Low temperature responsive nucleotide sequences and uses thereof
This disclosure provides gene sequence of a novel gene DaRub1 of Deschampsia antarctica expressing in low temperatures. The promoter sequence of this gene is identified and characterized. The promoter is inducible by low temperatures, wounding and auxin treatment. Additionally the disclosure shows improved low temperature tolerance of transgenic Eucalyptus plants expressing DaRub1 gene.
1. Field of the Invention
The present invention relates to the field of improved stress tolerance of plants, more specifically to genes and promoter sequences expressing at low temperatures and even more specifically to low temperature tolerance improved by means of gene transfer.
2. Background
Low temperature is one of the major limiting factors of growth, development and geographical distribution of plants. Some plants are able to acclimate by increasing their freezing tolerance upon exposure to low non-freezing temperature. This process involves physiological and biochemical changes, many of which are regulated through qualitative and quantitative modification of gene expression leading to the accumulation of newly synthesized proteins and mRNAs.
A number of genes having expression induced by low temperature have been isolated and characterized in a wide range of species. Most of the studies of gene expression during cold acclimation have been performed in plants from temperate and semi-temperate climates. Differently to this approach, our approach has been to study gene expression of genes induced by cold acclimation in a highly freezing tolerant plant. Deschampsia antarctica Desv. (Poacea) is a highly tolerant plant to the harsh freezing conditions and it is one of the two vascular plant species that have naturally colonized Maritime Antarctic Peninsula. A high accumulation of soluble carbohydrates, especially sucrose and furctans has been found in leaves of D. antarctica during growth period in the Antarctic summer. Total protein extracts from leaves of D. antaratica growing in the Antarctica has been shown to have a high cryoprotective activity on barley chloroplasts. Membrane lipid contents and the degree of unsaturation of fatty acids in the leaves do not differ significantly from plants in temperate zones. The optimal photosynthetic activity of this species is at 13° C. and it can maintain up to 30% of this rate at 0° C. Cold acclimation experiments have shown that D. antarctica is able to acclimate from −14.8° C. (LT50 at −14° C.) to −26.8° C. when growing at +2/−1.5° C. for 21 days in a solid substrate in the laboratory.
Due to the high capacity of the cold acclimation that this species possesses we were interested of its gene expression during cold acclimation. Not only is there a need to characterize genes that are responsible for low temperature tolerance of plants but there is also a need for characterization and identification of new plant promoters. Characterization and identification of such genes and promoters will be greatly useful in improvement of various crops. There is a clear need to improve low temperature tolerance of various sensitive plant species. Furthermore, in plant breeding and research there is a constant need for plant promoters inducible by various environmental factors such as low temperature.
Therefore, one object of the present disclosure is to increase cold resistance or tolerance of plants through gene transfer, especially of fruit trees such as, but not limited to eucalyptus, avocado, orange and peach trees. The system can be applied both to monocots and to dicots.
Another object of this invention is to reduce photoinhibition caused by chilling temperatures.
Still another object of the present invention is to provide transgenic plants, plant cells, plant tissue, plant organs or plant components of plants such as, but not limited to Arabidobis thaliana or Eucalyptus globulus carrying a recombinant transgene capable of expressing a modified transcript of a related-to-ubiquitin protein of Deschampsia antarctica.
An even further object of the present invention is to provide promoters inducible by low temperatures, wounding and auxin treatment.
Eucalyptus globulus has become one of the most important forest species for example in Chile due to its fast growth and good wood quality especially for the purposes of pulp manufacturing. Currently, it represents the second most planted species in Chile, amounting approximately along with other eucalyptus species to a total of 350,000 hectares. However, strong world market competition makes it necessary to develop better technologies for its cultivation. Despite of its excellent characteristic there are wide surface areas up to 2 million hectares where growth limiting restrictions are to be found. In particular areas under frost conditions along with this species' low cold tolerance have limited plantation expansion both to the south and to the foothills of Andean Mountains. Also Chile's Center Valley has undergone frequent losses in those areas affected by frost conditions.
