTGCCTGC 0.65 5252 miR169k (4088) bna-miR169l TAGCCAAGGATGACTTGCCTGC 0.65 5253 (4089) far-miR169 TAGCCAAGGATGACTTGCCTA (4090) 0.65 5254 glib- TAGCCAAGGATGACTTGCCTG (4091) 0.65 5255 miR169a ghr-miR169 ACGCCAAGGATGTCTTGCGTC (4092) 0.6 5256 mtr-miR169f AAGCCAAGGATGACTTGCCTA (4093) 0.6 5257 osa-miR169e TAGCCAAGGATGACTTGCCGG (4094) 0.6 5258 osa-miR169f TAGCCAAGGATGACTTGCCTA (4095) 0.65 5259 osa-miR169g TAGCCAAGGATGACTTGCCTA (4096) 0.65 5260 osa-miR169h TAGCCAAGGATGACTTGCCTG (4097) 0.65 5261 osa-miR169i TAGCCAAGGATGACTTGCCTG (4098) 0.65 5262 osa-miR169j TAGCCAAGGATGACTTGCCTG (4099) 0.65 5263 osa-miR169k TAGCCAAGGATGACTTGCCTG (4100) 0.65 5264 osa-miR169l TAGCCAAGGATGACTTGCCTG (4101) 0.65 5265 osa- TAGCCAAGGATGACTTGCCTG (4102) 0.65 5266 miR169m osa-miR169n TAGCCAAGAATGACTTGCCTA (4103) 0.65 5267 osa-miR169o TAGCCAAGAATGACTTGCCTA (4104) 0.65 5268 ptc- TAGCCAAGGACGACTTGCCCA (4105) 0.6 5269 miR169ab ptc- TAGCCAAGGACGACTTGCCCA (4106) 0.6 5270 miR169ac ptc- TAGCCAAGGACGACTTGCCCA (4107) 0.6 5271 miR169ad ptc- TAGCCAAGGACGACTTGCCCA (4108) 0.6 5272 miR169ae ptc- TAGCCAAGGACGACTTGCCCA (4109) 0.6 5273 miR169af ptc-miR169i TAGCCAAGGATGACTTGCCTG (4110) 0.65 5274 ptc-miR169j TAGCCAAGGATGACTTGCCTG (4111) 0.65 5275 ptc-miR169k TAGCCAAGGATGACTTGCCTG (4112) 0.65 5276 ptc-miR169l TAGCCAAGGATGACTTGCCTG (4113) 0.65 5277 ptc- TAGCCAAGGATGACTTGCCTG (4114) 0.65 5278 miR169m ptc-miR169o AAGCCAAGGATGACTTGCCTG (4115) 0.6 5279 ptc-miR169p AAGCCAAGGATGACTTGCCTG (4116) 0.6 5280 ptc-miR169q TAGCCAAGGACGACTTGCCTG (4117) 0.65 5281 ptc-miR169r TAGCCAAGGATGACTTGCCTA (4118) 0.65 5282 ptc-miR169s TCAGCCAAGGATGACTTGCCG (4119) 0.65 5283 ptc-miR169u TAGCCAAGGACGACTTGCCTA (4120) 0.65 5284 ptc-miR169v TAGCCAAGGATGACTTGCCCA (4121) 0.6 5285 ptc- TAGCCAAGGATGACTTGCCCA (4122) 0.6 5286 miR169w sbi-miR169c TAGCCAAGGATGACTTGCCTA (4123) 0.65 5287 sbi-miR169d TAGCCAAGGATGACTTGCCTA (4124) 0.65 5288 sbi-miR169e TAGCCAAGGATGACTTGCCGG (4125) 0.6 5289 sbi-miR169f TAGCCAAGGATGACTTGCCTG (4126) 0.65 5290 sbi-miR169g TAGCCAAGGATGACTTGCCTG (4127) 0.65 5291 sbi-miR169h TAGCCAAGGATGACTTGCCTA (4128) 0.65 5292 sbi-miR169i TAGCCAAGAATGACTTGCCTA (4129) 0.65 5293 sbi-miR169j TAGCCAAGGATGACTTGCCGG (4130) 0.6 5294 sbi-miR169l TAGCCAAGGATGACTTGCCTG (4131) 0.65 5295 sbi- TAGCCAAGGATGACTTGCCTA (4132) 0.65 5296 miR169m sbi-miR169n TAGCCAAGGATGACTTGCCTA (4133) 0.65 5297 sbi-miR169o TAGCCAAGGATGATTTGCCTG (4134) 0.6 5298 sbi-miR169p TAGCCAAGAATGGCTTGCCTA (4135) 0.65 5299 sbi-miR169q TAGCCAAGAATGGCTTGCCTA (4136) 0.65 5300 sly-miR169b TAGCCAAGGATGACTTGCCTG (4137) 0.65 5301 sly-miR169d TAGCCAAGGATGACTTGCCTA (4138) 0.65 5302 sof-miR169 TAGCCAAGGATGACTTGCCGG (4139) 0.6 5303 ssp-miR169 TAGCCAAGGATGACTTGCCGG (4140) 0.6 5304 tcc-miR169d TAGCCAAGGATGACTTGCCTA (4141) 0.65 5305 tcc-miR169f AAGCCAAGAATGACTTGCCTG (4142) 0.6 5306 tcc-miR169g TAGCCAGGGATGACTTGCCTA (4143) 0.6 5307 tcc-miR169h TAGCCAAGGATGACTTGCCTG (4144) 0.65 5308 tcc-miR169i TAGCCAAGGATGAGTTGCCTG (4145) 0.6 5309 tcc-miR169j TAGCCAAGGATGACTTGCCTG (4146) 0.65 5310 vvi-miR169e TAGCCAAGGATGACTTGCCTGC 0.65 5311 (4147) vvi-miR169x TAGCCAAGGATGACTTGCCTA (4148) 0.65 5312 vvi-miR169y TAGCGAAGGATGACTTGCCTA (4149) 0.6 5313 zma- GGCAAGTTGTTCTTGGCTACA (4150) 0.8 5314 miR169a* zma- GGCAAGTTGTTCTTGGCTACA (4151) 0.8 5315 miR169b* zma- GGCAAGTCTGTCCTTGGCTACA 0.85 5316 miR169c* (4152) zma- TAGCCAAGGATGACTTGCCTA (4153) 0.65 5317 miR169f zma- GGCATGTCTTCCTTGGCTACT (4154) 0.7 5318 miR169f* zma- TAGCCAAGGATGACTTGCCTA (4155) 0.65 5319 miR169g zma- TAGCCAAGGATGACTTGCCTA (4156) 0.65 5320 miR169h zma- TAGCCAAGGATGACTTGCCTG (4157) 0.65 5321 miR169i zma- GGCAGTCTCCTTGGCTAG (4158) 0.65 5322 miR169i* zma- TAGCCAAGGATGACTTGCCTG (4159) 0.65 5323 miR169j zma- GGCAGTCTCCTTGGCTAG (4160) 0.65 5324 miR169j* zma- TAGCCAAGGATGACTTGCCTG (4161) 0.65 5325 miR169k zma- GGCAGTCTCCTTGGCTAG (4162) 0.65 5326 miR169k* zma- TAGCCAAGAATGGCTTGCCTA (4163) 0.65 5327 miR169m zma- TAGCCAAGAATGGCTTGCCTA (4164) 0.65 5328 miR169n zma- GGCAGGCCTTCTTGGCTAAG (4165) 0.6 5329 miR169n* zma- TAGCCAAGAATGACTTGCCTA (4166) 0.65 5330 miR169o zma- GGCAGGTCTTCTTGGCTAGC (4167) 0.65 5331 miR169o* zma- TAGCCAAGGATGACTTGCCGG (4168) 0.6 5332 miR169p zma- GGCAAGTCATCTGGGGCTACG (4169) 0.6 5333 miR169p* zma- TAGCCAAGAATGGCTTGCCTA (4170) 0.65 5334 miR169q zma- GGCAAGTTGTCCTTGGCTACA (4171) 0.85 5335 miR169r* ppt-miR533b- ppt- GAGCTGGCCAGGCTGTGAGGG 0.95 5336 5p miR533a* (4172) ptc- aly- TAATCTGCATCCTGAGGTTTA (4173) 0.95 5337 miRf11953- miR2111a akr aly- TAATCTGCATCCTGAGGTTTA (4174) 0.95 5338 miR2111b ath- TAATCTGCATCCTGAGGTTTA (4175) 0.95 5339 miR2111a ath- TAATCTGCATCCTGAGGTTTA (4176) 0.95 5340 miR2111b bna- TAATCTGCATCCTGAGGTTTA (4177) 0.95 5341 miR2111a bna- TAATCTGCATCCTGAGGTTTA (4178) 0.95 5342 miR2111b- 5p bra- TAATCTGCATCCTGAGGTTTA (4179) 0.95 5343 miR2111a bra- TAATCTGCATCCTGAGGTTTA (4180) 0.95 5344 miR2111b lja-miR2111 TAATCTGCATCCTGAGGTTTA (4181) 0.95 5345 mtr- TAATCTGCATCCTGAGGTTTA (4182) 0.95 5346 miR2111a mtr- TAATCTGCATCCTGAGGTTTA (4183) 0.95 5347 miR2111b mtr- TAATCTGCATCCTGAGGTTTA (4184) 0.95 5348 miR2111c mtr- TAATCTGCATCCTGAGGTTTA (4185) 0.95 5349 miR2111d mtr- TAATCTGCATCCTGAGGTTTA (4186) 0.95 5350 miR2111e mtr- TAATCTGCATCCTGAGGTTTA (4187) 0.95 5351 miR2111f mtr- TAATCTGCATCCTGAGGTTTA (4188) 0.95 5352 miR2111h mtr- TAATCTGCATCCTGAGGTTTA (4189) 0.95 5353 miR2111i mtr- TAATCTGCATCCTGAGGTTTA (4190) 0.95 5354 miR2111j mtr- TAATCTGCATCCTGAGGTTTA (4191) 0.95 5355 miR2111k mtr- TAATCTGCATCCTGAGGTTTA (4192) 0.95 5356 miR2111l mtr- TAATCTGCATCCTGAGGTTTA (4193) 0.95 5357 miR2111m mtr- TAATCTGCATCCTGAGGTTTA (4194) 0.95 5358 miR2111n mtr- TAATCTGCATCCTGAGGTTTA (4195) 0.95 5359 miR2111o mtr- TAATCTGCATCCTGAGGTTTA (4196) 0.95 5360 miR2111p mtr- TAATCTGCATCCTGAGGTTTA (4197) 0.95 5361 miR2111q mtr- TAATCTGCATCCTGAGGTTTA (4198) 0.95 5362 miR2111r mtr- TAATCTGCATCCTGAGGTTTA (4199) 0.95 5363 miR2111s tcc-miR2111 TAATCTGCATCCTGAGGTTTA (4200) 0.95 5364 vvi- TAATCTGCATCCTGAGGTCTA (4201) 0.9 5365 miR2111-5p vvi-miR2111- aly- TAATCTGCATCCTGAGGTTTA (4202) 0.95 5366 5p miR2111a aly- TAATCTGCATCCTGAGGTTTA (4203) 0.95 5367 miR2111b ath- TAATCTGCATCCTGAGGTTTA (4204) 0.95 5368 miR2111a ath- TAATCTGCATCCTGAGGTTTA (4205) 0.95 5369 miR2111b bna- TAATCTGCATCCTGAGGTTTA (4206) 0.95 5370 miR2111a bna- TAATCTGCATCCTGAGGTTTA (4207) 0.95 5371 miR2111b- 5p bra- TAATCTGCATCCTGAGGTTTA (4208) 0.95 5372 miR2111a bra- TAATCTGCATCCTGAGGTTTA (4209) 0.95 5373 miR2111b lja-miR2111 TAATCTGCATCCTGAGGTTTA (4210) 0.95 5374 mtr- TAATCTGCATCCTGAGGTTTA (4211) 0.95 5375 miR2111a mtr- TAATCTGCATCCTGAGGTTTA (4212) 0.95 5376 miR2111b mtr- TAATCTGCATCCTGAGGTTTA (4213) 0.95 5377 miR2111c mtr- TAATCTGCATCCTGAGGTTTA (4214) 0.95 5378 miR2111d mtr- TAATCTGCATCCTGAGGTTTA (4215) 0.95 5379 miR2111e mtr- TAATCTGCATCCTGAGGTTTA (4216) 0.95 5380 miR2111f mtr- TAATCTGCATCCTGAGGTTTA (4217) 0.95 5381 miR2111h mtr- TAATCTGCATCCTGAGGTTTA (4218) 0.95 5382 miR2111i mtr- TAATCTGCATCCTGAGGTTTA (4219) 0.95 5383 miR2111j mtr- TAATCTGCATCCTGAGGTTTA (4220) 0.95 5384 miR2111k mtr- TAATCTGCATCCTGAGGTTTA (4221) 0.95 5385 miR2111l mtr- TAATCTGCATCCTGAGGTTTA (4222) 0.95 5386 miR2111m mtr- TAATCTGCATCCTGAGGTTTA (4223) 0.95 5387 miR2111n mtr- TAATCTGCATCCTGAGGTTTA (4224) 0.95 5388 miR2111o mtr- TAATCTGCATCCTGAGGTTTA (4225) 0.95 5389 miR2111p mtr- TAATCTGCATCCTGAGGTTTA (4226) 0.95 5390 miR2111q mtr- TAATCTGCATCCTGAGGTTTA (4227) 0.95 5391 miR2111r mtr- TAATCTGCATCCTGAGGTTTA (4228) 0.95 5392 miR2111s tcc-miR2111 TAATCTGCATCCTGAGGTTTA (4229) 0.95 5393 zma- aly- GTTCAATAAAGCTGTGGGAAG 0.95 5394 miR396b-3p miR396a-3p (4230) aly- GCTCAAGAAAGCTGTGGGAAA 0.9 5395 miR396b-3p (4231) csi-miR396c TTCAAGAAATCTGTGGGAAG (4232) 0.81 5396 gma- AAGAAAGCTGTGGGAGAATATGGC 0.71 5397 miR396d (4233) osa- GTTCAAGAAAGCCCATGGAAA 0.76 5398 miR396e* (4234) osa- ATGGTTCAAGAAAGCCCATGGAAA 0.76 5399 miR396e-3p (4235) osa- GTTCAAGAAAGTCCTTGGAAA (4236) 0.76 5400 miR396f* osa- ATAGTTCAAGAAAGTCCTTGGAAA 0.76 5401 miR396f-3p (4237) zma- GTTCAATAAAGCTGTGGGAAA 1 5402 miR396a* (4238) zma- GGTCAAGAAAGCCGTGGGAAG 0.81 5403 miR396e* (4239) zma- GGTCAAGAAAGCTGTGGGAAG 0.86 5404 miR396f* (4240) zma- GTTCAAGAAAGCTGTGGAAGA 0.86 5405 miR396g* (4241) ctr-miR171 aly-miR171a TGATTGAGCCGCGCCAATATC (4242) 0.81 5406 aly-miR171b TTGAGCCGTGCCAATATCACG (4243) 0.81 5407 aly-miR171c TTGAGCCGTGCCAATATCACG (4244) 0.81 5408 aqc-miR171a TGATTGAGCCGTGCCAATATC (4245) 0.76 5409 aqc- TGATTGAGCCGTGCCAATATC (4246) 0.76 5410 miR171b aqc-miR171c TAATTGAACCGCACTAATATC (4247) 0.67 5411 aqc- TGATTGAGCCGTGCCAATATC (4248) 0.76 5412 miR171d aqc-miR171e TGAATGAACCGAGCCAACATC 0.62 5413 (4249) aqc-miR171f TAATTGAGCCGTGCCAATATC (4250) 0.76 5414 ath-miR171a TGATTGAGCCGCGCCAATATC (4251) 0.81 5415 ath-miR171b TTGAGCCGTGCCAATATCACG (4252) 0.81 5416 ath-miR171c TTGAGCCGTGCCAATATCACG (4253) 0.81 5417 bdi-miR17la TGATTGAGCCGCGCCAATATC (4254) 0.81 5418 bdi-miR171b TGATTGAGCCGTGCCAATATC (4255) 0.76 5419 bdi-miR171c TGATTGAGCCGTGCCAATATC (4256) 0.76 5420 bdi-miR171d TGATTGAGCCGTGCCAATATC (4257) 0.76 5421 bna- TTGAGCCGTGCCAATATCACG (4258) 0.81 5422 miR171a bna- TTGAGCCGTGCCAATATCACG (4259) 0.81 5423 miR171b bna- TTGAGCCGTGCCAATATCACG (4260) 0.81 5424 miR171c bna- TTGAGCCGTGCCAATATCACG (4261) 0.81 5425 miR171d bna- TTGAGCCGTGCCAATATCACG (4262) 0.81 5426 miR171e bna-miR171f TGATTGAGCCGCGCCAATATC (4263) 0.81 5427 bna- TGATTGAGCCGCGCCAATATCT 0.86 5428 miR171g (4264) bol-miR171a TTGAGCCGTGCCAATATCACG (4265) 0.81 5429 bra-miR171a TTGAGCCGTGCCAATATCACG (4266) 0.81 5430 bra-miR171b TTGAGCCGTGCCAATATCACG (4267) 0.81 5431 bra-miR171c TTGAGCCGTGCCAATATCACG (4268) 0.81 5432 bra-miR171d TTGAGCCGTGCCAATATCACG (4269) 0.81 5433 bra-miR11e TGATTGAGCCGCGCCAATATC (4270) 0.81 5434 ccl-miR171 TGATTGAGCCGCGCCAATATC (4271) 0.81 5435 crt-miR171 TGATTGAGCCGTGCCAATATC (4272) 0.76 5436 csi-miR171a TTGAGCCGCGCCAATATCAC (4273) 0.86 5437 csi-miR171b CGAGCCGAATCAATATCACTC (4274) 0.71 5438 ctr-miR171 TTGAGCCGCGTCAATATCTCC (4275) 1 5439 far-miR171 TGATTGAGCCGTGCCAATATC (4276) 0.76 5440 gma- TGAGCCGTGCCAATATCACGA (4277) 0.76 5441 miR171a gma- CGAGCCGAATCAATATCACTC (4278) 0.71 5442 miR171b-3p hvu-miR171 TGATTGAGCCGTGCCAATATC (4279) 0.76 5443 mtr-miR171 TGATTGAGTCGTGCCAATATC (4280) 0.71 5444 mtr- TGATTGAGCCGCGTCAATATC (4281) 0.86 5445 miR171b mtr-miR171c TGATTGAGCCGTGCCAATATT (4282) 0.71 5446 mtr- TGATTGAGCCGTGCCAATATC (4283) 0.76 5447 miR171d mtr-miR171e AGATTGAGCCGCGCCAATATC (4284) 0.81 5448 mtr-miR171f TTGAGCCGTGCCAATATCACG (4285) 0.81 5449 mtr- TGATTGAGCCGTGCCAATATC (4286) 0.76 5450 miR171g osa-miR171a TGATTGAGCCGCGCCAATATC (4287) 0.81 5451 osa-miR171b TGATTGAGCCGTGCCAATATC (4288) 0.76 5452 osa-miR171c TGATTGAGCCGTGCCAATATC (4289) 0.76 5453 osa-miR171d TGATTGAGCCGTGCCAATATC (4290) 0.76 5454 osa-miR171e TGATTGAGCCGTGCCAATATC (4291) 0.76 5455 osa-miR171f TGATTGAGCCGTGCCAATATC (4292) 0.76 5456 osa-miR171g GAGGTGAGCCGAGCCAATATC 0.71 5457 (4293) osa-miR171h GTGAGCCGAACCAATATCACT (4294) 0.71 5458 osa-miR171i GGATTGAGCCGCGTCAATATC (4295) 0.86 5459 ppt-miR171a TGAGCCGCGCCAATATCACAT (4296) 0.81 5460 ppt-miR171b TTGAGCCGCGCCAATATCACA (4297) 0.86 5461 pta-miR171 TGATTGAGACGAGTCCATATC (4298) 0.71 5462 ptc-miR171a TTGAGCCGTGCCAATATCACG (4299) 0.81 5463 ptc-miR171b TTGAGCCGTGCCAATATCACG (4300) 0.81 5464 ptc-miR171c AGATTGAGCCGCGCCAATATC (4301) 0.81 5465 ptc-miR171d AGATTGAGCCGCGCCAATATC (4302) 0.81 5466 ptc-miR171e TGATTGAGCCGTGCCAATATC (4303) 0.76 5467 ptc-miR171f TGATTGAGCCGTGCCAATATC (4304) 0.76 5468 ptc-miR171g TGATTGAGCCGTGCCAATATC (4305) 0.76 5469 ptc-miR171h TGATTGAGCCGTGCCAATATC (4306) 0.76 5470 ptc-miR171i TGATTGAGCCGTGCCAATATC (4307) 0.76 5471 ptc-miR171j GGATTGAGCCGCGCCAATACT (4308) 0.71 5472 ptc-miR171k GGATTGAGCCGCGCCAATATC (4309) 0.81 5473 ptc-miR171l CGAGCCGAATCAATATCACT (4310) 0.71 5474 ptc- CGAGCCGAATCAATATCACT (4311) 0.71 5475 miR171m ptc-miR171n CGAGCCGAATCAATATCACT (4312) 0.71 5476 rco-miR171a TTGAGCCGTGCCAATATCACG (4313) 0.81 5477 rco-miR171b TTGAGCCGTGCCAATATCACG (4314) 0.81 5478 rco-miR171c TGATTGAGCCGTGCCAATATC (4315) 0.76 5479 rco-miR171d TGATTGAGCCGTGCCAATATC (4316) 0.76 5480 rco-miR171e TGATTGAGCCGTGCCAATATC (4317) 0.76 5481 rco-miR171f TGATTGAGCCGTGCCAATATC (4318) 0.76 5482 rco-miR171g AGATTGAGCCGCGCCAATATC (4319) 0.81 5483 sbi-miR171a TGATTGAGCCGTGCCAATATC (4320) 0.76 5484 sbi-miR171b TGATTGAGCCGTGCCAATATC (4321) 0.76 5485 sbi-miR171c GAGGTGAGCCGAGCCAATATC 0.71 5486 (4322) sbi-miR171d TGATTGAGCCGTGCCAATATC (4323) 0.76 5487 sbi-miR171e GTGAGCCGAACCAATATCACT (4324) 0.71 5488 sbi-miR171f ATGAGCCGAACCAATATCACT (4325) 0.71 5489 sbi-miR171g TGATTGAGCCGCGCCAATATC (4326) 0.81 5490 sbi-miR171h GGATTGAGCCGCGTCAATATC (4327) 0.86 5491 sbi-miR171i TGATTGAGCCGTGCCAATATC (4328) 0.76 5492 sbi-miR171j TGATTGAGCCGCGCCAATATC (4329) 0.81 5493 sbi-miR171k TGATTGAGCCGTGCCAATATC (4330) 0.76 5494 sly-miR171a TGATTGAGCCGTGCCAATATC (4331) 0.76 5495 sly-miR171b TTGAGCCGTGCCAATATCACG (4332) 0.81 5496 sly-miR171d TTGAGCCGCGCCAATATCAC (4333) 0.86 5497 smo- TTGAGCCGTGCCAATATCACT (4334) 0.81 5498 miR171a smo- TGAGCCGTGCCAATATCACAT (4335) 0.76 5499 miR171b smo- TTGAGTCGCGCCAATATCATG (4336) 0.76 5500 miR171c smo- TGAGCCGCGCCAATATCACAT (4337) 0.81 5501 miR171d tae-miR171a TGATTGAGCCGTGCCAATATC (4338) 0.76 5502 tae-miR171b TTGAGCCGTGCCAATATCACG (4339) 0.81 5503 tcc-miR171a TGATTGAGCCGCGCCAATATC (4340) 0.81 5504 tcc-miR171b AGATTGAGCCGCGCCAATATC (4341) 0.81 5505 tcc-miR171c AGATTGAGCCGCGCCAATATC (4342) 0.81 5506 tcc-miR171d TGATTGAGCCGTGCCAATATC (4343) 0.76 5507 tcc-miR171e TGATTGAGCCGTGCCAATATC (4344) 0.76 5508 tcc-miR171f TGATTGAGCCGTGCCAATATC (4345) 0.76 5509 tcc-miR171g TGATTGAGCCGTGCCAATATC (4346) 0.76 5510 tcc-miR171h TGATTGAGCCGTGCCAATATC (4347) 0.76 5511 vvi-miR171a TGATTGAGCCGTGCCAATATC (4348) 0.76 5512 vvi-miR171b TGATTGAGCCGCGTCAATATC (4349) 0.86 5513 vvi-miR171c TGATTGAGCCGTGCCAATATC (4350) 0.76 5514 vvi-miR171d TGATTGAGCCGTGCCAATATC (4351) 0.76 5515 vvi-miR171e TGATTGAGCCGCGCCAATATC (4352) 0.81 5516 vvi-miR171f TTGAGCCGCGCCAATATCACT (4353) 0.86 5517 vvi-miR171g TTGAGCCGAACCAATATCACC (4354) 0.81 5518 vvi-miR171h TGGTTGAGCCGCGCCAATATC (4355) 0.81 5519 vvi-miR171i TGATTGAGCCGTGCCAATATC (4356) 0.76 5520 zma- TGATTGAGCCGCGCCAATAT (4357) 0.76 5521 miR171a zma- TTGAGCCGTGCCAATATCAC (4358) 0.81 5522 miR171b zma- TGACTGAGCCGTGCCAATATC (4359) 0.71 5523 miR171c zma- TGATTGAGCCGTGCCAATATC (4360) 0.76 5524 miR171d zma- TGATTGAGCCGTGCCAATATC (4361) 0.76 5525 miR171e zma- TTGAGCCGTGCCAATATCACA (4362) 0.81 5526 miR171f zma- GAGGTGAGCCGAGCCAATATC 0.71 5527 miR171g (4363) zma- GTGAGCCGAACCAATATCACT (4364) 0.71 5528 miR171h zma- TGATTGAGCCGTGCCAATATC (4365) 0.76 5529 miR171i zma- TGATTGAGCCGTGCCAATATC (4366) 0.76 5530 miR171j zma- GTGAGCCGAACCAATATCACT (4367) 0.71 5531 miR171k zma- GGATTGAGCCGCGTCAATATC (4368) 0.86 5532 miR171l zma- GGATTGAGCCGCGTCAATATC (4369) 0.86 5533 miR171m zma- TGATTGAGCCGCGCCAATATC (4370) 0.81 5534 miR171n aly-miR160c- ahy-miR160- GCATGAAGGGAGTCACGCAGG 0.67 5535 3p 3p (4371) aly- GCGTATGAGGAGCCATGCATA 0.81 5536 miR160a* (4372) aly- GCGTACAGAGTAGTCAAGCATG 0.86 5537 miR160b* (4373) bra- GCGTATGAGGAGCCATGCATA 0.81 5538 miR160a-3p (4374) zma- GCGTGCAAGGGGCCAAGCATG 0.9 5539 miR160a* (4375) zma- GCGTGCAAGGAGCCAAGCATG 0.95 5540 miR160b* (4376) zma- GCGTGCATGGTGCCAAGCATA 0.81 5541 miR160c* (4377) zma- GCGTGCGTGGAGCCAAGCATG 0.86 5542 miR160d* (4378) zma- GCGTGCGAGGTGCCAGGCATG 0.81 5543 miR160f* (4379) zma- GCGTGCAAGGAGCCAAGCATG 0.95 5544 miR160g* (4380) bra-miR160a- aly- GCGTATGAGGAGCCATGCATA 1 5545 3p miR160a* (4381) aly- GCGTACAGAGTAGTCAAGCATG 0.76 5546 miR160b* (4382) aly- GCGTACAAGGAGCCAAGCATG 0.81 5547 miR160c-3p (4383) zma- GCGTGCAAGGGGCCAAGCATG 0.71 5548 miR160a* (4384) zma- GCGTGCAAGGAGCCAAGCATG 0.76 5549 miR160b* (4385) zma- GCGTGCATGGTGCCAAGCATA 0.71 5550 miR160c* (4386) zma- GCGTGCGTGGAGCCAAGCATG 0.76 5551 miR160d* (4387) zma- GCGTGCGAGGTGCCAGGCATG 0.76 5552 miR160f* (4388) zma- GCGTGCAAGGAGCCAAGCATG 0.76 5553 miR160g* (4389) gma- ahy- CCTCGTTCCATACATCATCTA 0.77 5554 miR1507a miR1507 (4390) gma- TCTCATTCCATACATCGTCTG 0.95 5555 miR1507b (4391) gso- TCTCATTCCATACATCGTCTGA 1 5556 miR1507a (4392) gso- TCTCATTCCATACATCGTCTGA 1 5557 miR1507b (4393) mtr- CCTCGTTCCATACATCATCTAG 0.77 5558 miR1507 (4394) vun- TCTCATTCCATACATCGTCTG (4395) 0.95 5559 miR1507a vun- TCTCATTCCATACATCGTCTG (4396) 0.95 5560 miR1507b gma- gma- AAGTGATGACATGACAAGCGAAGT 0.75 5561 miR4371b miR4371a (4397) gso-miR482a aqc-miR482a TCTTGCCGACTCCTCCCATACC 0.86 5562 (4398) aqc- TCTTGCCGACTCCTCCCATACC 0.86 5563 miR482b (4399) aqc-miR482c TCTTGCCGACTCCTCCCATACC 0.86 5564 (4400) csi-miR482a TCTTCCCTATGCCTCCCATTCC (4401) 0.86 5565 csi-miR482b TCTTGCCCACCCCTCCCATTCC 0.81 5566 (4402) csi-miR482c TTCCCTAGTCCCCCTATTCCTA (4403) 0.67 5567 ghr-miR482a TCTTTCCTACTCCTCCCATACC (4404) 0.9 5568 ghr-miR482b TCTTGCCTACTCCACCCATGCC 0.81 5569 (4405) gma-miR482 TCTTCCCAATTCCGCCCATTCCTA 0.76 5570 (4406) gma- TCTTCCCAATTCCGCCCATTCCTA 0.76 5571 miR482a-3p (4407) gra-miR482 TCTTTCCAATTCCTCCCATTCC (4408) 0.76 5572 gso- TCTTCCCTACACCTCCCATAC (4409) 1 5573 miR482b mdm- TCTTCCCAAGCCCGCCCATTCC 0.76 5574 miR482 (4410) mdo-miR482 TCTTCCCAAGCCCGCCCATTCC 0.76 5575 (4411) pab- TCTTCCCTACTCCTCCCATTCC (4412) 0.9 5576 miR482a pab- TCTTCCCTATTCCTCCCATTCC (4413) 0.86 5577 miR482b pab- TCTTTCCTACTCCTCCCATTCC (4414) 0.86 5578 miR482c pta-miR482a TCTTCCCTACTCCTCCCATTCC (4415) 0.9 5579 pta-miR482b TCTTCCCTACTCCTCCCATTCC (4416) 0.9 5580 pta-miR482c TCTTCCCTATTCCTCCCATT (4417) 0.81 5581 pta-miR482d TCCTCCCTACTCCTCCCATT (4418) 0.81 5582 ptc- CCTACTCCTCCCATTCC (4419) 0.67 5583 miR482.1 ptc- TCTTGCCTACTCCTCCCATT (4420) 0.81 5584 miR482.2 pvu-miR482 TCTTCCCAATTCCGCCCATTCC 0.76 5585 (4421) sly-miR482 TTTCCAATTCCACCCATTCCTA 0.62 5586 (4422) vvi-miR482 TCTTTCCTACTCCTCCCATTCC (4423) 0.86 5587 zma-miR482 TCTTCCTTGTTCCTCCCATT (4424) 0.71 5588 osa- osa- AGTGAGGAGGCCGGGGCCGCT 0.75 5589 miR1846e miR1846a- (4425) 5p osa- AGTGAGGAGGCCGGGGCCGCT 0.75 5590 miR1846b- (4426) 5p osa- AGTGAGGAGGCCGGGGCCGCT 0.75 5591 miR1846c- (4427) 5p ppt-miR166m aly-miR166a TCGGACCAGGCTTCATTCCCC (4428) 0.86 5592 aly-miR166b TCGGACCAGGCTTCATTCCCC (4429) 0.86 5593 aly-miR166c TCGGACCAGGCTTCATTCCCC (4430) 0.86 5594 aly-miR166d TCGGACCAGGCTTCATTCCCC (4431) 0.86 5595 aly-miR166e TCGGACCAGGCTTCATTCCCC (4432) 0.86 5596 aly-miR166f TCGGACCAGGCTTCATTCCCC (4433) 0.86 5597 aly-miR166g TCGGACCAGGCTTCATTCCCC (4434) 0.86 5598 aqc-miR166a TCGGACCAGGCTTCATTCCTC (4435) 0.9 5599 aqc- TCGGACCAGGCTTCATTCCCC (4436) 0.86 5600 miR166b aqc-miR166c TCGGACCAGGCTTCATTCCT (4437) 0.9 5601 aqc- TCGGACCAGGCTTCATTCCTC (4438) 0.9 5602 miR166d aqc-miR166e TCGGACCAGGCTTCATTCCCC (4439) 0.86 5603 ath-miR166a TCGGACCAGGCTTCATTCCCC (4440) 0.86 5604 ath-miR166b TCGGACCAGGCTTCATTCCCC (4441) 0.86 5605 ath-miR166c TCGGACCAGGCTTCATTCCCC (4442) 0.86 5606 ath-miR166d TCGGACCAGGCTTCATTCCCC (4443) 0.86 5607 ath-miR166e TCGGACCAGGCTTCATTCCCC (4444) 0.86 5608 ath-miR166f TCGGACCAGGCTTCATTCCCC (4445) 0.86 5609 ath-miR166g TCGGACCAGGCTTCATTCCCC (4446) 0.86 5610 bdi-miR166 TCGGACCAGGCTTCATTCCCC (4447) 0.86 5611 bdi-miR166a TCGGACCAGGCTTCATTCCCC (4448) 0.86 5612 bdi-miR166b TCGGACCAGGCTTCATTCCCC (4449) 0.86 5613 bdi-miR166c TCGGACCAGGCTTCATTCCCC (4450) 0.86 5614 bdi-miR166d TCGGACCAGGCTTCATTCCCC (4451) 0.86 5615 bdi-miR166e CTCGGACCAGGCTTCATTCCC (4452) 0.86 5616 bdi-miR166f TCTCGGACCAGGCTTCATTCC (4453) 0.86 5617 bna- TCGGACCAGGCTTCATTCCCC (4454) 0.86 5618 miR166a bna- TCGGACCAGGCTTCATTCCCC (4455) 0.86 5619 miR166b bna- TCGGACCAGGCTTCATTCCCC (4456) 0.86 5620 miR166c bna- TCGGACCAGGCTTCATTCCCC (4457) 0.86 5621 miR166d cpt-miR166 TCGGACCAGGCTTCATTCCC (4458) 0.86 5622 crt-miR166a TCGGACCAGGCTTCATTCCCGT 0.86 5623 (4459) crt-miR166b TCGGACCAGGCTTCATTCCCTT 0.9 5624 (4460) csi-miR166 TCGGACCAGGCTTCATTCCCC (4461) 0.86 5625 csi-miR166a TCGGACCAGGCTTCATTCCCCC 0.86 5626 (4462) csi-miR166b TCGGACCAGGCTTCATTCCCGT 0.86 5627 (4463) csi-miR166c TCGGACCAGGCTTCATTCCC (4464) 0.86 5628 csi-miR166d TCGGACCAGGCTTCATTCCCT (4465) 0.9 5629 csi-miR166e TCGGACCAGGCTTCATTCCCC (4466) 0.86 5630 ctr-miR166 TCGGACCAGGCTTCATTCCCCC 0.86 5631 (4467) far-miR166 CCGGACCAGGCTTCATCCCAG (4468) 0.76 5632 flm-miR166 TCGGACCAGGCTTCATCCCCC (4469) 0.81 5633 ghr-miR166a TCGGACCAGGCTTCATTCCCC (4470) 0.86 5634 ghr-miR166b TCGGACCAGGCTTCATTCCCC (4471) 0.86 5635 gma- TCGGACCAGGCTTCATTCCCC (4472) 0.86 5636 miR166a gma- TCGGACCAGGCTTCATTCCCC (4473) 0.86 5637 miR166b gma- TCGGACCAGGCTTCATTCCCC (4474) 0.86 5638 miR166n gma- TCGGACCAGGCTTCATTCCCC (4475) 0.86 5639 miR166o gma- TCGGACCAGGCTTCATTCCCG (4476) 0.86 5640 miR166q gma- TCGGACCAGGCTTCATTCCCT (4477) 0.9 5641 miR166r hvu-miR166 TCGGACCAGGCTTCATTCCCC (4478) 0.86 5642 hvu- TCGGACCAGGCTTCATTCCCC (4479) 0.86 5643 miR166b hvu- TCGGACCAGGCTTCATTCCCC (4480) 0.86 5644 miR166c hvv-miR166 TCGGACCAGGCTTCATTCCCC (4481) 0.86 5645 ini-miR166 TCGGACCAGGCTTCATTCCTC (4482) 0.9 5646 mtr-miR166 TCGGACCAGGCTTCATTCCCC (4483) 0.86 5647 mtr- TCGGACCAGGCTTCATTCCTA (4484) 0.9 5648 miR166b (TCGGACCAGGCTTCATTCCCC (5115) mtr-miR166c TCGGACCAGGCTTCATTCCTC (4485) 0.9 5649 mtr- TCGGGCCAGGCTTCATCCCCC (4486) 0.76 5650 miR166d mtr-miR166e TCGGACCAGGCTTCATTCCCC (4487) 0.86 5651 mtr-miR166f TCGGACCAGGCTTCATTCCTC (4488) 0.9 5652 mtr- TCGGACCAGGCTTCATTCCCC (4489) 0.86 5653 miR166g mtr- TCGGACCAGGCTTCATTCCCC (4490) 0.86 5654 miR166h nsy-miR166 TCGGACCAGGCTTCATTCCCC (4491) 0.86 5655 osa-miR166a TCGGACCAGGCTTCATTCCCC (4492) 0.86 5656 osa-miR166b TCGGACCAGGCTTCATTCCCC (4493) 0.86 5657 osa-miR166c TCGGACCAGGCTTCATTCCCC (4494) 0.86 5658 osa-miR166d TCGGACCAGGCTTCATTCCCC (4495) 0.86 5659 osa-miR166e TCGAACCAGGCTTCATTCCCC (4496) 0.81 5660 osa-miR166f TCGGACCAGGCTTCATTCCCC (4497) 0.86 5661 osa-miR166g TCGGACCAGGCTTCATTCCTC (4498) 0.9 5662 osa-miR166h TCGGACCAGGCTTCATTCCTC (4499) 0.9 5663 osa-miR166i TCGGATCAGGCTTCATTCCTC (4500) 0.86 5664 osa-miR166j TCGGATCAGGCTTCATTCCTC (4501) 0.86 5665 osa-miR166k TCGGACCAGGCTTCAATCCCT (4502) 0.86 5666 osa-miR166l TCGGACCAGGCTTCAATCCCT (4503) 0.86 5667 osa- TCGGACCAGGCTTCATTCCCT (4504) 0.9 5668 miR166m osa-miR166n TCGGACCAGGCTTCATTCCCC (4505) 0.86 5669 pab- TCGGACCAGGCTTCATTCCTC (4506) 0.9 5670 miR166a pab- TCGGACCAGGCTTCATTCCTT (4507) 0.95 5671 miR166b pga-miR166 TCGGACCAGGCTTCATTCCTT (4508) 0.95 5672 ppt-miR166a TCGGACCAGGCTTCATTCCCC (4509) 0.86 5673 ppt-miR166b TCGGACCAGGCTTCATTCCCC (4510) 0.86 5674 ppt-miR166c TCGGACCAGGCTTCATTCCCC (4511) 0.86 5675 ppt-miR166d TCGGACCAGGCTTCATTCCCC (4512) 0.86 5676 ppt-miR166e TCGGACCAGGCTTCATTCCCC (4513) 0.86 5677 ppt-miR166f TCGGACCAGGCTTCATTCCCC (4514) 0.86 5678 ppt-miR166g TCGGACCAGGCTTCATTCCCC (4515) 0.86 5679 ppt-miR166h TCGGACCAGGCTTCATTCCCC (4516) 0.86 5680 ppt-miR166i TCGGACCAGGCTTCATTCCCC (4517) 0.86 5681 ppt-miR166j TCCGGACCAGGCTTCATTCCC (4518) 0.81 5682 ppt-miR166k TCCGGACCAGGCTTCATTCCC (4519) 0.81 5683 ppt-miR166l TCCGGACCAGGCTTCATTCCC (4520) 0.81 5684 pta-miR166a TCGGACCAGGCTTCATTCCCC (4521) 0.86 5685 pta-miR166b TCGGACCAGGCTTCATTCCCC (4522) 0.86 5686 pta-miR166c CCGGACCAGGCTTCATCCCAG (4523) 0.76 5687 ptc-miR166a TCGGACCAGGCTTCATTCCCC (4524) 0.86 5688 ptc-miR166b TCGGACCAGGCTTCATTCCCC (4525) 0.86 5689 ptc-miR166c TCGGACCAGGCTTCATTCCCC (4526) 0.86 5690 ptc-miR166d TCGGACCAGGCTTCATTCCCC (4527) 0.86 5691 ptc-miR166e TCGGACCAGGCTTCATTCCCC (4528) 0.86 5692 ptc-miR166f TCGGACCAGGCTTCATTCCCC (4529) 0.86 5693 ptc-miR166g TCGGACCAGGCTTCATTCCCC (4530) 0.86 5694 ptc-miR166h TCGGACCAGGCTTCATTCCCC (4531) 0.86 5695 ptc-miR166i TCGGACCAGGCTTCATTCCCC (4532) 0.86 5696 ptc-miR166j TCGGACCAGGCTTCATTCCCC (4533) 0.86 5697 ptc-miR166k TCGGACCAGGCTTCATTCCCC (4534) 0.86 5698 ptc-miR166l TCGGACCAGGCTTCATTCCCC (4535) 0.86 5699 ptc- TCGGACCAGGCTTCATTCCCC (4536) 0.86 5700 miR166m ptc-miR166n TCGGACCAGGCTTCATTCCTT (4537) 0.95 5701 ptc-miR166o TCGGACCAGGCTTCATTCCTT (4538) 0.95 5702 ptc-miR166p TCGGACCAGGCTCCATTCCTT (4539) 0.9 5703 ptc-miR166q TCGGACCAGGCTTCATTCCTT (4540) 0.95 5704 pvu-miR166 TCGGACCAGGCTTCATTCCCC (4541) 0.86 5705 pvu- TCGGACCAGGCTTCATTCCCC (4542) 0.86 5706 miR166a rco-miR166a TCGGACCAGGCTTCATTCCCC (4543) 0.86 5707 rco-miR166b TCGGACCAGGCTTCATTCCCC (4544) 0.86 5708 rco-miR166c TCGGACCAGGCTTCATTCCCC (4545) 0.86 5709 rco-miR166d TCGGACCAGGCTTCATTCCCC (4546) 0.86 5710 rco-miR166e TCGGACCAGGCTTCATTCCCC (4547) 0.86 5711 sbi-miR166a TCGGACCAGGCTTCATTCCC (4548) 0.86 5712 sbi-miR166b TCGGACCAGGCTTCATTCCC (4549) 0.86 5713 sbi-miR166c TCGGACCAGGCTTCATTCCC (4550) 0.86 5714 sbi-miR166d TCGGACCAGGCTTCATTCCC (4551) 0.86 5715 sbi-miR166e TCGGACCAGGCTTCAATCCCT (4552) 0.86 5716 sbi-miR166f TCGGACCAGGCTTCATTCCTC (4553) 0.9 5717 sbi-miR166g TCGGACCAGGCTTCAATCCCT (4554) 0.86 5718 sbi-miR166h TCGGACCAGGCTTCATTCCC (4555) 0.86 5719 sbi-miR166i TCGGACCAGGCTTCATTCCC (4556) 0.86 5720 sbi-miR166j TCGGACCAGGCTTCATTCCC (4557) 0.86 5721 sbi-miR166k TCGGACCAGGCTTCATTCCT (4558) 0.9 5722 sly-miR166a TCGGACCAGGCTTCATTCCCC (4559) 0.86 5723 sly-miR166b TCGGACCAGGCTTCATTCCCC (4560) 0.86 5724 smo- TCGGACCAGGCTTCATTCCCC (4561) 0.86 5725 miR166a smo- TCGGACCAGGCTTCATTCCCC (4562) 0.86 5726 miR166b smo- TCGGACCAGGCTTCATTCCCC (4563) 0.86 5727 miR166c sof-miR166 TCGGACCAGGCTTCATTCCCC (4564) 0.86 5728 tae-miR166 CCGGACCAGGCTTCATTCCCA (4565) 0.81 5729 tcc-miR166a TCGGACCAGGCTTCATTCCCC (4566) 0.86 5730 tcc-miR166b TCGGACCAGGCTTCATTCCC (4567) 0.86 5731 tcc-miR166c TCGGACCAGGCTTCATTCCTC (4568) 0.9 5732 tcc-miR166d TCGGACCAGGCTTCATTCCCC (4569) 0.86 5733 vvi-miR166a TCGGACCAGGCTTCATTCC (4570) 0.86 5734 vvi-miR166b TCGGACCAGGCTTCATTCC (4571) 0.86 5735 vvi-miR166c TCGGACCAGGCTTCATTCCCC (4572) 0.86 5736 vvi-miR166d TCGGACCAGGCTTCATTCCCC (4573) 0.86 5737 vvi-miR166e TCGGACCAGGCTTCATTCCCC (4574) 0.86 5738 vvi-miR166f TCGGACCAGGCTTCATTCCCC (4575) 0.86 5739 vvi-miR166g TCGGACCAGGCTTCATTCCCC (4576) 0.86 5740 vvi-miR166h TCGGACCAGGCTTCATTCCCC (4577) 0.86 5741 zma- TCGGACCAGGCTTCATTCCCC (4578) 0.86 5742 miR166a zma- TCGGACCAGGCTTCATTCCC (4579) 0.86 5743 miR166b zma- TCGGACCAGGCTTCATTCCC (4580) 0.86 5744 miR166c zma- TCGGACCAGGCTTCATTCCC (4581) 0.86 5745 miR166d zma- TCGGACCAGGCTTCATTCCC (4582) 0.86 5746 miR166e zma- TCGGACCAGGCTTCATTCCC (4583) 0.86 5747 miR166f zma- TCGGACCAGGCTTCATTCCC (4584) 0.86 5748 miR166g zma- TCGGACCAGGCTTCATTCCC (4585) 0.86 5749 miR166h zma- TCGGACCAGGCTTCATTCCC (4586) 0.86 5750 miR166i zma- TCGGACCAGGCTTCAATCCCT (4587) 0.86 5751 miR166j zma- TCGGACCAGGCTTCAATCCCT (4588) 0.86 5752 miR166k zma- TCGGACCAGGCTTCATTCCTC (4589) 0.9 5753 miR166l zma- TCGGACCAGGCTTCATTCCTC (4590) 0.9 5754 miR166m zma- TCGGACCAGGCTTCAATCCCT (4591) 0.86 5755 miR166n zma- TCGGACCAGGCTTCATTCCCC (4592) 0.86 5756 miR166o zma- TCGGACCAGGCTTCATTCCCC (4593) 0.86 5757 miR166p zma- TCGGACCAGGCTTCATTCCCC (4594) 0.86 5758 miR166q zma- TCGGACCAGGCTTCATTCCCC (4595) 0.86 5759 miR166r zma- TCGGACCAGGCTTCATTCCCC (4596) 0.86 5760 miR166s zma- TCGGACCAGGCTTCATTCCCC (4597) 0.86 5761 miR166t zma- TCGGACCACGCTTCATTCCCC (4598) 0.81 5762 miR166u pta-miR166c aly-miR166a TCGGACCAGGCTTCATTCCCC (4599) 0.81 5763 aly-miR166b TCGGACCAGGCTTCATTCCCC (4600) 0.81 5764 aly-miR166c TCGGACCAGGCTTCATTCCCC (4601) 0.81 5765 aly-miR166d TCGGACCAGGCTTCATTCCCC (4602) 0.81 5766 aly-miR166e TCGGACCAGGCTTCATTCCCC (4603) 0.81 5767 aly-miR166f TCGGACCAGGCTTCATTCCCC (4604) 0.81 5768 aly-miR166g TCGGACCAGGCTTCATTCCCC (4605) 0.81 5769 aqc-miR166a TCGGACCAGGCTTCATTCCTC (4606) 0.81 5770 aqc- TCGGACCAGGCTTCATTCCCC (4607) 0.81 5771 miR166b aqc-miR166c TCGGACCAGGCTTCATTCCT (4608) 0.81 5772 aqc- TCGGACCAGGCTTCATTCCTC (4609) 0.81 5773 miR166d aqc-miR166e TCGGACCAGGCTTCATTCCCC (4610) 0.81 5774 ath-miR166a TCGGACCAGGCTTCATTCCCC (4611) 0.81 5775 ath-miR166b TCGGACCAGGCTTCATTCCCC (4612) 0.81 5776 ath-miR166c TCGGACCAGGCTTCATTCCCC (4613) 0.81 5777 ath-miR166d TCGGACCAGGCTTCATTCCCC (4614) 0.81 5778 ath-miR166e TCGGACCAGGCTTCATTCCCC (4615) 0.81 5779 ath-miR166f TCGGACCAGGCTTCATTCCCC (4616) 0.81 5780 ath-miR166g TCGGACCAGGCTTCATTCCCC (4617) 0.81 5781 bdi-miR166 TCGGACCAGGCTTCATTCCCC (4618) 0.81 5782 bdi-miR166a TCGGACCAGGCTTCATTCCCC (4619) 0.81 5783 bdi-miR166b TCGGACCAGGCTTCATTCCCC (4620) 0.81 5784 bdi-miR166c TCGGACCAGGCTTCATTCCCC (4621) 0.81 5785 bdi-miR166d TCGGACCAGGCTTCATTCCCC (4622) 0.81 5786 bdi-miR166e CTCGGACCAGGCTTCATTCCC (4623) 0.81 5787 bdi-miR166f TCTCGGACCAGGCTTCATTCC (4624) 0.81 5788 bna- TCGGACCAGGCTTCATTCCCC (4625) 0.81 5789 miR166a bna- TCGGACCAGGCTTCATTCCCC (4626) 0.81 5790 miR166b bna- TCGGACCAGGCTTCATTCCCC (4627) 0.81 5791 miR166c bna- TCGGACCAGGCTTCATTCCCC (4628) 0.81 5792 miR166d cpt-miR166 TCGGACCAGGCTTCATTCCC (4629) 0.81 5793 crt-miR166a TCGGACCAGGCTTCATTCCCGT 0.86 5794 (4630) crt-miR166b TCGGACCAGGCTTCATTCCCTT 0.81 5795 (4631) csi-miR166 TCGGACCAGGCTTCATTCCCC (4632) 0.81 5796 csi-miR166a TCGGACCAGGCTTCATTCCCCC 0.81 5797 (4633) csi-miR166b TCGGACCAGGCTTCATTCCCGT 0.86 5798 (4634) csi-miR166c TCGGACCAGGCTTCATTCCC (4635) 0.81 5799 csi-miR166d TCGGACCAGGCTTCATTCCCT (4636) 0.81 5800 csi-miR166e TCGGACCAGGCTTCATTCCCC (4637) 0.81 5801 ctr-miR166 TCGGACCAGGCTTCATTCCCCC 0.81 5802 (4638) far-miR166 CCGGACCAGGCTTCATCCCAG (4639) 1 5803 flm-miR166 TCGGACCAGGCTTCATCCCCC (4640) 0.86 5804 ghr-miR166a TCGGACCAGGCTTCATTCCCC (4641) 0.81 5805 ghr-miR166b TCGGACCAGGCTTCATTCCCC (4642) 0.81 5806 gma- TCGGACCAGGCTTCATTCCCC (4643) 0.81 5807 miR166a gma- TCGGACCAGGCTTCATTCCCC (4644) 0.81 5808 miR166b gma- TCGGACCAGGCTTCATTCCCC (4645) 0.81 5809 miR166n gma- TCGGACCAGGCTTCATTCCCC (4646) 0.81 5810 miR166o gma- TCGGACCAGGCTTCATTCCCG (4647) 0.86 5811 miR166q gma- TCGGACCAGGCTTCATTCCCT (4648) 0.81 5812 miR166r hvu-miR166 TCGGACCAGGCTTCATTCCCC (4649) 0.81 5813 hvu- TCGGACCAGGCTTCATTCCCC (4650) 0.81 5814 miR166b hvu- TCGGACCAGGCTTCATTCCCC (4651) 0.81 5815 miR166c hvv-miR166 TCGGACCAGGCTTCATTCCCC (4652) 0.81 5816 ini-miR166 TCGGACCAGGCTTCATTCCTC (4653) 0.81 5817 mtr-miR166 TCGGACCAGGCTTCATTCCCC (4654) 0.81 5818 mtr- TCGGACCAGGCTTCATTCCTA (4655) 0.81 5819 miR166b mtr-miR166c TCGGACCAGGCTTCATTCCTC (4656) 0.81 5820 mtr- TCGGGCCAGGCTTCATCCCCC (4657) 0.81 5821 miR166d mtr-miR166e TCGGACCAGGCTTCATTCCCC (4658) 0.81 5822 mtr-miR166f TCGGACCAGGCTTCATTCCTC (4659) 0.81 5823 mtr- TCGGACCAGGCTTCATTCCCC (4660) 0.81 5824 miR166g mtr- TCGGACCAGGCTTCATTCCCC (4661) 0.81 5825 miR166h nsy-miR166 TCGGACCAGGCTTCATTCCCC (4662) 0.81 5826 osa-miR166a TCGGACCAGGCTTCATTCCCC (4663) 0.81 5827 osa-miR166b TCGGACCAGGCTTCATTCCCC (4664) 0.81 5828 osa-miR166c TCGGACCAGGCTTCATTCCCC (4665) 0.81 5829 osa-miR166d TCGGACCAGGCTTCATTCCCC (4666) 0.81 5830 osa-miR166e TCGAACCAGGCTTCATTCCCC (4667) 0.76 5831 osa-miR166f TCGGACCAGGCTTCATTCCCC (4668) 0.81 5832 osa-miR166g TCGGACCAGGCTTCATTCCTC (4669) 0.81 5833 osa-miR166h TCGGACCAGGCTTCATTCCTC (4670) 0.81 5834 osa-miR166i TCGGATCAGGCTTCATTCCTC (4671) 0.76 5835 osa-miR166j TCGGATCAGGCTTCATTCCTC (4672) 0.76 5836 osa-miR166k TCGGACCAGGCTTCAATCCCT (4673) 0.76 5837 osa-miR166l TCGGACCAGGCTTCAATCCCT (4674) 0.76 5838 osa- TCGGACCAGGCTTCATTCCCT (4675) 0.81 5839 miR166m osa-miR166n TCGGACCAGGCTTCATTCCCC (4676) 0.81 5840 pab- TCGGACCAGGCTTCATTCCTC (4677) 0.81 5841 miR166a pab- TCGGACCAGGCTTCATTCCTT (4678) 0.81 5842 miR166b pga-miR166 TCGGACCAGGCTTCATTCCTT (4679) 0.81 5843 ppt-miR166a TCGGACCAGGCTTCATTCCCC (4680) 0.81 5844 ppt-miR166b TCGGACCAGGCTTCATTCCCC (4681) 0.81 5845 ppt-miR166c TCGGACCAGGCTTCATTCCCC (4682) 0.81 5846 ppt-miR166d TCGGACCAGGCTTCATTCCCC (4683) 0.81 5847 ppt-miR166e TCGGACCAGGCTTCATTCCCC (4684) 0.81 5848 ppt-miR166f TCGGACCAGGCTTCATTCCCC (4685) 0.81 5849 ppt-miR166g TCGGACCAGGCTTCATTCCCC (4686) 0.81 5850 ppt-miR166h TCGGACCAGGCTTCATTCCCC (4687) 0.81 5851 ppt-miR166i TCGGACCAGGCTTCATTCCCC (4688) 0.81 5852 ppt-miR166j TCCGGACCAGGCTTCATTCCC (4689) 0.86 5853 ppt-miR166k TCCGGACCAGGCTTCATTCCC (4690) 0.86 5854 ppt-miR166l TCCGGACCAGGCTTCATTCCC (4691) 0.86 5855 ppt- TCGGACCAGGCATCATTCCTT (4692) 0.76 5856 miR166m pta-miR166a TCGGACCAGGCTTCATTCCCC (4693) 0.81 5857 pta-miR166b TCGGACCAGGCTTCATTCCCC (4694) 0.81 5858 ptc-miR166a TCGGACCAGGCTTCATTCCCC (4695) 0.81 5859 ptc-miR166b TCGGACCAGGCTTCATTCCCC (4696) 0.81 5860 ptc-miR166c TCGGACCAGGCTTCATTCCCC (4697) 0.81 5861 ptc-miR166d TCGGACCAGGCTTCATTCCCC (4698) 0.81 5862 ptc-miR166e TCGGACCAGGCTTCATTCCCC (4699) 0.81 5863 ptc-miR166f TCGGACCAGGCTTCATTCCCC (4700) 0.81 5864 ptc-miR166g TCGGACCAGGCTTCATTCCCC (4701) 0.81 5865 ptc-miR166h TCGGACCAGGCTTCATTCCCC (4702) 0.81 5866 ptc-miR166i TCGGACCAGGCTTCATTCCCC (4703) 0.81 5867 ptc-miR166j TCGGACCAGGCTTCATTCCCC (4704) 0.81 5868 ptc-miR166k TCGGACCAGGCTTCATTCCCC (4705) 0.81 5869 ptc-miR166l TCGGACCAGGCTTCATTCCCC (4706) 0.81 5870 ptc- TCGGACCAGGCTTCATTCCCC (4707) 0.81 5871 miR166m ptc-miR166n TCGGACCAGGCTTCATTCCTT (4708) 0.81 5872 ptc-miR166o TCGGACCAGGCTTCATTCCTT (4709) 0.81 5873 ptc-miR166p TCGGACCAGGCTCCATTCCTT (4710) 0.76 5874 ptc-miR166q TCGGACCAGGCTTCATTCCTT (4711) 0.81 5875 pvu-miR166 TCGGACCAGGCTTCATTCCCC (4712) 0.81 5876 pvu- TCGGACCAGGCTTCATTCCCC (4713) 0.81 5877 miR166a rco-miR166a TCGGACCAGGCTTCATTCCCC (4714) 0.81 5878 rco-miR166b TCGGACCAGGCTTCATTCCCC (4715) 0.81 5879 rco-miR166c TCGGACCAGGCTTCATTCCCC (4716) 0.81 5880 rco-miR166d TCGGACCAGGCTTCATTCCCC (4717) 0.81 5881 rco-miR166e TCGGACCAGGCTTCATTCCCC (4718) 0.81 5882 sbi-miR166a TCGGACCAGGCTTCATTCCC (4719) 0.81 5883 sbi-miR166b TCGGACCAGGCTTCATTCCC (4720) 0.81 5884 sbi-miR166c TCGGACCAGGCTTCATTCCC (4721) 0.81 5885 sbi-miR166d TCGGACCAGGCTTCATTCCC (4722) 0.81 5886 sbi-miR166e TCGGACCAGGCTTCAATCCCT (4723) 0.76 5887 sbi-miR166f TCGGACCAGGCTTCATTCCTC (4724) 0.81 5888 sbi-miR166g TCGGACCAGGCTTCAATCCCT (4725) 0.76 5889 sbi-miR166h TCGGACCAGGCTTCATTCCC (4726) 0.81 5890 sbi-miR166i TCGGACCAGGCTTCATTCCC (4727) 0.81 5891 sbi-miR166j TCGGACCAGGCTTCATTCCC (4728) 0.81 5892 sbi-miR166k TCGGACCAGGCTTCATTCCT (4729) 0.81 5893 sly-miR166a TCGGACCAGGCTTCATTCCCC (4730) 0.81 5894 sly-miR166b TCGGACCAGGCTTCATTCCCC (4731) 0.81 5895 smo- TCGGACCAGGCTTCATTCCCC (4732) 0.81 5896 miR166a smo- TCGGACCAGGCTTCATTCCCC (4733) 0.81 5897 miR166b smo- TCGGACCAGGCTTCATTCCCC (4734) 0.81 5898 miR166c sof-miR166 TCGGACCAGGCTTCATTCCCC (4735) 0.81 5899 tae-miR166 CCGGACCAGGCTTCATTCCCA (4736) 0.86 5900 tcc-miR166a TCGGACCAGGCTTCATTCCCC (4737) 0.81 5901 tcc-miR166b TCGGACCAGGCTTCATTCCC (4738) 0.81 5902 tcc-miR166c TCGGACCAGGCTTCATTCCTC (4739) 0.81 5903 tcc-miR166d TCGGACCAGGCTTCATTCCCC (4740) 0.81 5904 vvi-miR166a TCGGACCAGGCTTCATTCC (4741) 0.81 5905 vvi-miR166b TCGGACCAGGCTTCATTCC (4742) 0.81 5906 vvi-miR166c TCGGACCAGGCTTCATTCCCC (4743) 0.81 5907 vvi-miR166d TCGGACCAGGCTTCATTCCCC (4744) 0.81 5908 vvi-miR166e TCGGACCAGGCTTCATTCCCC (4745) 0.81 5909 vvi-miR166f TCGGACCAGGCTTCATTCCCC (4746) 0.81 5910 vvi-miR166g TCGGACCAGGCTTCATTCCCC (4747) 0.81 5911 vvi-miR166h TCGGACCAGGCTTCATTCCCC (4748) 0.81 5912 zma- TCGGACCAGGCTTCATTCCCC (4749) 0.81 5913 miR166a zma- TCGGACCAGGCTTCATTCCC (4750) 0.81 5914 miR166b zma- TCGGACCAGGCTTCATTCCC (4751) 0.81 5915 miR166c zma- TCGGACCAGGCTTCATTCCC (4752) 0.81 5916 miR166d zma- TCGGACCAGGCTTCATTCCC (4753) 0.81 5917 miR166e zma- TCGGACCAGGCTTCATTCCC (4754) 0.81 5918 miR166f zma- TCGGACCAGGCTTCATTCCC (4755) 0.81 5919 miR166g zma- TCGGACCAGGCTTCATTCCC (4756) 0.81 5920 miR166h zma- TCGGACCAGGCTTCATTCCC (4757) 0.81 5921 miR166i zma- TCGGACCAGGCTTCAATCCCT (4758) 0.76 5922 miR166j zma- TCGGACCAGGCTTCAATCCCT (4759) 0.76 5923 miR166k zma- TCGGACCAGGCTTCATTCCTC (4760) 0.81 5924 miR166l zma- TCGGACCAGGCTTCATTCCTC (4761) 0.81 5925 miR166m zma- TCGGACCAGGCTTCAATCCCT (4762) 0.76 5926 miR166n zma- TCGGACCAGGCTTCATTCCCC (4763) 0.81 5927 miR166o zma- TCGGACCAGGCTTCATTCCCC (4764) 0.81 5928 miR166p zma- TCGGACCAGGCTTCATTCCCC (4765) 0.81 5929 miR166q zma- TCGGACCAGGCTTCATTCCCC (4766) 0.81 5930 miR166r zma- TCGGACCAGGCTTCATTCCCC (4767) 0.81 5931 miR166s zma- TCGGACCAGGCTTCATTCCCC (4768) 0.81 5932 miR166t zma- TCGGACCACGCTTCATTCCCC (4769) 0.76 5933 miR166u ptc-miR166p aly-miR166a TCGGACCAGGCTTCATTCCCC (4770) 0.86 5934 aly-miR166b TCGGACCAGGCTTCATTCCCC (4771) 0.86 5935 aly-miR166c TCGGACCAGGCTTCATTCCCC (4772) 0.86 5936 aly-miR166d TCGGACCAGGCTTCATTCCCC (4773) 0.86 5937 aly-miR166e TCGGACCAGGCTTCATTCCCC (4774) 0.86 5938 aly-miR166f TCGGACCAGGCTTCATTCCCC (4775) 0.86 5939 aly-miR166g TCGGACCAGGCTTCATTCCCC (4776) 0.86 5940 aqc-miR166a TCGGACCAGGCTTCATTCCTC (4777) 0.9 5941 aqc- TCGGACCAGGCTTCATTCCCC (4778) 0.86 5942 miR166b aqc-miR166c TCGGACCAGGCTTCATTCCT (4779) 0.9 5943 aqc- TCGGACCAGGCTTCATTCCTC (4780) 0.9 5944 miR166d aqc-miR166e TCGGACCAGGCTTCATTCCCC (4781) 0.86 5945 ath-miR166a TCGGACCAGGCTTCATTCCCC (4782) 0.86 5946 ath-miR166b TCGGACCAGGCTTCATTCCCC (4783) 0.86 5947 ath-miR166c TCGGACCAGGCTTCATTCCCC (4784) 0.86 5948 ath-miR166d TCGGACCAGGCTTCATTCCCC (4785) 0.86 5949 ath-miR166e TCGGACCAGGCTTCATTCCCC (4786) 0.86 5950 ath-miR166f TCGGACCAGGCTTCATTCCCC (4787) 0.86 5951 ath-miR166g TCGGACCAGGCTTCATTCCCC (4788) 0.86 5952 bdi-miR166 TCGGACCAGGCTTCATTCCCC (4789) 0.86 5953 bdi-miR166a TCGGACCAGGCTTCATTCCCC (4790) 0.86 5954 bdi-miR166b TCGGACCAGGCTTCATTCCCC (4791) 0.86 5955 bdi-miR166c TCGGACCAGGCTTCATTCCCC (4792) 0.86 5956 bdi-miR166d TCGGACCAGGCTTCATTCCCC (4793) 0.86 5957 bdi-miR166e CTCGGACCAGGCTTCATTCCC (4794) 0.86 5958 bdi-miR166f TCTCGGACCAGGCTTCATTCC (4795) 0.86 5959 bna- TCGGACCAGGCTTCATTCCCC (4796) 0.86 5960 miR166a bna- TCGGACCAGGCTTCATTCCCC (4797) 0.86 5961 miR166b bna- TCGGACCAGGCTTCATTCCCC (4798) 0.86 5962 miR166c bna- TCGGACCAGGCTTCATTCCCC (4799) 0.86 5963 miR166d cpt-miR166 TCGGACCAGGCTTCATTCCC (4800) 0.86 5964 crt-miR166a TCGGACCAGGCTTCATTCCCGT 0.86 5965 (4801) crt-miR166b TCGGACCAGGCTTCATTCCCTT 0.9 5966 (4802) csi-miR166 TCGGACCAGGCTTCATTCCCC (4803) 0.86 5967 csi-miR166a TCGGACCAGGCTTCATTCCCCC 0.86 5968 (4804) csi-miR166b TCGGACCAGGCTTCATTCCCGT 0.86 5969 (4805) csi-miR166c TCGGACCAGGCTTCATTCCC (4806) 0.86 5970 csi-miR166d TCGGACCAGGCTTCATTCCCT (4807) 0.9 5971 csi-miR166e TCGGACCAGGCTTCATTCCCC (4808) 0.86 5972 ctr-miR166 TCGGACCAGGCTTCATTCCCCC 0.86 5973 (4809) far-miR166 CCGGACCAGGCTTCATCCCAG (4810) 0.76 5974 flm-miR166 TCGGACCAGGCTTCATCCCCC (4811) 0.81 5975 ghr-miR166a TCGGACCAGGCTTCATTCCCC (4812) 0.86 5976 ghr-miR166b TCGGACCAGGCTTCATTCCCC (4813) 0.86 5977 gma- TCGGACCAGGCTTCATTCCCC (4814) 0.86 5978 miR166a gma- TCGGACCAGGCTTCATTCCCC (4815) 0.86 5979 miR166b gma- TCGGACCAGGCTTCATTCCCC (4816) 0.86 5980 miR166n gma- TCGGACCAGGCTTCATTCCCC (4817) 0.86 5981 miR166o gma- TCGGACCAGGCTTCATTCCCG (4818) 0.86 5982 miR166q gma- TCGGACCAGGCTTCATTCCCT (4819) 0.9 5983 miR166r hvu-miR166 TCGGACCAGGCTTCATTCCCC (4820) 0.86 5984 hvu- TCGGACCAGGCTTCATTCCCC (4821) 0.86 5985 miR166b hvu- TCGGACCAGGCTTCATTCCCC (4822) 0.86 5986 miR166c hvv-miR166 TCGGACCAGGCTTCATTCCCC (4823) 0.86 5987 ini-miR166 TCGGACCAGGCTTCATTCCTC (4824) 0.9 5988 mtr-miR166 TCGGACCAGGCTTCATTCCCC (4825) 0.86 5989 mtr- TCGGACCAGGCTTCATTCCTA (4826) 0.9 5990 miR166b (TCGGACCAGGCTTCATTCCCC (5116) mtr-miR166c TCGGACCAGGCTTCATTCCTC (4827) 0.9 5991 mtr- TCGGGCCAGGCTTCATCCCCC (4828) 0.76 5992 miR166d mtr-miR166e TCGGACCAGGCTTCATTCCCC (4829) 0.86 5993 mtr-miR166f TCGGACCAGGCTTCATTCCTC (4830) 0.9 5994 mtr- TCGGACCAGGCTTCATTCCCC (4831) 0.86 5995 miR166g mtr- TCGGACCAGGCTTCATTCCCC (4832) 0.86 5996 miR166h nsy-miR166 TCGGACCAGGCTTCATTCCCC (4833) 0.86 5997 osa-miR166a TCGGACCAGGCTTCATTCCCC (4834) 0.86 5998 osa-miR166b TCGGACCAGGCTTCATTCCCC (4835) 0.86 5999 osa-miR166c TCGGACCAGGCTTCATTCCCC (4836) 0.86 6000 osa-miR166d TCGGACCAGGCTTCATTCCCC (4837) 0.86 6001 osa-miR166e TCGAACCAGGCTTCATTCCCC (4838) 0.81 6002 osa-miR166f TCGGACCAGGCTTCATTCCCC (4839) 0.86 6003 osa-miR166g TCGGACCAGGCTTCATTCCTC (4840) 0.9 6004 osa-miR166h TCGGACCAGGCTTCATTCCTC (4841) 0.9 6005 osa-miR166i TCGGATCAGGCTTCATTCCTC (4842) 0.86 6006 osa-miR166j TCGGATCAGGCTTCATTCCTC (4843) 0.86 6007 osa-miR166k TCGGACCAGGCTTCAATCCCT (4844) 0.86 6008 osa-miR166l TCGGACCAGGCTTCAATCCCT (4845) 0.86 6009 osa- TCGGACCAGGCTTCATTCCCT (4846) 0.9 6010 miR166m osa-miR166n TCGGACCAGGCTTCATTCCCC (4847) 0.86 6011 pab- TCGGACCAGGCTTCATTCCTC (4848) 0.9 6012 miR166a pab- TCGGACCAGGCTTCATTCCTT (4849) 0.95 6013 miR166b pga-miR166 TCGGACCAGGCTTCATTCCTT (4850) 0.95 6014 ppt-miR166a TCGGACCAGGCTTCATTCCCC (4851) 0.86 6015 ppt-miR166b TCGGACCAGGCTTCATTCCCC (4852) 0.86 6016 ppt-miR166c TCGGACCAGGCTTCATTCCCC (4853) 0.86 6017 ppt-miR166d TCGGACCAGGCTTCATTCCCC (4854) 0.86 6018 ppt-miR166e TCGGACCAGGCTTCATTCCCC (4855) 0.86 6019 ppt-miR166f TCGGACCAGGCTTCATTCCCC (4856) 0.86 6020 ppt-miR166g TCGGACCAGGCTTCATTCCCC (4857) 0.86 6021 ppt-miR166h TCGGACCAGGCTTCATTCCCC (4858) 0.86 6022 ppt-miR166i TCGGACCAGGCTTCATTCCCC (4859) 0.86 6023 ppt-miR166j TCCGGACCAGGCTTCATTCCC (4860) 0.81 6024 ppt-miR166k TCCGGACCAGGCTTCATTCCC (4861) 0.81 6025 ppt-miR166l TCCGGACCAGGCTTCATTCCC (4862) 0.81 6026 ppt- TCGGACCAGGCATCATTCCTT (4863) 0.9 6027 miR166m pta-miR166a TCGGACCAGGCTTCATTCCCC (4864) 0.86 6028 pta-miR166b TCGGACCAGGCTTCATTCCCC (4865) 0.86 6029 pta-miR166c CCGGACCAGGCTTCATCCCAG (4866) 0.76 6030 ptc-miR166a TCGGACCAGGCTTCATTCCCC (4867) 0.86 6031 ptc-miR166b TCGGACCAGGCTTCATTCCCC (4868) 0.86 6032 ptc-miR166c TCGGACCAGGCTTCATTCCCC (4869) 0.86 6033 ptc-miR166d TCGGACCAGGCTTCATTCCCC (4870) 0.86 6034 ptc-miR166e TCGGACCAGGCTTCATTCCCC (4871) 0.86 6035 ptc-miR166f TCGGACCAGGCTTCATTCCCC (4872) 0.86 6036 ptc-miR166g TCGGACCAGGCTTCATTCCCC (4873) 0.86 6037 ptc-miR166h TCGGACCAGGCTTCATTCCCC (4874) 0.86 6038 ptc-miR166i TCGGACCAGGCTTCATTCCCC (4875) 0.86 6039 ptc-miR166j TCGGACCAGGCTTCATTCCCC (4876) 0.86 6040 ptc-miR166k TCGGACCAGGCTTCATTCCCC (4877) 0.86 6041 ptc-miR166l TCGGACCAGGCTTCATTCCCC (4878) 0.86 6042 ptc- TCGGACCAGGCTTCATTCCCC (4879) 0.86 6043 miR166m ptc-miR166n TCGGACCAGGCTTCATTCCTT (4880) 0.95 6044 ptc-miR166o TCGGACCAGGCTTCATTCCTT (4881) 0.95 6045 ptc-miR166q TCGGACCAGGCTTCATTCCTT (4882) 0.95 6046 pvu-miR166 TCGGACCAGGCTTCATTCCCC (4883) 0.86 6047 pvu- TCGGACCAGGCTTCATTCCCC (4884) 0.86 6048 miR166a rco-miR166a TCGGACCAGGCTTCATTCCCC (4885) 0.86 6049 rco-miR166b TCGGACCAGGCTTCATTCCCC (4886) 0.86 6050 rco-miR166c TCGGACCAGGCTTCATTCCCC (4887) 0.86 6051 rco-miR166d TCGGACCAGGCTTCATTCCCC (4888) 0.86 6052 rco-miR166e TCGGACCAGGCTTCATTCCCC (4889) 0.86 6053 sbi-miR166a TCGGACCAGGCTTCATTCCC (4890) 0.86 6054 sbi-miR166b TCGGACCAGGCTTCATTCCC (4891) 0.86 6055 sbi-miR166c TCGGACCAGGCTTCATTCCC (4892) 0.86 6056 sbi-miR166d TCGGACCAGGCTTCATTCCC (4893) 0.86 6057 sbi-miR166e TCGGACCAGGCTTCAATCCCT (4894) 0.86 6058 sbi-miR166f TCGGACCAGGCTTCATTCCTC (4895) 0.9 6059 sbi-miR166g TCGGACCAGGCTTCAATCCCT (4896) 0.86 6060 sbi-miR166h TCGGACCAGGCTTCATTCCC (4897) 0.86 6061 sbi-miR166i TCGGACCAGGCTTCATTCCC (4898) 0.86 6062 sbi-miR166j TCGGACCAGGCTTCATTCCC (4899) 0.86 6063 sbi-miR166k TCGGACCAGGCTTCATTCCT (4900) 0.9 6064 sly-miR166a TCGGACCAGGCTTCATTCCCC (4901) 0.86 6065 sly-miR166b TCGGACCAGGCTTCATTCCCC (4902) 0.86 6066 smo- TCGGACCAGGCTTCATTCCCC (4903) 0.86 6067 miR166a smo- TCGGACCAGGCTTCATTCCCC (4904) 0.86 6068 miR166b smo- TCGGACCAGGCTTCATTCCCC (4905) 0.86 6069 miR166c sof-miR166 TCGGACCAGGCTTCATTCCCC (4906) 0.86 6070 tae-miR166 CCGGACCAGGCTTCATTCCCA (4907) 0.81 6071 tcc-miR166a TCGGACCAGGCTTCATTCCCC (4908) 0.86 6072 tcc-miR166b TCGGACCAGGCTTCATTCCC (4909) 0.86 6073 tcc-miR166c TCGGACCAGGCTTCATTCCTC (4910) 0.9 6074 tcc-miR166d TCGGACCAGGCTTCATTCCCC (4911) 0.86 6075 vvi-miR166a TCGGACCAGGCTTCATTCC (4912) 0.86 6076 vvi-miR166b TCGGACCAGGCTTCATTCC (4913) 0.86 6077 vvi-miR166c TCGGACCAGGCTTCATTCCCC (4914) 0.86 6078 vvi-miR166d TCGGACCAGGCTTCATTCCCC (4915) 0.86 6079 vvi-miR166e TCGGACCAGGCTTCATTCCCC (4916) 0.86 6080 vvi-miR166f TCGGACCAGGCTTCATTCCCC (4917) 0.86 6081 vvi-miR166g TCGGACCAGGCTTCATTCCCC (4918) 0.86 6082 vvi-miR166h TCGGACCAGGCTTCATTCCCC (4919) 0.86 6083 zma- TCGGACCAGGCTTCATTCCCC (4920) 0.86 6084 miR166a zma- TCGGACCAGGCTTCATTCCC (4921) 0.86 6085 miR166b zma- TCGGACCAGGCTTCATTCCC (4922) 0.86 6086 miR166c zma- TCGGACCAGGCTTCATTCCC (4923) 0.86 6087 miR166d zma- TCGGACCAGGCTTCATTCCC (4924) 0.86 6088 miR166e zma- TCGGACCAGGCTTCATTCCC (4925) 0.86 6089 miR166f zma- TCGGACCAGGCTTCATTCCC (4926) 0.86 6090 miR166g zma- TCGGACCAGGCTTCATTCCC (4927) 0.86 6091 miR166h zma- TCGGACCAGGCTTCATTCCC (4928) 0.86 6092 miR166i zma- TCGGACCAGGCTTCAATCCCT (4929) 0.86 6093 miR166j zma- TCGGACCAGGCTTCAATCCCT (4930) 0.86 6094 miR166k zma- TCGGACCAGGCTTCATTCCTC (4931) 0.9 6095 miR166l zma- TCGGACCAGGCTTCATTCCTC (4932) 0.9 6096 miR166m zma- TCGGACCAGGCTTCAATCCCT (4933) 0.86 6097 miR166n zma- TCGGACCAGGCTTCATTCCCC (4934) 0.86 6098 miR166o zma- TCGGACCAGGCTTCATTCCCC (4935) 0.86 6099 miR166p zma- TCGGACCAGGCTTCATTCCCC (4936) 0.86 6100 miR166q zma- TCGGACCAGGCTTCATTCCCC (4937) 0.86 6101 miR166r zma- TCGGACCAGGCTTCATTCCCC (4938) 0.86 6102 miR166s zma- TCGGACCAGGCTTCATTCCCC (4939) 0.86 6103 miR166t zma- TCGGACCACGCTTCATTCCCC (4940) 0.81 6104 miR166u vvi-miR394b ahy-miR394 TTGGCATTCTGTCCACCTCC (4941) 1 6105 aly-miR394a TTGGCATTCTGTCCACCTCC (4942) 1 6106 aly-miR394b TTGGCATTCTGTCCACCTCC (4943) 1 6107 ath-miR394a TTGGCATTCTGTCCACCTCC (4944) 1 6108 ath-miR394b TTGGCATTCTGTCCACCTCC (4945) 1 6109 bdi-miR394 TTGGCATTCTGTCCACCTCC (4946) 1 6110 csi-miR394 TTGGCATTCTGTCCACCTCC (4947) 1 6111 ghr-miR394 TTGGCATTCTGTCCACCTCC (4948) 1 6112 ghr-miR394a TTGGCATTCTGTCCACCTCC (4949) 1 6113 ghr-miR394b TTGGCATTCTGTCCACCTCC (4950) 1 6114 gma- AGGTGGGCATACTGTCAACT (4951) 0.65 6115 miR394b osa-miR394 TTGGCATTCTGTCCACCTCC (4952) 1 6116 ptc- TTGGCATTCTGTCCACCTCC (4953) 1 6117 miR394a-5p ptc- TTGGCATTCTGTCCACCTCC (4954) 1 6118 miR394b-5p sbi-miR394a TTGGCATTCTGTCCACCTCC (4955) 1 6119 sbi-miR394b TTGGCATTCTGTCCACCTCC (4956) 1 6120 tcc-miR394a TTGGCATTCTGTCCACCTCC (4957) 1 6121 tcc-miR394b TTGGCATTCTGTCCACCTCC (4958) 1 6122 vvi-miR394a TTGGCATTCTGTCCACCTCCAT 1 6123 (4959) vvi-miR394c TTGGCATTCTGTCCACCTCCAT 1 6124 (4960) zma- TTGGCATTCTGTCCACCTCC (4961) 1 6125 miR394a zma- TTGGCATTCTGTCCACCTCC (4962) 1 6126 miR394b zma-miR167u ahy-miR167- TGAAGCTGCCAGCATGATCTT (4963) 0.95 6127 5p aly-miR167a TGAAGCTGCCAGCATGATCTA (4964) 0.95 6128 aly-miR167b TGAAGCTGCCAGCATGATCTA (4965) 0.95 6129 aly- GGTCATGCTCTGACAGCCTCACT 0.5 6130 miR167b* (4966) aly-miR167c TAAGCTGCCAGCATGATCTTG (4967) 0.85 6131 aly-miR167d TGAAGCTGCCAGCATGATCTGG 1 6132 (4968) aqc-miR167 TCAAGCTGCCAGCATGATCTA (4969) 0.9 6133 ath-miR167a TGAAGCTGCCAGCATGATCTA (4970) 0.95 6134 ath-miR167b TGAAGCTGCCAGCATGATCTA (4971) 0.95 6135 ath-miR167c TAAGCTGCCAGCATGATCTTG (4972) 0.85 6136 ath-miR167d TGAAGCTGCCAGCATGATCTGG 1 6137 (4973) ath- TGAAGCTGCCAGCATGATCTG (4974) 1 6138 miR167m bdi-miR167 TGAAGCTGCCAGCATGATCTA (4975) 0.95 6139 bdi-miR167a TGAAGCTGCCAGCATGATCTA (4976) 0.95 6140 bdi-miR167b TGAAGCTGCCAGCATGATCTA (4977) 0.95 6141 bdi-miR167c TGAAGCTGCCAGCATGATCTGA 1 6142 (4978) bdi-miR167d TGAAGCTGCCAGCATGATCTGA 1 6143 (4979) bna- TGAAGCTGCCAGCATGATCTAA 0.95 6144 miR167a (4980) bna- TGAAGCTGCCAGCATGATCTAA 0.95 6145 miR167b (4981) bna- TGAAGCTGCCAGCATGATCTA (4982) 0.95 6146 miR167c bra-miR167a TGAAGCTGCCAGCATGATCTA (4983) 0.95 6147 bra-miR167b TGAAGCTGCCAGCATGATCTA (4984) 0.95 6148 bra-miR167c TGAAGCTGCCAGCATGATCTA (4985) 0.95 6149 bra-miR167d TGAAGCTGCCAGCATGATCTA (4986) 0.95 6150 ccl-miR167a TGAAGCTGCCAGCATGATCTGA 1 6151 (4987) ccl-miR167b TGAAGCTGCCAGCATGATCTGA 1 6152 (4988) cle-miR167 TGAAGCTGCCAGCATGATCTG (4989) 1 6153 csi-miR167a TGAAGCTGCCAGCATGATCTG (4990) 1 6154 csi-miR167b TGAAGCTGCCAGCATGATCTT (4991) 0.95 6155 csi-miR167c TGAAGCTGCCAGCATGATCTG (4992) 1 6156 ctr-miR167 TGAAGCTGCCAGCATGATCTGA 1 6157 (4993) ghr-miR167 TGAAGCTGCCAGCATGATCTA (4994) 0.95 6158 gma- TGAAGCTGCCAGCATGATCTA (4995) 0.95 6159 miR167a gma- TGAAGCTGCCAGCATGATCTA (4996) 0.95 6160 miR167b gma- TGAAGCTGCCAGCATGATCTG (4997) 1 6161 miR167c gma- TGAAGCTGCCAGCATGATCTA (4998) 0.95 6162 miR167d gma- TGAAGCTGCCAGCATGATCTT (4999) 0.95 6163 miR167e gma- TGAAGCTGCCAGCATGATCTT (5000) 0.95 6164 iR167f gma- TGAAGCTGCCAGCATGATCTGA 1 6165 miR167g (5001) gma- TGAAGCTGCCAGCATGATCT (5002) 0.95 6166 miR167n gma- TGAAGCTGCCAGCATGATCTG (5003) 1 6167 miR167o gso-miR167a TGAAGCTGCCAGCATGATCTG (5004) 1 6168 ini-miR167 TGAAGCTGCCAGCATGATCTG (5005) 1 6169 lja-miR167 TGAAGCTGCCAGCATGATCTG (5006) 1 6170 mtr-miR167 TGAAGCTGCCAGCATGATCTA (5007) 0.95 6171 osa-miR167a TGAAGCTGCCAGCATGATCTA (5008) 0.95 6172 osa- ATCATGCATGACAGCCTCATTT 0.65 6173 miR167a* (5009) osa-miR167b TGAAGCTGCCAGCATGATCTA (5010) 0.95 6174 osa-miR167c TGAAGCTGCCAGCATGATCTA (5011) 0.95 6175 osa-miR167d TGAAGCTGCCAGCATGATCTG (5012) 1 6176 osa-miR167e TGAAGCTGCCAGCATGATCTG (5013) 1 6177 osa-miR167f TGAAGCTGCCAGCATGATCTG (5014) 1 6178 osa-miR167g TGAAGCTGCCAGCATGATCTG (5015) 1 6179 osa-miR167h TGAAGCTGCCAGCATGATCTG (5016) 1 6180 osa-miR167i TGAAGCTGCCAGCATGATCTG (5017) 1 6181 osa-miR167j TGAAGCTGCCAGCATGATCTG (5018) 1 6182 osa- TGAAGCTGCCAGCATGATCTG (5019) 1 6183 miR167m osa-miR167n TGAAGCTGCCAGCATGATCTG (5020) 1 6184 pco-miR167 TGAAGCTGCCAGCATGATCTT (5021) 0.95 6185 ppl-miR167a TGAAGCTGCCAGCATGATCTA (5022) 0.95 6186 ppl-miR167b TGAAGCTGCCAGCATGATCTG (5023) 1 6187 ppt-miR167 GGAAGCTGCCAGCATGATCCT (5024) 0.85 6188 ptc-miR167a TGAAGCTGCCAGCATGATCTA (5025) 0.95 6189 ptc-miR167b TGAAGCTGCCAGCATGATCTA (5026) 0.95 6190 ptc-miR167c TGAAGCTGCCAGCATGATCTA (5027) 0.95 6191 ptc-miR167d TGAAGCTGCCAGCATGATCTA (5028) 0.95 6192 ptc-miR167e TGAAGCTGCCAGCATGATCTG (5029) 1 6193 ptc-miR167f TGAAGCTGCCAGCATGATCTT (5030) 0.95 6194 ptc-miR167g TGAAGCTGCCAGCATGATCTT (5031) 0.95 6195 ptc-miR167h TGAAGCTGCCAACATGATCTG (5032) 1 6196 pts-miR167 TGAAGCTGCCAGCATGATCTG (5033) 1 6197 rco-miR167a TGAAGCTGCCAGCATGATCTA (5034) 0.95 6198 rco-miR167b TGAAGCTGCCAGCATGATCTA (5035) 0.95 6199 rco-miR167c TGAAGCTGCCAGCATGATCTGG 1 6200 (5036) sbi-miR167a TGAAGCTGCCAGCATGATCTA (5037) 0.95 6201 sbi-miR167b TGAAGCTGCCAGCATGATCTA (5038) 0.95 6202 sbi-miR167c TGAAGCTGCCAGCATGATCTG (5039) 1 6203 sbi-miR167d TGAAGCTGCCAGCATGATCTG (5040) 1 6204 sbi-miR167e TGAAGCTGCCAGCATGATCTG (5041) 1 6205 sbi-miR167f TGAAGCTGCCAGCATGATCTG (5042) 1 6206 sbi-miR167g TGAAGCTGCCAGCATGATCTG (5043) 1 6207 sbi-miR167h TGAAGCTGCCAGCATGATCTG (5044) 1 6208 sbi-miR167i TGAAGCTGCCAGCATGATCTA (5045) 0.95 6209 sly-miR167 TGAAGCTGCCAGCATGATCTA (5046) 0.95 6210 sof-miR167a TGAAGCTGCCAGCATGATCTG (5047) 1 6211 sof-miR167b TGAAGCTGCCAGCATGATCTG (5048) 1 6212 ssp-miR167 TGAAGCTGCCAGCATGATCTG (5049) 1 6213 ssp-miR167b TGAAGCTGCCAGCATGATCTG (5050) 1 6214 tae-miR167 TGAAGCTGCCAGCATGATCTA (5051) 0.95 6215 tae-miR167b TGAAGCTGACAGCATGATCTA (5052) 0.9 6216 tcc-miR167a TGAAGCTGCCAGCATGATCTA (5053) 0.95 6217 tcc-miR167b TGAAGCTGCCAGCATGATCTA (5054) 0.95 6218 tcc-miR167c TGAAGCTGCCAGCATGATCTT (5055) 0.95 6219 vvi-miR167a TGAAGCTGCCAGCATGATCTG (5056) 1 6220 vvi-miR167b TGAAGCTGCCAGCATGATCTA (5057) 0.95 6221 vvi-miR167c TGAAGCTGCCAGCATGATCTC (5058) 0.95 6222 vvi-miR167d TGAAGCTGCCAGCATGATCTA (5059) 0.95 6223 vvi-miR167e TGAAGCTGCCAGCATGATCTA (5060) 0.95 6224 zma- TGAAGCTGCCAGCATGATCTA (5061) 0.95 6225 miR167a zma- TGAAGCTGCCAGCATGATCTA (5062) 0.95 6226 miR167b zma- GATCATGCTGTGACAGTTTCACT 0.55 6227 miR167b* (5063) zma- TGAAGCTGCCAGCATGATCTA (5064) 0.95 6228 miR167c zma- TGAAGCTGCCAGCATGATCTA (5065) 0.95 6229 miR167d zma- TGAAGCTGCCAGCATGATCTG (5066) 1 6230 miR167e zma- TGAAGCTGCCAGCATGATCTG (5067) 1 6231 miR167f zma- TGAAGCTGCCAGCATGATCTG (5068) 1 6232 miR167g zma- TGAAGCTGCCAGCATGATCTG (5069) 1 6233 miR167h zma- TGAAGCTGCCAGCATGATCTG (5070) 1 6234 miR167i zma- TGAAGCTGCCAGCATGATCTG (5071) 1 6235 miR167j zma- TGAAGCTGCCAGCATGATCTG (5072) 1 6236 miR167k zma- TGAAGCTGCCAGCATGATCTG (5073) 1 6237 miR167l zma- TGAAGCTGCCAGCATGATCTG (5074) 1 6238 miR167m zma- TGAAGCTGCCAGCATGATCTA (5075) 0.95 6239 miR167n zma- TGAAGCTGCCAGCATGATCTA (5076) 0.95 6240 miR167o zma- TGAAGCTGCCAGCATGATCTA (5077) 0.95 6241 miR167p zma- TGAAGCTGCCAGCATGATCTA (5078) 0.95 6242 miR167q zma- TGAAGCTGCCAGCATGATCTA (5079) 0.95 6243 miR167r zma- TGAAGCTGCCAGCATGATCTA (5080) 0.95 6244 miR167s zma- TGAAGCTGCCAGCATGATCTA (5081) 0.95 6245 miR167t gma-miR2119 mtr- TCAAAGGGAGGTGTGGAGTAG 0.76 6246 miR2119 (5082) pvu- TCAAAGGGAGTTGTAGGGGAA 1 6247 miR2119 (5083) osa-miR162a aly-miR162a TCGATAAACCTCTGCATCCAG (5084) 1 6248 aly-miR162b TCGATAAACCTCTGCATCCAG (5085) 1 6249 ath-miR162a TCGATAAACCTCTGCATCCAG (5086) 1 6250 ath-miR162b TCGATAAACCTCTGCATCCAG (5087) 1 6251 bdi-miR162 TCGATAAACCTCTGCATCCGG (5088) 0.95 6252 cpa-miR162a TCGATAAACCTCTGCATCCAG (5089) 1 6253 csi-miR162 TCGATAAACCTCTGCATCCAG (5090) 1 6254 csi-miR162.5 TCGATAAACCTCTGCATCCAG (5091) 1 6255 ghr-miR162a TCGATAAACCTCTGCATCCAG (5092) 1 6256 gma-miR162 TCGATAAACCTCTGCATCCA (5093) 0.95 6257 gma- TCGATAAACCTCTGCATCCAG (5094) 1 6258 miR162a gma- TCGATAAACCTCTGCATCCAG (5095) 1 6259 miR162m llu-miR162 TCGATAAACCTCTGCATCCAG (5096) 1 6260 lsa-miR162 TCGATAAACCTCTGCATCCAG (5097) 1 6261 mdo-miR162 TCGATAAACCTTTGCATCCAG (5098) 0.95 6262 mtr-miR162 TCGATAAACCTCTGCATCCAG (5099) 1 6263 mtr- TCGATAAACCTCTGCATCCA (5100) 0.95 6264 miR162b mtr-miR162c TCGATGAACCGCTGCATCCAG (5101) 0.9 6265 mtr- TCGATAAACCTCTGCATCCAG (5102) 1 6266 miR162d osa-miR162b TCGATAAGCCTCTGCATCCAG (5103) 0.95 6267 osa- TCGATAAGCCTCTGCATCCAG (5104) 0.95 6268 miR162m ptc-miR162a TCGATAAACCTCTGCATCCAG (5105) 1 6269 ptc-miR162b TCGATAAACCTCTGCATCCAG (5106) 1 6270 ptc-miR162c TCGATAAACCTCTGCATCCAG (5107) 1 6271 rco-miR162 TCGATAAACCTCTGCATCCAG (5108) 1 6272 sbi-miR162 TCGATAAACCTCTGCATCCAG (5109) 1 6273 sly-miR162 TCGATAAACCTCTGCATCCAG (5110) 1 6274 tcc-miR162 TCGATAAACCTCTGCATCCAG (5111) 1 6275 vvi-miR162 TCGATAAACCTCTGCATCCAG (5112) 1 6276 zma-miR162 TCGATAAACCTCTGCATCCA (5113) 0.95 6277 zma- TCGATAAACCTCTGCATCCAG (5114) 1 6278 miR162b