The present disclosure resolves the problem of low freezing tolerance of trees such as eucalyptus by a method rendering transgenic plants to tolerate lower temperatures. In addition to eucalyptus this method is applicable to various low temperature susceptible plants for example peach.
BRIEF DESCRIPTION OF THE DRAWINGS
(A) Total RNA of Arabidopsis plants: wild type (wt), transgenic lines L1, L2, L3 and ΔUBQ-RUB (vector alone) was extracted and hybridized with a UBQ-RUB probe (top panel). Sample loading (20 20 μg) was monitored using a 28S RNA probe (central panel). siRNA (50 μg) was hybridized with an anti-sense transcript corresponding to the UbiRub 3′-UTR (bottom panel)
(B) Total protein (15 μg) of A. thaliana wild-type, transgenic lines L1, L2, L3 and AUBQ-RUB (vector alone) plants were separated by SDS-PAGE, blotted on nitrocellulose membranes, and probed with a UBQ-RUB polyclonal antibody
During the exposure of plants to low temperature many physiological and biochemical changes occur which lead to the development of freezing tolerance. The survival of tolerant plants at freezing temperatures depends on timely modulation of the gene sets of the species, the accumulation of both mRNAs and protein products of such genes correlates with the development of freezing tolerance. A major difficulty is in the fact that many low temperature responsive genes are also induced by other stimuli, such as drought, abscisic acid (ABA) and salinity. It is unclear, however, how such different stimuli converge to induce the same gene. For example, it has been reported that low temperature and ABA regulates gene expression through separate transduction pathways. An alternative explanation is that several cis-acting elements are present in the promoter regions of these genes that respond to multiple factors.
Ubiquitin (UBQ) is one of the most conserved proteins among eukaryotes. The covalent attachment of UBQ to other proteins targets them for degradation by the 26S proteosome. Attachment of the ubiquitin carboxyl terminus to ε-amino lysyl-groups of substrate proteins requires ubiquitin-activating enzyme (E1), in an adenosine 5′triphosphate-(ATP)-dependent reaction in which a thiolester bond is formed between the COOH-terminus of UBQ and a cysteine within the E1 enzyme. The UBQ-moiety is transferred to a cysteine residue of ubiquitin-conjugating enzymes (E2). Finally, UBQ is covalently attached to a target protein by an isopeptide linkage directly from E2 or by UBQ-protein ligase (E3), such as the SCF (Skp1, Cdc53, F box protein, respectively). Recently, several families of ubiquitin-like proteins (RUB; related to Ubiquitin) have been described. These RUB-protein families include the mouse protein Nedd-8, Arabidopsis thaliana ubiquitin UBQ7, and the Saccaromyces cerevisae protein ScRub1p. Arabidopsis ubiquitin-like protein has 62% identity to ubiquitin, 83% identity to Nedd-8, and 57% identity to ScRublp. The RUB family includes the plant RUB1, RUB2, and RUB3 of A. thaliana, and RUB1 of Brassica napus, the mammal RUB of mouse, rat and human, an open reading frame with significant RUB identity from C. elegans, and the fungal RUBs. The Arabidobsis proteins RUB1 and RUB2 differ by only one amino acid at position 60. BnRUB1 and AtRUB1 encode identical proteins with the exception of the COOH-terminal additional amino acid.
Several studies in different models have shown that RUB proteins are conjugated to target proteins through the sequential action of RUB-activating and RUB-conjugating enzymes in a similar way as ubiguitin conjugation. In Arabidopsis, RUB1 is activated by an E1-like heterodimer AXR1/ECR1 and transferred, by an RUB-E2 enzyme called RCE1, to a cullin protein of a SCF complex. The unique targets for RUB modification are members of cullin protein family. These cullins are subunit of E2 ligase protein of the SCFs complex. In Arabidobsis, an E3 complex called SCFTIR1 cullin is required for auxin respond and it seems to be target for AUX/IAA proteins for degradation.