Example 3 Identification of miRNAs Associated with Abiotic Stress and Target Prediction Using Bioinformatics Tools

Small RNAs that are potentially associated with improved abiotic or biotic stress tolerance can be identified by proprietary computational algorithms that analyze RNA expression profiles alongside publicly available gene and protein databases. A high throughput screening is performed on microarrays loaded with miRNAs that were found to be differential under multiple stress and optimal environmental conditions and in different plant tissues. The initial trait-associated miRNAs are later validated by quantitative Real Time PCR (qRT-PCR).

Target prediction—homologous or orthologous genes to the genes of interest in soybean and/or arabidopsis are found through a proprietary tool that analyzes publicly available genomic as well as expression and gene annotation databases from multiple plant species. Homologous and orthologous protein and nucleotide sequences of target genes of the small RNA sequences of the invention, were found using BLAST having at least 70% identity on at least 60% of the entire master gene length, and are summarized in Tables 9-10 below.

TABLE 9 Target Genes of upregulated Small RNA Molecules Associated with Abiotic Stress Tolerance in Soybean Plants. Mir Homolog Nucleotide Binding NCBI NCBI GI Protein Nucleotide Mir Name Position Accession number Identity Organism Seq id no: Seq id no: aqc-miR159 305-325 XP_003551790 356567161 1 Glycine max 6315 8130 334-354 XP_003554567 356572827 1 Glycine max 6316 8131 XP_003521605 356505654 0.9723 Glycine max 6317 8132 XP_003521606 356505656 0.9723 Glycine max 6318 8133 XP_003626013 357511448 0.8949 Medicago truncatula 6319 8134 XP_002272575 225437676 0.8423 Vitis vinifera 6320 8135 CBI37003 270254427 0.8409 Vitis vinifera 6321 8136 XP_002515224 255761086 0.8382 Ricinus communis 6322 CAN71135 147786943 0.8354 Vitis vinifera 6323 8137 XP_002301535 255761085 0.8313 Populus trichocarpa 6324 ADF30190 294713705 0.8119 Brassica napus 6325 8138 124-144 XP_003543825 356550908 1 Glycine max 6326 8139 752-772 XP_003543825 356550908 1 Glycine max 6327 8140 XP_003556814 356577399 0.813 Glycine max 6328 8141 360-380 XP_003549039 356561539 1 Glycine max 6329 8142 XP_003533180 356529191 0.8282 Glycine max 6330 8143 614-634 XP_003541563 356546291 1 Glycine max 6331 8144 XP_003545791 356554924 0.805 Glycine max 6332 8145 905-925 XP_003556814 356577399 1 Glycine max 6333 8146 XP_003543825 356550908 0.8659 Glycine max 6334 8147 141-161 XP_003518351 356499037 1 Glycine max 6335 8148 2016-2036 XP_003538988 356541033 1 Glycine max 6336 8149 XP_003607189 357473808 0.7407 Medicago truncatula 6337 8150 XP_003604038 357467506 0.7035 Medicago truncatula 6338 8151 839-859 XP_003526354 356515330 1 Glycine max 6339 8152 XP_003523913 356510372 0.9333 Glycine max 6340 8153 842-862 XP_003523913 356510372 1 Glycine max 6341 8154 XP_003526354 356515330 0.9333 Glycine max 6342 8155 926-946 XP_003545791 356554924 1 Glycine max 6343 8156 XP_003541563 356546291 0.8662 Glycine max 6344 8157 ath-miR159b 334-354 XP_003554567 356572827 1 Glycine max 6345 8158 XP_003521605 356505654 0.9723 Glycine max 6346 8159 XP_003521606 356505656 0.9723 Glycine max 6347 8160 XP_003626013 357511448 0.8949 Medicago truncatula 6348 8161 XP_002272575 225437676 0.8423 Vitis vinifera 6349 8162 CBI37003 270254427 0.8409 Vitis vinifera 6350 8163 XP_002515224 255761086 0.8382 Ricinus communis 6351 CAN71135 147786943 0.8354 Vitis vinifera 6352 8164 XP_002301535 255761085 0.8313 Populus trichocarpa 6353 ADF30190 294713705 0.8119 Brassica napus 6354 8165 405-425 XP_003542140 356547479 1 Glycine max 6355 8166 XP_003546908 356557204 0.8696 Glycine max 6356 8167 305-325 XP_003541823 356546825 1 Glycine max 6357 8168 124-144 XP_003543825 356550908 1 Glycine max 6358 8169 XP_003556814 356577399 0.813 Glycine max 6359 8170 839-859 XP_003526354 356515330 1 Glycine max 6360 8171 XP_003523913 356510372 0.9333 Glycine max 6361 8172 2079-2099 XP_003538988 356541033 1 Glycine max 6362 8173 XP_003607189 357473808 0.7407 Medicago truncatula 6363 8174 XP_003604038 357467506 0.7035 Medicago truncatula 6364 8175 614-634 XP_003541563 356546291 1 Glycine max 6365 8176 XP_003545791 356554924 0.805 Glycine max 6366 8177 905-925 XP_003556814 356577399 1 Glycine max 6367 8178 XP_003543825 356550908 0.8659 Glycine max 6368 8179 926-946 XP_003545791 356554924 1 Glycine max 6369 8180 XP_003541563 356546291 0.8662 Glycine max 6370 8181 842-862 XP_003523913 356510372 1 Glycine max 6371 8182 XP_003526354 356515330 0.9333 Glycine max 6372 8183 ath-miR159c 251-271 NP_001236122 351727005 1 Glycine max 6373 8184 ACU21384 255642238 0.7676 Glycine max 6374 8185 46-66 XP_003519140 356500640 1 Glycine max 6375 8186 XP_003549552 356562588 0.8757 Glycine max 6376 8187 XP_003610353 357480134 0.9006 Medicago truncatula 6377 8188 817-837 XP_003525997 356514606 1 Glycine max 6378 8189 XP_003540066 356543230 0.8441 Glycine max 6379 8190 289-309 XP_003518627 356499601 1 Glycine max 6380 8191 XP_003542153 356547506 0.9478 Glycine max 6381 8192 ADN33938 307136081 0.7937 Cucumis melo 6382 8193 subsp. melo XP_002518919 255761086 0.7755 Ricinus communis 6383 XP_002279642 225426567 0.7755 Vitis vinifera 6384 8194 XP_002870592 297853636 0.7664 Arabidopsis lyrata 6385 subsp. lyrata NP_199024 30693991 0.7642 Arabidopsis thaliana 6386 8195 AAM63843 21405504 0.7596 Arabidopsis thaliana 6387 8196 XP_002299422 255761085 0.7528 Populus trichocarpa 6388 XP_002303695 255761085 0.7574 Populus trichocarpa 6389 124-144 XP_003543825 356550908 1 Glycine max 6390 8197 XP_003556814 356577399 0.813 Glycine max 6391 8198 461-481 XP_003542153 356547506 1 Glycine max 6392 8199 XP_003518627 356499601 0.9436 Glycine max 6393 8200 1162-1182 XP_003531162 356525093 1 Glycine max 6394 8201 XP_003524148 356510852 0.7692 Glycine max 6395 8202 839-859 XP_003526354 356515330 1 Glycine max 6396 8203 XP_003523913 356510372 0.9333 Glycine max 6397 8204 495-515 XP_003524148 356510852 1 Glycine max 6398 8205 XP_003531162 356525093 0.7762 Glycine max 6399 8206 949-969 XP_003547199 356557800 1 Glycine max 6400 8207 XP_003541668 356546507 0.8748 Glycine max 6401 8208 614-634 XP_003541563 356546291 1 Glycine max 6402 8209 XP_003545791 356554924 0.805 Glycine max 6403 8210 905-925 XP_003556814 356577399 1 Glycine max 6404 8211 XP_003543825 356550908 0.8659 Glycine max 6405 8212 2016-2036 XP_003538988 356541033 1 Glycine max 6406 8213 XP_003607189 357473808 0.7407 Medicago truncatula 6407 8214 XP_003604038 357467506 0.7035 Medicago truncatula 6408 8215 1330-1350 XP_003541668 356546507 1 Glycine max 6409 8216 XP_003547199 356557800 0.8383 Glycine max 6410 8217 842-862 XP_003523913 356510372 1 Glycine max 6411 8218 XP_003526354 356515330 0.9333 Glycine max 6412 8219 926-946 XP_003545791 356554924 1 Glycine max 6413 8220 XP_003541563 356546291 0.8662 Glycine max 6414 8221 ath-miRf10240-akr 288-307 AES96257 357486022 1 Medicago truncatula 6415 8222 XP_003613299 357486022 1 Medicago truncatula 6416 8223 XP_003517816 356497943 0.9446 Glycine max 6417 8224 XP_003519545 356501464 0.9418 Glycine max 6418 8225 XP_003517817 356497945 0.9446 Glycine max 6419 8226 XP_003530656 356524070 0.8809 Glycine max 6420 8227 XP_003551180 356565911 0.8753 Glycine max 6421 8228 XP_002531401 255761086 0.8421 Ricinus communis 6422 XP_003628672 357516766 0.8504 Medicago truncatula 6423 8229 XP_002266222 225424743 0.8393 Vitis vinifera 6424 8230 CAN76955 147776916 0.8338 Vitis vinifera 6425 8231 1503-1522 XP_003547951 356559326 1 Glycine max 6426 8232 ACU23369 255645751 0.998 Glycine max 6427 8233 XP_003547950 356559324 0.8408 Glycine max 6428 8234 ACU18289 255635883 0.8388 Glycine max 6429 8235 XP_003629354 357518130 0.7531 Medicago truncatula 6430 8236 XP_002531509 255761086 0.7204 Ricinus communis 6431 ABK95760 118487875 0.7245 Populus trichocarpa 6432 8237 XP_003612122 357483670 0.7327 Medicago truncatula 6433 8238 XP_002333330 255761085 0.7122 Populus trichocarpa 6434 XP_002310843 255761085 0.702 Populus trichocarpa 6435 115-134 AES78100 357503186 1 Medicago truncatula 6436 8239 XP_003621882 357503186 1 Medicago truncatula 6437 8240  95-114 AET03830 357518130 1 Medicago truncatula 6438 8241 XP_003547951 356559326 0.811 Glycine max 6439 8242 487-506 NP_001238238 351721588 1 Glycine max 6440 8243 NP_001237618 351725834 0.9947 Glycine max 6441 8244 ACU16478 255632239 0.9679 Glycine max 6442 8245 XP_003519150 356500660 0.7968 Glycine max 6443 8246 149-168 XP_003531007 356524781 1 Glycine max 6444 8247 XP_003528405 356519488 0.9391 Glycine max 6445 8248 XP_003608343 357476114 0.8746 Medicago truncatula 6446 8249 XP_002264303 225429239 0.7885 Vitis vinifera 6447 8250 CBI35448 270252044 0.7885 Vitis vinifera 6448 XP_002518318 255761086 0.767 Ricinus communis 6449 NP_201251 145359643 0.7742 Arabidopsis thaliana 6450 8251 XP_002866616 297853636 0.7778 Arabidopsis lyrata 6451 subsp. lyrata ABK95206 118486740 0.7527 Populus trichocarpa 6452 8252 XP_002313210 255761085 0.7491 Populus trichocarpa 6453 214-233 XP_003525932 356514476 1 Glycine max 6454 8253 700-719 XP_003523287 356509093 1 Glycine max 6455 8254 XP_003526789 356516210 0.9406 Glycine max 6456 8255 XP_003518282 356498893 0.7406 Glycine max 6457 8256 XP_003544853 356553012 0.7406 Glycine max 6458 8257 ath-miRf10368-akr 587-606 XP_003543893 356551052 1 Glycine max 6459 8258 XP_003554723 356573142 0.9659 Glycine max 6460 8259 ACJ85427 357496652 0.8447 Medicago truncatula 6461 8260 XP_003531841 356526470 0.8333 Glycine max 6462 8261 XP_003552550 356568703 0.8106 Glycine max 6463 8262 XP_002284521 225457306 0.7765 Vitis vinifera 6464 8263 XP_002323884 255761085 0.7765 Populus trichocarpa 6465 XP_002284184 225452935 0.7803 Vitis vinifera 6466 8264 XP_002306045 255761085 0.7424 Populus trichocarpa 6467 XP_002526069 255761086 0.7424 Ricinus communis 6468 456-475 XP_003539013 356541084 1 Glycine max 6469 8265 XP_003540676 356544475 0.8768 Glycine max 6470 8266 XP_003539012 356541082 0.7183 Glycine max 6471 8267 685-704 NP_001235161 351721419 1 Glycine max 6472 8268 XP_003548144 356559717 0.9705 Glycine max 6473 8269 XP_003548143 356559715 0.7785 Glycine max 6474 8270 BAB86923 19911192 0.711 Vigna angularis 6475 8271 685-704 NP_001235161 351721419 1 Glycine max 6476 8272 3330-3349 XP_003551446 356566453 1 Glycine max 6477 347-366 XP_003540896 356544921 1 Glycine max 6478 8273 XP_003533477 356529802 0.7278 Glycine max 6479 8274 XP_003607171 357473772 0.8086 Medicago truncatula 6480 8275 XP_002533189 255761086 0.7412 Ricinus communis 6481 XP_002279051 225428040 0.7305 Vitis vinifera 6482 8276 XP_003522637 356507769 0.7466 Glycine max 6483 8277 XP_003526942 356516520 0.7035 Glycine max 6484 8278  88-107 XP_002533189 255761086 1 Ricinus communis 6485 XP_003540896 356544921 0.7035 Glycine max 6486 8279 XP_002270345 225457886 0.7008 Vitis vinifera 6487 8280 589-608 XP_003518505 356499351 1 Glycine max 6488 8281 75-94 XP_002312957 255761085 1 Populus trichocarpa 6489 XP_002306186 255761085 0.9181 Populus trichocarpa 6490 CAN67732 147790359 0.8836 Vitis vinifera 6491 8282 682-701 XP_003556840 356577453 1 Glycine max 6492 8283 XP_003519003 356500365 0.7261 Glycine max 6493 8284 XP_003542320 356547854 0.7261 Glycine max 6494 8285 220-239 XP_003527967 356518600 1 Glycine max 6495 8286 XP_003523399 356509321 0.7599 Glycine max 6496 8287 1834-1853 XP_003539709 356542508 1 Glycine max 6497 8288 XP_003538207 356539441 0.9136 Glycine max 6498 8289 XP_003606389 357472208 0.8066 Medicago truncatula 6499 8290 NP_001238028 351722912 0.7617 Glycine max 6500 8291 XP_003543464 356550174 0.7375 Glycine max 6501 8292 XP_003539710 356542510 0.8394 Glycine max 6502 8293 XP_002530284 255761086 0.7081 Ricinus communis 6503  0-19 AES82704 357512394 1 Medicago truncatula 6504 XP_003521781 356506009 0.8339 Glycine max 6505 CBI28651 270241399 0.747 Vitis vinifera 6506 XP_002267871 225430630 0.7263 Vitis vinifera 6507 XP_003553769 356571203 0.8332 Glycine max 6508 1104-1123 XP_003518991 356500340 1 Glycine max 6509 8294 XP_003535145 356533178 0.8841 Glycine max 6510 8295 XP_003535146 356533180 0.8509 Glycine max 6511 8296 439-458 XP_003526441 356515505 1 Glycine max 6512 8297 XP_003522648 356507791 0.9351 Glycine max 6513 8298 XP_003522647 356507789 0.8643 Glycine max 6514 8299 XP_002284618 225430104 0.7935 Vitis vinifera 6515 8300 XP_003526440 356515503 0.8525 Glycine max 6516 8301 XP_002284775 225445329 0.7788 Vitis vinifera 6517 8302 XP_002515572 255761086 0.7699 Ricinus communis 6518 AES73734 357466396 0.7876 Medicago truncatula 6519 8303 1245-1264 NP_001238286 351722970 1 Glycine max 6520 8304 BAG72094 207367147 0.9584 Glycine max 6521 8305 ACE79196 190586158 0.9558 Glycine max 6522 8306 ACE79197 190586160 0.9019 Glycine max 6523 8307 XP_003555766 356575272 0.8983 Glycine max 6524 8308 P93673 0.8453 Lathyrus sativus 6525 P15001 0.8453 Pisum sativum 6526 AES61525 357441992 0.8426 Medicago truncatula 6527 8309 XP_002278610 225450404 0.7772 Vitis vinifera 6528 8310 ACC60969 183239021 0.7763 Vitis riparia 6529 177-196 XP_002306186 255761085 1 Populus trichocarpa 6530 XP_002312957 255761085 0.7553 Populus trichocarpa 6531 439-458 XP_003522648 356507791 1 Glycine max 6532 8311 XP_003526441 356515505 0.9351 Glycine max 6533 8312 NP_189078 42565156 0.7168 Arabidopsis thaliana 6534 8313 200-219 XP_003597608 357454654 1 Medicago truncatula 6535 8314 ABN08398 357454654 1 Medicago truncatula 6536 8315 XP_003546676 356556729 0.8954 Glycine max 6537 8316 XP_003543598 356550445 0.8942 Glycine max 6538 8317 XP_003531618 356526020 0.8609 Glycine max 6539 8318 XP_003529875 356522481 0.8537 Glycine max 6540 8319 CAA07236 316995680 0.849 Cicer arietinum 6541 8320 ABK96254 118488889 0.8121 Populus trichocarpa × 6542 8321 Populus deltoides CAC44500 14970838 0.8157 Fragaria × ananassa 6543 8322 XP_002327432 255761085 0.8109 Populus trichocarpa 6544 ABV32545 157313303 0.824 Prunus persica 6545 8323 20-39 XP_003538511 356540064 1 Glycine max 6546 XP_003540789 356544707 0.9546 Glycine max 6547 AES88424 357471884 0.8454 Medicago truncatula 6548 XP_002328167 255761085 0.78 Populus trichocarpa 6549 XP_002529065 255761086 0.7791 Ricinus communis 6550 XP_002269920 225436294 0.7732 Vitis vinifera 6551 1726-1745 XP_003538207 356539441 1 Glycine max 6552 8324 XP_003539709 356542508 0.901 Glycine max 6553 8325 AES88586 357472208 0.8038 Medicago truncatula 6554 8326 XP_003538208 356539443 0.8362 Glycine max 6555 8327 ath-miRf10763-akr 137-156 XP_003540953 356545038 1 Glycine max 6556 8328 XP_003537828 356538677 0.9174 Glycine max 6557 8329 246-265 ACU17625 255634523 1 Glycine max 6558 8330 XP_003520499 356503402 0.9227 Glycine max 6559 8331 XP_003554133 356571948 0.8886 Glycine max 6560 8332 448-467 XP_003555015 356573740 1 Glycine max 6561 8333 145-164 XP_002267145 225438252 1 Vitis vinifera 6562 8334 XP_003517356 356497006 0.8121 Glycine max 6563 8335 XP_003539260 356541595 0.8166 Glycine max 6564 8336 XP_003611551 357482528 0.7919 Medicago truncatula 6565 8337 NP_566927 42565786 0.7696 Arabidopsis thaliana 6566 8338 XP_002877705 297853636 0.774 Arabidopsis lyrata 6567 subsp. lyrata XP_002285420 225458889 0.8076 Vitis vinifera 6568 8339 AAM61258 21403407 0.7673 Arabidopsis thaliana 6569 8340 NP_201393 30698164 0.7405 Arabidopsis thaliana 6570 8341 AAL32554 17064799 0.7383 Arabidopsis thaliana 6571 8342 523-542 XP_003524815 356512212 1 Glycine max 6572 8343 356528136 0.981 Glycine max 6573 136-155 XP_003520083 356502552 1 Glycine max 6574 8344 XP_003517797 356497905 0.8522 Glycine max 6575 8345  993-1012 AET34792 356650815 1 Pisum sativum 6576 8346 AET34790 356650811 0.9979 Pisum sativum 6577 8347 AET34786 356650803 0.9358 Medicago truncatula 6578 8348 XP_003625012 357509446 0.9337 Medicago truncatula 6579 8349 AET34796 356650823 0.8654 Glycine max 6580 8350 XP_003521136 356504705 0.8551 Glycine max 6581 8351 AEM62768 343794555 0.8778 Lotus japonicus 6582 8352 XP_002275980 225441316 0.8282 Vitis vinifera 6583 8353 CAN80112 147852377 0.8282 Vitis vinifera 6584 8354 XP_002308905 255761085 0.824 Populus trichocarpa 6585 223-242 XP_003520499 356503402 1 Glycine max 6586 8355 ACU17625 255634523 0.9878 Glycine max 6587 8356 217-236 XP_003526336 356515293 1 Glycine max 6588 8357 XP_003540834 356544797 0.7611 Glycine max 6589 8358 241-260 XP_003519685 356501746 1 Glycine max 6590 8359 ACU23918 255646896 0.9948 Glycine max 6591 8360 XP_003545065 356553441 0.8093 Glycine max 6592 8361 26-45 CBI33098 270247736 1 Vitis vinifera 6593 8362 237-256 AAF73257 8132346 1 Pisum sativum 6594 8363 XP_003523778 356510099 0.9489 Glycine max 6595 8364 XP_003527981 356518628 0.9382 Glycine max 6596 8365 CAN70091 123701299 0.8817 Vitis vinifera 6597 8366 Q40517 0.8817 Nicotiana tabacum 6598 NP_001233761 350539780 0.8737 Solanum lycopersicum 6599 8367 Q40884 0.8737 Petunia × hybrida 6600 XP_002302017 255761085 0.871 Populus trichocarpa 6601 XP_002510434 255761086 0.8737 Ricinus communis 6602 360-379 XP_003539534 356542151 1 Glycine max 6603 8368 XP_003543335 356549913 0.8571 Glycine max 6604 8369 26-45 XP_003601902 357463240 1 Medicago truncatula 6605 8370 XP_003538598 356540240 0.8571 Glycine max 6606 8371 XP_003551994 356567575 0.8521 Glycine max 6607 8372 XP_003531333 356525440 0.8045 Glycine max 6608 8373 XP_003525038 356512665 0.797 Glycine max 6609 8374 XP_002530039 255761086 0.7845 Ricinus communis 6610 XP_002314593 255761085 0.7694 Populus trichocarpa 6611 XP_002282407 225424658 0.7669 Vitis vinifera 6612 8375 XP_002311761 255761085 0.7669 Populus trichocarpa 6613 CBI16790 270228074 0.7569 Vitis vinifera 6614 502-521 NP_001234991 351723886 1 Glycine max 6615 8376 XP_003552315 356568227 0.9954 Glycine max 6616 8377 XP_003543429 356550102 0.9815 Glycine max 6617 8378 NP_001236946 351721215 0.9769 Glycine max 6618 8379 XP_003596822 357453090 0.9444 Medicago truncatula 6619 8380 XP_003611340 357482108 0.9444 Medicago truncatula 6620 8381 XP_003600923 357461282 0.9444 Medicago truncatula 6621 8382 NP_001237030 351723638 0.9306 Glycine max 6622 8383 ACG24758 195605855 0.875 Zea mays 6623 8384 ACG33436 195623211 0.875 Zea mays 6624 8385 129-148 ACU17625 255634523 1 Glycine max 6625 8386 290-309 XP_003548849 356561151 1 Glycine max 6626 8387 XP_003519868 356502117 0.8445 Glycine max 6627 8388 XP_003629318 357518058 0.7456 Medicago truncatula 6628 8389 237-256 XP_003527981 356518628 1 Glycine max 6629 8390 AAF73257 8132346 0.9407 Pisum sativum 6630 8391 ABA00652 74231015 0.8814 Gossypium hirsutum 6631 8392 37-56 XP_003547100 356557592 1 Glycine max 6632 8393 XP_003541782 356546742 0.862 Glycine max 6633 8394 XP_003593272 357445988 0.7085 Medicago truncatula 6634 8395 248-267 ACU23918 255646896 1 Glycine max 6635 8396 XP_003519685 356501746 0.9948 Glycine max 6636 8397 ath-miRf11042-akr 757-777 XP_003629993 357519408 1 Medicago truncatula 6637 8398 ACJ84083 217071445 0.9917 Medicago truncatula 6638 8399 NP_001235375 351727608 0.8595 Glycine max 6639 8400 NP_001237170 351727706 0.8264 Glycine max 6640 8401 CAA10134 3860332 0.8347 Cicer arietinum 6641 8402 XP_002298184 255761085 0.719 Populus trichocarpa 6642 NP_001237531 351723330 0.7107 Glycine max 6643 8403 XP_003523409 356509341 0.7107 Glycine max 6644 8404 357519363 1 Medicago truncatula 6645 361-381 XP_003592180 357443804 1 Medicago truncatula 6646 8405 XP_003556131 356576015 0.7984 Glycine max 6647 8406 XP_003535589 356534086 0.8 Glycine max 6648 8407 XP_002329680 255761085 0.777 Populus trichocarpa 6649 XP_002276766 225464654 0.7475 Vitis vinifera 6650 8408 CBI22616 270233919 0.7213 Vitis vinifera 6651 8409 1042-1062 XP_003616507 357492436 1 Medicago truncatula 6652 8410 XP_003518398 356499134 0.8512 Glycine max 6653 8411 XP_003545247 356553814 0.8492 Glycine max 6654 8412 XP_003537472 356537955 0.7738 Glycine max 6655 8413 XP_003552860 356569339 0.7718 Glycine max 6656 8414 XP_002524242 255761086 0.7321 Ricinus communis 6657 XP_002277622 225449359 0.7063 Vitis vinifera 6658 8415 520-540 XP_003534554 356531980 1 Glycine max 6659 XP_003552402 356568406 0.9572 Glycine max 6660 XP_003548671 356560791 0.7736 Glycine max 6661 XP_003528847 356520393 0.7732 Glycine max 6662 XP_003623999 357507420 0.7898 Medicago truncatula 6663 XP_003627563 357514548 0.7385 Medicago truncatula 6664 XP_002276245 225454279 0.7367 Vitis vinifera 6665 XP_002511882 255761086 0.7349 Ricinus communis 6666 CAN74059 147789689 0.7228 Vitis vinifera 6667 1412-1432 XP_003556131 356576015 1 Glycine max 6668 8416 XP_003592180 357443804 0.8203 Medicago truncatula 6669 8417 csi-miR3948 43-66 XP_003547789 356558998 1 Glycine max 6670 8418 XP_003531955 356526700 0.9164 Glycine max 6671 8419 ACU23577 255646183 0.9078 Glycine max 6672 8420 209-232 XP_003540784 356544697 1 Glycine max 6673 8421 XP_003539180 356541429 0.8869 Glycine max 6674 8422 40-63 XP_003556473 356576709 1 Glycine max 6675 8423 XP_003535369 356533638 0.8958 Glycine max 6676 8424 47-70 XP_003527776 356518214 1 Glycine max 6677 8425  77-100 XP_003550061 356563623 1 Glycine max 6678 8426 XP_003525811 356514233 0.9621 Glycine max 6679 8427 XP_002310135 255761085 0.7098 Populus trichocarpa 6680 XP_002523601 255761086 0.7035 Ricinus communis 6681 173-196 XP_003525811 356514233 1 Glycine max 6682 8428 XP_003550061 356563623 0.9591 Glycine max 6683 8429 208-231 XP_003542594 356548408 1 Glycine max 6684 8430 XP_003537062 356537086 0.7495 Glycine max 6685 8431 179-202 XP_003539180 356541429 1 Glycine max 6686 8432 XP_003540784 356544697 0.8923 Glycine max 6687 8433 209-232 BAD18437 47077005 1 Homo sapiens 6688 8434 XP_003522605 356507705 1 Glycine max 6689 8435 XP_003526400 356515423 0.9316 Glycine max 6690 8436 232-255 XP_003537062 356537086 1 Glycine max 6691 8437 XP_003542594 356548408 0.7416 Glycine max 6692 8438 ghr-miR2950 37-57 XP_003518096 356498514 1 Glycine max 6693 8439 XP_003537196 356537360 0.9379 Glycine max 6694 8440 XP_003516696 356495666 0.7495 Glycine max 6695 8441 909-929 XP_003529456 356521627 1 Glycine max 6696 8442 XP_003556690 356577148 0.8891 Glycine max 6697 8443 XP_003601600 357462636 0.8073 Medicago truncatula 6698 8444 XP_003601595 357462626 0.8073 Medicago truncatula 6699 8445 XP_003601599 357462634 0.8073 Medicago truncatula 6700 8446 XP_003601596 357462628 0.8036 Medicago truncatula 6701 8447 XP_003607816 357475060 0.7764 Medicago truncatula 6702 8448 XP_003601601 357462638 0.7982 Medicago truncatula 6703 8449 XP_003538519 356540080 0.7436 Glycine max 6704 8450 XP_002303974 255761085 0.7491 Populus trichocarpa 6705 1446-1466 BAG68945 197209811 1 Lotus japonicus 6706 8451 XP_003549436 356562352 0.881 Glycine max 6707 8452 AAC09468 6503252 0.8541 Pisum sativum 6708 8453 XP_003541616 356546403 0.8824 Glycine max 6709 8454 XP_003610109 357479646 0.8598 Medicago truncatula 6710 8455 XP_002270732 225446043 0.8116 Vitis vinifera 6711 8456 ACN54324 224551851 0.7805 Gossypium hirsutum 6712 8457 AAK15261 13183565 0.7748 Populus trichocarpa × 6713 8458 Populus deltoides CBI17838 270228824 0.7734 Vitis vinifera 6714 XP_002324469 255761085 0.7677 Populus trichocarpa 6715 177-197 XP_003554852 356573405 1 Glycine max 6716 8459 XP_003543493 356550234 0.8998 Glycine max 6717 8460 461-481 XP_003536297 356535528 1 Glycine max 6718 8461 XP_003556292 356576342 0.9205 Glycine max 6719 8462 238-258 XP_003518581 356499506 1 Glycine max 6720 8463 XP_003618091 357495604 0.7113 Medicago truncatula 6721 8464 gma-miR156g 75-94 XP_003520455 356503312 1 Glycine max 6722 8465 XP_003530170 356523079 0.848 Glycine max 6723 8466 371-390 XP_003553428 356570509 1 Glycine max 6724 8467 XP_003520534 356503475 0.9081 Glycine max 6725 8468 759-778 XP_003520534 356503475 1 Glycine max 6726 8469 XP_003553428 356570509 0.9081 Glycine max 6727 8470 108-127 XP_003553944 356571558 1 Glycine max 6728 8471 XP_003549130 356561725 0.9452 Glycine max 6729 8472 237-256 XP_003551188 356565928 1 Glycine max 6730 8473 XP_003538544 356540131 0.9106 Glycine max 6731 8474 ACU18328 255635963 0.9083 Glycine max 6732 8475 XP_003601767 357462970 0.7064 Medicago truncatula 6733 8476 36-55 AAM12880 20149261 1 Helianthus annuus 6734 8477 CBI28152 270240501 0.991 Vitis vinifera 6735 XP_002284967 225430201 0.991 Vitis vinifera 6736 8478 CBI21000 270231236 0.991 Vitis vinifera 6737 CBI36254 270253379 0.9819 Vitis vinifera 6738 8479 NP_200330 145359269 0.9864 Arabidopsis thaliana 6739 8480 XP_003522628 356507751 0.9819 Glycine max 6740 8481 AEM97804 344189954 0.9864 Dimocarpus longan 6741 8482 XP_002864382 297853636 0.9864 Arabidopsis lyrata 6742 subsp. lyrata XP_002285307 225442824 0.9819 Vitis vinifera 6743 8483 1020-1039 XP_003532399 356527605 1 Glycine max 6744 8484 XP_003525415 356513426 0.8914 Glycine max 6745 8485 114-133 ACU18105 255635506 1 Glycine max 6746 8486 756-775 XP_003518080 356498481 1 Glycine max 6747 8487 XP_003551421 356566402 0.8408 Glycine max 6748 8488 118-137 XP_003549130 356561725 1 Glycine max 6749 8489 XP_003553944 356571558 0.9452 Glycine max 6750 8490 662-681 XP_003550514 356564545 1 Glycine max 6751 8491 XP_003528668 356520027 0.9389 Glycine max 6752 8492 XP_003541638 356546447 0.8242 Glycine max 6753 8493 XP_003547234 356557871 0.808 Glycine max 6754 8494 XP_003594096 357447640 0.803 Medicago truncatula 6755 8495 XP_002279739 225432499 0.7382 Vitis vinifera 6756 8496 CAN70618 147801938 0.7406 Vitis vinifera 6757 8497 XP_002314424 255761085 0.7406 Populus trichocarpa 6758 XP_002516799 255761086 0.7219 Ricinus communis 6759 XP_002312735 255761085 0.7157 Populus trichocarpa 6760 691-710 XP_003525415 356513426 1 Glycine max 6761 8498 XP_003532399 356527605 0.9051 Glycine max 6762 8499 114-133 XP_003538544 356540131 1 Glycine max 6763 8500 XP_003551188 356565928 0.9097 Glycine max 6764 8501 1068-1087 XP_003525436 356513468 1 Glycine max 6765 8502 XP_003550708 356564947 0.9204 Glycine max 6766 8503 XP_003522278 356507037 0.7595 Glycine max 6767 8504  999-1018 XP_003550708 356564947 1 Glycine max 6768 8505 XP_003525436 356513468 0.9373 Glycine max 6769 8506 1098-1117 XP_003520128 356502644 1 Glycine max 6770 8507 XP_003517860 356498034 0.9129 Glycine max 6771 8508 179-198 XP_003523155 356508826 1 Glycine max 6772 8509 711-730 XP_003551421 356566402 1 Glycine max 6773 8510 XP_003518080 356498481 0.7962 Glycine max 6774 8511 gma-miR157c 164-183 XP_003549130 356561725 1 Glycine max 6775 8512 XP_003553944 356571558 0.9452 Glycine max 6776 8513 593-612 NP_001236309 351724988 1 Glycine max 6777 8514 XP_003529339 356521389 0.838 Glycine max 6778 8515 gma-miR159a-3p 305-325 XP_003551790 356567161 1 Glycine max 6779 8516 305-325 XP_003541823 356546825 1 Glycine max 6780 8517 124-144 XP_003543825 356550908 1 Glycine max 6781 8518 XP_003556814 356577399 0.813 Glycine max 6782 8519 405-425 XP_003542140 356547479 1 Glycine max 6783 8520 XP_003546908 356557204 0.8696 Glycine max 6784 8521 305-325 XP_003541823 356546825 1 Glycine max 6785 8522 124-144 XP_003543825 356550908 1 Glycine max 6786 8523 839-859 XP_003526354 356515330 1 Glycine max 6787 8524 XP_003523913 356510372 0.9333 Glycine max 6788 8525 73-93 XP_003535315 356533526 1 Glycine max 6789 8526 XP_003555178 356574075 0.9462 Glycine max 6790 8527 XP_003591226 357441896 0.7849 Medicago truncatula 6791 8528 XP_002512536 255761086 0.7465 Ricinus communis 6792 CBI39621 270257428 0.7465 Vitis vinifera 6793 8529 CAP59645 163913883 0.7558 Vitis vinifera 6794 8530 XP_002277312 225450534 0.7496 Vitis vinifera 6795 8531 XP_002280462 225432056 0.7404 Vitis vinifera 6796 8532 CAP59646 163913885 0.7512 Vitis vinifera 6797 8533 CAN63178 123711273 0.7373 Vitis vinifera 6798 8534 614-634 XP_003541563 356546291 1 Glycine max 6799 8535 XP_003545791 356554924 0.805 Glycine max 6800 8536 905-925 XP_003556814 356577399 1 Glycine max 6801 8537 XP_003543825 356550908 0.8659 Glycine max 6802 8538 2016-2036 XP_003538988 356541033 1 Glycine max 6803 8539 XP_003607189 357473808 0.7407 Medicago truncatula 6804 8540 XP_003604038 357467506 0.7035 Medicago truncatula 6805 8541 926-946 XP_003545791 356554924 1 Glycine max 6806 8542 XP_003541563 356546291 0.8662 Glycine max 6807 8543 842-862 XP_003523913 356510372 1 Glycine max 6808 8544 XP_003526354 356515330 0.9333 Glycine max 6809 8545 iba-miR157 164-184 XP_003549130 356561725 1 Glycine max 6810 8546 XP_003553944 356571558 0.9452 Glycine max 6811 8547 238-258 XP_003551188 356565928 1 Glycine max 6812 8548 XP_003538544 356540131 0.9106 Glycine max 6813 8549 ACU18328 255635963 0.9083 Glycine max 6814 8550 XP_003601767 357462970 0.7064 Medicago truncatula 6815 8551 1129-1149 XP_003525415 356513426 1 Glycine max 6816 8552 XP_003532399 356527605 0.9051 Glycine max 6817 8553 898-918 XP_003540473 356544059 1 Glycine max 6818 8554 XP_003543233 356549706 0.9305 Glycine max 6819 8555 ACU24116 255647298 0.9251 Glycine max 6820 8556 118-138 XP_003525436 356513468 1 Glycine max 6821 8557 XP_003550708 356564947 0.9204 Glycine max 6822 8558 XP_003522278 356507037 0.7595 Glycine max 6823 8559 77-97 XP_003520455 356503312 1 Glycine max 6824 8560 XP_003530170 356523079 0.848 Glycine max 6825 8561 498-518 XP_003553428 356570509 1 Glycine max 6826 8562 XP_003520534 356503475 0.9081 Glycine max 6827 8563 50-70 XP_003550708 356564947 1 Glycine max 6828 8564 XP_003525436 356513468 0.9373 Glycine max 6829 8565 170-190 XP_003538544 356540131 1 Glycine max 6830 8566 XP_003551188 356565928 0.9097 Glycine max 6831 8567 593-613 NP_001236309 351724988 1 Glycine max 6832 8568 XP_003529339 356521389 0.838 Glycine max 6833 8569 144-164 XP_002275728 225446415 1 Vitis vinifera 6834 8570 AAY16440 62856978 0.7396 Betula platyphylla 6835 8571 112-132 XP_003522278 356507037 1 Glycine max 6836 8572 396-416 XP_003520128 356502644 1 Glycine max 6837 8573 XP_003517860 356498034 0.9129 Glycine max 6838 8574 181-201 XP_003523155 356508826 1 Glycine max 6839 8575 77-97 XP_003520455 356503312 1 Glycine max 6840 8576 373-393 XP_003553428 356570509 1 Glycine max 6841 8577 761-781 XP_003520534 356503475 1 Glycine max 6842 8578 XP_003553428 356570509 0.9081 Glycine max 6843 8579 110-130 XP_003553944 356571558 1 Glycine max 6844 8580 239-259 XP_003551188 356565928 1 Glycine max 6845 8581 1022-1042 XP_003532399 356527605 1 Glycine max 6846 8582 XP_003525415 356513426 0.8914 Glycine max 6847 8583 593-613 NP_001236309 351724988 1 Glycine max 6848 8584 116-136 ACU18105 255635506 1 Glycine max 6849 8585 758-778 XP_003518080 356498481 1 Glycine max 6850 8586 XP_003551421 356566402 0.8408 Glycine max 6851 8587 120-140 XP_003549130 356561725 1 Glycine max 6852 8588 693-713 XP_003525415 356513426 1 Glycine max 6853 8589 656-676 XP_003517558 356497418 1 Glycine max 6854 8590 XP_003537666 356538348 0.9182 Glycine max 6855 8591 XP_003539001 356541059 0.7453 Glycine max 6856 8592 XP_003540042 356543182 0.7421 Glycine max 6857 8593 116-136 XP_003538544 356540131 1 Glycine max 6858 8594 1070-1090 XP_003525436 356513468 1 Glycine max 6859 8595 404-424 XP_003526029 356514674 1 Glycine max 6860 8596 XP_003540122 356543345 0.8919 Glycine max 6861 8597 1100-1120 XP_003520128 356502644 1 Glycine max 6862 8598 1001-1021 XP_003550708 356564947 1 Glycine max 6863 8599 243-263 XP_003540122 356543345 1 Glycine max 6864 8600 XP_003526029 356514674 0.8684 Glycine max 6865 8601 555-575 XP_003524444 356511459 1 Glycine max 6866 8602 XP_003533073 356528975 0.7951 Glycine max 6867 8603 181-201 XP_003523155 356508826 1 Glycine max 6868 8604 713-733 XP_003551421 356566402 1 Glycine max 6869 8605 XP_003518080 356498481 0.7962 Glycine max 6870 8606 mdm-miR482a-5p 517-537 XP_003528897 356520494 1 Glycine max 6871 8607 ACU19201 255637757 0.988 Glycine max 6872 8608 XP_003529981 356522693 0.7784 Glycine max 6873 8609 XP_003521936 356506325 0.7695 Glycine max 6874 8610 626-646 XP_003554327 356572340 1 Glycine max 6875 8611 XP_003521338 356505115 0.984 Glycine max 6876 8612 XP_003554326 356572338 1 Glycine max 6877 8613 XP_003521337 356505113 0.984 Glycine max 6878 8614 AES81717 357510420 0.869 Medicago truncatula 6879 8615 ACJ84304 217071887 0.8658 Medicago truncatula 6880 8616 ABN05708 46063642 0.8594 Medicago truncatula 6881 8617 AES84650 339649035 0.8339 Medicago truncatula 6882 8618 XP_003542462 356548141 0.8115 Glycine max 6883 8619 XP_003542461 356548139 0.8115 Glycine max 6884 8620 204-224 XP_003625987 357511396 1 Medicago truncatula 6885 8621 AES82205 357511396 1 Medicago truncatula 6886 8622 XP_003520757 356503939 0.8043 Glycine max 6887 8623 XP_003554555 356572802 0.802 Glycine max 6888 8624 175-195 XP_003554555 356572802 1 Glycine max 6889 8625 XP_002271147 225437597 0.7397 Vitis vinifera 6890 8626 XP_002515261 255761086 0.7188 Ricinus communis 6891 716-736 XP_003539613 356542313 1 Glycine max 6892 8627 XP_003543221 356549682 0.8767 Glycine max 6893 8628 778-798 XP_003625499 357510420 1 Medicago truncatula 6894 8629 XP_003554327 356572340 0.8395 Glycine max 6895 8630 XP_003537175 356537316 0.8056 Glycine max 6896 8631 osa-miR159e 500-520 XP_003541668 356546507 1 Glycine max 6897 8632 XP_003547199 356557800 0.8383 Glycine max 6898 8633 495-515 XP_003524148 356510852 1 Glycine max 6899 8634 XP_003531162 356525093 0.7762 Glycine max 6900 8635 26-46 XP_003547199 356557800 1 Glycine max 6901 8636 124-144 XP_003543825 356550908 1 Glycine max 6902 8637 XP_003556814 356577399 0.813 Glycine max 6903 8638 817-837 XP_003525997 356514606 1 Glycine max 6904 8639 XP_003540066 356543230 