We have now isolated and characterized a gene expressing during cold acclimation of Deschampsia antarctica. The gene is called DaRub1, and it has an open reading frame (ORF) encoding for 153 amino acids polypeptide consisting of an ubiquitin monomer fused in the same ORF to a RUB protein. By Northern blot analysis we verified that this gene is expressed during cold acclimation during the first hours and being maintained with different expression levels up to 12 hours of acclimation. Furthermore, we isolated the promoter region of DaRub1 gene and identified and characterized the 5′-regularory region of this gene.
The present invention is directed toward a novel gene of Deschampsia antarctica expressing during acclimation and a promoter region of the gene. The invention is also directed to transgenic plants containing a modified gene transcript of Deschampsia antarctica.
The present disclosure includes the steps of a) characterization and identification of a novel gene of Deschampsia antarctica expressing during cold acclimation of the plant; b) characterization of the promoter region of the novel gene and showing the functionality of the promoter by fusioning it to a reporter gene and transforming into Arabidobis plants c) introducing into plant cells a transgene including a DNA encoding a modified version of a related-to-ubiquitin protein from Deschampsia antarctica operably linked to a promoter functional in plant cells to yield transformed plant cells; and d) regenerating a transgenic plant from the transformed cell, wherein the transcript of the modified version of the related-to-ubiquitin protein (RUB) interacts with signal transduction machinery of the plant, thereby increasing the level of cold-resistance or—tolerance in the transgenic plant. As a result the ice-nucleation and freezing temperatures are significantly lower in the transgenic plant.
Furthermore, the invention features a method for reducing the photoinhibition caused by chilling temperatures. The method includes the steps of a) introducing into plant cells a transgene including a DNA encoding a modified version of a related-to-ubiquitin protein from Deschampsia antarctica operably linked to a promoter functional in plant cells to yield transformed plant cells; and b) regeneration a transgenic plant from the transformed cell, wherein the transcript of the modified version of the related-to-ubiquitin protein interacts with the photosynthetic machinery of the plant, thereby increasing the photochemical or non-photochemical quenching capacity in the transgenic plant. As a result the transgenic plant is more tolerant or resistant to adverse effects caused by photoinhibition.
Even further the invention according to this disclosure features a model explaining auxin dependent modification of RUBs.
The following examples are meant to be descriptive and by no means limiting of the various embodiments of the present invention.
EXAMPLE 1 Plant Material and Growth Conditions for Obtaining Cold Acclimated Deschampsia antarctica PlantsDeschampsia antarctica Desv. (Poaceae) plants were collected in the Coppermine Peninsula on Robert Island, Maritime Antarctica (62° 22′S; 59° 43′W) during the austral summer and transported in plastic bags to the laboratory. Plants were propagated vegetatively in plastic pots using a soil: peat mixture (3:1), fertilized with 0.12 g/l Phostrogen (Solaris, Buckinghamshire, UK) once every 2 weeks, and maintained at 13° C. in a growth chamber with a photon flux density of 180 μmol m−2 s−1 at the top of the canopy and photoperiod of 21 h/3 h of light/dark. The light source consisted of cool-white florescent tubes (F40CW IGE, Charlotte, N.C., USA). Relative humidity was around 60-70%. Plants growing under these conditions were considered as controls. For cold-acclimation studies plants were maintained 4° C. at the same light and photoperiod conditions than control plants for different times (0-21 days). De-acclimated plants were obtained by returning cold-acclimated plants to normal growth conditions for 24 hours.
EXAMPLE 2 Construction of Cold-Acclimation cDNA Library and Identification of Cold-Acclimation-Responsive cDNAs by mRNA Differential DisplayTotal RNA isolated from 24- and 48 h cold-acclimated D. antractica leaves were pooled and used for cDNA library construction by means of the SMART cDNA Library Construction Kit (Clontech, Palo Alto, Calif., USA) and Gigapack II Gold Packaging Extract (Stratagene, La Jolla, Calif., USA), following the manufacturer's instructions. The primary library contained an estimated 5×106 independent clones with an average insert size of 1,200 bp. The library was amplified and stored in 7% DMSO at −80° C. The cDNA library was screened by in situ plague hybridization whit a random-primed 32P-labeled probe of differential display clone D0-B1.