0.8441 Glycine max 6905 8640 289-309 XP_003518627 356499601 1 Glycine max 6906 8641 XP_003542153 356547506 0.9478 Glycine max 6907 8642 ADN33938 307136081 0.7937 Cucumis melo 6908 8643 subsp. melo XP_002518919 255761086 0.7755 Ricinus communis 6909 XP_002279642 225426567 0.7755 Vitis vinifera 6910 8644 XP_002870592 297853636 0.7664 Arabidopsis lyrata 6911 subsp. lyrata NP_199024 30693991 0.7642 Arabidopsis thaliana 6912 8645 AAM63843 21405504 0.7596 Arabidopsis thaliana 6913 8646 XP_002299422 255761085 0.7528 Populus trichocarpa 6914 XP_002303695 255761085 0.7574 Populus trichocarpa 6915 124-144 XP_003543825 356550908 1 Glycine max 6916 8647 461-481 XP_003542153 356547506 1 Glycine max 6917 8648 XP_003518627 356499601 0.9436 Glycine max 6918 8649 1162-1182 XP_003531162 356525093 1 Glycine max 6919 8650 XP_003524148 356510852 0.7692 Glycine max 6920 8651 839-859 XP_003526354 356515330 1 Glycine max 6921 8652 XP_003523913 356510372 0.9333 Glycine max 6922 8653 495-515 XP_003524148 356510852 1 Glycine max 6923 8654 949-969 XP_003547199 356557800 1 Glycine max 6924 8655 614-634 XP_003541563 356546291 1 Glycine max 6925 8656 XP_003545791 356554924 0.805 Glycine max 6926 8657 905-925 XP_003556814 356577399 1 Glycine max 6927 8658 XP_003543825 356550908 0.8659 Glycine max 6928 8659 2016-2036 XP_003538988 356541033 1 Glycine max 6929 8660 XP_003607189 357473808 0.7407 Medicago truncatula 6930 8661 XP_003604038 357467506 0.7035 Medicago truncatula 6931 8662 1330-1350 XP_003541668 356546507 1 Glycine max 6932 8663 842-862 XP_003523913 356510372 1 Glycine max 6933 8664 XP_003526354 356515330 0.9333 Glycine max 6934 8665 926-946 XP_003545791 356554924 1 Glycine max 6935 8666 XP_003541563 356546291 0.8662 Glycine max 6936 8667 osa-miR159f 124-144 XP_003543825 356550908 1 Glycine max 6937 8668 XP_003556814 356577399 0.813 Glycine max 6938 8669 305-325 XP_003541823 356546825 1 Glycine max 6939 8670 124-144 XP_003543825 356550908 1 Glycine max 6940 8671 839-859 XP_003526354 356515330 1 Glycine max 6941 8672 XP_003523913 356510372 0.9333 Glycine max 6942 8673 614-634 XP_003541563 356546291 1 Glycine max 6943 8674 XP_003545791 356554924 0.805 Glycine max 6944 8675 905-925 XP_003556814 356577399 1 Glycine max 6945 8676 2016-2036 XP_003538988 356541033 1 Glycine max 6946 8677 XP_003607189 357473808 0.7407 Medicago truncatula 6947 8678 XP_003604038 357467506 0.7035 Medicago truncatula 6948 8679 842-862 XP_003523913 356510372 1 Glycine max 6949 8680 XP_003526354 356515330 0.9333 Glycine max 6950 8681 926-946 XP_003545791 356554924 1 Glycine max 6951 8682 XP_003541563 356546291 0.8662 Glycine max 6952 8683 osa-miR1850.1 796-816 ABC49719 84028520 1 Arachis hypogaea 6953 8684 NP_001236448 351734389 0.9568 Glycine max 6954 8685 XP_003535034 356532953 0.9496 Glycine max 6955 8686 XP_003594440 357448328 0.8993 Medicago truncatula 6956 8687 ACJ84098 217071475 0.8921 Medicago truncatula 6957 8688 XP_003629907 357519236 0.8705 Medicago truncatula 6958 8689 ABD63906 89212811 0.8921 Gossypium hirsutum 6959 8690 ABD66505 89276296 0.8849 Gossypium hirsutum 6960 8691 ADN34239 307136431 0.8633 Cucumis melo 6961 8692 subsp. melo ABD66508 89276302 0.8849 Gossypium hirsutum 6962 8693 746-766 XP_003535034 356532953 1 Glycine max 6963 8694 CAJ38384 106879600 0.8849 Plantago major 6964 8695 XP_002299887 255761085 0.9065 Populus trichocarpa 6965 17-37 XP_003534041 356530948 1 Glycine max 6966 8696 117-137 XP_003524950 356512486 1 Glycine max 6967 8697 243-263 XP_003548988 356561437 1 Glycine max 6968 8698 XP_003548995 356561451 0.7944 Glycine max 6969 8699 XP_003548992 356561445 0.728 Glycine max 6970 8700 XP_003548994 356561449 0.7846 Glycine max 6971 8701 XP_003548993 356561447 0.921 Glycine max 6972 8702 XP_003548986 356561433 0.8079 Glycine max 6973 8703 XP_003548991 356561443 0.807 Glycine max 6974 8704 XP_003617757 357494936 0.8241 Medicago truncatula 6975 8705 XP_003616414 357492250 0.7971 Medicago truncatula 6976 8706 53-73 XP_003552127 356567847 1 Glycine max 6977 8707 XP_003532277 356527355 0.9545 Glycine max 6978 8708 ADB79567 284156655 0.7995 Arachis hypogaea 6979 8709 XP_002262721 225470104 0.7433 Vitis vinifera 6980 8710 ABX82799 296916970 0.7219 Jatropha curcas 6981 8711 XP_002532744 255761086 0.7166 Ricinus communis 6982 XP_002863277 297853636 0.7112 Arabidopsis lyrata 6983 subsp. lyrata AAC49002 595956 0.7059 Brassica rapa 6984 8712 141-161 XP_003555849 356575439 1 Glycine max 6985 8713 XP_003592693 357444830 0.8289 Medicago truncatula 6986 8714 XP_002529805 255761086 0.7425 Ricinus communis 6987 XP_002306206 255761085 0.7331 Populus trichocarpa 6988 XP_002264823 225467465 0.7221 Vitis vinifera 6989 8715 XP_002278507 225428128 0.719 Vitis vinifera 6990 8716 XP_002312937 255761085 0.7159 Populus trichocarpa 6991 2940-2960 XP_003550417 356564348 1 Glycine max 6992 8717 XP_003523561 356509653 0.7407 Glycine max 6993 8718 XP_003523562 356509655 0.7323 Glycine max 6994 8719 osa-miR1858a  90-110 XP_003520359 356503118 1 Glycine max 6995 8720 XP_003547751 356558921 0.94 Glycine max 6996 8721 AES83637 339648991 0.7389 Medicago truncatula 6997 XP_003522288 356507057 0.7176 Glycine max 6998 8722 XP_003604071 357467572 0.706 Medicago truncatula 6999 8723 24-44 XP_003553781 356571227 1 Glycine max 7000 8724 NP_001235053 351725668 0.8396 Glycine max 7001 8725 BAF49302 133874197 0.7167 Clitoria ternatea 7002 8726 364-384 XP_003554024 356571724 1 Glycine max 7003 8727 XP_003554025 356571726 0.9937 Glycine max 7004 8728 XP_003548728 356560906 0.9669 Glycine max 7005 8729 XP_003624635 357508692 0.8873 Medicago truncatula 7006 8730 XP_002285720 225435753 0.8202 Vitis vinifera 7007 8731 XP_002281591 225441588 0.8229 Vitis vinifera 7008 8732 XP_003531251 356525273 0.8157 Glycine max 7009 8733 XP_002304857 255761085 0.797 Populus trichocarpa 7010 XP_002299105 255761085 0.7898 Populus trichocarpa 7011 XP_003629733 357518888 0.7987 Medicago truncatula 7012 8734 345-365 XP_003548728 356560906 1 Glycine max 7013 8735 XP_003554024 356571724 0.9704 Glycine max 7014 8736 24-44 XP_003553781 356571227 1 Glycine max 7015 8737 56-76 XP_003521247 356504932 1 Glycine max 7016 8738 XP_003554255 356572193 0.9395 Glycine max 7017 8739 XP_002520726 255761086 0.7893 Ricinus communis 7018 XP_002278267 225437025 0.8136 Vitis vinifera 7019 8740 XP_002307588 255761085 0.7966 Populus trichocarpa 7020 XP_002892149 297853636 0.7215 Arabidopsis lyrata 7021 subsp. lyrata NP_563676 30678481 0.7361 Arabidopsis thaliana 7022 8741 360-380 NP_001237118 351726189 1 Glycine max 7023 8742 XP_003556230 356576216 0.9243 Glycine max 7024 8743 XP_002529571 255761086 0.7775 Ricinus communis 7025 XP_002315301 255761085 0.7706 Populus trichocarpa 7026 XP_002275232 225449067 0.7752 Vitis vinifera 7027 8744 XP_002312018 255761085 0.7569 Populus trichocarpa 7028 ACM45079 222136858 0.7729 Vitis vinifera 7029 8745 XP_002894135 297853636 0.7729 Arabidopsis lyrata 7030 subsp. lyrata ABA54870 76782199 0.7638 Fagus sylvatica 7031 8746 CAN73646 123693264 0.7706 Vitis vinifera 7032 277-297 XP_003591923 357443290 1 Medicago truncatula 7033 8747 180-200 XP_003524517 356511610 1 Glycine max 7034 8748 XP_003549799 356563090 0.9173 Glycine max 7035 8749 564-584 NP_001235053 351725668 1 Glycine max 7036 8750 XP_003553781 356571227 0.8319 Glycine max 7037 8751 XP_003626556 357512534 0.7059 Medicago truncatula 7038 8752 ACJ85806 217074891 0.7017 Medicago truncatula 7039 8753 369-389 XP_003530234 356523208 1 Glycine max 7040 8754 XP_003551508 356566578 0.9298 Glycine max 7041 8755 188-208 XP_002529571 255761086 1 Ricinus communis 7042 NP_564534 145336530 0.8046 Arabidopsis thaliana 7043 8756 AAG50662 12321108 0.8023 Arabidopsis thaliana 7044 8757 378-398 XP_003551508 356566578 1 Glycine max 7045 8758 XP_003530234 356523208 0.8745 Glycine max 7046 8759 231-251 XP_003528545 356519775 1 Glycine max 7047 8760 XP_003556667 356577102 0.9204 Glycine max 7048 8761 XP_003607899 357475226 0.7898 Medicago truncatula 7049 8762 156-176 XP_003547641 356558699 1 Glycine max 7050 8763 XP_003548802 356561057 0.9768 Glycine max 7051 8764 141-161 XP_003543554 356550357 1 Glycine max 7052 8765 XP_003554155 356571993 0.932 Glycine max 7053 8766 180-200 XP_003549799 356563090 1 Glycine max 7054 8767 XP_003524517 356511610 0.9176 Glycine max 7055 8768 192-212 XP_003531267 356525308 1 Glycine max 7056 8769 XP_003624841 357509104 0.7936 Medicago truncatula 7057 8770 XP_003522101 356506673 0.7277 Glycine max 7058 8771 132-152 XP_003556667 356577102 1 Glycine max 7059 8772 XP_003528545 356519775 0.9129 Glycine max 7060 8773 psi-miR159 124-144 XP_003543825 356550908 1 Glycine max 7061 8774 XP_003556814 356577399 0.813 Glycine max 7062 8775 289-309 XP_003518627 356499601 1 Glycine max 7063 8776 XP_003542153 356547506 0.9478 Glycine max 7064 8777 ADN33938 307136081 0.7937 Cucumis melo 7065 8778 subsp. melo XP_002518919 255761086 0.7755 Ricinus communis 7066 XP_002279642 225426567 0.7755 Vitis vinifera 7067 8779 XP_002870592 297853636 0.7664 Arabidopsis lyrata 7068 subsp. lyrata NP_199024 30693991 0.7642 Arabidopsis thaliana 7069 8780 AAM63843 21405504 0.7596 Arabidopsis thaliana 7070 8781 XP_002299422 255761085 0.7528 Populus trichocarpa 7071 XP_002303695 255761085 0.7574 Populus trichocarpa 7072 124-144 XP_003543825 356550908 1 Glycine max 7073 8782 461-481 XP_003542153 356547506 1 Glycine max 7074 8783 XP_003518627 356499601 0.9436 Glycine max 7075 8784 839-859 XP_003526354 356515330 1 Glycine max 7076 8785 XP_003523913 356510372 0.9333 Glycine max 7077 8786 614-634 XP_003541563 356546291 1 Glycine max 7078 8787 XP_003545791 356554924 0.805 Glycine max 7079 8788 905-925 XP_003556814 356577399 1 Glycine max 7080 8789 19-39 NP_001236539 351724240 1 Glycine max 7081 8790 NP_001237767 351722762 0.9915 Glycine max 7082 8791 NP_001237736 351721871 0.7778 Glycine max 7083 8792 BAF50740 139005586 0.7436 Apios americana 7084 8793 XP_003623947 357507316 0.7094 Medicago truncatula 7085 8794 2016-2036 XP_003538988 356541033 1 Glycine max 7086 8795 XP_003607189 357473808 0.7407 Medicago truncatula 7087 8796 XP_003604038 357467506 0.7035 Medicago truncatula 7088 8797 926-946 XP_003545791 356554924 1 Glycine max 7089 8798 XP_003541563 356546291 0.8662 Glycine max 7090 8799 842-862 XP_003523913 356510372 1 Glycine max 7091 8800 XP_003526354 356515330 0.9333 Glycine max 7092 8801 pta-miR156a 161-180 XP_003549130 356561725 1 Glycine max 7093 8802 XP_003553944 356571558 0.9452 Glycine max 7094 8803 106-125 XP_003520455 356503312 1 Glycine max 7095 8804 XP_003530170 356523079 0.848 Glycine max 7096 8805 115-134 XP_003525436 356513468 1 Glycine max 7097 8806 XP_003550708 356564947 0.9204 Glycine max 7098 8807 XP_003522278 356507037 0.7595 Glycine max 7099 8808 47-66 XP_003550708 356564947 1 Glycine max 7100 8809 XP_003525436 356513468 0.9373 Glycine max 7101 8810 495-514 XP_003553428 356570509 1 Glycine max 7102 8811 XP_003520534 356503475 0.9081 Glycine max 7103 8812 303-322 XP_003530747 356524258 1 Glycine max 7104 XP_003553084 356569799 0.9116 Glycine max 7105 393-412 XP_003520128 356502644 1 Glycine max 7106 8813 XP_003517860 356498034 0.9129 Glycine max 7107 8814 109-128 XP_003522278 356507037 1 Glycine max 7108 8815 178-197 XP_003523155 356508826 1 Glycine max 7109 8816 755-774 XP_003518080 356498481 1 Glycine max 7110 8817 XP_003551421 356566402 0.8408 Glycine max 7111 8818 117-136 XP_003549130 356561725 1 Glycine max 7112 8819 734-753 XP_003553428 356570509 1 Glycine max 7113 8820 815-834 XP_003553944 356571558 1 Glycine max 7114 8821 121-140 ACU18105 255635506 1 Glycine max 7115 8822 1067-1086 XP_003525436 356513468 1 Glycine max 7116 8823 106-125 XP_003520455 356503312 1 Glycine max 7117 8824 1097-1116 XP_003520128 356502644 1 Glycine max 7118 8825  998-1017 XP_003550708 356564947 1 Glycine max 7119 8826 178-197 XP_003523155 356508826 1 Glycine max 7120 8827 590-609 NP_001236309 351724988 1 Glycine max 7121 8828 XP_003529339 356521389 0.838 Glycine max 7122 8829 710-729 XP_003551421 356566402 1 Glycine max 7123 8830 XP_003518080 356498481 0.7962 Glycine max 7124 8831 pta-miR156b 161-180 XP_003549130 356561725 1 Glycine max 7125 8832 XP_003553944 356571558 0.9452 Glycine max 7126 8833 320-339 XP_003531511 356525799 1 Glycine max 7127 8834 XP_003546792 356556969 0.7324 Glycine max 7128 8835 115-134 XP_003525436 356513468 1 Glycine max 7129 8836 XP_003550708 356564947 0.9204 Glycine max 7130 8837 XP_003522278 356507037 0.7595 Glycine max 7131 8838 106-125 XP_003520455 356503312 1 Glycine max 7132 8839 XP_003530170 356523079 0.848 Glycine max 7133 8840 47-66 XP_003550708 356564947 1 Glycine max 7134 8841 XP_003525436 356513468 0.9373 Glycine max 7135 8842 495-514 XP_003553428 356570509 1 Glycine max 7136 8843 XP_003520534 356503475 0.9081 Glycine max 7137 8844 396-415 ABW03160 157922334 1 Pisum sativum 7138 8845 XP_003546545 356556463 0.9946 lipoamide 7139 8846 ACU19644 255638677 0.9919 Glycine max 7140 8847 XP_003533815 356530492 0.9621 lipoamide 7141 8848 CAG14980 45720177 0.8916 Cicer arietinum 7142 8849 ABW03161 157922336 0.8862 Pisum sativum 7143 8850 XP_003595440 357450326 0.878 Medicago truncatula 7144 8851 XP_002314330 255761085 0.8699 Populus trichocarpa 7145 XP_003621874 357503170 0.8564 Medicago truncatula 7146 8852 XP_002267959 225432170 0.8618 Vitis vinifera 7147 8853 1563-1582 XP_002526256 255761086 1 Ricinus communis 7148 XP_002318437 255761085 0.9495 Populus trichocarpa 7149 XP_002276600 225455335 0.946 Vitis vinifera 7150 8854 CBI23029 270234399 0.946 Vitis vinifera 7151 8855 XP_002515853 255761086 0.9414 Ricinus communis 7152 XP_003530452 356523654 0.8886 Glycine max 7153 8856 XP_003525330 356513256 0.884 Glycine max 7154 8857 XP_002864245 297853636 0.8794 Arabidopsis lyrata 7155 subsp. lyrata NP_200160 42568511 0.876 Arabidopsis thaliana 7156 8858 BAJ93177 326526000 0.8324 Hordeum vulgare 7157 8859 subsp. vulgare 393-412 XP_003520128 356502644 1 Glycine max 7158 8860 XP_003517860 356498034 0.9129 Glycine max 7159 8861 109-128 XP_003522278 356507037 1 Glycine max 7160 8862 178-197 XP_003523155 356508826 1 Glycine max 7161 8863 203-222 XP_003551276 356566105 1 Glycine max 7162 8864 XP_003538548 356540139 0.9368 Glycine max 7163 8865 XP_003601783 357463002 0.8103 Medicago truncatula 7164 8866 XP_003524894 356512372 0.7615 Glycine max 7165 8867 XP_003531195 356525159 0.7759 Glycine max 7166 8868 XP_002514915 255761086 0.7557 Ricinus communis 7167 XP_002297844 255761085 0.7471 Populus trichocarpa 7168 XP_002304680 255761085 0.7414 Populus trichocarpa 7169 XP_002271442 225425417 0.7098 Vitis vinifera 7170 8869 74-93 XP_003520455 356503312 1 Glycine max 7171 8870 370-389 XP_003553428 356570509 1 Glycine max 7172 8871 758-777 XP_003520534 356503475 1 Glycine max 7173 8872 XP_003553428 356570509 0.9081 Glycine max 7174 8873 107-126 XP_003553944 356571558 1 Glycine max 7175 8874 35-54 AAM12880 20149261 1 Helianthus annuus 7176 8875 CBI28152 270240501 0.991 Vitis vinifera 7177 XP_002284967 225430201 0.991 Vitis vinifera 7178 8876 CBI21000 270231236 0.991 Vitis vinifera 7179 CBI36254 270253379 0.9819 Vitis vinifera 7180 8877 NP_200330 145359269 0.9864 Arabidopsis thaliana 7181 8878 XP_003522628 356507751 0.9819 Glycine max 7182 8879 AEM97804 344189954 0.9864 Dimocarpus longan 7183 8880 XP_002864382 297853636 0.9864 Arabidopsis lyrata 7184 subsp. lyrata XP_002285307 225442824 0.9819 Vitis vinifera 7185 8881 1019-1038 XP_003532399 356527605 1 Glycine max 7186 8882 XP_003525415 356513426 0.8914 Glycine max 7187 8883 113-132 ACU18105 255635506 1 Glycine max 7188 8884 755-774 XP_003518080 356498481 1 Glycine max 7189 8885 XP_003551421 356566402 0.8408 Glycine max 7190 8886 117-136 XP_003549130 356561725 1 Glycine max 7191 8887 690-709 XP_003525415 356513426 1 Glycine max 7192 8888 XP_003532399 356527605 0.9051 Glycine max 7193 8889 1067-1086 XP_003525436 356513468 1 Glycine max 7194 8890 1097-1116 XP_003520128 356502644 1 Glycine max 7195 8891  998-1017 XP_003550708 356564947 1 Glycine max 7196 8892 178-197 XP_003523155 356508826 1 Glycine max 7197 8893 467-486 XP_003610314 357480056 1 Medicago truncatula 7198 8894 XP_003549541 356562566 0.8796 Glycine max 7199 8895 XP_003519149 356500658 0.8728 Glycine max 7200 8896 XP_003540100 356543299 0.8605 Glycine max 7201 8897 XP_002278464 225445858 0.8098 Vitis vinifera 7202 8898 XP_002529385 255761086 0.8167 Ricinus communis 7203 XP_002325129 255761085 0.7852 Populus trichocarpa 7204 NP_851209 42570605 0.762 Arabidopsis thaliana 7205 8899 XP_002864540 297853636 0.7579 Arabidopsis lyrata 7206 subsp. lyrata NP_974953 42573713 0.7565 Arabidopsis thaliana 7207 8900 710-729 XP_003551421 356566402 1 Glycine max 7208 8901 XP_003518080 356498481 0.7962 Glycine max 7209 8902 ptc-miRf10226-akr 312-334 XP_003547131 356557655 1 Glycine max 7210 8903 XP_003541752 356546681 0.9148 Glycine max 7211 8904 247-269 XP_003542817 356548860 1 Glycine max 7212 8905 XP_003546711 356556804 0.9141 Glycine max 7213 8906 AET02361 357515192 0.7607 Medicago truncatula 7214 8907 131-153 XP_003523607 1 Glycine max 7215 XP_003525906 0.9439 Glycine max 7216 106-128 XP_003549610 356562705 1 Glycine max 7217 8908 XP_003529657 356522038 0.8762 Glycine max 7218 8909 161-183 XP_003525906 356514424 1 Glycine max 7219 8910 XP_003523607 356509746 0.9381 Glycine max 7220 8911 ptc-miRf10271-akr 123-143 XP_003543825 356550908 1 Glycine max 7221 8912 XP_003556814 356577399 0.813 Glycine max 7222 8913 423-443 XP_002325684 255761085 1 Populus trichocarpa 7223 XP_002319934 255761085 0.9342 Populus trichocarpa 7224 ACU14088 255627486 0.8202 Glycine max 7225 8914 XP_003543368 356549979 0.8114 Glycine max 7226 8915 NP_001237648 351726723 0.7982 Glycine max 7227 8916 ACU20677 255640786 0.7807 Glycine max 7228 8917 XP_002284361 225461286 0.7719 Vitis vinifera 7229 8918 ADU05416 315364829 0.7851 Citrullus lanatus 7230 8919 XP_002265183 225465748 0.75 Vitis vinifera 7231 8920 XP_002513246 255761086 0.807 Ricinus communis 7232 544-564 ACU20677 255640786 1 Glycine max 7233 8921 P26291 0.7099 Pisum sativum 7234 XP_003597086 357453610 0.7023 Medicago truncatula 7235 8922 304-324 XP_003541823 356546825 1 Glycine max 7236 8923 288-308 XP_003518627 356499601 1 Glycine max 7237 8924 XP_003542153 356547506 0.9478 Glycine max 7238 8925 ADN33938 307136081 0.7937 Cucumis melo 7239 8926 subsp. melo XP_002518919 255761086 0.7755 Ricinus communis 7240 XP_002279642 225426567 0.7755 Vitis vinifera 7241 8927 XP_002870592 297853636 0.7664 Arabidopsis lyrata 7242 subsp. lyrata NP_199024 30693991 0.7642 Arabidopsis thaliana 7243 8928 AAM63843 21405504 0.7596 Arabidopsis thaliana 7244 8929 XP_002299422 255761085 0.7528 Populus trichocarpa 7245 XP_002303695 255761085 0.7574 Populus trichocarpa 7246 123-143 XP_003543825 356550908 1 Glycine max 7247 8930 460-480 XP_003542153 356547506 1 Glycine max 7248 8931 XP_003518627 356499601 0.9436 Glycine max 7249 8932 838-858 XP_003526354 356515330 1 Glycine max 7250 8933 XP_003523913 356510372 0.9333 Glycine max 7251 8934 72-92 XP_003535315 356533526 1 Glycine max 7252 8935 XP_003555178 356574075 0.9462 Glycine max 7253 8936 XP_003591226 357441896 0.7849 Medicago truncatula 7254 8937 XP_002512536 255761086 0.7465 Ricinus communis 7255 CBI39621 270257428 0.7465 Vitis vinifera 7256 8938 CAP59645 163913883 0.7558 Vitis vinifera 7257 8939 XP_002277312 225450534 0.7496 Vitis vinifera 7258 8940 XP_002280462 225432056 0.7404 Vitis vinifera 7259 8941 CAP59646 163913885 0.7512 Vitis vinifera 7260 8942 CAN63178 123711273 0.7373 Vitis vinifera 7261 8943 157-177 XP_003594856 357449158 1 Medicago truncatula 7262 8944 XP_003533661 356530178 0.913 Glycine max 7263 8945 ACU18911 255637160 0.9091 Glycine max 7264 8946 ACU19698 255638787 0.9051 Glycine max 7265 8947 XP_002273965 225423594 0.83 Vitis vinifera 7266 8948 NP_001058303 115469407 0.7984 Oryza sativa 7267 8949 Japonica Group XP_002528147 255761086 0.8063 Ricinus communis 7268 AEL99129 343172851 0.8142 Silene latifolia 7269 8950 AEL99130 343172853 0.8103 Silene latifolia 7270 8951 XP_002438809 255761094 0.7787 Sorghum bicolor 7271 613-633 XP_003541563 356546291 1 Glycine max 7272 8952 XP_003545791 356554924 0.805 Glycine max 7273 8953 904-924 XP_003556814 356577399 1 Glycine max 7274 8954 2015-2035 XP_003538988 356541033 1 Glycine max 7275 8955 XP_003607189 357473808 0.7407 Medicago truncatula 7276 8956 XP_003604038 357467506 0.7035 Medicago truncatula 7277 8957 841-861 XP_003523913 356510372 1 Glycine max 7278 8958 XP_003526354 356515330 0.9333 Glycine max 7279 8959 925-945 XP_003545791 356554924 1 Glycine max 7280 8960 XP_003541563 356546291 0.8662 Glycine max 7281 8961 ptc-miRf10734-akr 371-391 XP_003518621 356499589 1 Glycine max 7282 8962 XP_003529232 356521172 0.9575 Glycine max 7283 8963 ABI48270 113911567 0.8826 Lotus japonicus 7284 8964 XP_003525213 356513021 0.8512 Glycine max 7285 8965 XP_003530935 356524637 0.8502 Glycine max 7286 8966 XP_003631014 357521450 0.836 Medicago truncatula 7287 8967 XP_002285117 225424439 0.8117 Vitis vinifera 7288 8968 ACE63259 190148352 0.8067 Betula pendula 7289 8969 ABI48271 113911569 0.8259 Lotus japonicus 7290 8970 XP_002314765 255761085 0.7783 Populus trichocarpa 7291 1151-1171 XP_003520774 356503973 1 Glycine max 7292 8971 1761-1781 XP_003523576 356509683 1 Glycine max 7293 XP_003527692 356518039 0.8899 Glycine max 7294 1929-1949 XP_003527692 356518039 1 Glycine max 7295 XP_003523576 356509683 0.8906 Glycine max 7296 1230-1250 XP_003538849 356540752 1 Glycine max 7297 8972 XP_003520774 356503973 0.7213 Glycine max 7298 8973 ptc-miRf10985-akr 161-180 XP_003549130 356561725 1 Glycine max 7299 8974 XP_003553944 356571558 0.9452 Glycine max 7300 8975 1659-1678 AAF67341 7682676 1 Vigna radiata 7301 8976 ACF22882 193850556 0.9362 Glycine max 7302 XP_003546457 356556285 0.9334 Glycine max 7303 8977 XP_003550633 356564793 0.8239 Glycine max 7304 8978 CAA09457 3641864 0.8017 Cicer arietinum 7305 8979 CAA06309 14274980 0.7961 Cicer arietinum 7306 8980 CAA09467 3860419 0.8058 Lupinus angustifolius 7307 8981 XP_002514108 255761086 0.7878 Ricinus communis 7308 XP_003595162 357449770 0.7906 Medicago truncatula 7309 8982 XP_002308268 255761085 0.7684 Populus trichocarpa 7310 235-254 BAF31130 114213453 1 Vicia faba 7311 8983 P48488 0.9751 Medicago sativa 7312 subsp. × varia ACJ84258 217071795 0.972 Medicago truncatula 7313 8984 XP_003532976 356528780 0.9346 Glycine max 7314 8985 XP_003525372 356513340 0.9283 Glycine max 7315 8986 ACU20069 255639548 0.9252 Glycine max 7316 8987 XP_002509868 255761086 0.9034 Ricinus communis 7317 XP_002298008 255761085 0.8972 Populus trichocarpa 7318 XP_002277816 225426133 0.9034 Vitis vinifera 7319 8988 NP_176587 145337150 0.8442 Arabidopsis thaliana 7320 8989 235-254 XP_003551188 356565928 1 Glycine max 7321 8990 XP_003538544 356540131 0.9106 Glycine max 7322 8991 ACU18328 255635963 0.9083 Glycine max 7323 8992 XP_003601767 357462970 0.7064 Medicago truncatula 7324 8993 495-514 XP_003553428 356570509 1 Glycine max 7325 8994 XP_003520534 356503475 0.9081 Glycine max 7326 8995 51-70 XP_003545057 356553424 1 Glycine max 7327 8996 XP_003519693 356501762 0.9036 Glycine max 7328 8997 XP_002312804 255761085 0.7267 Populus trichocarpa 7329 XP_002279611 225428277 0.7199 Vitis vinifera 7330 8998 167-186 XP_003538544 356540131 1 Glycine max 7331 8999 XP_003551188 356565928 0.9097 Glycine max 7332 9000 109-128 XP_003522278 356507037 1 Glycine max 7333 9001 XP_003525436 356513468 0.7319 Glycine max 7334 9002 XP_003550708 356564947 0.7072 Glycine max 7335 9003 393-412 XP_003520128 356502644 1 Glycine max 7336 9004 XP_003517860 356498034 0.9129 Glycine max 7337 9005 217-236 AES84797 339649045 1 Medicago truncatula 7338 9006 XP_003518611 356499568 0.8041 Glycine max 7339 9007 XP_003529219 356521146 0.7947 Glycine max 7340 9008 XP_003525231 356513057 0.7665 Glycine max 7341 9009 XP_003630941 357521304 0.7834 Medicago truncatula 7342 9010 XP_003530877 356524520 0.7552 Glycine max 7343 9011 XP_002525995 255761086 0.7269 Ricinus communis 7344 XP_002315857 255761085 0.7213 Populus trichocarpa 7345 ABK94575 118485436 0.7213 Populus trichocarpa 7346 9012 XP_002311530 255761085 0.7175 Populus trichocarpa 7347 398-417 XP_003588450 357436348 1 Medicago truncatula 7348 9013 XP_003526513 356515652 0.8496 Glycine max 7349 9014 XP_003522729 356507956 0.8453 Glycine max 7350 9015 XP_003603665 357466760 0.839 Medicago truncatula 7351 9016 ACU21356 255642182 0.8432 Glycine max 7352 9017 XP_003550117 356563738 0.8305 Glycine max 7353 9018 CAD92450 31455392 0.7479 Brassica napus 7354 9019 ADB92670 284519839 0.75 Populus tremula × 7355 9020 Populus alba XP_002510013 255761086 0.7373 Ricinus communis 7356 XP_002301129 255761085 0.7373 Populus trichocarpa 7357 370-389 XP_003553428 356570509 1 Glycine max 7358 9021 758-777 XP_003520534 356503475 1 Glycine max 7359 9022 XP_003553428 356570509 0.9081 Glycine max 7360 9023 236-255 XP_003551188 356565928 1 Glycine max 7361 9024 35-54 AAM12880 20149261 1 Helianthus annuus 7362 9025 CBI28152 270240501 0.991 Vitis vinifera 7363 XP_002284967 225430201 0.991 Vitis vinifera 7364 9026 CBI21000 270231236 0.991 Vitis vinifera 7365 CBI36254 270253379 0.9819 Vitis vinifera 7366 9027 NP_200330 145359269 0.9864 Arabidopsis thaliana 7367 9028 XP_003522628 356507751 0.9819 Glycine max 7368 9029 AEM97804 344189954 0.9864 Dimocarpus longan 7369 9030 XP_002864382 297853636 0.9864 Arabidopsis lyrata 7370 subsp. lyrata XP_002285307 225442824 0.9819 Vitis vinifera 7371 9031 755-774 XP_003518080 356498481 1 Glycine max 7372 9032 XP_003551421 356566402 0.8408 Glycine max 7373 9033 56-75 XP_003522398 356507283 1 Glycine max 7374 9034 XP_003526192 356515005 0.9095 Glycine max 7375 9035 XP_003526191 356515003 0.9128 Glycine max 7376 9036 XP_003527777 356518217 0.7966 Glycine max 7377 9037 113-132 XP_003538544 356540131 1 Glycine max 7378 9038 1097-1116 XP_003520128 356502644 1 Glycine max 7379 9039 1482-1501 XP_003546504 356556379 1 Glycine max 7380 9040 XP_003550617 356564761 0.7923 Glycine max 7381 9041 XP_003542359 356547932 0.7889 Glycine max 7382 9042 XP_002279041 225444747 0.7337 Vitis vinifera 7383 9043 XP_002870435 297853636 0.7119 Arabidopsis lyrata 7384 subsp. lyrata XP_002516284 255761086 0.7102 Ricinus communis 7385 NP_568528 22327353 0.7018 Arabidopsis thaliana 7386 9044 XP_002326282 255761085 0.7002 Populus trichocarpa 7387 ptc-miRf11315-akr 264-283 XP_003518840 356500034 1 Glycine max 7388 9045 XP_003529395 356521503 0.9171 Glycine max 7389 9046 XP_003607985 357475398 0.8275 Medicago truncatula 7390 9047 XP_002518769 255761086 0.7579 Ricinus communis 7391 XP_002313117 255761085 0.7496 Populus trichocarpa 7392 AAQ90244 37223341 0.7446 Solanum lycopersicum 7393 9048 NP_001234399 350534489 0.7446 Solanum lycopersicum 7394 9049 NP_188555 30685246 0.7247 Arabidopsis thaliana 7395 9050 XP_002883169 297853636 0.7164 Arabidopsis lyrata 7396 subsp. lyrata CBI32416 270245997 0.7313 Vitis vinifera 7397 9051 324-343 XP_003550774 356565082 1 Glycine max 7398 9052 XP_003525472 356513541 0.8489 Glycine max 7399 9053 324-343 XP_003550774 356565082 1 Glycine max 7400 9054 680-699 XP_003554964 356573636 1 Glycine max 7401 9055 ptc-miRf11757-akr 404-426 XP_003612685 357484794 1 Medicago truncatula 7402 9056 XP_003516858 356495999 0.8914 Glycine max 7403 9057 XP_003534304 356531476 0.8801 Glycine max 7404 9058 BAH03477 218744535 0.8015 Nicotiana tabacum 7405 9059 XP_002519001 255761086 0.824 Ricinus communis 7406 XP_002303454 255761085 0.8127 Populus trichocarpa 7407 ABK93338 118482845 0.8052 Populus trichocarpa 7408 9060 XP_002326571 255761085 0.8015 Populus trichocarpa 7409 XP_002274060 225427054 0.764 Vitis vinifera 7410 9061 XP_002890966 297853636 0.7603 Arabidopsis lyrata 7411 subsp. lyrata ath-miR157a 164-184 XP_003549130 356561725 1 Glycine max 7412 9062 XP_003553944 356571558 0.9452 Glycine max 7413 9063 238-258 XP_003551188 356565928 1 Glycine max 7414 9064 XP_003538544 356540131 0.9106 Glycine max 7415 9065 ACU18328 255635963 0.9083 Glycine max 7416 9066 XP_003601767 357462970 0.7064 Medicago truncatula 7417 9067 1129-1149 XP_003525415 356513426 1 Glycine max 7418 9068 XP_003532399 356527605 0.9051 Glycine max 7419 9069 898-918 XP_003540473 356544059 1 Glycine max 7420 9070 XP_003543233 356549706 0.9305 Glycine max 7421 9071 ACU24116 255647298 0.9251 Glycine max 7422 9072 118-138 XP_003525436 356513468 1 Glycine max 7423 9073 XP_003550708 356564947 0.9204 Glycine max 7424 9074 XP_003522278 356507037 0.7595 Glycine max 7425 9075 77-97 XP_003520455 356503312 1 Glycine max 7426 9076 XP_003530170 356523079 0.848 Glycine max 7427 9077 498-518 XP_003553428 356570509 1 Glycine max 7428 9078 XP_003520534 356503475 0.9081 Glycine max 7429 9079 50-70 XP_003550708 356564947 1 Glycine max 7430 9080 XP_003525436 356513468 0.9373 Glycine max 7431 9081 854-875 XP_003555667 356575073 1 Glycine max 7432 9082 170-190 XP_003538544 356540131 1 Glycine max 7433 9083 XP_003551188 356565928 0.9097 Glycine max 7434 9084 593-613 NP_001236309 351724988 1 Glycine max 7435 9085 XP_003529339 356521389 0.838 Glycine max 7436 9086 144-164 XP_002275728 225446415 1 Vitis vinifera 7437 9087 AAY16440 62856978 0.7396 Betula platyphylla 7438 9088 112-132 XP_003522278 356507037 1 Glycine max 7439 9089 396-416 XP_003520128 356502644 1 Glycine max 7440 9090 XP_003517860 356498034 0.9129 Glycine max 7441 9091 181-201 XP_003523155 356508826 1 Glycine max 7442 9092 593-613 NP_001236309 351724988 1 Glycine max 7443 9093 116-136 ACU18105 255635506 1 Glycine max 7444 9094 758-778 XP_003518080 356498481 1 Glycine max 7445 9095 XP_003551421 356566402 0.8408 Glycine max 7446 9096 120-140 XP_003549130 356561725 1 Glycine max 7447 693-713 XP_003525415 356513426 1 Glycine max 7448 9097 737-757 XP_003553428 356570509 1 Glycine max 7449 9098 116-136 XP_003538544 356540131 1 Glycine max 7450 9099 818-838 XP_003553944 356571558 1 Glycine max 7451 9100 238-258 XP_003551188 356565928 1 Glycine max 7452 9101 1070-1090 XP_003525436 356513468 1 Glycine max 7453 9102 109-129 XP_003520455 356503312 1 Glycine max 7454 9103 404-424 XP_003526029 356514674 1 Glycine max 7455 9104 XP_003540122 356543345 0.8919 Glycine max 7456 9105 181-201 XP_003523155 356508826 1 Glycine max 7457 9106 713-733 XP_003551421 356566402 1 Glycine max 7458 9107 XP_003518080 356498481 0.7962 Glycine max 7459 9108 sbi-miR159a 305-325 XP_003541823 356546825 1 Glycine max 7460 9109 305-325 XP_003541823 356546825 1 Glycine max 7461 9110 289-309 XP_003518627 356499601 1 Glycine max 7462 9111 XP_003542153 356547506 0.9478 Glycine max 7463 9112 ADN33938 307136081 0.7937 Cucumis melo 7464 9113 subsp. melo XP_002518919 255761086 0.7755 Ricinus communis 7465 XP_002279642 225426567 0.7755 Vitis vinifera 7466 9114 XP_002870592 297853636 0.7664 Arabidopsis lyrata 7467 subsp. lyrata NP_199024 30693991 0.7642 Arabidopsis thaliana 7468 9115 AAM63843 21405504 0.7596 Arabidopsis thaliana 7469 9116 XP_002299422 255761085 0.7528 Populus trichocarpa 7470 XP_002303695 255761085 0.7574 Populus trichocarpa 7471 124-144 XP_003543825 356550908 1 Glycine max 7472 9117 XP_003556814 356577399 0.813 Glycine max 7473 9118 461-481 XP_003542153 356547506 1 Glycine max 7474 9119 XP_003518627 356499601 0.9436 Glycine max 7475 9120 839-859 XP_003526354 356515330 1 Glycine max 7476 9121 XP_003523913 356510372 0.9333 Glycine max 7477 9122 73-93 XP_003535315 356533526 1 Glycine max 7478 9123 XP_003555178 356574075 0.9462 Glycine max 7479 9124 XP_003591226 357441896 0.7849 Medicago truncatula 7480 9125 XP_002512536 255761086 0.7465 Ricinus communis 7481 CBI39621 270257428 0.7465 Vitis vinifera 7482 9126 CAP59645 163913883 0.7558 Vitis vinifera 7483 9127 XP_002277312 225450534 0.7496 Vitis vinifera 7484 9128 XP_002280462 225432056 0.7404 Vitis vinifera 7485 9129 CAP59646 163913885 0.7512 Vitis vinifera 7486 9130 CAN63178 123711273 0.7373 Vitis vinifera 7487 9131 614-634 XP_003541563 356546291 1 Glycine max 7488 9132 XP_003545791 356554924 0.805 Glycine max 7489 9133 905-925 XP_003556814 356577399 1 Glycine max 7490 9134 XP_003543825 356550908 0.8659 Glycine max 7491 9135 smo-miR156b 164-184 XP_003549130 356561725 1 Glycine max 7492 9136 XP_003553944 356571558 0.9452 Glycine max 7493 9137 238-258 XP_003551188 356565928 1 Glycine max 7494 9138 XP_003538544 356540131 0.9106 Glycine max 7495 9139 ACU18328 255635963 0.9083 Glycine max 7496 9140 XP_003601767 357462970 0.7064 Medicago truncatula 7497 9141 1129-1149 XP_003525415 356513426 1 Glycine max 7498 9142 XP_003532399 356527605 0.9051 Glycine max 7499 9143 118-138 XP_003525436 356513468 1 Glycine max 7500 9144 XP_003550708 356564947 0.9204 Glycine max 7501 9145 XP_003522278 356507037 0.7595 Glycine max 7502 9146 77-97 XP_003520455 356503312 1 Glycine max 7503 9147 XP_003530170 356523079 0.848 Glycine max 7504 9148 50-70 XP_003550708 356564947 1 Glycine max 7505 9149 XP_003525436 356513468 0.9373 Glycine max 7506 9150 498-518 XP_003553428 356570509 1 Glycine max 7507 9151 XP_003520534 356503475 0.9081 Glycine max 7508 9152 170-190 XP_003538544 356540131 1 Glycine max 7509 9153 XP_003551188 356565928 0.9097 Glycine max 7510 9154 593-613 NP_001236309 351724988 1 Glycine max 7511 9155 XP_003529339 356521389 0.838 Glycine max 7512 9156 475-495 XP_003528960 356520620 1 Glycine max 7513 9157 NP_001235425 351721650 0.9279 Glycine max 7514 9158 144-164 XP_002275728 225446415 1 Vitis