D. antarctica cold-acclimation gene expression was studied by mRNA differential display using leaf total RNA extracted from non-acclimated and cold-acclimated Deschampsia antarctica plants taken at different intervals of treatment. A total of 38 cDNA bands were found to exhibit differential expression. Fragments were cut out of the gels, reamplified by PCR, and sub cloned into the pGEM-Easy vector. Twenty three partial cDNAs were shown by Northern blot analysis to be up- or down-regulated upon cold acclimation. DNA inserts of seven clones, ranging in size from 200 to 500 bp, were sequenced and the resulting sequences were compared with the NCBO non-redundant sequence database and three clones were left with unknown functions. The seven clones and the found homology of four of them are shown in Table 1 below.
A 260-bp differential clone, DO-BI, was isolated from total RNA from cold-acclimated Deschampsia antarctica plants and unveiled a ca. 1.0 kb transcript in Northern blots. In order to isolate a full-length cDNA, a cDNA library (95×104 pfu), prepared from total RNA isolated from cold-acclimated Deschampsia antarctica leaves, was screened with the 260 bp insert as the probe. An 831 bp cDNA, DACOR-1.0 was isolated. This cDNA has a putative open reading frame (ORF) of 462 bp, flanked by a 120 bp 5′ untranslated region and a 3′ UTR of 249 bp that includes a 28 bp poly-A tail (
To investigate the regulation of DaRub1 during cold acclimation, total RNA was extracted from leaves of Deschampsia antarctica at various time points of cold acclimation treatment. There was no detectable signal for the gene in total RNA samples from young leaves, although rather low signal was found in older leaves. Due to the presence of the ubiquitin encoding moiety of the gene DaRub1, which in other systems seems to be encoded by a family of genes, the Northern blots were probed with the 3′UTR of the cDNA clone DACOR-1.0. Cold-acclimated leaves accumulated mRNA of DaRub1 as early as 30 min (
For promoter isolation genomic DNA was isolated through a CsC1 gradient. For DaRub1 primer extension analysis total RNA was extracted from cold-acclimated plants (30 min to 24 hours) using Concert™ Plant RNA Reagent (Invitrogen) following the instructions of the manufacturer. Quality of total RNA was checked by electrophoresis on 1×TAE agarose gels. Primer extension analysis was performed using the 5′-TCTTCTCCTCCTGCTCCCGTGTGGC-3′ (SEQ ID NO:5) primer.
GenomeWalker libraries were prepared from D. antarctica genomic DNA using the Universal GenomeWalker™ kit (Clontech, Palo Alto, Calif., USA) following the instructions of the manufacturer. Three gene specific primers (GSP) were designed from DaRub1 cDNA sequence:
In order to confirm the co-linearity of the putative promoter fragment and the previously isolated DaRub1 cDNA the following two primers were designed:
Resulting promoter fragments were cloned into pGEM T-Easy vector (Promega, Madison, Wis., USA).
Sequencing of the amplified fragments was performed in an automatic sequencer using ABI PRISM Big Dye Terminator Cycle Sequencing Ready Reaction Kit (PROMEGA, Southampton, UK). The obtained sequences were analyzed for regulatory sequences and promoter-like elements using the MathInspector program.
The genomic DNA was digested with DraI, EcoRV, PvuI or StuI restriction enzymes, provided by the Kit, generating thus GW Bank (GWB). Subsequently, the DNA fragments generated were ligated to adapters in the kit. Finally, PCR reactions were executed utilizing the GSP primers and adapter primer, also supplied by the kit. Three PCR reactions were carried out following the instructions of the kit.
From third PCR two fragments were isolated; one being 1200 pb and originating from the third GWB (DL3:PvuI) and another of 566 pb originating from the fourth GWB (DL4:StuI). Both PCR fragments (1200 pb and 566 pb) were cloned in pGEM T Easy vector (Promega) and their adequate insertion in the vector MCS was analyzed by restriction.
The cloned fragments were sequenced and their sequences were compared. DL4 GWB fragments have high similarity with 3′-terminal sequence of the DL3 GWB. DL3 GWB (1200 pB) fragment sequence was compared at MatInspector program for searching regulatory sequences and promoter like elements. Several typical eukaryotic and plant regulatory sequences were found but only those directly related to DaRub1 gene characteristic or function were taken into account. The most important responding elements found were the ethylene response element (ERE), auxin response element (AuxRE) and dehydration response element (DRE) (
Two primers were designed from promoter 3′-terminal sequence and cDNA 5′-terminal sequence, and used to isolate a 672 pb fragment from the genomic DNA. This 672 pb fragment was used to determine the transcription star site (TSS) and to verify promoter sequence (GW product) and cDNA sequence co-linearity. The fragment amplified by PCR was isolated and cloned in pGEM-T Easy. Its adequate insertion in the vector was checked by restriction analysis and by PCR amplification of an internal fragment, utilizing fragment internal primers. The sequence of the 672 pb fragment was compared with the sequence expected, about 296 bases from 3′-terminal sequence were read resulting to 99.3% identity with expected sequence.
TSS was determined by mean primer extension method. TSS resulted to be a G, which was found 50 pB downstream to putative TATA box.
To study the putative promoter functionality, different reporter fusions were carried out with the promoter and its deletions (
All fusions were introduced to Arabidobsis thaliana Columbia mediated Floral Dip method. pCAMBIA1303 vector having 5′GusA-mgfp5*-3′ fusion having expression directed by 35S CaMV promoter region was used as a transformation control. Plants that contained pCAMBIA 1303 vector were utilized as GUS expression positive control (
Promoter region functionality in transgenic plants obtained for each one of the fusions (
Analysis was carried out in different organs of adult transgenic plants, such as flowers, siliques leaves, senescent leaves and roots. We also analyzed GUS expression in whole in vitro plantlets. Adult plants were also analyzed after wounding (detachment of leaf or aphis infection).
We studied expression in relation different auxins (2,4D) concentrations as well. Auxin treatment was carried out by transferring plants for 18 hours to liquid MS medium supplemented with 10 NM, 1.0 uM and 10 mM of 2.4 D. GUS expression induced by auxin was little more intense than GUS expression induced by cold but less than GUS expression induced by 35S promoter region in pCAMBIA 1303 (
No synergic effect in GUS expression was observed when plantlets were cold acclimated and auxin treated simultaneously
When adult plants (approximately 2-3 weeks in greenhouse) were cold acclimated an equal GUS expression was observed as in the in vitro plantlets. Interestingly, a clear GUS expression was observed in senescent leaves (
We studied the GUS expression in relation to other stress factors and could only find expression related to wounding. As seen from
In FIGS. 7D-H, it can be seen that GUS expression changes during different flower development phases: the expression is strong in early flower development phase and is less intense in advanced phases.
A fragment of 190 pb, which included the 3′UTR, was amplified for PCR using DaRub1 cDNA and the primers 5′-CCTGTGTGTAACATCAGACTCTCTCCAC-3′ (SEQ ID NO: 11) and 5′TCCACTTCTGCCCAATGCTAACTCC-3′ (SEQ ID NO: 12.) The amplified product was cloned in pGEM® T-Easy vector (Promega). RNA probes Digoxigenin-11-UTP labeling was carried out by Digoxigenin RNA labeling kit (Roche), following manufacturer's instructions. Sense and antisense probes were used.