vinifera 7515 9159 AAY16440 62856978 0.7396 Betula platyphylla 7516 9160 112-132 XP_003522278 356507037 1 Glycine max 7517 9161 396-416 XP_003520128 356502644 1 Glycine max 7518 9162 XP_003517860 356498034 0.9129 Glycine max 7519 9163 243-263 XP_003540122 356543345 1 Glycine max 7520 9164 XP_003526029 356514674 0.8684 Glycine max 7521 9165 181-201 XP_003523155 356508826 1 Glycine max 7522 9166 77-97 XP_003520455 356503312 1 Glycine max 7523 9167 373-393 XP_003553428 356570509 1 Glycine max 7524 9168 761-781 XP_003520534 356503475 1 Glycine max 7525 9169 XP_003553428 356570509 0.9081 Glycine max 7526 9170 110-130 XP_003553944 356571558 1 Glycine max 7527 9171 239-259 XP_003551188 356565928 1 Glycine max 7528 9172 1022-1042 XP_003532399 356527605 1 Glycine max 7529 9173 XP_003525415 356513426 0.8914 Glycine max 7530 9174 593-613 NP_001236309 351724988 1 Glycine max 7531 9175 116-136 ACU18105 255635506 1 Glycine max 7532 9176 758-778 XP_003518080 356498481 1 Glycine max 7533 9177 XP_003551421 356566402 0.8408 Glycine max 7534 9178 1231-1251 XP_003525415 356513426 1 Glycine max 7535 9179 20-40 XP_003549130 356561725 1 Glycine max 7536 9180 1070-1090 XP_003525436 356513468 1 Glycine max 7537 9181 404-424 XP_003526029 356514674 1 Glycine max 7538 9182 XP_003540122 356543345 0.8919 Glycine max 7539 9183 185-205 XP_003538544 356540131 1 Glycine max 7540 9184 713-733 XP_003551421 356566402 1 Glycine max 7541 9185 XP_003518080 356498481 0.7962 Glycine max 7542 9186 osa-miRf10839-akr 32-52 AAM97011 22531013 1 Arabidopsis thaliana 7543 9187 NP_563815 145335272 0.9929 Arabidopsis thaliana 7544 9188 XP_002892455 297853636 0.9786 Arabidopsis lyrata 7545 subsp. lyrata BAJ33638 312281544 0.9429 Thellungiella halophila 7546 9189 XP_002523852 255761086 0.7714 Ricinus communis 7547 AEL99169 343172931 0.75 Silene latifolia 7548 9190 XP_002313603 255761085 0.7429 Populus trichocarpa 7549 ACJ86143 217075565 0.7214 Medicago truncatula 7550 9191 ADI45844 297525844 0.7429 Silene vulgaris 7551 9192 XP_002328107 255761085 0.75 Populus trichocarpa 7552 ptc-miRf10300-akr 35-54 ACJ37435 212717187 1 Glycine max 7553 9193 ACU23160 255645326 0.9948 Glycine max 7554 9194 ACJ37436 212717189 0.933 Glycine max 7555 9195 537-556 NP_001235206 351722714 1 Glycine max 7556 9196 NP_001236569 351725110 0.9581 Glycine max 7557 9197 XP_002866588 297853636 0.7126 Arabidopsis lyrata 7558 subsp. lyrata XP_002309915 255761085 0.7665 Populus trichocarpa 7559 NP_201209 145359627 0.7066 Arabidopsis thaliana 7560 9198 ABK96256 118488893 0.7605 Populus trichocarpa × 7561 9199 Populus deltoides XP_002526638 255761086 0.7485 Ricinus communis 7562 XP_002306249 255761085 0.7784 Populus trichocarpa 7563 2WSC_N 0.7844 Phaseolus vulgaris 7564 BAJ33864 312281996 0.7066 Thellungiella halophila 7565 9200 39-58 XP_002283864 225429937 1 Vitis vinifera 7566 9201 ptc-miRf10619-akr 318-339 BAG09382 167961874 1 Glycine max 7567 9202 NP_001238412 351726609 0.9838 Glycine max 7568 9203 ACU19205 255637765 0.9704 Glycine max 7569 9204 CAN67413 123711204 0.9272 Vitis vinifera 7570 9205 ACD93720 223987377 0.903 Mikania micrantha 7571 9206 XP_002862992 297853636 0.9191 Arabidopsis lyrata 7572 subsp. lyrata XP_002277249 225462095 0.9299 Vitis vinifera 7573 9207 XP_002317470 255761085 0.9218 Populus trichocarpa 7574 1803516A 0.9191 Lens culinaris 7575 XP_002519658 255761086 0.9084 Ricinus communis 7576 32-53 ACU18791 255636916 1 Glycine max 7577 9208 1512-1532 ACQ44234 228485370 1 Glycine max 7578 9209 55-75 XP_002512977 255761086 1 Ricinus communis 7579 ptc-miRf11847-akr 418-438 ACU17540 255634349 1 Glycine max 7580 9210 ath-miRf10701-akr 293-314 ACU18306 255635917 1 Glycine max 7581 9211 918-939 NP_001237102 351725712 1 Glycine max 7582 9212 XP_002284425 225445231 0.7562 Vitis vinifera 7583 9213 348-369 NP_001236604 351726125 1 Glycine max 7584 9214 1178-1199 ACU21144 255641746 1 Glycine max 7585 9215 XP_002277008 225444658 0.7859 Vitis vinifera 7586 9216 XP_002276983 225444660 0.7859 Vitis vinifera 7587 9217 CAB75429 6996559 0.7204 Nicotiana plumbaginifolia 7588 9218 XP_002331184 255761085 0.733 Populus trichocarpa 7589 XP_002529199 255761086 0.7355 Ricinus communis 7590 XP_002516242 255761086 0.7179 Ricinus communis 7591 XP_002270823 225442060 0.7254 Vitis vinifera 7592 9219 CBI35841 270253379 0.7179 Vitis vinifera 7593 CAN65009 147797980 0.7229 Vitis vinifera 7594 9220 osa-miRf11595-akr 321-339 ABB02162 77744234 1 Medicago sativa 7595 9221 ABB02161 77744232 0.975 Medicago sativa 7596 9222 ACJ85732 217074743 0.9711 Medicago truncatula 7597 9223 AEO21428 346229108 0.8227 Glycine max 7598 9224 ABC59101 84514184 0.8073 Medicago truncatula 7599 9225 ABC68398 85001688 0.7842 Glycine max 7600 9226 ABS53040 153869430 0.8073 Leucaena leucocephala 7601 9227 AAT39511 47933889 0.7553 Camptotheca acuminata 7602 9228 XP_002327769 255761085 0.7572 Populus trichocarpa 7603 XP_002327770 255761085 0.7437 Populus trichocarpa 7604 107-125 NP_001236740 351722666 1 Glycine max 7605 9229 56-74 CAE02645 34495198 1 Lotus japonicus 7606 9230 CAA65585 2347053 0.7513 Vitis vinifera 7607 9231 AAP36992 46371994 0.753 Cucumis sativus 7608 9232 BAE71301 84468435 0.7598 Trifolium pratense 7609 9233 XP_002269030 225427781 0.7445 Vitis vinifera 7610 9234 BAE71251 84468335 0.7581 Trifolium pratense 7611 9235 BAG68575 195976672 0.7496 Prunus persica 7612 9236 BAD06581 40645471 0.7394 Nicotiana tabacum 7613 9237 CAN65288 147782233 0.7291 Vitis vinifera 7614 9238 CAB64599 6646839 0.7359 Datura stramonium 7615 9239 311-329 ACU18654 255636632 1 Glycine max 7616 9240 515-533 NP_001235161 351721419 1 Glycine max 7617 9241 BAB86923 19911192 0.711 Vigna angularis 7618 9242 22-40 NP_001237655 351726929 1 Glycine max 7619 9243 421-439 ACU22898 255644792 1 Glycine max 7620 9244 osa-miRf11013-akr 407-428 NP_001237033 351723724 1 Glycine max 7621 9245 32-53 ABY84658 166203235 1 Glycine max 7622 9246 NP_001236902 351727360 0.9715 Glycine max 7623 9247 AAL32033 18158618 0.7967 Retama raetam 7624 9248 597-618 ACU23333 255645678 1 Glycine max 7625 9249 29-50 NP_001236902 351727360 1 Glycine max 7626 9250 ABY84658 166203235 0.9696 Glycine max 7627 9251 ptc-miRf10148-akr 679-698 NP_001238384 351725780 1 Glycine max 7628 9252 547-566 XP_002283799 225435835 1 Vitis vinifera 7629 9253 CAN72395 147774368 0.9606 Vitis vinifera 7630 ACU20767 255640974 0.9462 Glycine max 7631 9254 XP_002304844 255761085 1.0896 Populus trichocarpa 7632 CBI16575 270227042 0.9176 Vitis vinifera 7633 XP_002523383 255761086 0.8746 Ricinus communis 7634 XP_002299088 255761085 0.8853 Populus trichocarpa 7635 NP_850182 42570348 0.81 Arabidopsis thaliana 7636 9255 NP_565736 42569548 0.8065 Arabidopsis thaliana 7637 9256 XP_002862885 297853636 0.8029 Arabidopsis lyrata 7638 subsp. lyrata 135-154 ACU17996 255635284 1 Glycine max 7639 9257 ACU23482 255645988 0.8725 Glycine max 7640 9258 XP_002307595 255761085 0.8406 Populus trichocarpa 7641 XP_002524761 255761086 0.8319 Ricinus communis 7642 XP_002300832 255761085 0.8261 Populus trichocarpa 7643 XP_002279156 225437057 0.8029 Vitis vinifera 7644 9259 XP_002878504 297853636 0.7072 Arabidopsis lyrata 7645 subsp. lyrata 141-160 XP_002283799 225435835 1 Vitis vinifera 7646 9260 367-386 ACU17970 255635230 1 Glycine max 7647 9261 ACU18145 255635589 0.9494 Glycine max 7648 9262 XP_002510492 255761086 0.7946 Ricinus communis 7649 XP_002278539 225458064 0.7798 Vitis vinifera 7650 9263 XP_002306908 255761085 0.7619 Populus trichocarpa 7651 ABL10371 118723367 0.75 Medicago truncatula 7652 9264 XP_002301996 255761085 0.7738 Populus trichocarpa 7653 NP_568605 145358761 0.7024 Arabidopsis thaliana 7654 9265 110-129 ACU17996 255635284 1 Glycine max 7655 9266 zma-miR482-5p 122-140 ACU21375 255642220 1 Glycine max 7656 9267 128-146 XP_002314999 255761085 1 Populus trichocarpa 7657 XP_002312287 255761085 0.9432 Populus trichocarpa 7658 XP_002285502 225424638 0.8428 Vitis vinifera 7659 9268 XP_002520520 255761086 0.8341 Ricinus communis 7660 XP_002876891 297853636 0.8035 Arabidopsis lyrata 7661 subsp. lyrata NP_178465 30678070 0.7948 Arabidopsis thaliana 7662 9269 NP_001149451 226506925 0.7773 Zea mays 7663 9270 XP_002875224 297853636 0.7904 Arabidopsis lyrata 7664 subsp. lyrata NP_001054237 115461273 0.7686 Oryza sativa 7665 9271 Japonica Group CAH68184 90399185 0.7642 Oryza sativa 7666 9272 Indica Group 745-763 NP_001235027 351724922 1 Glycine max 7667 9273 NP_001238461 351728042 0.9389 Glycine max 7668 9274 NP_001235888 351727642 0.9389 Glycine max 7669 9275 NP_001235511 351724120 0.9313 Glycine max 7670 9276 ADD11814 289586041 0.8244 Cajanus cajan 7671 9277 AAC49369 1420884 0.7939 Phaseolus vulgaris 7672 9278 40-58 ACU20629 255640688 1 Glycine max 7673 9279 27-45 ACU20555 255640539 1 Glycine max 7674 9280 19-37 ACU23548 255646123 1 Glycine max 7675 9281 Q96452 0.9922 Glycine max 7676 NP_001235679 351721598 1 Glycine max 7677 9282 ACU19187 255637728 0.9457 Glycine max 7678 9283 ACU17765 255634808 0.8876 Glycine max 7679 9284 XP_002523376 255761086 0.8411 Ricinus communis 7680 ACQ45020 228552591 0.845 Cicer arietinum 7681 9285 XP_002285427 225461653 0.8256 Vitis vinifera 7682 9286 P42654 0.8372 Vicia faba 7683 XP_002316863 255761085 0.8333 Populus trichocarpa 7684 59-77 ACU24228 255647528 1 Glycine max 7685 9287 ACU18882 255637100 0.7652 Glycine max 7686 9288 XP_002276186 225429425 0.7652 Vitis vinifera 7687 9289 XP_002516481 255761086 0.7391 Ricinus communis 7688 XP_002324746 255761085 0.7304 Populus trichocarpa 7689 NP_565612 145360329 0.7217 Arabidopsis thaliana 7690 9290 XP_002880724 297853636 0.7275 Arabidopsis lyrata 7691 subsp. lyrata XP_002281479 225442372 0.7362 Vitis vinifera 7692 9291 ABB86253 82621129 0.7014 Solanum tuberosum 7693 9292 CBI35995 270253379 0.7362 Vitis vinifera 7694 296-314 NP_001237978 351721473 1 Glycine max 7695 9293 59-77 ACU18882 255637100 1 Glycine max 7696 9294 ACU24228 255647528 0.9209 Glycine max 7697 9295 NP_001031418 79323070 0.723 Arabidopsis thaliana 7698 9296 204-222 ACU20859 255641163 1 Glycine max 7699 9297  91-109 ACU15870 255631011 1 Glycine max 7700 9298 390-408 CAI43251 57283984 1 Phaseolus vulgaris 7701 9299 var. nanus ABA86966 77540215 0.937 Glycine max 7702 9300 NP_001237472 351721637 0.937 Glycine max 7703 9301 ACU23435 255645890 0.9213 Glycine max 7704 9302 XP_002283671 225434934 0.8228 Vitis vinifera 7705 9303 ACJ11723 211906459 0.8386 Gossypium hirsutum 7706 9304 ABA46792 76573374 0.8228 Solanum tuberosum 7707 9305 XP_002299871 255761085 0.815 Populus trichocarpa 7708 CAN67342 147772559 0.815 Vitis vinifera 7709 XP_002876302 297853636 0.811 Arabidopsis lyrata 7710 subsp. lyrata 61-79 ACU17423 255634119 1 Glycine max 7711 9306 140-158 ABA86966 77540215 1 Glycine max 7712 9307 CAI43251 57283984 0.9407 Phaseolus vulgaris 7713 9308 var. nanus XP_002283693 225449540 0.8261 Vitis vinifera 7714 9309 309-327 AAV87173 56404220 1 Phaseolus vulgaris 7715 9310 BAD97829 63002633 0.7487 Prunus persica 7716 9311 ptc-miRf10522-akr 79-98 ACU20325 255640067 1 Glycine max 7717 9312 321-340 ADM32504 304421409 1 Glycine max 7718 9313 CAD12837 18075959 0.8679 Lupinus luteus 7719 9314 CBI27290 270239516 0.7896 Vitis vinifera 7720 XP_002316086 255761085 0.7847 Populus trichocarpa 7721 XP_002512077 255761086 0.7765 Ricinus communis 7722 CAD12836 18075957 0.7471 Lupinus luteus 7723 9315 XP_002311341 255761085 0.7553 Populus trichocarpa 7724 NP_172830 145335664 0.7259 Arabidopsis thaliana 7725 9316 XP_002892769 297853636 0.7243 Arabidopsis lyrata 7726 subsp. lyrata 1811-1830 NP_001237605 351725462 1 Glycine max 7727 9317 NP_001235120 351727636 0.7738 Glycine max 7728 9318 osa-miRf10362-akr 663-683 ACU20209 255639831 1 Glycine max 7729 9319 309-329 XP_002531192 255761086 1 Ricinus communis 7730 XP_002298817 255761085 0.7018 Populus trichocarpa 7731 415-435 NP_001238595 351724492 1 Glycine max 7732 9320 ath-miRf10702-akr 261-280 ACU23703 255646448 1 Glycine max 7733 9321 328-347 ABD28727 49405947 1 Medicago truncatula 7734 NP_001236252 351723348 0.9592 Glycine max 7735 9322 NP_001236882 351726775 0.9456 Glycine max 7736 9323 CAG14986 45720189 0.9184 Cicer arietinum 7737 9324 XP_002268544 225442984 0.8844 Vitis vinifera 7738 9325 XP_002517623 255761086 0.8912 Ricinus communis 7739 XP_002298252 255761085 0.8707 Populus trichocarpa 7740 NP_172989 145335736 0.8639 Arabidopsis thaliana 7741 9326 EEC76567 54362548 0.8571 Oryza sativa 7742 Indica Group BAJ92153 326514005 0.8435 Hordeum vulgare 7743 9327 subsp. vulgare 690-709 ACU24052 255647167 1 Glycine max 7744 9328 NP_001237955 351720763 0.8561 Glycine max 7745 9329 ath-miRf10148-akr 343-362 NP_001234975 351723428 1 Glycine max 7746 9330 XP_002314377 255761085 0.8174 Populus trichocarpa 7747 XP_002270067 225431754 0.8119 Vitis vinifera 7748 9331 CBI22983 270234210 0.8119 Vitis vinifera 7749 XP_002328602 255761085 0.7953 Populus trichocarpa 7750 BAG16526 171854672 0.7898 Capsicum chinense 7751 9332 Q39659 0.7621 Cucumis sativus 7752 NP_187342 145338207 0.7759 Arabidopsis thaliana 7753 9333 XP_002882497 297853636 0.7718 Arabidopsis lyrata 7754 subsp. lyrata O49809 0.7552 Brassica napus 7755 176-195 NP_001235442 351722139 1 Glycine max 7756 9334 NP_001236219 351722401 0.9712 Glycine max 7757 9335 ABC46708 83776785 0.8417 Arachis hypogaea 7758 9336 Q40519 0.8201 Nicotiana tabacum 7759 NP_001234042 350537546 0.8273 Solanum lycopersicum 7760 9337 P06183 0.8201 Solanum tuberosum 7761 ADB93062 284520973 0.8273 Jatropha curcas 7762 9338 CAA27989 21490 0.8058 Solanum tuberosum 7763 9339 XP_002332206 255761085 0.7914 Populus trichocarpa 7764 ABK96223 118488825 0.7914 Populus trichocarpa × 7765 9340 Populus deltoides 80-99 ACJ85304 217073887 1 Medicago truncatula 7766 9341 ABF66654 120650107 0.9086 Ammopiptanthus mongolicus 7767 9342 ACU19677 255638744 0.9213 Glycine max 7768 9343 CBI18248 270229319 0.8807 Vitis vinifera 7769 XP_002530504 255761086 0.8858 Ricinus communis 7770 XP_002308228 255761085 0.8756 Populus trichocarpa 7771 XP_002262986 225439379 0.8807 Vitis vinifera 7772 9344 ACU23134 255645273 0.8858 Glycine max 7773 9345 ABJ97690 116292767 0.8503 Solanum tuberosum 7774 9346 XP_002322994 255761085 0.7995 Populus trichocarpa 7775 488-507 ACU23010 255645020 1 Glycine max 7776 9347  989-1008 XP_002314377 255761085 1 Populus trichocarpa 7777 NP_001234975 351723428 0.814 Glycine max 7778 9348  82-101 ABF66654 120650107 1 Ammopiptanthus mongolicus 7779 9349 ACJ85304 217073887 0.9266 Medicago truncatula 7780 9350  91-110 ACU22749 255644490 1 Glycine max 7781 9351 ath-miRf10451-akr 256-277 NP_001238139 351726107 1 Glycine max 7782 9352 NP_001237827 351724486 0.9394 Glycine max 7783 9353 NP_001237200 351721157 0.8838 Glycine max 7784 9354 NP_001236083 351725850 0.8333 Glycine max 7785 9355 143-164 NP_001238139 351726107 1 Glycine max 7786 9356 ath-miRf10751-akr 188-207 ACU18963 255637265 1 Glycine max 7787 9357 ACU21242 255641949 0.7764 Glycine max 7788 9358 23-42 ACU20965 255641375 1 Glycine max 7789 9359 XP_002301406 255761085 0.8099 Populus trichocarpa 7790 XP_002320196 255761085 0.7851 Populus trichocarpa 7791 XP_002281449 225454509 0.7879 Vitis vinifera 7792 9360 NP_566074 145361064 0.7245 Arabidopsis thaliana 7793 9361 XP_002880239 297853636 0.7245 Arabidopsis lyrata 7794 subsp. lyrata AAU93592 53793715 0.7135 Solanum demissum 7795 9362 XP_002876635 297853636 0.719 Arabidopsis lyrata 7796 subsp. lyrata NP_191729 145339747 0.7107 Arabidopsis thaliana 7797 9363 1857-1876 XP_002525341 255761086 1 Ricinus communis 7798 XP_002326656 255761085 0.8901 Populus trichocarpa 7799 CAN79431 147866563 0.8524 Vitis vinifera 7800 NP_001235564 351725644 0.8599 Glycine max 7801 9364 ADW84019 321438026 0.8419 Gossypium hirsutum 7802 9365 XP_002303363 255761085 0.8584 Populus trichocarpa 7803 2FON_A 0.8238 Solanum lycopersicum 7804 NP_001234198 350535510 0.8238 Solanum lycopersicum 7805 9366 AAW78691 58531951 0.8223 Solanum cheesmaniae 7806 XP_002868103 297853636 0.8313 Arabidopsis lyrata 7807 subsp. lyrata 738-757 CAD31838 21068663 1 Cicer arietinum 7808 9367 NP_001237954 351720733 0.9412 Glycine max 7809 9368 ACU19740 255638874 0.9314 Glycine max 7810 9369 NP_001237941 351727802 0.9118 Glycine max 7811 9370 XP_002518592 255761086 0.8824 Ricinus communis 7812 XP_002534445 255761086 0.8873 Ricinus communis 7813 AAD38143 5031274 0.8676 Prunus armeniaca 7814 9371 XP_002283286 225461208 0.8627 Vitis vinifera 7815 9372 ABN12320 124488471 0.848 Gossypium hirsutum 7816 9373 XP_002867516 297853636 0.8578 Arabidopsis lyrata 7817 subsp. lyrata 188-207 ACU18963 255637265 1 Glycine max 7818 9374  87-106 ACU21242 255641949 1 Glycine max 7819 9375 XP_002285386 225430399 0.7263 Vitis vinifera 7820 9376 CBI21096 270231236 0.7263 Vitis vinifera 7821 387-406 ABP88240 145652370 1 Glycine max 7822 9377 ppt-miR1220a 182-202 ACU23202 255645411 1 Glycine max 7823 9378 BAG06274 318612463 0.8691 Vigna unguiculata 7824 9379 CBI31552 270244444 0.7404 Vitis vinifera 7825 XP_002280217 225449239 0.7404 Vitis vinifera 7826 9380 XP_002316242 255761085 0.7652 Populus trichocarpa 7827 NP_181518 30688068 0.7111 Arabidopsis thaliana 7828 9381 XP_002879830 297853636 0.7133 Arabidopsis lyrata 7829 subsp. lyrata AAM65420 21406633 0.7088 Arabidopsis thaliana 7830 9382 NP_191133 42565959 0.7314 Arabidopsis thaliana 7831 9383 XP_002876330 297853636 0.7246 Arabidopsis lyrata 7832 subsp. lyrata 539-559 NP_001234951 351722740 1 Glycine max 7833 9384 182-202 ACU23202 255645411 1 Glycine max 7834 9385 233-253 ACU22926 255644851 1 Glycine max 7835 9386 ACU23107 255645218 0.8212 Glycine max 7836 9387 ABU93486 156739649 0.7848 Vigna angularis 7837 9388 ABK30788 116871383 0.745 Litchi chinensis 7838 9389 AAK51119 14029148 0.7152 Carica papaya 7839 9390 XP_002523709 255761086 0.7053 Ricinus communis 7840 CAA48324 311834 0.7119 Tropaeolum majus 7841 9391 XP_002275862 225436483 0.7219 Vitis vinifera 7842 9392 125-145 BAG06274 318612463 1 Vigna unguiculata 7843 9393 ath-miRf10068-akr 17-36 ABY78023 166014266 1 Glycine max 7844 9394 XP_002310310 255761085 0.815 Populus trichocarpa 7845 XP_002269295 225467972 0.7974 Vitis vinifera 7846 9395 AAX47170 61611670 0.7665 Pisum sativum 7847 9396 ACY82403 267850662 0.793 Petunia × hybrida 7848 9397 CAG27846 83999599 0.7665 Antirrhinum majus 7849 9398 CAL36572 113207064 0.7621 Misopates orontium 7850 9399 ABD66219 122056646 0.7665 Malus × domestica 7851 9400 AAF22455 6652755 0.7709 Paulownia kawakamii 7852 9401 AAP40641 30983947 0.7533 Eucalyptus occidentalis 7853 9402 816-835 AEH04452 334813894 1 Arachis hypogaea 7854 9403 XP_002512790 255761086 0.9358 Ricinus communis 7855 ACU21011 255641470 0.9309 Glycine max 7856 9404 NP_001238484 351721287 0.9309 Glycine max 7857 9405 P12858 0.9185 Pisum sativum 7858 CAA33264 20728 0.916 Pisum sativum 7859 9406 ACV32597 256862073 0.9185 Medicago sativa 7860 9407 BAJ34149 312282566 0.8938 Thellungiella halophila 7861 9408 ACT21568 251831337 0.8963 Bruguiera gymnorhiza 7862 9409 ADX97321 323650480 0.9185 Mangifera indica 7863 9410 898-917 AEH04452 334813894 1 Arachis hypogaea 7864 9411 121-140 ABC68403 85001696 1 Glycine max 7865 9412 XP_002275806 225426452 0.7992 Vitis vinifera 7866 9413 CAN80040 147844259 0.7992 Vitis vinifera 7867 9414 XP_002509820 255761086 0.803 Ricinus communis 7868 XP_002304502 255761085 0.7765 Populus trichocarpa 7869 AAZ39642 71726941 0.7708 Petunia × hybrida 7870 9415 XP_002320802 255761085 0.7557 Populus trichocarpa 7871 XP_002275115 225454267 0.7614 Vitis vinifera 7872 9416 CAN80156 147852118 0.7557 Vitis vinifera 7873 9417 XP_002882043 297853636 0.75 Arabidopsis lyrata 7874 subsp. lyrata 621-640 NP_001238484 351721287 1 Glycine max 7875 9418 AEH04452 334813894 0.9355 Arachis hypogaea 7876 9419 ABK96233 118488846 0.8958 Populus trichocarpa × 7877 9420 Populus deltoides 419-438 ACU19391 255638154 1 Glycine max 7878 9421 511-530 CAC80373 18072796 1 Capsicum annuum 7879 9422 CAC80372 18072794 0.9583 Capsicum annuum 7880 9423 P09043 0.9263 Nicotiana tabacum 7881 osa-miRf11352-akr 56-78 ACU19975 255639357 1 Glycine max 7882 9424 ACU19227 255637811 0.9593 Glycine max 7883 9425 ACU19215 255637786 0.7647 Glycine max 7884 9426 XP_002513621 255761086 0.7059 Ricinus communis 7885 XP_002318354 255761085 0.724 Populus trichocarpa 7886 ath-miRf11021-akr 134-154 NP_001236767 351723442 1 Glycine max 7887 9427 18-38 ACJ84983 217073247 1 Medicago truncatula 7888 9428 O48905 0.991 Medicago sativa 7889 CAC10208 10334492 0.9639 Cicer arietinum 7890 9429 NP_001236661 351727792 0.9518 Glycine max 7891 9430 XP_002332745 255761085 0.9428 Populus trichocarpa 7892 XP_002533463 255761086 0.9398 Ricinus communis 7893 AEB60994 328908588 0.9488 Lupinus angustifolius 7894 9431 XP_002312583 255761085 0.9367 Populus trichocarpa 7895 CAH58641 52851185 0.9247 Plantago major 7896 9432 ABC01890 83283964 0.9337 Solanum tuberosum 7897 9433 aly-miR831-5p 234-256 XP_002513787 255761086 1 Ricinus communis 7898 XP_002337051 255761085 0.7 Populus trichocarpa 7899 XP_002300997 255761085 0.7174 Populus trichocarpa 7900 far-miR1134 222-245 ACF22880 193850552 1 Glycine max 7901 9434 XP_002325840 255761085 0.7248 Populus trichocarpa 7902 XP_002281809 225441606 0.7202 Vitis vinifera 7903 9435 ABK95741 118487835 0.7294 Populus trichocarpa 7904 9436 XP_002319160 255761085 0.7248 Populus trichocarpa 7905 XP_002525421 255761086 0.7018 Ricinus communis 7906 48-71 CAD31838 21068663 1 Cicer arietinum 7907 9437 NP_001237954 351720733 0.9412 Glycine max 7908 9438 ACU19740 255638874 0.9314 Glycine max 7909 9439 NP_001237941 351727802 0.9118 Glycine max 7910 9440 XP_002518592 255761086 0.8824 Ricinus communis 7911 XP_002534445 255761086 0.8873 Ricinus communis 7912 AAD38143 5031274 0.8676 Prunus armeniaca 7913 9441 XP_002283286 225461208 0.8627 Vitis vinifera 7914 9442 ABN12320 124488471 0.848 Gossypium hirsutum 7915 9443 XP_002867516 297853636 0.8578 Arabidopsis lyrata 7916 subsp. lyrata 39-62 AAD49742 5733805 1 Pisum sativum 7917 9444 AAM97354 22476945 0.9894 Pisum sativum 7918 9445 AAD33959 4929351 0.9814 Pisum sativum 7919 9446 ACU21225 255641912 0.9204 Glycine max 7920 9447 XP_002313052 255761085 0.9072 Populus trichocarpa 7921 XP_002284375 225428500 0.8992 Vitis vinifera 7922 9448 XP_002509478 255761086 0.8992 Ricinus communis 7923 XP_002306098 255761085 0.8992 Populus trichocarpa 7924 P93563 0.8674 Solanum tuberosum 7925 P93397 0.87 Nicotiana tabacum 7926 180-203 ACC85689 186477889 1 Medicago truncatula 7927 9449 NP_001235733 351734425 0.8957 Glycine max 7928 9450 XP_002318640 255761085 0.872 Populus trichocarpa 7929 XP_002322155 255761085 0.8768 Populus trichocarpa 7930 AEQ62558 352740725 0.8815 Aquilaria microcarpa 7931 9451 NP_001048088 115448616 0.8483 Oryza sativa 7932 9452 Japonica Group NP_201093 186532680 0.8531 Arabidopsis thaliana 7933 9453 NP_566897 30692961 0.8483 Arabidopsis thaliana 7934 9454 CAD42725 27527522 0.8436 Nicotiana tabacum 7935 9455 XP_002511439 255761086 0.8578 Ricinus communis 7936 819-842 NP_001235100 351727055 1 Glycine max 7937 9456 CBZ41765 323669526 0.8864 Glycine max 7938 9457 CCD42020 347630190 0.8701 Glycine max 7939 9458 180-203 ACC85689 186477889 1 Medicago truncatula 7940 9459 429-452 NP_001238108 351725208 1 Glycine max 7941 9460 NP_001238275 351722648 0.9264 Glycine max 7942 9461 ath-miRf10687-akr 1224-1244 ACO48252 226320261 1 Arachis hypogaea 7943 9462 NP_001237378 351726308 0.889 Glycine max 7944 9463 ABR29877 149789411 0.8301 Ricinus communis 7945 9464 XP_002280842 225423836 0.8205 Vitis vinifera 7946 9465 CAN62388 147809569 0.8127 Vitis vinifera 7947 XP_002893416 297853636 0.7954 Arabidopsis lyrata 7948 subsp. lyrata XP_002888679 297853636 0.7597 Arabidopsis lyrata 7949 subsp. lyrata NP_177043 42563058 0.7558 Arabidopsis thaliana 7950 9466 ACT54615 254032061 0.779 Brassica napus 7951 9467 ACN39927 224284384 0.7413 Picea sitchensis 7952 9468 735-755 ACU24612 255648320 1 Glycine max 7953 9469 ACU19270 255637904 0.771 Glycine max 7954 9470 XP_002311695 255761085 0.7252 Populus trichocarpa 7955 585-605 ACU18495 255636311 1 Glycine max 7956 9471 1116-1136 ACJ85683 217074645 1 Medicago truncatula 7957 9472 NP_001235116 351727520 0.8244 Glycine max 7958 9473 BAD81043 56744206 0.8189 Glycine max 7959 9474 O82709 0.8743 Pisum sativum 7960 AAK84429 31321895 0.7301 Brassica napus 7961 9475 XP_002866454 297853636 0.7227 Arabidopsis lyrata 7962 subsp. lyrata NP_200987 145359541 0.7246 Arabidopsis thaliana 7963 9476 XP_002511066 255761086 0.7301 Ricinus communis 7964 XP_002277666 225447724 0.7227 Vitis vinifera 7965 9477 CAN83091 147858622 0.7227 Vitis vinifera 7966 9478 363-383 NP_001238368 351734499 1 Glycine max 7967 9479 291-311 NP_001237352 351734505 1 Glycine max 7968 9480 AAC32262 3426303 0.7348 Pisum sativum 7969 9481 NP_001238058 351723760 0.7652 Glycine max 7970 9482 AAV28488 54042994 0.7099 Populus tremula × 7971 9483 Populus alba XP_002518420 255761086 0.7155 Ricinus communis 7972 AAV49801 55276119 0.7127 Populus trichocarpa × 7973 9484 Populus deltoides ABO33478 132424650 0.732 Medicago truncatula 7974 9485 ADC35600 285804238 0.7155 Prunus persica 7975 9486 AAG27464 11037019 0.7293 Medicago truncatula 7976 9487 XP_002271944 225444459 0.7182 Vitis vinifera 7977 9488 24-44 XP_002509851 255761086 1 Ricinus communis 7978 XP_002304516 255761085 0.863 Populus trichocarpa 7979 XP_002298015 255761085 0.8527 Populus trichocarpa 7980 XP_002278860 225426165 0.8424 Vitis vinifera 7981 9489 AAN65180 25052803 0.8346 Petroselinum crispum 7982 9490 XP_002302599 255761085 0.832 Populus trichocarpa 7983 XP_002277669 225454333 0.8269 Vitis vinifera 7984 9491 XP_002511904 255761086 0.8217 Ricinus communis 7985 ACU20804 255641048 0.8191 Glycine max 7986 9492 Q40353 0.801 Medicago sativa 7987 ath-miRf11037-akr  93-113 AEA92304 327505552 1 Hevea brasiliensis 7988 9493 ADL59582 302595186 0.9815 Hevea brasiliensis 7989 9494 XP_002284365 225435057 0.9213 Vitis vinifera 7990 9495 CAN64127 147783306 0.9213 Vitis vinifera 7991 9496 XP_002534292 255761086 0.9259 Ricinus communis 7992 BAB84326 18447920 0.9491 Nicotiana tabacum 7993 9497 AEA92307 327505558 0.9213 Hevea brasiliensis 7994 9498 BAB84324 18447916 0.912 Nicotiana tabacum 7995 9499 XP_002284071 225449602 0.9167 Vitis vinifera 7996 9500 ACU20932 255641309 0.9213 Glycine max 7997 9501 mtr-miR2119 498-518 ACJ84572 217072423 1 Medicago truncatula 7998 9502 ACU20200 255639813 0.8895 Glycine max 7999 9503 XP_002520842 255761086 0.8226 Ricinus communis 8000 CBI25388 270236032 0.8072 Vitis vinifera 8001 9504 XP_002325811 255761085 0.8046 Populus trichocarpa 8002 Q42967 0.7841 Nicotiana tabacum 8003 1J93_A 0.7738 Nicotiana tabacum 8004 XP_002274385 225448634 0.7584 Vitis vinifera 8005 9505 XP_002879873 297853636 0.7661 Arabidopsis lyrata 8006 subsp. lyrata NP_001050049 115452896 0.7506 Oryza sativa 8007 9506 Japonica Group 153-173 CAA80691 452768 1 Phaseolus acutifolius 8008 9507 CAA80692 452766 0.9974 Phaseolus acutifolius 8009 9508 AAO72531 29373060 0.9421 Lotus corniculatus 8010 9509 CAG30579 51587337 0.9395 Lotus japonicus 8011 9510 P13603 0.9237 Trifolium repens 8012 P12886 0.9184 Pisum sativum 8013 XP_002309899 255761085 0.8868 Populus trichocarpa 8014 XP_002328464 255761085 0.8737 Populus trichocarpa 8015 ABK95643 118487635 0.8789 Populus trichocarpa 8016 9511 XP_002309900 255761085 0.8763 Populus trichocarpa 8017 osa-miR2055 514-534 ACU20018 255639446 1 Glycine max 8018 9512 ptc-miRf10132-akr 129-151 XP_003527653 356517960 1 Glycine max 8019 9513 XP_003523542 356509614 0.7828 Glycine max 8020 9514 tae-miR2003  89-110 ABC47858 83853825 1 Glycine max 8021 9515 1828-1849 ABC47841 83853806 1 Glycine max 8022 9516 XP_002283105 225438780 0.7143 Vitis vinifera 8023 9517 BAJ53195 317106690 0.7032 Jatropha curcas 8024 XP_002284923 225458677 0.746 Vitis vinifera 8025 9518 BAJ53194 317106690 0.7095 Jatropha curcas 8026 XP_002301171 255761085 0.7524 Populus trichocarpa 8027 XP_002327166 255761085 0.746 Populus trichocarpa 8028 CBI19489 270252251 0.7397 Vitis vinifera 8029 XP_002510185 255761086 0.7111 Ricinus communis 8030 AAK30205 13560782 0.7016 Daucus carota 8031 9519 osa-miRf11829-akr 166-186 AAA74456 500752 1 Phaseolus vulgaris 8032 9520 XP_003529397 356521507 0.933 Glycine max 8033 9521 XP_003518837 356500028 0.9175 Glycine max 8034 9522 XP_003607969 357475366 0.8763 Medicago truncatula 8035 9523 AAB50233 1906001 0.9021 Glycine max 8036 9524 CAC06095 9968472 0.8797 Lotus japonicus 8037 9525 ADJ68001 300119951 0.8488 Gossypium hirsutum 8038 9526 XP_002518763 255761086 0.8265 Ricinus communis 8039 XP_002330328 255761085 0.8196 Populus trichocarpa 8040 ABK95605 118487556 0.8179 Populus trichocarpa 8041 9527 134-154 CBI32147 270260094 1 Vitis vinifera 8042 9528 XP_002315592 255761085 0.8512 Populus trichocarpa 8043 XP_003556331 356576422 0.8095 Glycine max 8044 9529 XP_002262666 225424668 0.9683 Vitis vinifera 8045 9530 XP_002312609 255761085 0.8333 Populus trichocarpa 8046 XP_003536266 356535465 0.8036 Glycine max 8047 9531 XP_003590703 357440850 0.8472 Medicago truncatula 8048 9532 ADN33838 307135962 0.871 Cucumis melo 8049 9533 subsp. melo ACF86937 194705705 0.756 Zea mays 8050 9534 NP_001152185 226494944 0.7421 Zea mays 8051 9535 345-365 XP_003522862 356508229 1 Glycine max 8052 9536 XP_003533465 356529778 0.9262 Glycine max 8053 9537 302-322 XP_003546711 356556804 1 Glycine max 8054 9538 XP_003542817 356548860 0.9169 Glycine max 8055 9539 XP_003627885 357515192 0.7569 Medicago truncatula 8056 9540 236-256 XP_003526444 356515512 1 Glycine max 8057 CBI20954 270231236 0.7572 Vitis vinifera 8058 XP_003603503 357466436 0.758 Medicago truncatula 8059 XP_002516594 255761086 0.7337 Ricinus communis 8060 XP_002308627 255761085 0.7281 Populus trichocarpa 8061 XP_002282016 225430126 0.756 Vitis vinifera 8062 564-584 XP_002509464 255761086 1 Ricinus communis 8063 XP_002329785 255761085 0.8641 Populus trichocarpa 8064 XP_003543041 356549318 0.8345 Glycine max 8065 9541 XP_002305792 255761085 0.8746 Populus trichocarpa 8066 XP_003545990 356555337 0.8537 Glycine max 8067 9542 NP_193830 30685267 0.8084 Arabidopsis thaliana 8068 9543 AAL38704 17528987 0.8066 Arabidopsis thaliana 8069 9544 XP_002869916 297853636 0.8049 Arabidopsis lyrata 8070 subsp. lyrata ABF69959 102139737 0.7787 Musa acuminata 8071 9545 XP_002863589 297853636 0.7805 Arabidopsis lyrata 8072 subsp. lyrata  92-112 AAT35563 47558925 1 Phaseolus vulgaris 8073 9546 NP_001237920 351727189 0.8889 Glycine max 8074 9547 XP_003556188 356576132 0.8468 Glycine max 8075 9548 CAA06615 3413499 0.7387 Pisum sativum 8076 9549 30-50 XP_003530858 356524482 1 Glycine max 8077 9550 123-143 XP_003629209 357517840 1 Medicago truncatula 8078 9551 XP_003520082 356502550 0.8531 Glycine max 8079 9552 XP_003547906 356559235 0.8431 Glycine max 8080 9553 CBI20672 270231236 0.7496 Vitis vinifera 8081 XP_002279909 225429561 0.7613 Vitis vinifera 8082 9554 XP_002516094 255761086 0.7963 Ricinus communis 8083 BAK61816 343887266 0.7947 Citrus unshiu 8084 9555 XP_002308543 255761085 0.7813 Populus trichocarpa 8085 XP_002873542 297853636 0.7496 Arabidopsis lyrata 8086 subsp. lyrata NP_568256 18416731 0.7379 Arabidopsis thaliana 8087 9556 427-447 ACI23460 207113464 1 Glycine soja 8088 9557 XP_003544485 356552257 0.9828 Glycine max 8089 9558 NP_001235613 351727089 0.8798 Glycine max 8090 9559 ACU20715 255640864 0.8197 Glycine max 8091 9560 212-232 NP_001236871 351726450 1 Glycine max 8092 9561 XP_003523441 356509406 0.9197 Glycine max 8093 9562 ACS94038 242877144 0.8294 Cicer arietinum 8094 9563 XP_003602038 357463512 0.8261 Medicago truncatula 8095 9564 ACD39411 187940570 0.7759 Arachis hypogaea 8096 9565 AER45736 354992034 0.786 Medicago sativa 8097 9566 XP_002520341 255761086 0.7425 Ricinus communis 8098 AEF80001 333696915 0.7258 Corylus heterophylla 8099 9567 ACI15342 206584338 0.7324 Gossypium hirsutum 8100 9568 ADL36795 302399000 0.7492 Malus × domestica 8101 9569 616-636 XP_003534059 356530984 1 Glycine max 8102 9570 XP_003548267 356559966 0.8665 Glycine max 8103 9571 XP_003619718 357498858 0.7211 Medicago truncatula 8104 9572 118-138 XP_003589961 357439368 1 Medicago truncatula 8105 9573 XP_003535239 356533372 0.8081 Glycine max 8106 9574 XP_003519713 356501802 0.8046 Glycine max 8107 9575 XP_002514955 255761086 0.7729 Ricinus communis 8108 XP_002315622 255761085 0.7817 Populus trichocarpa 8109 CAA58823 639833 0.7676 Solanum tuberosum 8110 9576 NP_001148767 226532264 0.7588 Zea mays 8111 9577 XP_003557368 357111130 0.7588 Brachypodium distachyon 8112 9578 BAJ94094 326490040 0.7711 Hordeum vulgare 8113 9579 subsp. vulgare NP_196470 145357793 0.7835 Arabidopsis thaliana 8114 9580  92-112 XP_003597553 357454544 1 Medicago truncatula 8115 9581 XP_003542066 356547327 0.8553 Glycine max 8116 9582 XP_003546745 356556873 0.8496 Glycine max 8117 9583 XP_002514088 255761086 0.8177 Ricinus communis 8118 Q9MT28 0.7857 Solanum tuberosum 8119 XP_002285366 225430389 0.8233 Vitis vinifera 8120 9584 NP_194713 145349228 0.7989 Arabidopsis thaliana 8121 9585 AAB04607 1448916 0.7989 Arabidopsis thaliana 8122 9586 XP_002867385 297853636 0.7989 Arabidopsis lyrata 8123 subsp. lyrata 2C2B_A 0.7763 Arabidopsis thaliana 8124 135-155 XP_003541398 356545954 1 Glycine max 8125 9587 142-162 AAB50233 1906001 1 Glycine max 8126 9588 P38500 0.8037 Betula pendula 8127 123-143 XP_003547906 356559235 1 Glycine max 8128 9589 XP_003629209 357517840 0.8837 Medicago truncatula 8129 9590