D. antarctica plants were acclimated at 4° C. for 24 hours. The hybridization was according to the protocol of Jackson (1991) with modifications (Vielle Woen et al, 1999). 400 to 800 ng of RNA probes were utilized for each reaction. The hybridization was carried out at 55° C. overnight. For the immune detection, slides were incubated two times (45 minutes and 30 minutes) in 0.5% blocking agent (Boehringer Mannheim) in TBS (100 MM Tris HCl at pH 7.45, 150 mM NaCl) followed by 45 minutes in 1% BSA, 0.5% Triton X-100 in TBS. Antibody conjugation was made with 1:1250 in 1% BSA antidigoxigenine dilution for 2 hours. For revealed, the slices were washed in buffer C (100 mM Tris at Ph9.5, 50 mM MgCl2, 100 mM NaCl) two times and incubated for 2 to 5 days in 0.34 mg/l of nitroblue tetrazolium salt (NBT) and 0.175 mg/ml 5-bromo-4 chloro-3-indyl-phosphate-toluidinium salt (BCIP) in buffer C plus 7.6 mM levamisol (SIGMA). The reaction was stopped with 10 mM Tris HCl, 1 mM EDTA and the slices were re-hydrated in degree of ethanol series and Cytoseal mouted (Stephens Scientific). The analysis was carried out with a microscope Leica DMRB under brilliant field and optical Nomarski.
The antisense RNA in situ hybridization (
Genetic transformation of Eucalyptus globulus elite individuals via Agrobacterium tumefaciens was carried out according to the procedure described for recalcitrant species by Perez-Molphe & Ochoa-Alejo N. (1998) with some modifications. Agrobacterium tumefaciens hypervirulent strain AGLθ was used, a single colony of Agrobacterium was inoculated into 25 ml of YEP media (Yeast extract 20 g., peptone 20 g, NaCl 10 g.) together with the selection antibiotics, hygromycin 100 mg/L, rifampicin 100 mg/L, cloramphenicol 250 mg/L. The culture was shaken at constant 150 rpm. For 2-3 days until it reached an OD600 of 0.5. The culture was centrifuged a 3000×g for 20 min., resuspended in diluted MS media 1:10 and 50 μl of acetosyringone. Before use the suspension was incubated for 5 hours at 28° C. and at 100 rpm.
The tissue was prepared for transformation by selecting shoots that correspond to the second and third internodes of the in vitro cultivated plants. Additional longitudinal wounds were performed at both sides of the stem after which the explants were transferred an Erlenmeyer containing the Agrobacterium suspension.
The explants were incubated in the Agrobacterium suspension for 10 minutes under vacuum. Thereafter they were dried with sterile filter paper and transferred to the cocultivation media (MS [1/2] without hormones) placing them horizontally for 2 days.
After this the explants were rinsed in liquid MS plus cefotaxime 250 mg/mL to prevent Agrobacterium overgrowth, dried with sterile filter paper and placed vertically on selection media (MS, sucrose 3%, BAP 0.1 mg/mL, NAA 0.01 mg/mL, cefotaxime 250 mg/mL, selection antibiotic kanamycin 100 mg/mL or hygromycin 15 mg/mL). The explants were transferred to fresh new media every 7 days for the first 4 weeks.
Putative transgenic explants were transferred to rooting media (MS [1/2], IBA 2 mg/L, sucrose 20 g/L, agar 8 g/L, pH 5.8) with selection antibiotics, after which roots develop after 2 weeks.
Five transgenic eucalyptus lines were regenerated, each of which expressed DaRub1 gene.
EXAMPLE 9 Physiological and Biochemical Characterization of DaRub1 Transgenic Eucalyptus PlantsLethal Temperatures for 50% of Leaf Tissue (TL50) was analyzed from five transgenic Eucalyptus lines and two wild type lines in leaf tissue according to the methodology of Cloutier and Andrews (1984), with slight modifications (Alberdi et al., 1993). The leaves were placed in tight glass containers, AgI and H2O were added to prevent supercooling and to secure freezing of the samples. The glass containers were placed in a cryostat and exposed to freezing temperatures (approx. between −1 and −30° C.) for 120 minutes. After that the samples were thawed at 4° C. for many hours. Deionized water was added to the samples, stirred at 29° C. for 1 hour, and the ion leakage was measured by conductivity. TL50 corresponds to the temperature at which 50% of the dead tissue conductivity in liquid nitrogen is reached. This analysis was carried out first with control plants (wild type lines), and according to the results the conditions for cold acclimation and freezing were determined and used for the evaluation of the transgenic plants.