TABLE 10 Target Genes of down-regulated Small RNA Molecules Associated with Abiotic Stress Tolerance in Soybean Plants. Mir Homolog Nucleotide Protein Binding NCBI NCBI GI Seq id Nucleotide Mir Name Position Accession number Identity Organism no: Seq id no: aly- 116-136 XP_003531153 356525075 1 Glycine max 9591 10365 miR160c- 3p XP_003524859 356512301 0.936170213 Glycine max 9592 10366 ABO61516 134142361 0.932301741 Glycine max 9593 10367 BAF62636 148189857 0.868471954 Phaseolus 9594 10368 vulgaris ABI34432 113206403 0.785299807 Pisum sativum 9595 10369 XP_002312450 255761085 0.767891683 Populus 9596 trichocarpa XP_002284648 225424290 0.735009671 Vitis vinifera 9597 10370 BAG16374 171702836 0.721470019 Brassica 9598 10371 oleracea var. italica AEK06229 339779228 0.733075435 Vitis vinifera 9599 10372 bdi- 699-720 XP_003600994 357461424 1 Medicago 9600 10373 miR2508 truncatula XP_003538485 356540010 0.862608696 Glycine max 9601 10374 NP_001236616 351726477 0.850434783 Glycine max 9602 10375 XP_003519418 356501206 0.810434783 Glycine max 9603 10376 XP_003544045 356551362 0.812173913 Glycine max 9604 10377 XP_003616702 357492826 0.803478261 Medicago 9605 10378 truncatula XP_002520796 255761086 0.76 Ricinus 9606 communis XP_002315131 255761085 0.766956522 Populus 9607 trichocarpa ABK92474 118481040 0.768695652 Populus 9608 10379 trichocarpa XP_002312186 255761085 0.765217391 Populus 9609 trichocarpa 719-740 XP_003520941 356504312 1 Glycine max 9610 10380 XP_003520942 356504314 0.820557491 Glycine max 9611 10381 XP_003516921 356496125 0.740418118 Glycine max 9612 10382 73-94 XP_003540719 356544563 1 Glycine max 9613 10383 XP_003539077 356541217 0.940068493 Glycine max 9614 10384 XP_003606701 357472832 0.821917808 Medicago 9615 10385 truncatula CBI16224 270227042 0.741438356 Vitis vinifera 9616 CAN60348 147789065 0.731164384 Vitis vinifera 9617 10386 XP_002313424 255761085 0.75 Populus 9618 trichocarpa XP_002284473 225435091 0.729452055 Vitis vinifera 9619 10387 XP_002278215 225449449 0.731164384 Vitis vinifera 9620 10388 CBI16199 270227042 0.724315068 Vitis vinifera 9621 651-672 XP_003516921 356496125 1 Glycine max 9622 10389 XP_003520941 356504312 0.75308642 Glycine max 9623 10390 77-98 XP_003522150 356506771 1 Glycine max 9624 10391 XP_003516941 356496165 0.967684022 Glycine max 9625 10392 XP_003604619 357468668 0.845601436 Medicago 9626 10393 truncatula XP_002322961 255761085 0.782764811 Populus 9627 trichocarpa XP_002533894 255761086 0.763016158 Ricinus 9628 communis XP_002278638 225440625 0.782764811 Vitis vinifera 9629 10394 XP_002322962 255761085 0.777378815 Populus 9630 trichocarpa XP_002308209 255761085 0.771992819 Populus 9631 trichocarpa XP_003552227 356568050 0.822262118 Glycine max 9632 10395 AAC49536 1685086 0.755834829 Nicotiana 9633 10396 tabacum  86-107 CAN73336 147800866 1 Vitis vinifera 9634 XP_002282815 225449411 0.990859232 Vitis vinifera 9635 10397 XP_002282823 225449413 0.946983547 Vitis vinifera 9636 10398 XP_002278232 225449451 0.936014625 Vitis vinifera 9637 10399 CAN60069 147779995 0.92321755 Vitis vinifera 9638 CAN72263 147821463 0.92321755 Vitis vinifera 9639 10400 XP_002278275 225449453 0.91773309 Vitis vinifera 9640 10401 585-606 XP_003516921 356496125 1 Glycine max 9641 10402 549-570 XP_003606701 357472832 1 Medicago 9642 10403 truncatula XP_003540719 356544563 0.839316239 Glycine max 9643 10404 XP_003623041 357505504 0.733333333 Medicago 9644 10405 truncatula XP_003551448 356566457 0.714529915 Glycine max 9645 10406 XP_003532315 356527432 0.712820513 Glycine max 9646 10407 164-185 XP_003529133 356520972 1 Glycine max 9647 10408 XP_003552215 356568025 0.954385965 Glycine max 9648 10409 XP_003529131 356520968 0.722807018 Glycine max 9649 10410 ABC59623 84626065 0.721052632 Pisum sativum 9650 10411 3846-3867 XP_003551446 356566453 1 Glycine max 9651 699-720 XP_003600994 357461424 1 Medicago 9652 10412 truncatula 261-282 XP_003520941 356504312 1 Glycine max 9653 10413 576-597 XP_003604619 357468668 1 Medicago 9654 10414 truncatula XP_003522150 356506771 0.845601436 Glycine max 9655 10415 XP_002308208 255761085 0.777378815 Populus 9656 trichocarpa  0-21 XP_003516941 356496165 1 Glycine max 9657 10416 645-666 CBI16199 270227042 1 Vitis vinifera 9658 CAN80346 147858024 0.924028269 Vitis vinifera 9659 10417 XP_003552160 356567914 0.85335689 Glycine max 9660 10418 XP_002329138 255761085 0.846289753 Populus 9661 trichocarpa XP_002299296 255761085 0.85335689 Populus 9662 trichocarpa XP_002531824 255761086 0.848056537 Ricinus 9663 communis 690-711 XP_003530212 356523164 1 Glycine max 9664 10419 XP_003551482 356566526 0.955094991 Glycine max 9665 10420 XP_002308164 255761085 0.778929188 Populus 9666 trichocarpa XP_002531565 255761086 0.772020725 Ricinus 9667 communis CAA74105 3805963 0.773747841 Populus 9668 10421 trichocarpa XP_002300066 255761085 0.730569948 Populus 9669 trichocarpa 681-702 XP_003530213 356523166 1 Glycine max 9670 10422 XP_003552179 356567952 0.915447154 Glycine max 9671 10423 XP_003532290 356527381 0.765853659 Glycine max 9672 10424 XP_002309069 255761085 0.733333333 Populus 9673 trichocarpa XP_002531562 255761086 0.726829268 Ricinus 9674 communis XP_002271006 225440401 0.713821138 Vitis vinifera 9675 10425 XP_002268628 225440403 0.713821138 Vitis vinifera 9676 10426 XP_002269038 225440405 0.707317073 Vitis vinifera 9677 10427 CBI30529 270242856 0.704065041 Vitis vinifera 9678 651-672 XP_003551482 356566526 1 Glycine max 9679 10428 XP_003530212 356523164 0.960069444 Glycine max 9680 10429 666-687 XP_003539958 356543013 1 Glycine max 9681 10430 XP_003551299 356566152 0.941605839 Glycine max 9682 10431 XP_003518300 356498931 0.879562044 Glycine max 9683 10432 XP_003544873 356553053 0.881386861 Glycine max 9684 10433 XP_003615575 357490574 0.855839416 Medicago 9685 10434 truncatula XP_002520425 255761086 0.822992701 Ricinus 9686 communis XP_002314124 255761085 0.812043796 Populus 9687 trichocarpa XP_002299828 255761085 0.813868613 Populus 9688 trichocarpa XP_002280416 225434677 0.79379562 Vitis vinifera 9689 10435  86-107 CAN73336 147800866 1 Vitis vinifera 9690 121-142 XP_003615575 357490574 1 Medicago 9691 10436 truncatula XP_003539958 356543013 0.777403035 Glycine max 9692 10437 1113-1134 XP_003548937 356561332 1 Glycine max 9693 10438 XP_003519950 356502284 0.814741036 Glycine max 9694 10439 XP_002319173 255761085 0.802788845 Populus 9695 trichocarpa XP_002325825 255761085 0.794820717 Populus 9696 trichocarpa CAN70030 147821579 0.790836653 Vitis vinifera 9697 10440 XP_002525455 255761086 0.778884462 Ricinus 9698 communis XP_002304847 255761085 0.780876494 Populus 9699 trichocarpa XP_003625586 357510594 0.784860558 Medicago 9700 10441 truncatula XP_003607828 357475084 0.778884462 Medicago 9701 10442 truncatula XP_002523396 255761086 0.782868526 Ricinus 9702 communis 633-654 XP_003551299 356566152 1 Glycine max 9703 10443 1051-1072 XP_003520176 356502743 1 Glycine max 9704 10444 XP_003528495 356519673 0.93444227 Glycine max 9705 10445 XP_003608057 357475542 0.777886497 Medicago 9706 10446 truncatula 636-657 XP_003552213 356568021 1 Glycine max 9707 10447 XP_003529132 356520970 0.732517483 Glycine max 9708 10448 XP_003552214 356568023 0.723776224 Glycine max 9709 10449 XP_003529133 356520972 0.708041958 Glycine max 9710 10450 666-687 XP_003544873 356553053 1 Glycine max 9711 10451 666-687 XP_003552227 356568050 1 Glycine max 9712 10452 777-798 XP_003529132 356520970 1 Glycine max 9713 10453 XP_003552213 356568021 0.708551483 Glycine max 9714 10454 654-675 XP_003552215 356568025 1 Glycine max 9715 10455 660-681 XP_003529131 356520968 1 Glycine max 9716 10456 636-657 XP_003539077 356541217 1 Glycine max 9717 10457 XP_003551449 356566459 0.712328767 Glycine max 9718 10458 693-714 XP_003538485 356540010 1 Glycine max 9719 10459 CBI25418 270236032 0.785349233 Vitis vinifera 9720 10460 567-588 XP_003552179 356567952 1 Glycine max 9721 10461 XP_003530213 356523166 0.964041096 Glycine max 9722 10462 gma- 138-158 XP_003527195 356517033 1 Glycine max 9723 10463 miR2119 XP_003527162 356516966 0.885620915 Glycine max 9724 10464 XP_003527196 356517035 0.866013072 Glycine max 9725 10465 XP_003522929 356508367 0.81372549 Glycine max 9726 10466 XP_003522930 356508369 0.839869281 Glycine max 9727 10467 ACU24029 255647121 0.833333333 Glycine max 9728 10468 157-177 XP_003542005 356547201 1 Glycine max 9729 10469 ACU18712 255636755 0.994722955 Glycine max 9730 10470 XP_003545664 356554663 0.939313984 Glycine max 9731 10471 AAN03476 22597177 0.936675462 Glycine max 9732 10472 XP_003544738 356552774 0.802110818 Glycine max 9733 10473 AAO72531 29373060 0.807387863 Lotus 9734 10474 corniculatus CAA80691 452768 0.799472296 Phaseolus 9735 10475 acutifolius CAG30579 51587337 0.80474934 Lotus 9736 10476 japonicus AET21261 356582741 0.802110818 Lotus 9737 10477 japonicus P13603 0.799472296 Trifolium 9738 repens 526-546 XP_003521584 356505611 1 Glycine max 9739 10478 XP_003554536 356572764 0.971098266 Glycine max 9740 10479 XP_003536003 356534928 0.809248555 Glycine max 9741 10480 XP_003518934 356500225 0.800578035 Glycine max 9742 10481 XP_002302739 255761085 0.789017341 Populus 9743 trichocarpa XP_002320324 255761085 0.777456647 Populus 9744 trichocarpa NP_191825 145339785 0.757225434 Arabidopsis 9745 10482 thaliana XP_002876684 297853636 0.757225434 Arabidopsis 9746 lyrata subsp. lyrata XP_002872855 297853636 0.760115607 Arabidopsis 9747 lyrata subsp. lyrata CAB83116 7362737 0.748554913 Arabidopsis 9748 10483 thaliana 2061-2081 XP_003524240 356511040 1 Glycine max 9749 10484 XP_003532800 356528417 0.955097087 Glycine max 9750 10485 XP_003630005 357519432 0.82038835 Medicago 9751 10486 truncatula XP_002317684 255761085 0.770631068 Populus 9752 trichocarpa XP_002332198 255761085 0.766990291 Populus 9753 trichocarpa XP_003533825 356530512 0.769417476 Glycine max 9754 10487 XP_003547559 356558531 0.764563107 Glycine max 9755 10488 XP_002271023 225444212 0.751213592 Vitis vinifera 9756 10489 399-419 XP_003539263 356541601 1 Glycine max 9757 10490 XP_003517354 356497002 0.913716814 Glycine max 9758 10491 XP_003611556 357482538 0.767699115 Medicago 9759 10492 truncatula CAI79403 62700758 0.71460177 Senna 9760 10493 occidentalis 265-285 XP_003554536 356572764 1 Glycine max 9761 10494 XP_003521584 356505611 0.971098266 Glycine max 9762 10495 XP_003625940 357511302 0.75433526 Medicago 9763 10496 truncatula 159-179 XP_003545664 356554663 1 Glycine max 9764 10497 XP_003542005 356547201 0.959568733 Glycine max 9765 10498 P12886 0.789757412 Pisum sativum 9766 360-380 AAO83155 29365515 1 Phaseolus 9767 10499 vulgaris XP_003534097 356531061 0.870201097 Glycine max 9768 10500 XP_003548308 356560048 0.886654479 Glycine max 9769 10501 2055-2075 XP_003532800 356528417 1 Glycine max 9770 10502 XP_003524240 356511040 0.955097087 Glycine max 9771 10503 2157-2177 XP_003547559 356558531 1 Glycine max 9772 10504 174-194 XP_003517354 356497002 1 Glycine max 9773 10505 XP_003539263 356541601 0.919821826 Glycine max 9774 10506 gso- 22-42 AAU95080 53830374 1 Glycine max 9775 10507 miR482a 22-42 AAF44087 7263110 1 Glycine max 9776 10508 AAX81296 62361234 0.714285714 Arachis 9777 10509 hypogaea 1195-1215 NP_001237600 351725318 1 Glycine max 9778 10510 XP_003556265 356576288 0.891737892 Glycine max 9779 10511 XP_003591822 357443088 0.811965812 Medicago 9780 10512 truncatula ACI46678 209419748 0.811965812 Galega 9781 10513 orientalis XP_003518682 356499714 0.740740741 Glycine max 9782 10514 XP_003516851 356495985 0.752136752 Glycine max 9783 10515 XP_003614455 357488334 0.732193732 Medicago 9784 10516 truncatula 503-523 XP_003533606 356530067 1 Glycine max 9785 10517 59-79 XP_003518623 356499593 1 Glycine max 9786 10518 XP_003591325 357442094 0.832673267 Medicago 9787 10519 truncatula XP_003626036 357511494 0.751485149 Medicago 9788 10520 truncatula XP_002515202 255761086 0.7 Ricinus 9789 communis 22-42 AAF44087 7263110 1 Glycine max 9790 10521 osa- 342-362 XP_003590416 357440276 1 Medicago 9791 10522 miR162a truncatula XP_003554409 356572505 0.775075988 Glycine max 9792 10523 XP_003521428 356505296 0.767477204 Glycine max 9793 10524 XP_003625731 357510884 0.770516717 Medicago 9794 10525 truncatula XP_002264567 225441081 0.734042553 Vitis vinifera 9795 10526 XP_003541439 356546037 0.759878419 Glycine max 9796 10527 CAN74141 147838148 0.705167173 Vitis vinifera 9797 XP_002519415 255761086 0.703647416 Ricinus 9798 communis 619-639 XP_003528812 356520321 1 Glycine max 9799 10528 XP_003528810 356520317 0.979865772 Glycine max 9800 10529 XP_003548576 356560594 0.976510067 Glycine max 9801 10530 XP_003543259 356549760 0.963087248 Glycine max 9802 10531 XP_003543258 356549758 0.959731544 Glycine max 9803 10532 ACU23594 255646218 0.966442953 Glycine max 9804 10533 ACJ85054 217073389 0.89261745 Medicago 9805 10534 truncatula XP_002329431 255761085 0.879194631 Populus 9806 trichocarpa XP_003604056 357467542 0.848993289 Medicago 9807 10535 truncatula XP_002524558 255761086 0.82885906 Ricinus 9808 communis 585-605 XP_003543259 356549760 1 Glycine max 9809 10536 XP_003528812 356520321 0.963087248 Glycine max 9810 10537 XP_002330691 255761085 0.859060403 Populus 9811 trichocarpa 1037-1057 XP_002311013 255761085 1 Populus 9812 trichocarpa XP_002315438 255761085 0.935779817 Populus 9813 trichocarpa XP_002521182 255761086 0.862385321 Ricinus 9814 communis XP_003536707 356536360 0.834862385 Glycine max 9815 10538 XP_003555872 356575487 0.830275229 Glycine max 9816 10539 XP_002268975 225450253 0.811926606 Vitis vinifera 9817 10540 144-164 XP_003548576 356560594 1 Glycine max 9818 10541 63-83 XP_003528812 356520321 1 Glycine max 9819 10542 217-237 NP_001237819 351724250 1 Glycine max 9820 10543 NP_001238239 351721616 0.964285714 Glycine max 9821 10544 ACF06595 192912973 0.898809524 Elaeis 9822 10545 guineensis Q5J907 0.892857143 Elaeis 9823 guineensis ACF06596 192912975 0.904761905 Elaeis 9824 10546 guineensis ACF06557 192910897 0.875 Elaeis 9825 10547 guineensis XP_003577266 357155873 0.845238095 Brachypodium 9826 10548 distachyon XP_002516930 255761086 0.857142857 Ricinus 9827 communis AEH05972 334854631 0.863095238 Hevea 9828 10549 brasiliensis NP_001235906 351720717 0.851190476 Glycine max 9829 10550 osa- 615-634 XP_003531377 356525528 1 Glycine max 9830 10551 miR1846e XP_003525073 356512737 0.958823529 Glycine max 9831 10552 XP_002310600 255761085 0.785294118 Populus 9832 trichocarpa XP_002307126 255761085 0.8 Populus 9833 trichocarpa XP_002280295 225438578 0.808823529 Vitis vinifera 9834 10553 XP_003523264 356509047 0.826470588 Glycine max 9835 10554 AAZ66923 37694873 0.708823529 Brassica rapa 9836 10555 ACK44524 217426787 0.708823529 Arabidopsis 9837 10556 arenosa XP_002871399 297853636 0.7 Arabidopsis 9838 lyrata subsp. lyrata NP_196563 145357839 0.702941176 Arabidopsis 9839 10557 thaliana 379-398 XP_003531668 356526120 1 Glycine max 9840 10558 XP_003529761 356522251 0.915980231 Glycine max 9841 10559 XP_003530142 356523023 0.756177924 Glycine max 9842 10560 XP_003546477 356556325 0.73476112 Glycine max 9843 10561 XP_003531667 356526118 0.731466227 Glycine max 9844 10562 114-133 XP_003529761 356522251 1 Glycine max 9845 10563 XP_003531668 356526120 0.917491749 Glycine max 9846 10564 XP_003597728 357454894 0.724422442 Medicago 9847 10565 truncatula 367-386 XP_003530142 356523023 1 Glycine max 9848 10566 XP_003597726 357454890 0.700490998 Medicago 9849 10567 truncatula osa- 256-277 NP_001105847 162464254 1 Zea mays 9850 miR2104 ABA42672 76443928 0.881188119 Zea mays 9851 Q2N2K2 0.927392739 Glycine max 9852 XP_002447301 255761094 0.907590759 Sorghum 9853 bicolor ACG23902 195604143 0.811881188 Zea mays 9854 10568 256-277 NP_001105847 162464254 1 Zea mays 9855 10569 osa- 103-122 ABU94631 156754274 1 Phaseolus 9856 10570 miRf11415- vulgaris akr XP_003536353 356535640 0.944250871 Glycine max 9857 10571 XP_003556232 356576220 0.951219512 Glycine max 9858 10572 ACU24483 255648054 0.947735192 Glycine max 9859 10573 AAC17529 3158475 0.919860627 Samanea 9860 10574 saman ACJ85173 217073625 0.905923345 Medicago 9861 10575 truncatula XP_003548070 356559566 0.891986063 Glycine max 9862 10576 BAB40143 13486941 0.888501742 Pyrus 9863 10577 communis AUC20229 255639872 0.891986063 Glycine max 9864 10578 BAD90699 60498688 0.898954704 Mimosa 9865 10579 pudica ctr-miR171 477-497 XP_003538071 356539165 1 Glycine max 9866 10580 XP_003517966 356498249 0.849056604 Glycine max 9867 10581 pta- 17-37 XP_003627005 357513432 1 Medicago 9868 10582 miR166c truncatula XP_003531652 356526088 0.921875 Glycine max 9869 10583 XP_003530109 356522957 0.923076923 Glycine max 9870 10584 XP_003530112 356522963 0.913461538 Glycine max 9871 10585 ACI13685 206572104 0.889423077 Mains × 9872 10586 domestica XP_003597690 357454818 0.894230769 Medicago 9873 10587 truncatula XP_002515977 255761086 0.887019231 Ricinus 9874 communis XP_002284003 225442500 0.890625 Vitis vinifera 9875 10588 CBI36079 270253379 0.890625 Vitis vinifera 9876 XP_003531653 356526090 0.900240385 Glycine max 9877 10589  87-107 CAN73584 147820217 1 Vitis vinifera 9878 XP_002281868 225444032 1 Vitis vinifera 9879 10590 XP_002298892 255761085 0.918343195 Populus 9880 trichocarpa XP_002332526 255761085 0.90887574 Populus 9881 trichocarpa XP_003535078 356533042 0.880473373 Glycine max 9882 10591 XP_003546255 356555874 0.882840237 Glycine max 9883 10592 AAS66760 45479745 0.878106509 Nicotiana 9884 10593 sylvestris XP_003532788 356528393 0.852071006 Glycine max 9885 10594 XP_003524993 356512573 0.840236686 Glycine max 9886 10595 ACI13683 206572100 0.820118343 Mains × 9887 10596 domestica 40-60 AAS10176 41745611 1 Antirrhinum 9888 10597 majus 1228-1248 XP_002285176 225435326 1 Vitis vinifera 9889 10598 CAN61612 147783603 0.981042654 Vitis vinifera 9890 XP_002529946 255761086 0.918246445 Ricinus 9891 communis XP_003538150 356539326 0.892180095 Glycine max 9892 10599 XP_003539764 356542618 0.895734597 Glycine max 9893 10600 ACI13684 206572102 0.888625592 Mains × 9894 10601 domestica XP_003539765 356542620 0.890995261 Glycine max 9895 10602 AAX19050 60327620 0.881516588 Populus 9896 10603 trichocarpa DAA05766 109729904 0.853080569 Lotus 9897 japonicus AAY33856 63115353 0.8507109 Gossypium 9898 10604 barbadense 557-577 XP_002298892 255761085 1 Populus 9899 trichocarpa CAN73584 147820217 0.91943128 Vitis vinifera 9900 515-535 XP_003597690 357454818 1 Medicago 9901 10605 truncatula XP_002284014 225442502 0.897129187 Vitis vinifera 9902 10606 XP_002304217 255761085 0.888755981 Populus 9903 trichocarpa 560-580 XP_002285176 225435326 1 Vitis vinifera 9904 10607 554-574 XP_003603630 357466690 1 Medicago 9905 10608 truncatula XP_003522716 356507930 0.943645084 Glycine max 9906 10609 XP_003526496 356515618 0.940047962 Glycine max 9907 10610 ACI13686 206572106 0.872901679 Malus × 9908 10611 domestica ADL36609 302398628 0.863309353 Malus × 9909 10612 domestica CBI20838 270231236 0.862110312 Vitis vinifera 9910 XP_002283717 225429913 0.862110312 Vitis vinifera 9911 10613 ACL51017 219879369 0.858513189 Citrus 9912 10614 trifoliata XP_002309538 255761085 0.868105516 Populus 9913 trichocarpa XP_002324794 255761085 0.857314149 Populus 9914 trichocarpa 40-60 AAS10176 41745611 1 Antirrhinum 9915 10615 majus 554-574 XP_003530109 356522957 1 Glycine max 9916 10616 590-610 XP_003524993 356512573 1 Glycine max 9917 10617 XP_003594520 357448488 0.781946073 Medicago 9918 10618 truncatula 25-45 XP_003522716 356507930 1 Glycine max 9919 10619 XP_003603630 357466690 0.932464455 Medicago 9920 10620 truncatula 560-580 XP_003530112 356522963 1 Glycine max 9921 10621 530-550 XP_003532788 356528393 1 Glycine max 9922 10622  87-107 CAN73584 147820217 1 Vitis vinifera 9923 566-586 XP_003531653 356526090 1 Glycine max 9924 10623 560-580 XP_003539764 356542618 1 Glycine max 9925 10624 XP_002285176 225435326 0.894674556 Vitis vinifera 9926 10625 CAC84906 18076735 0.829585799 Zinnia 9927 10626 violacea 828-848 XP_003539765 356542620 1 Glycine max 9928 10627 ptc-  81-100 XP_003548151 356559731 1 Glycine max 9929 10628 miRf10976- akr XP_003529873 356522477 0.888 Glycine max 9930 10629 XP_003548400 356560236 0.849333333 Glycine max 9931 10630 249-268 NP_001238468 351720798 1 Glycine max 9932 10631 242-261 XP_003520705 356503828 1 Glycine max 9933 10632 XP_003553607 356570870 0.874626866 Glycine max 9934 10633 295-314 XP_003533044 356528917 1 Glycine max 9935 10634 XP_003529756 356522241 0.905759162 Glycine max 9936 10635 XP_003543627 356550505 0.732984293 Glycine max 9937 10636 XP_003546548 356556469 0.722513089 Glycine max 9938 10637 XP_003597684 357454806 0.712041885 Medicago 9939 10638 truncatula XP_003597685 357454808 0.701570681 Medicago 9940 10639 truncatula 268-287 XP_003528486 356519654 1 Glycine max 9941 10640 XP_003520183 356502757 0.899071926 Glycine max 9942 10641 ptc- 66-85 XP_003524954 356512494 1 Glycine max 9943 10642 miRf11018- akr XP_003531241 356525252 0.920604915 Glycine max 9944 10643 AET04202 357518874 0.797731569 Medicago 9945 10644 truncatula AET04197 357518864 0.752362949 Medicago 9946 10645 truncatula AET04200 357518870 0.756143667 Medicago 9947 10646 truncatula ptc- 1236-1255 XP_002275990 225451234 1 Vitis vinifera 9948 10647 miRf11669- akr XP_002512253 255761086 0.916923077 Ricinus 9949 communis XP_003554689 356573071 0.895384615 Glycine max 9950 10648 XP_002319618 255761085 0.916923077 Populus 9951 trichocarpa XP_002336146 255761085 0.895384615 Populus 9952 trichocarpa XP_002328363 255761085 0.895384615 Populus 9953 trichocarpa ACU22789 255644572 0.886153846 Glycine max 9954 10649 ADN33908 307136046 0.898461538 Cucumis melo 9955 10650 subsp. melo Q43317 0.898461538 Citrullus 9956 lanatus subsp. vulgaris XP_002311629 255761085 0.901538462 Populus 9957 trichocarpa 259-278 XP_003624868 357509158 1 Medicago 9958 10651 truncatula ACJ85972 217075223 0.995098039 Medicago 9959 10652 truncatula XP_003608106 357475640 0.965686275 Medicago 9960 10653 truncatula NP_001237278 351723416 0.965686275 Glycine max 9961 10654 NP_564149 30687501 0.931372549 Arabidopsis 9962 10655 thaliana NP_001237990 351721817 0.941176471 Glycine max 9963 10656 XP_002890456 297853636 0.926470588 Arabidopsis 9964 lyrata subsp. lyrata NP_565156 186496015 0.93627451 Arabidopsis 9965 10657 thaliana XP_002887683 297853636 0.931372549 Arabidopsis 9966 lyrata subsp. lyrata AAM62756 21404242 0.926470588 Arabidopsis 9967 10658 thaliana 170-189 XP_003535921 356534761 1 Glycine max 9968 10659 XP_003519071 356500502 0.968379447 Glycine max 9969 10660 XP_002284060 225441833 0.773386034 Vitis vinifera 9970 10661 CAN82225 147852313 0.770750988 Vitis vinifera 9971 10662 XP_002532077 255761086 0.744400527 Ricinus 9972 communis XP_002323318 255761085 0.737812912 Populus 9973 trichocarpa XP_002308029 255761085 0.749670619 Populus 9974 trichocarpa CBI29841 270242856 0.753623188 Vitis vinifera 9975 10663 NP_565960 18405800 0.723320158 Arabidopsis 9976 10664 thaliana XP_002878149 297853636 0.72859025 Arabidopsis 9977 lyrata subsp. lyrata 120-139 AAQ57205 34099832 1 Populus 9978 10665 tremula × Populus alba 877-896 XP_003526542 356515711 1 Glycine max 9979 10666 XP_003523783 356510109 0.846153846 Glycine max 9980 10667 588-607 XP_002264051 225429233 1 Vitis vinifera 9981 10668 CAN64867 123673833 0.996763754 Vitis vinifera 9982 XP_002513130 255761086 0.877022654 Ricinus 9983 communis XP_003525216 356513027 0.83171521 Glycine max 9984 10669 XP_003530931 356524629 0.828478964 Glycine max 9985 10670 ACU18834 255637002 0.828478964 Glycine max 9986 10671 XP_002319995 255761085 0.834951456 Populus 9987 trichocarpa BAH79622 240846167 0.822006472 Glycine max 9988 XP_002310364 255761085 0.805825243 Populus 9989 trichocarpa XP_003631000 357521422 0.812297735 Medicago 9990 10672 truncatula 917-936 XP_003548812 356561077 1 Glycine max 9991 10673 XP_003525850 356514311 0.700787402 Glycine max 9992 10674 1246-1265 XP_003555457 356574646 1 Glycine max 9993 10675 XP_003543286 356549814 0.955497382 Glycine max 9994 10676 XP_003617150 357493722 0.756544503 Medicago 9995 10677 truncatula XP_002272310 225435984 0.712041885 Vitis vinifera 9996 10678 CBI24343 270235077 0.712041885 Vitis vinifera 9997 1320-1339 XP_003519686 356501748 1 Glycine max 9998 10679 XP_003547896 356559215 0.95412844 Glycine max 9999 10680 XP_003547897 356559217 0.95412844 Glycine max 10000 10681 XP_003517138 356496566 0.812844037 Glycine max 10001 10682 XP_003612325 357484076 0.783486239 Medicago 10002 10683 truncatula XP_003629155 357517732 0.798165138 Medicago 10003 10684 truncatula XP_003537681 356538378 0.8 Glycine max 10004 10685 602-621 XP_003520116 356502619 1 Glycine max 10005 10686 XP_002280702 225438602 0.856050955 Vitis vinifera 10006 10687 EAZ28751 54398660 0.829299363 Oryza sativa 10007 Japonica Group 214-233 XP_003554103 356571887 1 Glycine max 10008 10688 XP_003521108 356504648 0.923076923 Glycine max 10009 10689 ACU18694 255636716 0.919230769 Glycine max 10010 10690 XP_003624904 357509230 0.807692308 Medicago 10011 10691 truncatula XP_002526199 255761086 0.734615385 Ricinus 10012 communis XP_002283307 225440154 0.761538462 Vitis vinifera 10013 10692 XP_002307956 255761085 0.726923077 Populus 10014 trichocarpa XP_002876377 297853636 0.703846154 Arabidopsis 10015 lyrata subsp. lyrata 329-348 XP_003547896 356559215 1 Glycine max 10016 10693 XP_003519686 356501748 0.961182994 Glycine max 10017 10694 XP_002521706 255761086 0.715341959 Ricinus 10018 communis XP_002306425 255761085 0.71349353 Populus 10019 trichocarpa vvi- 209-228 XP_003601765 357462966 1 Medicago 10020 10695 miR394b truncatula XP_003538543 356540129 0.843010753 Glycine max 10021 10696 XP_003551172 356565895 0.868817204 Glycine max 10022 10697 ACU23751 255646552 0.864516129 Glycine max 10023 10698 ACL51019 219879373 0.767741935 Citrus 10024 10699 trifoliata ACI13687 206572108 0.761290323 Malus × 10025 10700 domestica XP_002514903 255761086 0.746236559 Ricinus 10026 communis XP_002271194 225425399 0.739784946 Vitis vinifera 10027 10701 XP_002297845 255761085 0.750537634 Populus 10028 trichocarpa XP_003531199 356525167 0.735483871 Glycine max 10029 10702 1188-1207 XP_003551172 356565895 1 Glycine max 10030 10703 256-275 XP_003593155 357445754 1 Medicago 10031 10704 truncatula XP_003547599 356558613 0.890145396 Glycine max 10032 10705 XP_003547600 356558615 0.890145396 Glycine max 10033 10706 XP_003593158 357445760 0.843295638 Medicago 10034 10707 truncatula NP_567920 186515898 0.81098546 Arabidopsis 10035 10708 thaliana AEG25668 333952413 0.814216478 Gossypium 10036 10709 hirsutum AAK68074 14573458 0.809369952 Arabidopsis 10037 10710 thaliana ADE22249 292385867 0.822294023 Ageratina 10038 10711 adenophora XP_002867182 297853636 0.809369952 Arabidopsis 10039 lyrata subsp. lyrata AEA76434 327422166 0.81098546 Gossypium 10040 10712 hirsutum 268-287 XP_003524786 356512154 1 Glycine max 10041 10713 XP_002331852 255761085 0.762032086 Populus 10042 trichocarpa XP_002316738 255761085 0.751336898 Populus 10043 trichocarpa XP_002519740 255761086 0.748663102 Ricinus 10044 communis XP_003532647 356528107 0.71657754 Glycine max 10045 10714 CAN63784 147790991 0.703208556 Vitis vinifera 10046 10715 XP_002273992 225463405 0.703208556 Vitis vinifera 10047 10716 435-454 XP_003556143 356576040 1 Glycine max 10048 10717 XP_003556144 356576042 0.964285714 Glycine max 10049 10718 XP_003536435 356535807 0.932539683 Glycine max 10050 10719 XP_003536434 356535805 0.924603175 Glycine max 10051 10720 ACU19073 255637492 0.920634921 Glycine max 10052 10721 XP_003556145 356576044 0.94047619 Glycine max 10053 10722 XP_003536436 356535809 0.900793651 Glycine max 10054 10723 XP_003556146 356576046 0.912698413 Glycine max 10055 10724 XP_003592142 357443728 0.793650794 Medicago 10056 10725 truncatula ACU23298 255645607 0.777777778 Glycine max 10057 10726 475-494 XP_003531199 356525167 1 Glycine max 10058 10727 XP_003524898 356512380 0.911699779 Glycine max 10059 10728 ACU17886 255635055 0.905077263 Glycine max 10060 10729 1104-1123 XP_003538543 356540129 1 Glycine max 10061 10730 123-142 XP_003553643 356570944 1 Glycine max 10062 10731 XP_003521540 356505523 0.763779528 Glycine max 10063 10732 29-48 NP_001058751 115470304 1 Oryza sativa 10064 10733 Japonica Group EAZ02551 54362548 0.987012987 Oryza sativa 10065 Indica Group ACG30543 195617425 0.896103896 Zea mays 10066 10734 BAJ93722 326533897 0.896103896 Hordeum 10067 10735 vulgare subsp. vulgare XP_002459234 255761094 0.883116883 Sorghum 10068 bicolor XP_003557668 357111736 0.896103896 Brachypodium 10069 10736 distachyon ACG28009 195612357 0.883116883 Zea mays 10070 10737 ACG24589 195605517 0.844155844 Zea mays 10071 10738 XP_003555981 356575711 0.87012987 Glycine max 10072 10739 XP_002284176 225438945 0.87012987 Vitis vinifera 10073 10740 1029-1048 XP_003524898 356512380 1 Glycine max 10074 10741 1245-1264 XP_003601765 357462966 1 Medicago 10075 10742 truncatula zma- 68-87 XP_002519732 255761086 1 Ricinus 10076 miR167u communis XP_002298511 255761085 0.8183391 Populus 10077 trichocarpa XP_002317300 255761085 0.801038062 Populus 10078 trichocarpa XP_002272126 225463413 0.788927336 Vitis vinifera 10079 10743 XP_003524790 356512162 0.780276817 Glycine max 10080 10744 NP_180988 145360605 0.761245675 Arabidopsis 10081 10745 thaliana XP_003532649 356528111 0.780276817 Glycine max 10082 10746 XP_002879497 297853636 0.757785467 Arabidopsis 10083 lyrata subsp. lyrata NP_568662 30694937 0.742214533 Arabidopsis 10084 10747 thaliana AAL11600 15983463 0.740484429 Arabidopsis 10085 10748 thaliana 503-522 XP_003556422 356576607 1 Glycine max 10086 10749 XP_003556421 356576605 1 Glycine max 10087 10750 XP_003536179 356535285 0.754266212 Glycine max 10088 10751 109-128 XP_003533248 356529329 1 Glycine max 10089 10752 XP_003547372 356558152 0.944690265 Glycine max 10090 10753 XP_003550546 356564612 0.778761062 Glycine max 10091 10754 XP_003528627 356519941 0.783185841 Glycine max 10092 10755 XP_003609706 357478840 0.765486726 Medicago 10093 10756 truncatula XP_002273305 225431819 0.727876106 Vitis vinifera 10094 10757 CBI22951 270234210 0.727876106 Vitis vinifera 10095 1585-1604 XP_003550723 356564979 1 Glycine max 10096 10758 XP_003550724 356564981 0.985380117 Glycine max 10097 10759 XP_003529499 356521718 0.956140351 Glycine max 10098 10760 XP_003529500 356521720 0.946393762 Glycine max 10099 10761 XP_003546300 356555968 0.819688109 Glycine max 10100 10762 XP_002314972 255761085 0.726120858 Populus 10101 trichocarpa CBI22841 270234210 0.730994152 Vitis vinifera 10102 XP_002519280 255761086 0.717348928 Ricinus 10103 communis 335-354 XP_003516798 356495878 1 Glycine max 10104 10763 29-48 XP_003525532 356513666 1 Glycine max 10105 10764 24-43 XP_003529500 356521720 1 Glycine max 10106 10765 XP_003550723 356564979 0.959486166 Glycine max 10107 10766 XP_002883053 297853636 0.707509881 Arabidopsis 10108 lyrata subsp. lyrata NP_001118648 186510162 0.70256917 Arabidopsis 10109 10767 thaliana 671-690 XP_003533338 356529518 1 Glycine max 10110 10768 314-333 XP_003529470 356521656 1 Glycine max 10111 10769 XP_003556768 356577305 0.95687885 Glycine max 10112 10770 Q43088 0.80698152 Ribulose- 10113 bisphosphate carboxylase 1MLV_A 0.747433265 Pisum sativum 10114 2H21_A 0.743326489 Pisum sativum 10115 zma- 330-350 ABE91847 61675805 1 Medicago 10116 10771 miR396b- truncatula 3p 330-350 ABE91847 61675805 1 Medicago 10117 10772 truncatula aly- 330-350 ABE91847 61675805 1 Medicago 10118 10773 miR396a- truncatula 3p 330-350 ABE91847 61675805 1 Medicago 10119 10774 truncatula gma- 224-244 NP_001235045 351725442 1 Glycine max 10120 10775 miR4412- 3p XP_002274402 225425717 0.733905579 Vitis vinifera 10121 10776 XP_002315800 255761085 0.703862661 Populus 10122 trichocarpa 1796-1816 NP_001235618 351727227 1 Glycine max 10123 10777 gma- 177-198 AAX13306 60100357 1 Lotus 10124 10778 miR482b- japonicus 5p NP_001236130 351727233 0.959641256 Glycine max 10125 10779 AAN15183 23194452 0.865470852 Gossypium 10126 10780 hirsutum AAY30856 63094568 0.874439462 Prunus dulcis 10127 10781 ABV60385 157674586 0.874439462 Carica papaya 10128 ABM69043 122938394 0.860986547 Gossypium 10129 10782 hirsutum ADD91578 291278193 0.878923767 Prunus 10130 10783 serrulata var. lannesiana AAO20104 27763669 0.860986547 Momordica 10131 10784 charantia AAD01742 4103341 0.869955157 Cucumis 10132 10785 sativus ABQ85556 148535235 0.874439462 Prunus persica 10133 10786 339-360 BAG06679 166788446 1 Phaseolus 10134 10787 vulgaris ACU20774 255640988 0.995575221 Glycine max 10135 10788 ACU24523 255648136 0.977876106 Glycine max 10136 10789 AAM91028 57472398 0.977876106 Pisum sativum 10137 10790 XP_002272971 225462010 0.96460177 Vitis vinifera 10138 10791 ABW06389 157955930 0.938053097 Gossypium 10139 10792 hirsutum ABW06392 157955936 0.933628319 Gossypium 10140 10793 hirsutum ACJ86177 217075633 0.938053097 Medicago 10141 10794 truncatula XP_002532178 255761086 0.951327434 Ricinus 10142 communis ABW06390 157955932 0.938053097 Gossypium 10143 10795 hirsutum 35-56 CAN81115 147863854 1 Vitis vinifera 10144 10796 ptc- 753-772 XP_002271271 225468315 1 Vitis vinifera 10145 10797 miRf11953- akr XP_002532424 255761086 0.945652174 Ricinus 10146 communis ACU20760 255640960 0.945652174 Glycine max 10147 10798 XP_002877709 297853636 0.940217391 Arabidopsis 10148 lyrata subsp. lyrata NP_001235421 351721538 0.934782609 Glycine max 10149 10799 NP_001236131 351727263 0.940217391 Glycine max 10150 10800 NP_190556 145339306 0.934782609 Arabidopsis 10151 10801 thaliana ACU14878 255629066 0.940217391 Glycine max 10152 10802 XP_002866698 297853636 0.923913043 Arabidopsis 10153 lyrata subsp. lyrata NP_569051 186532841 0.918478261 Arabidopsis 10154 10803 thaliana 309-328 ACU18943 255637224 1 Glycine max 10155 10804 ACU23146 255645298 0.953405018 Glycine max 10156 10805 ACJ84492 217072263 0.810035842 Medicago 10157 10806 truncatula ABK94686 118485671 0.784946237 Populus 10158 10807 trichocarpa XP_002528545 255761086 0.76702509 Ricinus 10159 communis XP_002326541 255761085 0.741935484 Populus 10160 trichocarpa XP_002278543 225427135 0.752688172 Vitis vinifera 10161 10808 XP_002274164 225454758 0.734767025 Vitis vinifera 10162 10809 XP_002303431 255761085 0.749103943 Populus 10163 trichocarpa 218-237 ACU18943 255637224 1 Glycine max 10164 10810 1421-1440 P08926 1 Pisum sativum 10165 BAE71311 84468455 0.957410562 Trifolium 10166 10811 pratense BAE71231 84468295 0.955706985 Trifolium 10167 10812 pratense BAE71302 84468437 0.954003407 Trifolium 10168 10813 pratense BAE71227 84468287 0.93867121 Trifolium 10169 10814 pratense ACJ85785 217074849 0.94548552 Medicago 10170 10815 truncatula AEO21430 346229112 0.906303237 Glycine max 10171 10816 XP_002313525 255761085 0.877342419 Populus 10172 trichocarpa AAC68501 3790440 0.889267462 Canavalia 10173 10817 lineata XP_002328161 255761085 0.865417376 Populus 10174 trichocarpa 165-184 ACU23935 255646930 1 Glycine max 10175 10818 60-79 BAE71304 84468441 1 Trifolium 10176 10819 pratense P08926 0.947939262 Pisum sativum 10177 bna- 163-183 ACU23935 255646930 1 Glycine max 10178 10820 miR2111b- 5p 1419-1439 P08926 1 Pisum sativum 10179 BAE71311 84468455 0.957410562 Trifolium 10180 10821 pratense BAE71231 84468295 0.955706985 Trifolium 10181 10822 pratense BAE71302 84468437 0.954003407 Trifolium 10182 10823 pratense BAE71227 84468287 0.93867121 Trifolium 10183 10824 pratense ACJ85785 217074849 0.94548552 Medicago 10184 10825 truncatula AEO21430 346229112 0.906303237 Glycine max 10185 10826 XP_002313525 255761085 0.877342419 Populus 10186 trichocarpa AAC68501 3790440 0.889267462 Canavalia 10187 10827 lineata XP_002328161 255761085 0.865417376 Populus 10188 trichocarpa 153-173 ACU23159 255645324 1 Glycine max 10189 10828 CAF04055 119391878 0.745098039 Nicotiana 10190 10829 benthamiana CAF25317 119391874 0.735294118 Capsicum 10191 10830 annuum XP_002306360 255761085 0.715686275 Populus 10192 trichocarpa XP_002279217 225438516 0.732026144 Vitis vinifera 10193 10831 XP_002530256 255761086 0.715686275 Ricinus 10194 communis CBI22773 270234152 0.722222222 Vitis vinifera 10195 CBI21530 270232045 0.732026144 Vitis vinifera 10196 163-183 ACU23935 255646930 1 Glycine max 10197 10832 58-78 BAE71304 84468441 1 Trifolium 10198 10833 pratense P08926 0.947939262 Pisum sativum 10199 ptc- 720-743 ACU24381 255647842 1 Glycine max 10200 10834 miRf11079- akr NP_001238255 351722074 0.996688742 Glycine max 10201 10835 NP_001235901 351728022 0.943708609 Glycine max 10202 10836 AAK84883 15148911 0.917218543 Phaseolus 10203 10837 vulgaris AEE99077 332739375 0.870860927 Medicago 10204 10838 truncatula XP_002529954 255761086 0.768211921 Ricinus 10205 communis XP_002310688 255761085 0.771523179 Populus 10206 trichocarpa XP_002307195 255761085 0.741721854 Populus 10207 trichocarpa 69-92 AAK84883 15148911 1 Phaseolus 10208 10839 vulgaris 603-626 AAK84883 15148911 1 Phaseolus 10209 10840 vulgaris 720-743 NP_001235901 351728022 1 Glycine max 10210 10841 721-744 ACU24381 255647842 1 Glycine max 10211 10842 bra- 989-1009 XP_003530952 356524671 1 Glycine max 10212 10843 miR160a- 3p XP_003525194 356512983 0.970842333 Glycine max 10213 10844 XP_003521511 356505464 0.904967603 Glycine max 10214 10845 XP_003592908 357445260 0.792656587 Medicago 10215 10846 truncatula ABE91931 61675804 0.792656587 Medicago 10216 10847 truncatula XP_003626539 357512500 0.795896328 Medicago 10217 10848 truncatula XP_002281426 225441572 0.791576674 Vitis vinifera 10218 10849 Q9XHM1 0.789416847 Medicago 10219 truncatula XP_003589347 357438142 0.782937365 Medicago 10220 10850 truncatula CAN81874 147860525 0.761339093 Vitis vinifera 10221 10851 gma- 328-349 XP_003521176 356504786 1 Glycine max 10222 10852 miR1507a gma- 507-527 XP_003554498 356572687 1 Glycine max 10223 10853 miR1524 XP_003521507 356505456 0.941358025 Glycine max 10224 10854 XP_003535834 356534585 0.712962963 Glycine max 10225 10855 XP_003519022 356500404 0.712962963 Glycine max 10226 10856 ppt- 189-209 XP_003553029 356569688 1 Glycine max 10227 10857 miR166m XP_003537529 356538072 0.931216931 Glycine max 10228 10858 XP_003601737 357462910 0.727513228 Medicago 10229 10859 truncatula 557-577 XP_002298892 255761085 1 Populus 10230 trichocarpa CAN73584 147820217 0.91943128 Vitis vinifera 10231 XP_002332526 255761085 0.94549763 Populus 10232 trichocarpa XP_002281868 225444032 0.91943128 Vitis vinifera 10233 10860 XP_003535078 356533042 0.892180095 Glycine max 10234 10861 XP_003546255 356555874 0.893364929 Glycine max 10235 10862 AAS66760 45479745 0.86492891 Nicotiana 10236 10863 sylvestris XP_003532788 356528393 0.849526066 Glycine max 10237 10864 XP_003524993 356512573 0.845971564 Glycine max 10238 10865 ACI13683 206572100 0.816350711 Malus × 10239 10866 domestica 515-535 XP_003597690 357454818 1 Medicago 10240 10867 truncatula XP_003531652 356526088 0.918660287 Glycine max 10241 10868 XP_003530109 356522957 0.921052632 Glycine max 10242 10869 XP_002284003 225442500 0.897129187 Vitis vinifera 10243 10870 CBI36079 270253379 0.897129187 Vitis vinifera 10244 XP_002515977 255761086 0.901913876 Ricinus 10245 communis XP_003530112 356522963 0.916267943 Glycine max 10246 10871 XP_002284014 225442502 0.897129187 Vitis vinifera 10247 10872 ACI13685 206572104 0.89354067 Malus × 10248 10873 domestica XP_002304217 255761085 0.888755981 Populus 10249 trichocarpa 560-580 XP_002285176 225435326 1 Vitis vinifera 10250 10874 CAN61612 147783603 0.981042654 Vitis vinifera 10251 XP_002529946 255761086 0.918246445 Ricinus 10252 communis XP_003538150 356539326 0.892180095 Glycine max 10253 10875 XP_003539764 356542618 0.895734597 Glycine max 10254 10876 ACI13684 206572102 0.888625592 Malus × 10255 10877 domestica XP_003539765 356542620 0.890995261 Glycine max 10256 10878 AAX19050 60327620 0.881516588 Populus 10257 10879 trichocarpa DAA05766 109729904 0.853080569 Lotus 10258 japonicus AAY33856 63115353 0.8507109 Gossypium 10259 10880 barbadense 554-574 XP_003603630 357466690 1 Medicago 10260 10881 truncatula XP_003522716 356507930 0.943645084 Glycine max 10261 10882 XP_003526496 356515618 0.940047962 Glycine max 10262 10883 ACI13686 206572106 0.872901679 Malus × 10263 10884 domestica ADL36609 302398628 0.863309353 Malus × 10264 10885 domestica CBI20838 270231236 0.862110312 Vitis vinifera 10265 XP_002283717 225429913 0.862110312 Vitis vinifera 10266 10886 ACL51017 219879369 0.858513189 Citrus 10267 10887 trifoliata XP_002309538 255761085 0.868105516 Populus 10268 trichocarpa XP_002324794 255761085 0.857314149 Populus 10269 trichocarpa 40-60 AAS10176 41745611 1 Antirrhinum 10270 10888 majus 554-574 XP_003530109 356522957 1 Glycine max 10271 10889 XP_003531653 356526090 0.95823389 Glycine max 10272 10890 XP_003627005 357513432 0.91646778 Medicago 10273 10891 truncatula XP_003597690 357454818 0.918854415 Medicago 10274 10892 truncatula 590-610 XP_003524993 356512573 1 Glycine max 10275 10893 XP_002298892 255761085 0.832356389 Populus 10276 trichocarpa XP_003594520 357448488 0.781946073 Medicago 10277 10894 truncatula 25-45 XP_003522716 356507930 1 Glycine max 10278 10895 XP_003603630 357466690 0.932464455 Medicago 10279 10896 truncatula 560-580 XP_003530112 356522963 1 Glycine max 10280 10897 572-592 P00965 1 Phaseolus 10281 vulgaris XP_003544980 356553268 0.935393258 Glycine max 10282 10898 XP_003519325 356501016 0.935393258 Glycine max 10283 10899 ACU19484 255638343 0.926966292 Glycine max 10284 10900 XP_003519326 356501018 0.935393258 Glycine max 10285 10901 AAB61597 2213876 0.901685393 Hevea 10286 10902 brasiliensis P32289 0.901685393 Vigna 10287 aconitifolia ABW89460 159138920 0.904494382 Gossypium 10288 10903 herbaceum P04770 0.896067416 Phaseolus 10289 vulgaris ABW89461 159138922 0.901685393 Gossypium 10290 10904 hirsutum  87-107 CAN73584 147820217 1 Vitis vinifera 10291 530-550 XP_003532788 356528393 1 Glycine max 10292 10905 516-536 XP_003537529 356538072 1 Glycine max 10293 10906 566-586 XP_003531653 356526090 1 Glycine max 10294 10907 560-580 XP_003539764 356542618 1 Glycine max 10295 10908 XP_002285176 225435326 0.894674556 Vitis vinifera 10296 10909 CAC84906 18076735 0.829585799 Zinnia 10297 10910 violacea 828-848 XP_003539765 356542620 1 Glycine max 10298 10911 ptc- 557-577 XP_002298892 255761085 1 Populus 10299 miR166p trichocarpa CAN73584 147820217 0.91943128 Vitis vinifera 10300 XP_002332526 255761085 0.94549763 Populus 10301 trichocarpa XP_002281868 225444032 0.91943128 Vitis vinifera 10302 10912 XP_003535078 356533042 0.892180095 Glycine max 10303 10913 XP_003546255 356555874 0.893364929 Glycine max 10304 10914 AAS66760 45479745 0.86492891 Nicotiana 10305 10915 sylvestris XP_003532788 356528393 0.849526066 Glycine max 10306 10916 XP_003524993 356512573 0.845971564 Glycine max 10307 10917 ACI13683 206572100 0.816350711 Malus × 10308 10918 domestica 515-535 XP_003597690 357454818 1 Medicago 10309 10919 truncatula XP_003531652 356526088 0.918660287 Glycine max 10310 10920 XP_003530109 356522957 0.921052632 Glycine max 10311 10921 XP_002284003 225442500 0.897129187 Vitis vinifera 10312 10922 CBI36079 270253379 0.897129187 Vitis vinifera 10313 XP_002515977 255761086 0.901913876 Ricinus 10314 communis XP_003530112 356522963 0.916267943 Glycine max 10315 10923 XP_002284014 225442502 0.897129187 Vitis vinifera 10316 10924 ACI13685 206572104 0.89354067 Malus × 10317 10925 domestica XP_002304217 255761085 0.888755981 Populus 10318 trichocarpa 560-580 XP_002285176 225435326 1 Vitis vinifera 10319 10926 CAN61612 147783603 0.981042654 Vitis vinifera 10320 XP_002529946 255761086 0.918246445 Ricinus 10321 communis XP_003538150 356539326 0.892180095 Glycine max 10322 10927 XP_003539764 356542618 0.895734597 Glycine max 10323 10928 ACI13684 206572102 0.888625592 Malus × 10324 10929 domestica XP_003539765 356542620 0.890995261 Glycine max 10325 10930 AAX19050 60327620 0.881516588 Populus 10326 10931 trichocarpa DAA05766 109729904 0.853080569 Lotus 10327 japonicus AAY33856 63115353 0.8507109 Gossypium 10328 10932 barbadense 554-574 XP_003603630 357466690 1 Medicago 10329 10933 truncatula XP_003522716 356507930 0.943645084 Glycine max 10330 10934 XP_003526496 356515618 0.940047962 Glycine max 10331 10935 ACI13686 206572106 0.872901679 Malus × 10332 10936 domestica ADL36609 302398628 0.863309353 Malus × 10333 10937 domestica CBI20838 270231236 0.862110312 Vitis vinifera 10334 XP_002283717 225429913 0.862110312 Vitis vinifera 10335 10938 ACL51017 219879369 0.858513189 Citrus 10336 10939 trifoliata XP_002309538 255761085 0.868105516 Populus 10337 trichocarpa XP_002324794 255761085 0.857314149 Populus 10338 trichocarpa 40-60 AAS10176 41745611 1 Antirrhinum 10339 10940 majus 554-574 XP_003530109 356522957 1 Glycine max 10340 10941 XP_003531653 356526090 0.95823389 Glycine max 10341 10942 XP_003627005 357513432 0.91646778 Medicago 10342 10943 truncatula XP_003597690 357454818 0.918854415 Medicago 10343 10944 truncatula 590-610 XP_003524993 356512573 1 Glycine max 10344 10945 XP_003594520 357448488 0.781946073 Medicago 10345 10946 truncatula 25-45 XP_003522716 356507930 1 Glycine max 10346 10947 XP_003603630 357466690 0.932464455 Medicago 10347 10948 truncatula 560-580 XP_003530112 356522963 1 Glycine max 10348 10949 530-550 XP_003532788 356528393 1 Glycine max 10349 10950  87-107 CAN73584 147820217 1 Vitis vinifera 10350 113-133 XP_003516553 356495373 1 Glycine max 10351 10951 XP_003537620 356538255 0.909756098 Glycine max 10352 10952 566-586 XP_003531653 356526090 1 Glycine max 10353 10953 560-580 XP_003539764 356542618 1 Glycine max 10354 10954 XP_002285176 225435326 0.894674556 Vitis vinifera 10355 10955 CAC84906 18076735 0.829585799 Zinnia 10356 10956 violacea 828-848 XP_003539765 356542620 1 Glycine max 10357 10957 ptc- 368-388 XP_003550796 356565126 1 Glycine max 10358 10958 miRf10007- akr XP_003528595 356519875 0.931982634 Glycine max 10359 10959 XP_003609844 357479116 0.714905933 Medicago 10360 10960 truncatula ptc- 600-621 XP_003520116 356502619 1 Glycine max 10361 10961 miRf11396- alcr XP_002280702 225438602 0.856050955 Vitis vinifera 10362 10962 EAZ28751 54398660 0.829299363 Oryza sativa 10363 Japonica Group ptc-  88-108 NP_001236364 351726593 1 Glycine max 10364 10963 miRf12069- akr

Example 4 Verification of Expression of miRNA Molecules Associated with Abiotic Stress

Following identification of small RNA molecules potentially involved in improvement of soybean abiotic stress tolerance and their target genes (mRNAs) using bioinformatics tools, as described in Example 4 above, the actual mRNA levels in an experiment are determined using reverse transcription assay followed by quantitative Real-Time PCR (qRT-PCR) analysis. RNA levels are compared between different tissues, developmental stages, growing conditions and/or genetic backgrounds incorporated in each experiment. A correlation analysis between mRNA levels in different experimental conditions/genetic backgrounds is applied and used as evidence for the role of the gene in the plant.

Methods

Root and leaf samples are freshly excised from soybean plants grown as described above on Murashige-Skoog (Duchefa). Experimental plants are grown either under optimal irrigation conditions, salt levels or temperatures to be used as a control group, or under stressful conditions of prolonged water deprivation, high salt concentrations and a heat shock treatment at a temperature higher than 34° C. to be used as stress-induced groups to assess the drought, salinity and heat shock tolerance, respectively, of control versus transgenic plants. Total RNA is extracted from the different tissues, using mirVana™ commercial kit (Ambion) following the protocol provided by the manufacturer. For measurement and verification of messenger RNA (mRNA) expression level of all genes, reverse transcription followed by quantitative real time PCR (qRT-PCR) is performed on total RNA extracted from each plant tissue (i.e., roots and leaves) from each experimental group as described above. To elaborate, reverse transcription is performed on 1 μg total RNA, using a miScript Reverse Transcriptase kit (Qiagen), following the protocol suggested by the manufacturer. Quantitative RT-PCR is performed on cDNA (0.1 ng/μl final concentration), using a miScript SYBR GREEN PCR (Qiagen) forward (based on the miR sequence itself) and reverse primers (supplied with the kit). All qRT-PCR reactions are performed in triplicates using an ABI7500 real-time PCR machine, following the recommended protocol for the machine. To normalize the expression level of miRNAs associated with enhanced abiotic stress tolerance between the different tissues and growing conditions of the soybean plants, normalizer miRNAs are selected and used for comparison. Normalizer miRNAs, which are miRNAs with unchanged expression level between tissues and growing conditions, are custom selected for each experiment. The normalization procedure consists of second-degree polynomial fitting to a reference data (which is the median vector of all the data—excluding outliers) as described by Rosenfeld et al (2008, Nat Biotechnol, 26(4):462-469). A summary of primers for the differential small RNA molecules that will be used in the qRT-PCR validation and analysis is presented in Table 11a below.

TABLE 11a  Primers of Differential miRNA Molecules for qRT-PCR Validation Step. Primer Mir Name Primer Sequence (SEQ ID NO:) Length Tm ahy-miR3514-5p TGGCAGGATTCTGTATTAACGGTGGA (10964) 26 59.6 aly-miR160c-3p GCGTACAAGGAGCCAAGCATG (10965) 21 58.5 aly-miR396a-3p GGCGTTCAATAAAGCTGTGGGAAG (10966) 24 58.7 aly-miR396b-3p GCGCTCAAGAAAGCTGTGGGAAA (10967) 23 60.3 aly-miR831-5p GGCAGAAGAGGTACAAGGAGATGAGA (10968) 26 59.2 aqc-miR159 GGCTTTGGACTGAAGGGAGCTCTA (10969) 24 59.8 ath-miR157a TTTGGCTTGACAGAAGATAGAGAGCAC (10970) 27 58.8 ath-miR159b GGCTTTGGATTGAAGGGAGCTCTT (10971) 24 59.0 ath-miR159c GCTTTGGATTGAAGGGAGCTCCT (10972) 23 58.7 ath-miRf10068-akr CACCGGTGGAGGAGTGAGAG (10973) 20 58.0 ath-miRf10148-akr GGCGGTGGTGGAAAGATCAAGAT (10974) 23 59.1 ath-miRf10197-akr CACTCGACCAAGGGGGTCGAGTGA (10975) 24 63.6 ath-miRf10209-akr ATGGTGGTACTCGGCCAGGTGGT (10976) 23 63.5 ath-miRf10239-akr GCCGCCTTGCATCAACTGAATC (10977) 22 59.2 ath-miRf10240-akr GCATCGAAGGAGATGGAGGACG (10978) 22 59.0 ath-miRf10279-akr ACTCAGCCTGGGGGTCGAG (10979) 19 59.7 ath-miRf10368-akr GGCACTTGGGTGGTGCTGATTAT (10980) 23 59.3 ath-miRf10451-akr GGCAAGAAGGAGGAACAACCTGTTG (10981) 25 60.0 ath-miRf10633-akr TGGCGGTGGATACTTCTTGATCGG (10982) 24 60.5 ath-miRf10687-akr GGCTTAGCTGAAGAAGCAGAGGAG (10983) 24 58.9 ath-miRf10701-akr TGCAGTTCCTGGAGGTGGAGG (10984) 21 60.0 ath-miRf10702-akr CGTGGGAGGACTCCAAGTGTG (10985) 21 58.9 ath-miRf10751-akr GCCTTGTGGAGAGGAAGCAAGA (10986) 22 58.6 ath-miRf10763-akr GCGGTGGTGAAGAAGCATGGTT (10987) 22 60.1 ath-miRf10924-akr GCTGAGGCGTATCAGGAGGTAGT (10988) 23 59.4 ath-miRf11021-akr GGCGAGGTTTGCGATGAGAAAGAG (10989) 24 60.2 ath-miRf11037-akr GCTCATCGGAGAAACAGAGGAGC (10990) 23 59.2 ath-miRf11042-akr GGAAGAGGCAGTGCATGGGTA (10991) 21 58.3 ath-miRf11045-akr GGCTTTCTTGTGGAGGAAGCAAGAT (10992) 25 59.3 bdi-miR2508 GCATTGAGTGCAGCGTTGATGAAC (10993) 24 59.7 bna-miR2111b-5p CATTTGGCTAATCTGCATCCTGAGGTTTA (10994) 29 59.1 bra-miR160a-3p CGCGTATGAGGAGCCATGCATA (10995) 22 59.0 csi-miR162-5p TGGAGGCAGCGGTTCATCGATC (10996) 22 61.1 csi-miR3946 GGCTTGTAGAGAAAGAGAAGAGAGCAC (10997) 27 58.8 csi-miR3948 TGGAGTGGGAGTGGGAGTAGGGTG (10998) 24 62.6 ctr-miR171 GCTTGAGCCGCGTCAATATCTCC (10999) 23 60.1 far-miR1134 GCCGACAACAACAACAAGAAGAAGAG (11000) 26 58.9 ghr-miR2950 TGGTGTGCAGGGGGTGGAATA (11001) 21 59.6 gma-miR1507a TGGCTCTCATTCCATACATCGTCTGA (11002) 26 59.2 gma-miR1524 CGAGTCCGAGGAAGGAACTCC (11003) 21 58.2 gma-miR156g TTTGGCACAGAAGATAGAGAGCACAG (11004) 26 58.7 gma-miR157c TGGCTGACAGAAGACTAGAGAGCAC (11005) 25 59.6 gma-miR159a-3p TGGCTTTGGATTGAAGGGAGCTCTA (11006) 25 59.5 gma-miR159d GCAGCTGCTTAGCTATGGATCCC (11007) 23 59.3 gma-miR2119 GGCTCAAAGGGAGTTGTAGGGGAA (11008) 24 60.0 gma-miR396d GCAAGAAAGCTGTGGGAGAATATGGC (11009) 26 60.2 gma-miR4371b AAGTGATGACGTGGTAGACGGAGT (11010) 24 59.3 gma-miR4376-5p TACGCAGGAGAGATGACGCTGT (11011) 22 59.6 gma-miR4412-3p AGTGGCGTAGATCCCCACAAC (11012) 21 58.4 gma-miR4416a ACGGGTCGCTCTCACCTAGG (11013) 20 59.5 gma-miR482a-3p TCTTCCCAATTCCGCCCATTCCTA (11014) 24 59.6 gma-miR482b-5p GCTATGGGGGGATTGGGAAGGAAT (11015) 24 59.9 gso-miR169g* TCGGCAAGTTGGCCTTGGCT (11016) 20 61.5 gso-miR482a GGCTCTTCCCTACACCTCCCATAC (11017) 24 59.7 iba-miR157 CATTTGGCTTGACAGAAGATAGAGAGCAT (11018) 29 58.9 mdm-miR482a-5p CGGAATGGGCTGTTTGGGAACA (11019) 22 59.7 mtr-miR2119 GCTCAAAGGGAGGTGTGGAGTAG (11020) 23 58.5 osa-miR159e GCATTGGATTGAAGGGAGCTC CT (11021) 23 58.8 osa-miR159f GGCCTTGGATTGAAGGGAGCTCTA (11022) 24 59.9 osa-miR162a GGCTCGATAAACCTCTGCATCCAG (11023) 24 59.3 osa-miR1846e CAACGAGGAGGCCGGGACCA (11024) 20 62.8 osa-miR1850.1 GCTGGAAAGTTGGGAGATTGGGG (11025) 23 59.6 osa-miR1858a GAGAGGAGGACGGAGTGGGGC (11026) 21 62.2 osa-miR1869 GCTGAGAACAATAGGCATGGGAGGTA (11027) 26 60.0 osa-miR1874-3p GCTATGGATGGAGGTGTAACCCGATG (11028) 26 60.6 osa-miR1879 CGTGTTTGGTTTAGGGATGAGGTGG (11029) 25 59.6 osa-miR1881 GCAATGTTATTGTAGCGTGGTGGTGT (11030) 26 60.1 osa-miR2055 GGCTTTCCTTGGGAAGGTGGTTTC (11031) 24 60.0 osa-miR2104 GCGGCGAGGGGATGCGAGCG (11032) 20 67.4 osa-miRf10105-akr TTGGCCTCGTCGAAGAAGGAGA (11033) 22 59.5 osa-miRf10151-akr GGCTGGCTATATTTTGGGACGGAG (11034) 24 59.3 osa-miRf10362-akr GCTGGAGGATGCGACGGTGCT (11035) 21 63.6 osa-miRf10839-akr CCCTGTGACGTTGGTGAAGGTG (11036) 22 59.7 osa-miRf10849-akr TGGACTGTTTGGGGGAGCTTCT (11037) 22 59.6 osa-miRf11013-akr GGTTTGCCGGAGTTGGAGGAGA (11038) 22 60.6 osa-miRf11341-akr CGCGCCGACGATGACGGTGGAGT (11039) 23 67.4 osa-miRf11352-akr GCAGGGATTTTGGAAGGAGGTGACA (11040) 25 60.8 osa-miRf11355-akr GGTGGAGGTGGAGCTGTGCCAAA (11041) 23 63.2 osa-miRf11415-akr GAGAGCAGGATGCAGCCAAGG (11042) 21 59.6 osa-miRf11595-akr CCATCGGTGTTGGAGGTGGC (11043) 20 59.8 osa-miRf11649-akr AAACCGTGCAAAGGAGGTC CC (11044) 21 59.4 osa-miRf11829-akr ACGCGGAGGAGGTGGTGTTCT (11045) 21 62.0 osa-miRf11996-akr GCGTCTTATAACCTGAAACGGGGG (11046) 24 59.5 pab-miR3711 TGGCGCTAGAAGGAGGGCCT (11047) 20 61.6 ppt-miR1220a GCTTCCGGTGGTGAGGAAGATAG (11048) 23 58.6 ppt-miR166m GCTCGGACCAGGCATCATTCCTT (11049) 23 61.0 ppt-miR533b-5p GAGCTGTCCAGGCTGTGAGGG (11050) 21 61.0 ppt-miR895 GCGTAGCTTAGCGAGGTGTTGGTA (11051) 24 60.7 psi-miR159 GCCTTGGATTGAAGGGAGCTCCA (11052) 23 60.6 pta-miR156a TTTGGCCAGAAGATAGAGAGCACATC (11053) 26 58.5 pta-miR156b TTGGCCAGAAGATAGAGAGCACAAC (11054) 25 58.6 pta-miR166c CCGGACCAGGCTTCATCCCAG (11055) 21 61.1 ptc-miR166p TCGGACCAGGCTCCATTCCTT (11056) 21 59.4 ptc-miRf10007-akr GCCATTGACAGGGAAACTCACCA (11057) 23 59.2 ptc-miRf10132-akr TTGGCGGTGATTGAACGGAGGGT (11058) 23 62.7 ptc-miRf10148-akr TGGTGCACCTGGTGGTGGAG (11059) 20 60.8 ptc-miRf10226-akr TCCTTTGGGGAGATGGAGAGCTT (11060) 23 58.9 ptc-miRf10271-akr TGGCTTGGATTGAAGGGAGCTCTAA (11061) 25 59.5 ptc-miRf10300-akr GGCTTTGGAAAGCAAGTGAGGTG (11062) 23 58.7 ptc-miRf10522-akr TTGGGGAGCTGGACTCTGGA (11063) 20 58.6 ptc-miRf10619-akr GTTGGGCTTGCTGCTGGAGGA (11064) 21 61.5 ptc-miRf10734-akr GCCATCTAGGTGGTGGTCCAGTG (11065) 23 60.7 ptc-miRf10976-akr TGGGAACGTGGCTGTGGCTA (11066) 20 60.3 ptc-miRf10985-akr TGGCCAGAAGATAGAGAGCACTGA (11067) 24 58.8 ptc-miRf11018-akr CCTGCAAACCTAAGGGAGCGG (11068) 21 59.6 ptc-miRf11079-akr AAGATGGAGAAGCAGGGCACGTGC (11069) 24 63.4 ptc-miRf11315-akr GCCAACTTAGAGTTGGGGGTGG (11070) 22 59.2 ptc-miRf11324-akr CTTGTCGCAGGAGAGATGGCGCT (11071) 23 63.1 ptc-miRf11396-akr GCCAAGGCTCTGATACCATGTCAA (11072) 24 58.9 ptc-miRf11669-akr GGCCAAGGCTCTGATACCATGTT (11073) 23 58.8 ptc-miRf11757-akr CCTTGGTGAATGGTTGGGAGGAAT (11074) 24 58.7 ptc-miRf11844-akr CCCAACTTGGAGGTGGGTGTGG (11075) 22 61.4 ptc-miRf11847-akr GCGAAAGTGTGGAGAAGGTTGCC (11076) 23 60.6 ptc-miRf11855-akr GGCAGAGCATGGATGGAGCTA (11077) 21 58.2 ptc-miRf11953-akr GGCGTAATCTGCATCCTGAGGTT (11078) 23 58.9 ptc-miRf12069-akr GGAGGGGCTGCAAGACCCAAG (11079) 21 61.5 ptc-miRf12389-akr GTCGACCTGGCGAGTCAACCGGG (11080) 23 65.3 sbi-miR159a GGCTTTGGATTGAAGGGAGCTCTG (11081) 24 59.6 smo-miR1103-3p GCTGGAAAAAGGAGGTGCATTCTTGT (11082) 26 60.0 smo-miR156b TGGCCTGACAGAAGATAGAGAGCAC (11083) 25 59.7 tae-miR2003 CGGTTGGGCTGTATGATGGCGA (11084) 22 61.3 vvi-miR2111-5p TGGCTAATCTGCATCCTGAGGTCTA (11085) 25 58.7 vvi-miR394b GCTTGGCATTCTGTCCACCTCC (11086) 22 59.9 zma-miR167u GGCTGAAGCTGCCACATGATCTG (11087) 23 60.2 zma-miR396b-3p GGCTTCCACAGCTTTCTTGAACTG (11088) 24 58.5 zma-miR398a-5p TGTGTTCTCAGGTCGCCCCCG (11089) 21 62.9 zma-miR482-5p TGGCTCTTCCTTGTTCCTCCCATT (11090) 24 59.7

Alternative RT-PCR Validation Method of Selected microRNAs of the Invention

A novel microRNA quantification method has been applied using stem-loop RT followed by PCR analysis (Chen C, Ridzon D A, Broomer A J, Zhou Z, Lee D H, Nguyen J T, Barbisin M, Xu N L, Mahuvakar V R, Andersen M R, Lao K Q, Livak K J, Guegler K J. 2005, Nucleic Acids Res 33(20):e179; Varkonyi-Gasic E, Wu R, Wood M, Walton E F, Hellens R P. 2007, Plant Methods 3:12). This highly accurate method allows the detection of less abundant miRNAs. In this method, stem-loop RT primers are used, which provide higher specificity and efficiency to the reverse transcription process. While the conventional method relies on polyadenylated (poly (A)) tail and thus becomes sensitive to methylation because of the susceptibility of the enzymes involved, in this novel method the reverse transcription step is transcript-specific and insensitive to methylation. Reverse transcriptase reactions contained RNA samples including purified total RNA, 50 nM stem-loop RT primer (50-51 nucleotide long, see Table 11b, synthesized by Sigma), and using the SuperScript II reverse transcriptase (Invitrogen). A mix of up to 12 stem-loop RT primers may be used in each reaction, and the forward primers are such that the last 6 nucleotides are replaced with a GC rich sequence. For the PCR step, each miRNA has a custom forward primer (18-24 nucleotide long) and a universal stem loop reverse primer (5′-GTGCAGGGTCCGAGGT-3′—SEQ ID NO: 11617). Table 11b below lists the primers used for PCR validation using this method. Note, SL-RT stands for stem loop reverse transcription primer, and SL-F stands for stem loop forward primer.

TABLE 11b  Stem Loop Reverse Transcriptase Primers for RT-PCR Validation of Differential Mirs under Abiotic Stress. Forward Forward Primer Primer Mir Name Stem Loop Primer (SEQ ID NO:) (SEQ ID NO:) Length ahy-miR3514-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGAGGATTCTGTAT 22 GCACTGGATACGACTCCACC (11618) TAAC (11619) aly-miR396a-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGTTCAATAAAG 21 GCACTGGATACGACCTTCCC (11620) CTGT (11621) aly-miR396b-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGCTCAAGAAAG 21 GCACTGGATACGACTTTCCC (11622) CTGT (11623) aly-miR831-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGAGAAGAGGTAC 23 GCACTGGATACGACTCTCAT (11624) AAGGAG (11625) ath-miRf10197- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCTCACTCGACCAAGG 21 akr GCACTGGATACGACTCACTCG (11626) GGGT (11627) ath-miRf10279- GTCGTATCCAGTGCAGGGTCCGAGGTATTC TTCCACTCAGCCTGGGGG 21 akr GCACTGGATACGACATCACT (11628) TCG (11629) ath-miRf10687- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTAGCTGAAGA 21 akr GCACTGGATACGACCTCCTC (11630) AGCA (11631) gma-miRf10687- GTCGTATCCAGTGCAGGGTCCGAGGTATTC GAGCTTAGCCGCAGAGG 19 akr-homolog GCACTGGATACGACCTCCTC (11632) CA (11633) ath-miRf11021- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGAGGTTTGCGATG 19 akr GCACTGGATACGACCTCTTT (11634) AG (11635) ath-miRf11045- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTTCTTGTGGAG 22 akr GCACTGGATACGACATCTTG (11636) GAAG (11637) csi-miR162-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCTGGAGGCAGCGGTT 20 GCACTGGATACGACGATCGA (11638) CA (11639) far-miR1134 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCCGACAACAACAA 23 GCACTGGATACGACCTCTTC (11640) CAAGAA (11641) gma-miR159d GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGAGCTGCTTAGCT 21 GCACTGGATACGACGGGATC (11642) ATG (11643) gma-miR396d GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCAAGAAAGCTGTG 23 GCACTGGATACGACGCCATA (11644) GGAGAA (11645) gma-miR4376-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC GGCCGGTACGCAGGAGA 22 GCACTGGATACGACACAGCG (11646) GATGA (11647) gma-miR4412-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC TTCCAGTGGCGTAGATCC 19 GCACTGGATACGACGTTGTG (11648) C (11649) gma-miR4416a GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCACGGGTCGCTCTCA 18 GCACTGGATACGACCCTAGG (11650) (11651) gma-miR482a-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCTCTTCCCAATTCCG 22 GCACTGGATACGACTAGGAA (11652) CCCA (11653) gso-miR169g* GTCGTATCCAGTGCAGGGTCCGAGGTATTC GTTACTCGGCAAGTTGGC 18 GCACTGGATACGACAGCCAAG (11654) (11655) mtr-miR2119 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTCAAAGGGAGG 21 GCACTGGATACGACCTACTC (11656) TGTG (11657) osa-miR1874-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTATGGATGGAG 24 GCACTGGATACGACCATCGG (11658) GTGTAAC (11659) osa-miRf10105- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CCGGTTGGCCTCGTCGAA 20 akr GCACTGGATACGACTCTCCT (11660) GA (11661) osa-miRf10151- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTGGCTATATTTT 21 akr GCACTGGATACGACCTCCGT (11662) GGG (11663) osa-miRf10362- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGATGCTGGAGGATGCG 19 akr GCACTGGATACGACAGCACC (11664) AC (11665) osa-miRf10839- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCCCTGTGACGTTGGT 19 akr GCACTGGATACGACCACCTT (11666) G (11667) osa-miRf11649- GTCGTATCCAGTGCAGGGTCCGAGGTATTC GCGCAAACCGTGCAAAG 19 akr GCACTGGATACGACGGGACC (11668) GA (11669) pab-miR3711 GTCGTATCCAGTGCAGGGTCCGAGGTATTC GGCCCTGGCGCTAGAAG 19 GCACTGGATACGACAGGCCC (11670) GA (11671) ppt-miR533b-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGAGCTGTCCAGGCT 19 GCACTGGATACGACCCCTCA (11672) G (11673) ppt-miR895 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGTAGCTTAGCG 22 GCACTGGATACGACTACCAA (11674) AGGTG (11675) ptc-miRf10300- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTTGGAAAGCA 20 akr GCACTGGATACGACCACCTC (11676) AGT (11677) ptc-miRf10522- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCTTGGGGAGCTGG 19 akr GCACTGGATACGACTCCAGA (11678) AC (11679) ptc-miRf10619- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGTTGGGCTTGCTGC 19 akr GCACTGGATACGACTCCTCC (11680) T (11681) ptc-miRf11855- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCAGAGCATGGA 19 akr GCACTGGATACGACTAGCTC (11682) TG (11683) ptc-miRf12069- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCGGAGGGGCTGCAA 19 akr GCACTGGATACGACCTTGGG (11684) GA (11685) smo-miR1103-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCTGGAAAAAGGAGG 22 GCACTGGATACGACACAAGA (11686) TGCAT (11687) zma-miR396b-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGTTCAATAAAG 21 GCACTGGATACGACTTTCCC (11688) CTGT (11689) zma-miR482-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTGGGAGATGAA 19 GCACTGGATACGACAAGGCT (11690) GG (11691) aly-miR160c-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC GAATCGCGTACAAGGAG 20 GCACTGGATACGACCATGCT (11692) CCA (11693) aqc-miR159 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTTGGACTGAA 21 GCACTGGATACGACTAGAGC (11694) GGGA (11695) ath-miR157a GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTGACAGAAGA 21 GCACTGGATACGACGTGCTC (11696) TAGA (11697) ath-miR159b GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTTGGATTGAAG 21 GCACTGGATACGACAAGAGC (11698) GGA (11699) ath-miR159c GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTTGGATTGAAG 21 GCACTGGATACGACAGGAGC (11700) GGA (11701) ath-miRf10068- GTCGTATCCAGTGCAGGGTCCGAGGTATTC GGCCCACCGGTGGAGGA 18 akr GCACTGGATACGACCTCTCA (11702) G (11703) ath-miRf10148- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGGTGGTGGAAA 20 akr GCACTGGATACGACATCTTG (11704) GAT (11705) ath-miRf10209- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCATGGTGGTACTCGG 21 akr GCACTGGATACGACACCACC (11706) CCA (11707) ath-miRf10239- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCCGCCTTGCATCAAC 18 akr GCACTGGATACGACGATTCA (11708) (11709) ath-miRf10240- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGATCGAAGGAGA 20 akr GCACTGGATACGACCGTCCT (11710) TGG (11711) ath-miRf10368- GTCGTATCCAGTGCAGGGTCCGAGGTATTC AAGGCCTACTTGGGTGGT 21 akr GCACTGGATACGACATAATC (11712) GCT (11713) ath-miRf10451- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGAAGAAGGAGGA 22 akr GCACTGGATACGACCAACAG (11714) ACAAC (11715) ath-miRf10633- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCTGGCGGTGGATACT 22 akr GCACTGGATACGACCCGATC (11716) TCTT (11717) ath-miRf10701- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCTGCAGTTCCTGGA 21 akr GCACTGGATACGACTCCTCC (11718) GGT (11719) ath-miRf10702- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGTGGGAGGACTCC 18 akr GCACTGGATACGACCACACT (11720) A (11721) ath-miRf10751- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCTTGTGGAGAG 20 akr GCACTGGATACGACTCTTGC (11722) GAA (11723) ath-miRf10763- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCGGTGGTGAAGAA 19 akr GCACTGGATACGACAACCAT (11724) GC (11725) ath-miRf10924- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTAGGTGAGGCGTATC 21 akr GCACTGGATACGACACTACC (11726) AGGA (11727) ath-miRf11037- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTCATCGGAGAA 21 akr GCACTGGATACGACGCTCCT (11728) ACAG (11729) ath-miRf11042- GTCGTATCCAGTGCAGGGTCCGAGGTATTC AATCCTGGAAGAGGCAG 20 akr GCACTGGATACGACTACCCAT (11730) TGC (11731) bdi-miR2508 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCATTGAGTGCAGCGT 20 GCACTGGATACGACGTTCAT (11732) TG (11733) bna-miR2111b- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTAATCTGCATCC 21 5p GCACTGGATACGACTAAACC (11734) TGA (11735) bra-miR160a-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC GAATCGCGTATGAGGAG 20 GCACTGGATACGACTATGCA (11736) CCA (11737) csi-miR3946 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTGTAGAGAAA 24 GCACTGGATACGACGTGCTC (11738) GAGAAGA (11739) csi-miR3948 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCTGGAGTGGGAGTG 22 GCACTGGATACGACCACCCT (11740) GGAGT (11741) ctr-miR171 GTCGTATCCAGTGCAGGGTCCGAGGTATTC AATCCTTTGAGCCGCGTC 21 GCACTGGATACGACGGAGAT (11742) AAT (11743) ghr-miR2950 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCTGGTGTGCAGGGG 19 GCACTGGATACGACTATTCC (11744) GT (11745) gma-miR1507a GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTCTCATTCCATA 22 GCACTGGATACGACTCAGAC (11746) CATC (11747) gma-miR1524 GTCGTATCCAGTGCAGGGTCCGAGGTATTC GCGCCGAGTCCGAGGAA 19 GCACTGGATACGACGGAGTT (11748) GG (11749) gma-miR156g GTCGTATCCAGTGCAGGGTCCGAGGTATTC GCGGCGGACAGAAGATA 21 GCACTGGATACGACCTGTGC (11750) GAGA (11751) gma-miR157c GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTGACAGAAGAC 21 GCACTGGATACGACGTGCTC (11752) TAGA (11753) gma-miR159a-3p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTTGGATTGAAG 21 GCACTGGATACGACTAGAGC (11754) GGA (11755) gma-miR2119 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTCAAAGGGAGT 21 GCACTGGATACGACTTCCCC (11756) TGTA (11757) gma-miR4371b GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGAAGTGATGACG 24 GCACTGGATACGACACTCCG (11758) TGGTAGA (11759) gma-miR482b-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCTATGGGGGGATTG 20 GCACTGGATACGACATTCCT (11760) GGA (11761) gso-miR482a GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTCTTCCCTACAC 21 GCACTGGATACGACGTATGG (11762) CTC (11763) iba-miR157 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTGACAGAAGA 21 GCACTGGATACGACATGCTC (11764) TAGA (11765) mdm-miR482a- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGAATGGGCTGTTT 19 5p GCACTGGATACGACTGTTCC (11766) G (11767) osa-miR159e GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGATTGGATTGAA 21 GCACTGGATACGACAGGAGC (11768) GGGA (11769) osa-miR159f GTCGTATCCAGTGCAGGGTCCGAGGTATTC AAGGCCTCTTGGATTGAA 22 GCACTGGATACGACTAGAGC (11770) GGGA (11771) osa-miR162a GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTCGATAAACCTC 21 GCACTGGATACGACCTGGAT (11772) TGC (11773) osa-miR1846e GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCCAACGAGGAGGCC 18 GCACTGGATACGACTGGTCC (11774) G (11775) osa-miR1850.1 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTGGAAAGTTGG 21 GCACTGGATACGACCCCCAA (11776) GAGA (11777) osa-miR1858a GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGAGAGGAGGACGG 19 GCACTGGATACGACGCCCCA (11778) AG (11779) osa-miR1869 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCTGAGAACAATAG 23 GCACTGGATACGACTACCTC (11780) GCATGG (11781) osa-miR1879 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCGTGTTTGGTTTAG 23 GCACTGGATACGACCCACCT (11782) GGATG (11783) osa-miR1881 GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGAATGTTATTGTA 24 GCACTGGATACGACACACCA (11784) GCGTGG (11785) osa-miR2055 GTCGTATCCAGTGCAGGGTCCGAGGTATTC AAGGCCTTTTCCTTGGGA 22 GCACTGGATACGACGAAACC (11786) AGGT (11787) osa-miR2104 GTCGTATCCAGTGCAGGGTCCGAGGTATTC TTAGCGGCGAGGGGATG 19 GCACTGGATACGACCACGCT (11788) CG (11789) osa-miRf10849- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCTGGACTGTTTGGGG 20 akr GCACTGGATACGACAGAAGC (11790) GA (11791) osa-miRf11013- GTCGTATCCAGTGCAGGGTCCGAGGTATTC TAGGGTTTGCCGGAGTTG 19 akr GCACTGGATACGACTCTCCT (11792) G (11793) osa-miRf11341- GTCGTATCCAGTGCAGGGTCCGAGGTATTC TAGCGCGCCGACGATGA 19 akr GCACTGGATACGACACTCCAC (11794) CG (11795) osa-miRf11352- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCAGGGATTTTGGA 22 akr GCACTGGATACGACTGTCAC (11796) AGGAG (11797) osa-miRf11355- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCGGTGGAGGTGGAG 21 akr GCACTGGATACGACTTTGGC (11798) CTGT (11799) osa-miRf11415- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGAGAGCAGGATGC 19 akr GCACTGGATACGACCCTTGG (11800) AG (11801) osa-miRf11595- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCCATCGGTGTTGGA 18 akr GCACTGGATACGACGCCACC (11802) (11803) osa-miRf11829- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCACGCGGAGGAGGT 19 akr GCACTGGATACGACAGAACA (11804) GG (11805) osa-miRf11996- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGTCTTATAACCT 22 akr GCACTGGATACGACCCCCCG (11806) GAAA (11807) ppt-miR1220a GTCGTATCCAGTGCAGGGTCCGAGGTATTC GCGCTTCCGGTGGTGAGG 19 GCACTGGATACGACCTATCT (11808) A (11809) ppt-miR166m GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCTCGGACCAGGCAT 19 GCACTGGATACGACAAGGAA (11810) CA (11811) psi-miR159 GTCGTATCCAGTGCAGGGTCCGAGGTATTC AAGGCCTCTTGGATTGAA 22 GCACTGGATACGACTGGAGC (11812) GGGA (11813) pta-miR156a GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCAGAAGATAGA 20 GCACTGGATACGACGATGTG (11814) GAG (11815) pta-miR156b GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCAGAAGATAGA 20 GCACTGGATACGACGTTGTG (11816) GAG (11817) pta-miR166c GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCCCGGACCAGGCTTC 19 GCACTGGATACGACCTGGGA (11818) A (11819) ptc-miR166p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCTCGGACCAGGCTCC 19 GCACTGGATACGACAAGGAA (11820) A (11821) ptc-miRf10007- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCATTGACAGGG 21 akr GCACTGGATACGACTGGTGA (11822) AAAC (11823) ptc-miRf10132- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGTCTTGGCGGTGATTGA 21 akr GCACTGGATACGACACCCTC (11824) ACG (11825) ptc-miRf10148- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCTGGTGCACCTGGTG 18 akr GCACTGGATACGACCTCCAC (11826)  (11827) ptc-miRf10226- GTCGTATCCAGTGCAGGGTCCGAGGTATTC AATCCTTCCTTTGGGGAG 23 akr GCACTGGATACGACAAGCTC (11828) ATGGA (11829) ptc-miRf10271- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTGGATTGAAG 21 akr GCACTGGATACGACTTAGAG (11830) GGAG (11831) ptc-miRf10734- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCATCTAGGTGGT 21 akr GCACTGGATACGACCACTGG (11832) GGT (11833) ptc-miRf10976- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCTGGGAACGTGGCT 18 akr GCACTGGATACGACTAGCCA (11834) G (11835) ptc-miRf10985- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCAGAAGATAGA 20 akr GCACTGGATACGACTCAGTG (11836) GAG (11837) ptc-miRf11018- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCTGCAAACCTA 20 akr GCACTGGATACGACCCGCTC (11838) AGG (11839) ptc-miRf11079- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCAAGATGGAGAAGC 22 akr GCACTGGATACGACGCACGT (11840) AGGGC (11841) ptc-miRf11315- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCCGATCAACTTAGAGT 21 akr GCACTGGATACGACCCACCC (11842) TGG (11843) ptc-miRf11324- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCCTTGTCGCAGGAG 21 akr GCACTGGATACGACAGCGCC (11844) AGAT (11845) ptc-miRf11396- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGCGCCAAGGCTCTGATA 21 akr GCACTGGATACGACTTGACA (11846) CCA (11847) ptc-miRf11669- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCAAGGCTCTGA 20 akr GCACTGGATACGACAACATG (11848) TAC (11849) ptc-miRf11757- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCCTTGGTGAATGGTT 21 akr GCACTGGATACGACATTCCT (11850) GGG (11851) ptc-miRf11844- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCCCCAACTTGGAGGT 20 akr GCACTGGATACGACCCACAC (11852) GG (11853) ptc-miRf11847- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGAAAGTGTGGA 21 akr GCACTGGATACGACGGCAAC (11854) GAAG (11855) ptc-miRf11953- GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGTAATCTGCATC 20 akr GCACTGGATACGACAACCTC (11856) CT (11857) ptc-miRf12389- GTCGTATCCAGTGCAGGGTCCGAGGTATTC TTCCGTCGACCTGGCGAG 21 akr GCACTGGATACGACCCCGGT (11858) TCA (11859) sbi-miR159a GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTTGGATTGAAG 21 GCACTGGATACGACCAGAGC (11860) GGA (11861) smo-miR156b GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGCTGACAGAAGA 21 GCACTGGATACGACGTGCTC (11862) TAGA (11863) tae-miR2003 GTCGTATCCAGTGCAGGGTCCGAGGTATTC AACCGGTTGGGCTGTATG 19 GCACTGGATACGACTCGCCA (11864) A (11865) vvi-miR2111-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTAATCTGCATCC 21 GCACTGGATACGACTAGACC (11866) TGA (11867) vvi-miR394b GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGTTGGCATTCTGT 20 GCACTGGATACGACGGAGGT (11868) CC (11869) zma-miR167u GTCGTATCCAGTGCAGGGTCCGAGGTATTC CCGGGGTGAAGCTGCCA 20 GCACTGGATACGACCAGATC (11870) CAT (11871) zma-miR398a-5p GTCGTATCCAGTGCAGGGTCCGAGGTATTC CGGCGGGGCGAACTGAG 19 GCACTGGATACGACCATGTG (11872) AA (11873)

Example 5 Results of RT-PCR Validation of Selected miRNAs of the Invention

An RT-PCR analysis was run on selected microRNAs of the invention, using the stem-loop RT primers as described in Table 11b in Example 4 above. Total RNA was extracted from leaf tissues of soybean plants grown as described above, and was used as a template for RT-PCR analysis. Expression level and directionality of several up-regulated and down-regulated microRNAs that were found to be differential on the microarray analysis were verified. Results are summarized in Table 12 below.