Table 2 below shows the freezing temperatures (upper and lower limits) of the transgenic lines 1-5 and two wild type lines. The table also shows ice nucleation temperature of the plants. The lines have been ranked based on the freezing tolerance as deduced from the Lt50 value and the ice nucleation temperature. It can be clearly seen that all of the transgenic lines are more tolerant to freezing stress than the control lines and that lines 3 and 5 show the best freezing tolerance.
The transgenic plants and wild type plants were also evaluated based on the physiological state of photosystem II (PSII) at low temperatures during cold acclimation and freezing by monitoring PSII fluorescence in the leaves. Fluorescence was measured with a pulse amplitude fluorimeter (Hansatech). Table 3 below shows the order of average percentage of photoinhibition of the leaves at different freezing temperatures. Clearly the transgenic lines (1 to 5) possessed less photoinhibition in low temperatures, thereby proving better low temperature tolerance of the transgenic lines as compared to the wild type lines (lines 6 and 7). Again transgenic lines 3 and 5 showed the best low temperature tolerance of the transgenic lines.
The freezing damage of the transgenic and wild type Eucalyptus leaves were also evaluated visually. Freezing damage in Eucalyptus leaves can be detected by color change in the central vein that turns red. This experiment also showed that the transgenic plants were clearly more freezing tolerant than the wild type plants: central veins of wild type plants turned reddish at −3° C. and clearly red at −5° C.; while the leaves of all transgenic lines showed reddish central veins in temperatures clearly lower than the wild type plants.
Claims
1. A nucleotide sequence encoding for amino acid sequence essentially according to SEQ ID NO:4; said nucleotide sequence having coding sequence according to SEQ ID NO:3.
2. The nucleotide sequence according to claim 1, wherein the nucleotide sequence further comprises promoter sequence according to SEQ ID NO:2.
3. The nucleotide sequence according to claim 1, wherein the nucleotide sequence is essentially according to SEQ ID NO: 1.
4. An inducible promoter having nucleotide sequence according to SEQ ID NO:2.
5. The promoter according to claim 4, wherein the promoter is inducible by low temperature, wounding and auxin.
6. A method for conferring low temperature resistance in a plant, said method comprising a step of introducing into the plant a recombinant expression construct, said construct further comprising a plant promoter operably linked to DaRUB1 sequence essentially according to SEQ ID NO:3.
7. The method according to claim 6, wherein the promoter is essentially according to SEQ ID NO:2.
8. The method according to claim 6, wherein the sequence encodes a gene product having a amino acid sequence essentially according to SEQ ID NO:4.
9. The method according to claim 6, wherein the plant is Euclayptus globulus.
10. The method according to claim 6, wherein the plant is Arabidopsis thaliana.
11. The method according to claim 6, wherein the plant species is a fruit tree.
12. The method according to claim 11, wherein the plant species is selected from the group consisting of peach, avocado and orange.
13. A DNA construct for cloning and transforming plants, said construct comprising nucleotide sequence selected from a group consisting nucleotide sequences according to SEQ ID NO:2 and SEQ ID NO:3.
14. A transgenic plant comprising the DNA construct according to claim 13.
15. The transgenic plant according to claim 14, wherein the plant comprises DNA construct according to SEQ ID NO:3 and the plant further has an increased low temperature tolerance.
16. The transgenic plant according to claim 15, wherein the plant is an Eucalyptus globulus plant.
17. The transgenic plant according to claim 15, wherein the plant is an Arabidobsis thalina plant.
18. The transgenic plant according to claim 15, wherein the plant is a fruit tree.
19. The transgenic plant according to claim 18 wherein the plant is selected from the group consisting of peach, avocado and orange.
Type: Application
Filed: May 2, 2005
Publication Date: Nov 24, 2005
Inventors: Manuel Gidekel (Temuco), Ana Gutierrez (Temuco), Luis Destefano-Beltran (Fargo, ND), Pamela Leal (Temuco), Jorge Dinamarca (Victoria), Emilio Guerra (Temuco)
Application Number: 11/120,351