TABLE 12 Summary of RT-PCR Verification Results on Selected miRNAs using Stem Loop RT (Alternative) Method Trait Mir Name p-Value Fold Change Drought gma-miR4376-5p 8.50E−03 2.38 (−) zma-miR396b-3p 4.60E−03 1.41 (−) aly-miR396b-3p 3.80E−06 3.48 (−) gma-miR156g 5.40E−02 1.48 (+)  gma-miRf10687-akr-homolog 7.80E−02 1.95 (+)  Salt gma-miR159d 5.60E−05 3.35 (−) aly-miR396b-3p 3.80E−07 5.45 (−) gma-miR4416a 5.20E−04 2.58 (−) aly-miR396a-3p 1.20E−08 13.50 (−)  zma-miR396b-3p 4.90E−05 9.58 (−) Heat Shock gma-miR4412-3p 1.50E−03 2.31 (−) csi-miR162-5p 2.60E−03 1.86 (−) ath-miRf10279-akr 2.40E−02 1.40 (−)

Example 6 15 Generation of Transgenic Plants

Gene Cloning Strategies for miRNA Molecules and Creation of Binary Vectors for Expression in Plants

The best validated miRNA sequences are cloned into pORE-E1 binary vectors (FIG. 1) for the generation of transgenic plants. The full-length precursor sequence comprising of the hairpin sequence of each selected miRNA, is synthesized by Genscript (USA). The resulting clone is digested with appropriate restriction enzymes and inserted into the Multi Cloning Site (MCS) of a similarly digested binary vector through ligation using T4 DNA ligase enzyme (Promega, Madison, Wis., USA).

Example 7 Generation of Transgenic Model Plants Expressing Abiotic Stress Associated miRNAs

Arabidopsis thaliana Transformation Protocol

Arabidoposis thaliana transformation is performed using the floral dip procedure following a slightly modified version of the published protocol (Clough and Bent, 1998, Plant J 16(6): 735-43; and Desfeux et al., 2000, Plant Physiol 123(3): 895-904). Briefly, T0 Plants are planted in small pots filled with soil. The pots are 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 24° C. under 16 hr light:8 hr dark cycles. A week prior to transformation all individual flowering stems are removed to allow for growth of multiple flowering stems instead. A single colony of Agrobacterium (GV3101) carrying the binary vectors (pORE-E1 or pORE-E3, see FIGS. 1 and 3, respectively), harboring the selected miRNA hairpin sequences with additional flanking sequences both upstream and downstream of it, is cultured in LB medium supplemented with kanamycin (50 mg/L) and gentamycin (25 mg/L). Three days prior to transformation, each culture is incubated at 28° C. for 48 hrs, shaking at 180 rpm. The starter culture is split the day before transformation into two cultures, which are allowed to grow further at 28° C. for 24 hours at 180 rpm. Pellets containing the agrobacterium cells are obtained by centrifugation of the cultures at 5000 rpm for 15 minutes. The pellets are re-suspended in an infiltration medium (10 mM MgCl2, 5% sucrose, 0.044 μM BAP (Sigma) and 0.03% Tween 20) prepared with double-distilled water.

Transformation of T0 plants is performed by inverting each plant into the agrobacterium suspension, keeping the flowering stem submerged for 5 minutes. Following inoculation, each plant is blotted dry for 5 minutes on both sides, and placed sideways on a fresh covered tray for 24 hours at 22° C. Transformed (transgenic) plants are then uncovered and transferred to a greenhouse for recovery and maturation. The transgenic T0 plants are grown in the greenhouse for 3-5 weeks until the seeds are ready, which are then harvested from plants and kept at room temperature until sowing.

Tomato (Solanum lycopersicum) Transformation Protocol

  • M82 tomato (Solanum lycopersicum) transformation is performed using a slightly modified protocol described previously (McCormick 1991, Plant Tissue Culture Manual., Vol. B6, Lindsey, K., ed. Dordrecht, The Netherlands: Kluwer Academic Publishers, pp. 1-9). Briefly, seeds are surface-sterilized 10 days prior to transformation by soaking and shaking in 70% ethanol followed by a 3% bleach solution. After washing, seeds are sown and allowed to grow into seedlings. Cotyledons are cut and treated with an agrobacterium (GV3101, carrying the binary vector pORE-E2, see FIG. 2) solution using a gentle agitation, dried and left on feeder medium for two days in the dark. Then, cotyledons are transferred to a first selection medium (Jones I) for two weeks, followed by a two-week incubation in a second selection medium (Jones II) for callus initiation. Cotyledons are transferred every two weeks to a fresh selection medium (Jones II) until plantlet forms. Plantlets with active meristems are separated from the callus and transferred to a third selection medium (Jones III), and transferred into a rooting medium. Once roots form, the plantlets are planted in soil.

Transgenic Arabidopsis Plants Over-Expressing Selected microRNA Sequences

Several microRNAs of the invention were selected for over-expression in both Arabidopsis. Transformation protocols are followed as described above for each plant, and agrobacterium is utilized, carrying one of three binary vectors: pORE-E1, pORE-E2, or pORE-E3.

Arabidopsis transgenic plants were created with osa-miRf11996-akr of the invention. This miRNA was downregulated under drought and salinity stresses compared to optimal conditions. Thus, the researchers tested the effects of modifying its expression level in model Arabidopsis plants. Four transgenic plants over-expressing osa-miRf11996-akr (in binary vector pORE-E3) were created and compared to control Columbia plants. Transgenic and control plants were grown under 16 h light:8 h dark regime at 22° C. in controlled growth rooms until seedlings were four weeks old. Next, plants were divided into two groups: control plants were irrigated with tap water twice a week and treated plants were either subjected to drought and received no irrigation for 5 days, or irrigated with 300 mM NaCl solution for 10 days for salinity stress induction. At the end of each treatment, plants were harvested and dry weight was recorded.

An ANOVA test was applied for statistical analysis of the data and results are summarized in Table 13 below. Control plants' dry weight was averaged and recorded as 100%, to be used as a reference for comparison to the average of each treated strain for each condition. Interestingly, the dry weight of all transgenic strains over-expressing osa-miRf11996-akr was significantly (p<1.0E-6) decreased compared to wild type control plants under all conditions. These results correlate with the fact that osa-miRf11996-akr was shown to be down-regulated under various abiotic stresses (e.g., Tables 2 and 4), thus indicating that its expression level needs to be decreased to improve a plant's tolerance to abiotic stress. Accordingly, the researchers also down-regulate osa-miRf11996-akr in Arabidopsis plants by using target mimic, as described and explained in Example 12 below.

TABLE 13 Dry Weight Results of Control and Transgenic (Over-expressing osa-miRf11996-akr) Arabidopsis Plants. Number of Dry Weight % Treatment Strain Dry weight +− SD Plants of Control No treatment Control 483.353 +− 113.070 17 11996-2 305.909 +− 88.033 22 63.29% 11996-3 231.500 +− 72.002 26 47.90% 11996-5 179.194 +− 71.185 31 37.07% 11996-7 285.158 +− 101.236 19 59.00% Drought Control 225.478 +− 99.687 23 11996-2 170.000 +− 60.393 21 75.40% 11996-3 157.269 +− 63.415 26 69.75% 11996-5 186.353 +− 92.723 20 82.65% 11996-7 179.818 +− 68.019 22 79.75% Salinity Control 210.895 +− 76.991 19 11996-2  77.143 +− 41.214 21 36.58% 11996-3 109.130 +− 60.144 23 51.75% 11996-5 103.480 +− 44.930 25 49.07% 11996-7 116.789 +− 64.514 19 55.38%

Example 8 Selection of Transgenic Arabidopsis Plants Expressing Abiotic Stress Genes According to Expression Level

Arabidopsis seeds are sown and Basta is sprayed for the first time on 1-2 weeks old seedlings, at least twice every few days. Only resistant plants, which are heterozygous for the transgene, survive. PCR on the genomic gene sequence is performed on the surviving seedlings using primers pORE-F2 (fwd, 5′-TTTAGCGATGAACTTCACTC-3′, SEQ ID NO: 11614) and a custom designed reverse primer based on each small RNA sequence.

Example 9 Evaluating Changes in Root Architecture of Transgenic Plants

Many key traits in modern agriculture can be explained by changes in the root architecture of the plant. Root size and depth have been shown to logically correlate with drought tolerance and fertilizer use efficiency, since deeper and more branched root systems provide better coverage of the soil and can access water and nutrients stored in deeper soil layers.

To test whether the transgenic plants produce a modified root structure, plants can be grown in agar plates placed vertically. A digital picture of the plates is taken every few days and the maximal length and total area covered by the plant roots are assessed. From every construct created, several independent transformation events are checked in replicates. To assess significant differences between root features, statistical test, such as a Student's t-test, is employed in order to identify enhanced root features and to provide a statistical value to the findings.

Example 10

Abiotic Stress Tolerance Assessments of Control and Transgenic Plants

Transgenic plants expressing the polynucleotides of some embodiments of the invention exhibit tolerance to abiotic stress in the form of extreme deficiency in water, high salt concentrations, or heat shock and exhibit better overall survival and growth compared to control non-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. Under normal conditions (non-stress, optimal growth conditions), transgenic plants exhibit a phenotype equivalent or superior to that of the wild type plants. Following stress induction, 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. Following are a number of screens aimed at identifying the transgenic plants which exhibit abiotic stress tolerance according to some embodiments of the invention.

Soil-Based Drought Tolerance Assay

Screens are performed with plants over-expressing the differential small RNAs detailed above. Briefly, seeds from control Arabidopsis plants, or other transgenic plants over-expressing the small RNA molecule of the invention are germinated and transferred to pots. Drought stress is obtained when irrigation is ceased and the two plant types (transgenic and control plants) are compared when most control plants develop severe wilting, at which point rehydration of the plants is initiated. Transgenic plants are ranked on two levels compared to controls: (1) tolerance to drought conditions, and (2) recovery (survival) following re-watering.

To illustrate and elaborate on the above drought tolerance assays of any given wild type plant compared to a corresponding transgenic plant (in which a drought-associated miRNA has been over-expressed), two different approaches are taken as follows:

Lethal drought stress—whereby wild type (used as a control) and transgenic plants (1-3 weeks old) are grown under prolonged extreme drought conditions (duration varies in accordance with plant species). Next, a recovery attempt is implemented during which plants are regularly irrigated and survival level is estimated in the two plant groups 1-2 days post irrigation initiation. While the control (wild type) plant is not expected to survive this extreme stress, the transgenic plant is expected to demonstrate some improved drought tolerance, usually within hours of re-hydration.

Non-lethal drought stress—whereby wild type (used as a control) and transgenic plants (1-3 weeks old) are grown under regular short-term cycles of drought and re-hydration steps, such that re-hydration is applied when general visible drought symptoms (e.g., evident decrease in turgor pressure of lower leaves) emerge in the experimental plants. This drought/irrigation alternating treatment continues until the flowering stage of the plants is reached, followed by an evaluation of dry matter weight. Both wild type and transgenic plants are expected to survive this non-lethal stress, however, measurable differences in drought tolerance are demonstrated by increased yield of the transgenic compared with the wild type plants.

Drought Tolerance Assay Using Sorbitol

Another assay designed to assess whether transgenic plants are more tolerant to drought or severe water deprivation compared to control plants, involves induction of an osmotic stress by the non-ionic osmolyte sorbitol. 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, to cause delayed growth. Following the stress treatment, control and transgenic plants are compared by measuring plant weight (wet and dry), yield, and growth rate measured as time to flowering.

Methods for Salinity Tolerance Assessment

Osmotic stress assays, such as chloride and mannitol assays, are aimed to determine whether an osmotic stress phenotype is sodium chloride-specific or a result of a general osmotic stress. Plants which are tolerant to osmotic stress may also exhibit tolerance to drought and/or freezing. For salt and osmotic stress germination experiments, the medium is supplemented with 50, 100, or 200 mM NaCl or 100 mM, 200 mM NaCl, 400 mM mannitol.

Methods for Heat Stress Tolerance Assessment

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 nor heat stress.

Methods for Cold Stress Tolerance Assessment

To analyze cold stress, mature (25 day old) plants are transferred to 4° C. chambers for 1 or 2 weeks, with constitutive light. Next, plants are moved back to the greenhouse for 2 weeks to recover. Following the recovery period, chilling damages such as growth retardation are determined based on measurements of plant weight (wet and dry) and growth rates (e.g. time to flowering, plant size, yield, etc) taken on control and transgenic plants.

Example 11 Testing Morphologic Parameters in Transgenic Plants

To analyze whether the transgenic Arabidopsis plants are more tolerant to abiotic stresses, plants are grown under optimal versus stress conditions, i.e either drought for five days without irrigation, or high salt conditions for ten days, or a one-hour heat shock. Plants are allowed to grow until seed production, followed by an analysis of their overall size, time to flowering, yield, and protein content of shoot and/or grain. Additional 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. Transformed plants not exhibiting substantial physiological and/or morphological effects, or exhibiting higher measured parameters levels compared to wild-type plants, are identified as abiotic stress tolerant plants.

Example 12 Method for Generating Transgenic Plants with Enhanced or Reduced miRNA Regulation of Target Genes

Target prediction enables two contrasting strategies; an enhancement (positive) or a reduction (negative) of small RNA regulation. Both these strategies have been used in plants and have resulted in significant phenotype alterations. For complete in-vivo assessment of the phenotypic effects of the differential small RNAs of this invention, the inventors plan to implement both over-expression and down-regulation methods on the small RNA molecules found to associate with abiotic stress tolerance as listed in Tables 1-6. In the case of small RNAs that were up-regulated under abiotic stress conditions, an enhancement in abiotic stress tolerance can theoretically be achieved by maintaining their directionality, i.e. over-expressing them. Conversely, in the case of small RNAs that were down-regulated under abiotic stress conditions, enhancement in tolerance can be achieved by reducing their regulation. Regulation reduction of small RNA target genes can be accomplished in one of two approaches:

Expressing a miRNA-Resistant Target

In this method, silent mutations are introduced in the miRNA binding site of the target gene so that the DNA and resulting RNA sequences are changed to prevent miRNA binding, but the amino acid sequence of the protein is unchanged.

For design of miRNA-resistant target sequences for the small RNA molecules of the invention, optimization of the nucleic acid sequence in accordance with the preferred codon usage for a particular plant species is required. Tables such as those provided on-line at the Codon Usage Database through the NCBI (National Center for Biotechnology Information) webpage (Hypertext Transfer Protocol://World Wide Web (dot) ncbi (dot) nlm (dot) nih (dot) gov/ Taxonomy/Utils/wprintgc (dot) cgi) were used. The Genbank database contains codon usage tables for a number of different species, with its Table 11 (The Bacterial, Archaeal and Plant Plastid Code) being the most relevant for plant species of this invention. Mir-resistant target examples for upregulated and downregulated miRs of the invention are presented in Tables 14-15 below.

TABLE 14 miRNA-Resistant Target Examples for Selected upregulated miRNAs of the Invention. NCBI mutated Mir nucleotide Mir Binding sequence/SEQ name Homolog NCBI Accession Site ID NO: aqc- XP_003543825 0 miR159 958-978 11091 958-978 11092 XP_003541563 0 1111-1131 11093 1111-1131 11094 XP_003556814 0 952-972 11095 952-972 11096 XP_003526354 0 928-948 11097 928-948 11098 XP_003523913 0 931-951 11099 931-951 11100 XP_003545791 0 934-954 11101 934-954 11102 ath- XP_003542140 0 miR159b 404-424 11103 404-424 11104 ath- XP_003519140 0 miR159c 143-163 11105 143-163 11106 XP_003531162 0 2030-2050 11107 2030-2050 11108 XP_003524148 0 1188-1208 11109 1188-1208 11110 XP_003547199 0 1263-1283 11111 1263-1283 11112 XP_003541668 0 1329-1349 11113 1329-1349 11114 ath- XP_003525932 0 miRf10240- akr 357-376 11115 357-376 11116 XP_003523287 0 864-883 11117 864-883 11118 XP_003547951 0 1451-1470 11119 1451-1470 11120 XP_003629354 0 1224-1243 11121 1224-1243 11122 ath- XP_003543893 0 miRf10368- akr 584-603 11123 584-603 11124 XP_003539013 0 599-618 11125 599-618 11126 XP_003556840 0 727-746 11127 727-746 11128 XP_003538207 0 1733-1752 11129 1733-1752 11130 ath- XP_003520499 0 miRf10763- akr 245-264 11131 245-264 11132 XP_003519685 0 240-259 11133 240-259 11134 ACU17625 0 176-195 11135 176-195 11136 XP_003527981 0 558-577 11137 558-577 11138 XP_003547100 0 1686-1705 11139 1686-1705 11140 XP_003524815 0 524-543 11141 524-543 11142 csi- XP_003547789 0 miR3948 31-54 11143 31-54 11144 XP_003527776 0 46-69 11145 46-69 11146 XP_003550061 0 178-201 11147 178-201 11148 XP_003525811 0 178-201 11149 178-201 11150 XP_003539180 0 283-306 11151 283-306 11152 BAD18437 0 278-301 11153 278-301 11154 ghr- XP_003529456 0 miR2950 1017-1037 11155 1017-1037 11156 XP_003554852 0 380-400 11157 380-400 11158 gma- XP_003520455 0 miR156g 737-756 11159 737-756 11160 XP_003553428 0 734-753 11161 734-753 11162 XP_003520534 0 734-753 11163 734-753 11164 XP_003553944 0 1089-1108 11165 1089-1108 11166 XP_003551188 0 1046-1065 11167 1046-1065 11168 XP_003532399 0 941-960 11169 941-960 11170 XP_003549130 0 1034-1053 11171 1034-1053 11172 XP_003550514 0 706-725 11173 706-725 11174 XP_003525415 0 1214-1233 11175 1214-1233 11176 XP_003538544 0 1269-1288 11177 1269-1288 11178 XP_003525436 0 1333-1352 11179 1333-1352 11180 XP_003550708 0 1184-1203 11181 1184-1203 11182 XP_003520128 0 1007-1026 11183 1007-1026 11184 XP_003523155 0 959-978 11185 959-978 11186 XP_003551421 0 758-777 11187 758-777 11188 XP_003522278 0 1262-1281 11189 1262-1281 11190 gma- Redundant target XP_003549130 0 miR157c gma- Redundant targets: XP_003542140, XP_003543825, miR159a- XP_003526354, XP_003541563, XP_003556814, XP_003545791, 3p XP_003523913. iba- Redundant targets: XP_003520455, XP_003553428, miR157 XP_003520534, XP_003553944, XP_003551188, XP_003532399, XP_003549130, XP_003525415, XP_003538544, XP_003525436, XP_003520128, XP_003551421, XP_003523155, XP_003550708, XP_003522278 mdm- XP_003528897 miR482a- 5p 940-960 11191 940-960 11192 940-960 11193 940-960 11194 osa- Redundant targets: XP_003543825, XP_003531162, miR159e XP_003526354, XP_003524148, XP_003547199, XP_003541563, XP_003556814, XP_003541668, XP_003523913, XP_003545791. osa- Redundant targets: XP_003543825, XP_003526354, miR159f XP_003541563, XP_003556814, XP_003523913, XP_003545791. osa- XP_003555849 miR1850.1 147-167 11195 147-167 11196 XP_003534041 0 29-49 11197 29-49 11198 XP_003548988 0 451-471 11199 451-471 11200 osa- XP_003521247 0 miR1858a 287-307 11201 287-307 11202 NP_001235053 0 281-301 11203 281-301 11204 XP_003530234 0 368-388 11205 368-388 11206 XP_003551508 0 377-397 11207 377-397 11208 XP_003528545 0 131-151 11209 131-151 11210 XP_003547641 0 155-175 11211 155-175 11212 XP_003543554 0 185-205 11213 185-205 11214 XP_003556667 0 131-151 11215 131-151 11216 osa- XP_003546711 0 miRf11829- akr 346-366 11217 346-366 11218 ACI23460 0 334-354 11219 334-354 11220 XP_003541398 0 365-385 11221 365-385 11222 psi- Redundant targets: XP_003543825, XP_003526354, miR159 XP_003541563, XP_003556814, XP_003545791, XP_003523913. pta- Redundant targets: XP_003549130, XP_003553428, miR156a XP_003553944, XP_003525436, XP_003520455, XP_003520128, XP_003550708, XP_003523155, XP_003551421, XP_003522278. pta- XP_003551276 miR156b 202-221 11223 202-221 11224 202-221 11225 202-221 11226 ptc- XP_003527653 miRf10132- akr 128-150 11227 128-150 11228 128-150 11229 ptc- XP_003549610 0 miRf10226- akr 123-145 11230 123-145 11231 XP_003525906 0 174-196 11232 174-196 11233 XP_003547131 0 2282-2304 11234 2282-2304 11235 XP_003542817 0 240-262 11236 240-262 11237 ptc- Redundant targets: XP_003543825, XP_003526354, miRf10271- XP_003541563, XP_003556814, XP_003523913, XP_003545791. akr ptc- XP_003520774 0 miRf10734- akr 1439-1459 11238 1439-1459 11239 XP_003538849 0 1187-1207 11240 1187-1207 11241 ptc- XP_003546504 0 miRf10985- akr 1472-1491 11242 1472-1491 11243 XP_003545057 0 3399-3418 11244 3399-3418 11245 ptc- XP_003550774 0 miRf11315- akr 311-330 11246 311-330 11247 XP_003518840 0 255-274 11248 255-274 11249 ptc- XP_003612685 0 miRf11757- akr 388-410 11250 388-410 11251 388-410 11252 388-410 11253 ath- Redundant targets: XP_003525415, XP_003553428, miR157a XP_003538544, XP_003553944, XP_003551188, XP_003525436, XP_003520455, XP_003523155, XP_003551421, XP_003549130, XP_003522278. sbi- Redundant targets: XP_003543825, XP_003526354, miR159a XP_003541563, XP_003556814. smo- XP_003528960 miR156b 462-482 11254 462-482 11255 462-482 11256 462-482 11257

TABLE 15 miRNA-Resistant Target Examples for Selected down-regulated miRNAs of the Invention. Mutated Nucleotide Homolog NCBI NCBI Mir Sequence/ Mir name Accession Binding Site SEQ ID NO: bdi-miR2508 XP_003530212 689-710 11258 689-710 11259 XP_003530213 0 794-815 11260 794-815 11261 XP_003551482 0 689-710 11262 689-710 11263 XP_003548937 0 1148-1169 11264 1148-1169 11265 XP_003551299 0 733-754 11266 733-754 11267 XP_003520176 0 2159-2180 11268 2159-2180 11269 XP_003544873 0 656-677 11270 656-677 11271 XP_003552227 0 665-686 11272 665-686 11273 XP_003539077 0 713-734 11274 713-734 11275 XP_003552179 0 701-722 11276 701-722 11277 NP_001236616 0 698-719 11278 698-719 11279 XP_003540719 0 707-728 11280 707-728 11281 XP_003522150 0 662-683 11282 662-683 11283 bra-miR160a-3p XP_003530952 0 1283-1303 11284 1283-1303 11285 gma-miR2119 XP_003542005 0 212-232 11286 212-232 11287 XP_003521584 0 421-441 11288 421-441 11289 XP_003524240 0 1982-2002 11290 1982-2002 11291 XP_003545664 0  96-116 11292  96-116 11293 XP_003532800 0 1982-2002 11294 1982-2002 11295 XP_003547559 0 2084-2104 11296 2084-2104 11297 gso-miR482a NP_001237600 0 1153-1173 11298 1153-1173 11299 XP_003533606 0 523-543 11300 523-543 11301 XP_003518623 0 444-464 11302 444-464 11303 AAF44087 0 Jan-21 11304 Jan-21 11305 osa-miR162a XP_003528812 612-632 11306 612-632 11307 612-632 11308 612-632 11309 osa-miR1846e XP_003531668 0 471-490 11310 471-490 11311 XP_003529761 0 363-382 11312 363-382 11313 XP_003530142 0 366-385 11314 366-385 11315 ppt-miR166m XP_003553029 0 530-550 11316 530-550 11317 XP_003597690 0 875-895 11318 875-895 11319 XP_002285176 0 562-582 11320 562-582 11321 XP_003530109 0 906-926 11322 906-926 11323 XP_003524993 0 1030-1050 11324 1030-1050 11325 XP_003522716 0 825-845 11326 825-845 11327 XP_003530112 0 606-626 11328 606-626 11329 XP_003532788 0 577-597 11330 577-597 11331 XP_003537529 0 515-535 11332 515-535 11333 XP_003531653 0 777-797 11334 777-797 11335 XP_003539764 0 1227-1247 11336 1227-1247 11337 XP_003539765 0 1227-1247 11338 1227-1247 11339 ptc-miRf10007-akr XP_003550796 1378-1398 11340 1378-1398 11341 1378-1398 11342 1378-1398 11343 ptc-miRf10976-akr XP_003533044 0 318-337 11344 318-337 11345 XP_003528486 0 267-286 11346 267-286 11347 XP_003548151 0 885-904 11348 885-904 11349 NP_001238468 0 245-264 11350 245-264 11351 ptc-miRf11396-akr XP_003520116 764-785 11352 764-785 11353 764-785 11354 764-785 11355 ptc-miRf11669-akr XP_003554103 208-227 11356 208-227 11357 208-227 11358 208-227 11359

Expressing a Target-Mimic Sequence

Plant miRNAs usually lead to cleavage of their targeted gene, with this cleavage typically occurring between bases 10 and 11 of the miRNA. This position is therefore especially sensitive to mismatches between the miRNA and the target. It was found that expressing a DNA sequence that could potentially be targeted by a miRNA, but contains three extra nucleotides (ATC), and thus creating a bulge in a key position (between the two nucleotides that are predicted to hybridize with bases 10-11 of the miRNA), can inhibit the regulation of that miRNA on its native targets (Franco-Zorilla et al., 2007, Nat Genet 39(8):1033-1037).

This type of sequence is referred to as a “target-mimic”. Inhibition of the miRNA regulation is presumed to occur through physically capturing the miRNA by the target-mimic sequence and titering-out the miRNA, thereby reducing its abundance. This method was used to reduce the amount and, consequentially, the regulation of miRNA 399 in Arabidopsis. Target mimic examples for upregulated and downregulated miRs of the invention are presented in Tables 16-17 below.

TABLE 16 Target Mimic Examples for Selected upregulated miRNAs of the Invention. Mimic Reverse Complement Full Target Mimic Nucleotide Mir Name Mir/SEQ ID NO: Sequence/SEQ ID NO: ahy-miR3514- 11360 11437 5p aly-miR831- 11361 11438 5p aqc-miR159 11362 11439 ath-miR157a 11363 11440 ath-miR159b 11364 11441 ath-miR159c 11365 11442 ath- 11366 11443 miRf10068- akr ath- 11367 11444 miRf10148- akr ath- 11368 11445 miRf10209- akr ath- 11369 11446 miRf10240- akr ath- 11370 11447 miRf10368- akr ath- 11371 11448 miRf10451- akr ath- 11372 11449 miRf10633- akr ath- 11373 11450 miRf10687- akr ath- 11374 11451 miRf10701- akr ath- 11375 11452 miRf10702- akr ath- 11376 11453 miRf10751- akr ath- 11377 11454 miRf10763- akr ath- 11378 11455 miRf10924- akr ath- 11379 11456 miRf11021- akr ath- 11380 11457 miRf11037- akr ath- 11381 11458 miRf11042- akr ath- 11382 11459 miRf11045- akr csi-miR3946 11383 11460 csi-miR3948 11384 11461 far-miR1134 11385 11462 ghr-miR2950 11386 11463 gma-miR156g 11387 11464 gma-miR157c 11388 11465 gma- 11389 11466 miR159a-3p iba-miR157 11390 11467 mdm- 11391 11468 miR482a-5p mtr-miR2119 11392 11469 osa-miR159e 11393 11470 osa-miR159f 11394 11471 osa- 11395 11472 miR1850.1 osa-miR1858a 11396 11473 osa-miR1869 11397 11474 osa-miR1874- 11398 11475 3p osa-miR1879 11399 11476 osa-miR1881 11400 11477 osa-miR2055 11401 11478 osa- 11402 11479 miRf10105- akr osa- 11403 11480 miRf10362- akr osa- 11404 11481 miRf10839- akr osa- 11405 11482 miRf11013- akr osa- 11406 11483 miRf11341- akr osa- 11407 11484 miRf11352- akr osa- 11408 11485 miRf11355- akr osa- 11409 11486 miRf11595- akr osa- 11410 11487 miRf11649- akr osa- 11411 11488 miRf11829- akr pab-miR3711 11412 11489 ppt-miR1220a 11413 11490 ppt-miR895 11414 11491 psi-miR159 11415 11492 pta-miR156a 11416 11493 pta-miR156b 11417 11494 ptc- 11418 11495 miRf10132- akr ptc- 11419 11496 miRf10148- akr ptc- 11420 11497 miRf10226- akr ptc- 11421 11498 miRf10271- akr ptc- 11422 11499 miRf10300- akr ptc- 11423 11500 miRf10522- akr ptc- 11424 11501 miRf10619- akr ptc- 11425 11502 miRf10734- akr ptc- 11426 11503 miRf10985- akr ptc- 11427 11504 miRf11315- akr ptc- 11428 11505 miRf11757- akr ptc- 11429 11506 miRf11844- akr ptc- 11430 11507 miRf11847- akr ptc- 11431 11508 miRf11855- akr sbi-miR159a 11432 11509 smo- 11433 11510 miR1103-3p smo-miR156b 11434 11511 tae-miR2003 11435 11512 zma-miR482- 11436 11513 5p

TABLE 17 Target Mimic Examples for Selected downregulated miRNAs of the Invention. Full Target Mimic Nucleotide Mimic Reverse Complement Sequence/SEQ ID Mir Name Mir/SEQ ID NO: NO: aly-miR160c-3p 11514 11564 aly-miR396a-3p 11515 11565 aly-miR396b-3p 11516 11566 ath-miRf10197-akr 11517 11567 ath-miRf10239-akr 11518 11568 ath-miRf10279-akr 11519 11569 bdi-miR2508 11520 11570 bna-miR2111b-5p 11521 11571 bra-miR160a-3p 11522 11572 csi-miR162-5p 11523 11573 ctr-miR171 11524 11574 gma-miR1507a 11525 11575 gma-miR1524 11526 11576 gma-miR159d 11527 11577 gma-miR2119 11528 11578 gma-miR396d 11529 11579 gma-miR4371b 11530 11580 gma-miR4376-5p 11531 11581 gma-miR4412-3p 11532 11582 gma-miR4416a 11533 11583 gma-miR482a-3p 11534 11584 gma-miR482b-5p 11535 11585 gso-miR169g* 11536 11586 gso-miR482a 11537 11587 osa-miR162a 11538 11588 osa-miR1846e 11539 11589 osa-miR2104 11540 11590 osa-miRf10151-akr 11541 11591 osa-miRf10849-akr 11542 11592 osa-miRf11415-akr 11543 11593 osa-miRf11996-akr 11544 11594 ppt-miR166m 11545 11595 ppt-miR533b-5p 11546 11596 pta-miR166c 11547 11597 ptc-miR166p 11548 11598 ptc-miRf10007-akr 11549 11599 ptc-miRf10976-akr 11550 11600 ptc-miRf11018-akr 11551 11601 ptc-miRf11079-akr 11552 11602 ptc-miRf11324-akr 11553 11603 ptc-miRf11396-akr 11554 11604 ptc-miRf11669-akr 11555 11605 ptc-miRf11953-akr 11556 11606 ptc-miRf12069-akr 11557 11607 ptc-miRf12389-akr 11558 11608 vvi-miR2111-5p 11559 11609 vvi-miR394b 11560 11610 zma-miR167u 11561 11611 zma-miR396b-3p 11562 11612 zma-miR398a-5p 11563 11613

TABLE 18 Abbreviations of plant species Common Name Organism Name Abbreviation Peanut Arachis hypogaea ahy Arabidopsis lyrata Arabidopsis lyrata aly Rocky Mountain Columbine Aquilegia coerulea aqc Tausch's goatgrass Aegilops taushii ata Arabidopsis thaliana Arabidopsis thaliana ath Grass Brachypodium distachyon bdi Brassica napus canola Brassica napus bna (“liftit”) Brassica oleracea wild Brassica oleracea bol cabbage Brassica rapa yellow mustard Brassica rapa bra Clementine Citrus clementine ccl Orange Citrus sinensis csi Trifoliate orange Citrus trifoliata ctr Glycine max Glycine max gma Wild soybean Glycine soja gso Barley Hordeum vulgare hvu Lotus japonicus Lotus japonicus lja Medicago truncatula - Medicago truncatula mtr Barrel Clover (“tiltan”) Oryza sativa Oryza sativa osa European spruce Picea abies pab Physcomitrella patens (moss) Physcomitrella patens ppt Pinus taeda - Loblolly Pine Pinus taeda pta Populus trichocarpa - Populus trichocarpa ptc black cotton wood Castor bean (“kikayon”) Ricinus communis rco Sorghum bicolor Dura Sorghum bicolor sbi tomato microtom Solanum lycopersicum sly Selaginella moellendorffii Selaginella moellendorffii smo Sugarcane Saccharum officinarum sof Sugarcane Saccharum spp ssp Triticum aestivum Triticum aestivum tae cacao tree and cocoa tree Theobroma cacao tcc Vitis vinifera Grapes Vitis vinifera vvi corn Zea mays zma

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.

Claims

1. A method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11940-11955, 11959-11961, wherein said RNAi molecule regulates abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

2. A method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957 or 11958, wherein said nucleic acid sequence is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

3. A transgenic plant exogenously expressing a polynucleotide having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957 or 11958, wherein said nucleic acid sequence is capable of regulating abiotic stress tolerance of the plant.

4. The method of claim 2 or transgenic plant of claim 3, wherein said exogenous polynucleotide encodes a precursor of said nucleic acid sequence.

5. The method or transgenic plant of claim 4, wherein said precursor of said nucleic acid sequence is at least 60% identical to SEQ ID NO: 174-201, 220-235, 256-259, 2087-3910, 3911, 11875-11904, 11910-11939, 11615, 11956, 11957 or 11958.

6. The method of claim 2 or the transgenic plant of claim 3, wherein said exogenous polynucleotide encodes a mature miRNA.

7. The method of claim 2 or the transgenic plant of claim 3, wherein said exogenous polynucleotide is selected from the group consisting of SEQ ID NO: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957 or 11958.

8. A nucleic acid construct comprising a nucleic acid sequence being at least 90% identical to SEQ ID NO: 139, 1-201, 202-235, 236-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957, 11958, 11940-11955, 11905-11909, 11959-11961, wherein said nucleic acid sequence is capable of regulating abiotic stress tolerance of a plant and wherein said nucleic acid sequence is under the regulation of a cis-acting regulatory element.

9. The nucleic acid construct of claim 8, wherein said nucleic acid sequence is selected from the group consisting of SEQ ID NOs: 1-56, 174-201, 80-125, 220-235, 162-168, 256-259, 262-2086, 2087-3910, 3911, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957 or 11958.

10. The nucleic acid construct of claim 8, wherein said nucleic acid sequence is selected from the group consisting of SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11959-11961, 11940-11955.

11. The nucleic acid construct of claim 8, wherein said cis-acting regulatory element comprises a promoter.

12. The nucleic acid construct of claim 11, wherein said promoter comprises a tissue-specific promoter.

13. The nucleic acid construct of claim 12, wherein said tissue-specific promoter comprises a root specific promoter.

14. A transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11940-11955, 11959-11961.

15. A transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence at least 90% identical to SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11940-11955, 11959-11961.

16. An isolated polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence selected from the group consisting of SEQ ID NOs: 139, 57-79, 202-219, 126-138, 140-161, 236-255, 169-173, 260-261, 3953-5114, 5117-6277, 6278, 11905-11909, 11940-11955, 11959-11961.

17. An isolated polynucleotide which downregulates an activity or expression of a gene encoding an RNAi molecule having a nucleic acid sequence selected from the group consisting of SEQ ID NOs: 139, 1-201, 202-235, 236-3910, 3911, 3953-5114, 5117-6277, 6278, 11616, 11615, 11874, 11875-11904, 11910-11939, 11956, 11957, 11958, 11905-11909, 11940-11955, 11959-11961.

18. The method of claim 1, the transgenic plant of claim 14 or the isolated polynucleotide of claim 16, wherein said polynucleotide encodes a miRNA-Resistant Target as set forth in SEQ ID NO: 11258-11359.

19. The transgenic plant of claim 15, wherein said polynucleotide encodes a miRNA-Resistant Target as set forth in SEQ ID NO: 11091-11257.

20. The method of claim 1, the transgenic plant of claim 14 or the isolated polynucleotide of claim 16, wherein said isolated polynucleotide encodes a target mimic as set forth in SEQ ID NO: 11564-11613.

21. The transgenic plant of claim 15, wherein said polynucleotide encodes a target mimic as set forth in SEQ ID NO: 11437-11513.

22. A nucleic acid construct comprising the isolated polynucleotide of claim 16 or 17 under the regulation of a cis-acting regulatory element.

23. The nucleic acid construct of claim 22, wherein said cis-acting regulatory element comprises a promoter.

24. The nucleic acid construct of claim 23, wherein said promoter comprises a tissue-specific promoter.

25. The nucleic acid construct of claim 24, wherein said tissue-specific promoter comprises a root specific promoter.

26. The method of claim 1 or 2, further comprising growing the plant under limiting nitrogen conditions.

27. The method of claim 1 or 2, further comprising growing the plant under abiotic stress.

28. The method of claim 27, wherein said abiotic stress is selected from the group consisting of salinity, drought, water deprivation, flood, etiolation, low temperature, high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency, nutrient excess, atmospheric pollution and UV irradiation.

29. The method of claim 1 or 2, or the plant of claim 3 or 14, being a monocotyledon.

30. The method of claim 1 or 2, or the plant of claim 3 or 14, being a dicotyledon.

31. A method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide encoding a polypeptide having an amino acid sequence at least 80% homologous or identical to SEQ ID NOs: 9591-10364, wherein said polypeptide is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

32. A transgenic plant exogenously expressing a polynucleotide encoding a polypeptide having an amino acid sequence at least 80% homologous or identical to SEQ ID NOs: 9591-10364, wherein said polypeptide is capable of regulating abiotic stress tolerance of the plant.

33. A nucleic acid construct comprising a polynucleotide encoding a polypeptide having an amino acid sequence at least 80% homologous to SEQ ID NOs: 9591-10364, wherein said polypeptide is capable of regulating abiotic stress tolerance of the plant, and wherein said polynucleotide is under a transcriptional control of a cis-acting regulatory element.

34. The method of claim 31, the transgenic plant of claim 32 or the nucleic acid construct of claim 33, wherein said polynucleotide is selected from the group consisting of SEQ ID NO: 10365-10963.

35. The method of claim 31, the transgenic plant of claim 32 or the nucleic acid construct of claim 33, wherein said polypeptide is selected from the group consisting of SEQ ID NO: 9591-10364.

36. The nucleic acid construct of claim 33, wherein said cis-acting regulatory element comprises a promoter.

37. The nucleic acid construct of claim 36, wherein said promoter comprises a tissue-specific promoter.

38. The nucleic acid construct of claim 37, wherein said tissue-specific promoter comprises a root specific promoter.

39. The method of claim 31, further comprising growing the plant under limiting nitrogen conditions.

40. The method of claim 31, further comprising growing the plant under abiotic stress.

41. The method of claim 40, wherein said abiotic stress is selected from the group consisting of salinity, drought, water deprivation, flood, etiolation, low temperature, high temperature, heavy metal toxicity, anaerobiosis, nutrient deficiency, nutrient excess, atmospheric pollution and UV irradiation.

42. The method of claim 31, or the plant of claim 32, being a monocotyledon.

43. The method of claim 31, or the plant of claim 32, being a dicotyledon.

44. A method of improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of a plant, the method comprising expressing within the plant an exogenous polynucleotide which downregulates an activity or expression of a polypeptide having an amino acid sequence at least 80% homologous or identical to SEQ ID NOs: 6315-8129, wherein said polypeptide is capable of regulating abiotic stress tolerance of the plant, thereby improving abiotic stress tolerance, nitrogen use efficiency, biomass, vigor or yield of the plant.

45. A transgenic plant exogenously expressing a polynucleotide which downregulates an activity or expression of a polypeptide having an amino acid sequence at least 80% homologous or identical to SEQ ID NOs: 6315-8129, wherein said polypeptide is capable of regulating abiotic stress tolerance of the plant.

46. A nucleic acid construct comprising a polynucleotide which downregulates an activity or expression of a polypeptide having an amino acid sequence at least 80% homologous to SEQ ID NOs: 6315-8129, wherein said polypeptide is capable of regulating abiotic stress tolerance of a plant, said nucleic acid sequence being under the regulation of a cis-acting regulatory element.

47. The method of claim 44, the transgenic plant of claim 45 or the nucleic acid construct of claim 46, wherein said polynucleotide acts by a mechanism selected from the group consisting of sense suppression, antisense suppression, ribozyme inhibition, gene disruption.

48. The nucleic acid construct of claim 46, wherein said cis-acting regulatory element comprises a promoter.

49. The nucleic acid construct of claim 48, wherein said promoter comprises a tissue-specific promoter.

50. The nucleic acid construct of claim 49, wherein said tissue-specific promoter comprises a root specific promoter.

Patent History
Publication number: 20190085354
Type: Application
Filed: Nov 30, 2018
Publication Date: Mar 21, 2019
Inventors: Rudy Maor (Rechovot), Iris Nesher (Tel-Aviv), Orly Noivirt-Brik (Givataim), Osnat Yanai-Azulay (Rishon-LeZion)
Application Number: 16/206,610
Classifications
International Classification: C12N 15/82 (20060101);