CN109354618B - Application of G protein alpha subunit in regulation and control of cucumber seed germination, seedling growth and plant low temperature resistance - Google Patents
Application of G protein alpha subunit in regulation and control of cucumber seed germination, seedling growth and plant low temperature resistance Download PDFInfo
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- CN109354618B CN109354618B CN201811525835.3A CN201811525835A CN109354618B CN 109354618 B CN109354618 B CN 109354618B CN 201811525835 A CN201811525835 A CN 201811525835A CN 109354618 B CN109354618 B CN 109354618B
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Abstract
The invention relates to application of a G protein alpha subunit in regulation and control of seed germination of cucumber, seedling growth and low temperature resistance of plants. Experiments prove that the cucumber G protein alpha subunit and the coding gene thereof can regulate and control seed germination, seedling growth and low temperature resistance of plants of cucumbers. By implementing the method, low-temperature-resistant varieties of cucumbers can be cultivated, and corresponding cultivation technical measures are taken according to the low-temperature-resistant characteristics of the cucumbers, so that the low-temperature harm to the cucumbers is reduced to the maximum extent; the germination rate of cucumber seeds can be improved, and the growth of cucumber seedlings is promoted; the method has important theoretical significance and practical value for relieving or eliminating the low temperature in winter encountered in facility production and improving the yield.
Description
Technical Field
The invention relates to the field of biotechnology, in particular to application of a G protein alpha subunit in regulation and control of cucumber seed germination, seedling growth and low temperature resistance of plants.
Background
Plant G proteins are heterotrimers composed of three protein subunits, alpha, beta, and gamma. G proteins are widely found in monocotyledonous plants such as maize, soybean and rice, and dicotyledonous plants such as Arabidopsis thaliana. Although the expression pattern of AGB1(G-protein beta. subbunit) is similar to that of GPA1(G-protein alpha. subbunit), the intracellular localization of the encoded proteins is different, and thus AGB1 and GPA1 may play different functions in plants.
As an important facility vegetable crop in China, the low temperature in winter encountered in facility production is an important factor for limiting the yield of the cucumber. Research shows that when the cucumber is stressed by cold damage, the germination of seeds in the germination stage is inhibited, and radicles stretch slowly; when leaves of cucumber seedlings appear, the leaves shrink, wilting and the leaf veins begin to yellow, so that the phenomenon of withering appears; the growth of plants in early flowering stage is slow, and serious phenomena of flower topping, melon melting and the like can occur. According to the invention, through deeply researching the expression characteristics and related functions of the cucumber G protein alpha subunit CsGPA1 gene, the molecular mechanism of the cucumber for resisting low temperature is explored, the low temperature resistant variety can be cultivated, and corresponding cultivation technical measures can be taken according to the low temperature resistance characteristics of the cucumber, so that the low temperature harm to the cucumber is reduced to the maximum extent.
Disclosure of Invention
The invention aims to solve the technical problem of how to regulate and control the germination of cucumber seeds, the growth of seedlings and the low-temperature resistance of plants.
The research of the invention finds that the expression of the cucumber G protein alpha subunit CsGPA1 gene has correlation with cucumber seed germination, seedling growth and low temperature resistance of plants, thereby providing the invention.
Specifically, the invention provides application of cucumber G protein alpha subunit in regulation and control of cucumber seed germination, seedling growth and/or low temperature resistance of plants.
In the above-mentioned application, the first and second substrates,
the amino acid sequence of the G protein alpha subunit:
1) as shown in SEQ ID No. 2; or,
2) the amino acid sequence shown in SEQ ID No.2 is an amino acid sequence which is substituted, deleted and/or added with one or more amino acid residues and has the same activity.
It is understood that one skilled in the art can substitute, delete and/or add one or several amino acids according to the amino acid sequence of the alpha subunit of G protein disclosed in the present invention (SEQ ID No.2) without affecting its activity to obtain the mutant sequence of the alpha subunit of G protein. Therefore, the G protein alpha subunit of the invention also comprises a derivative polypeptide which is obtained by substituting, replacing and/or adding one or more amino acids in the amino acid sequence shown in SEQ ID No.2 and has the same activity with the G protein alpha subunit.
Specifically, the plurality of amino acid residues includes no more than 10 amino acid residues.
The G protein alpha subunit can be artificially synthesized, or can be obtained by synthesizing the coding gene and then carrying out biological expression.
The invention also claims application of the nucleic acid molecule for coding the G protein alpha subunit in regulation and control of cucumber seed germination, seedling growth and low temperature resistance of plants.
In particular, the nucleotide sequence of the nucleic acid molecule encoding the alpha subunit of the G protein:
1) as shown in SEQ ID No. 1; or
2) A nucleic acid molecule which is obtained by substituting, deleting and/or adding one or more nucleotides in the nucleotide sequence shown in SEQ ID No.1 and codes the alpha subunit of the G protein;
3) a nucleic acid molecule which hybridizes with the nucleotide sequence defined in 1) or 2) under stringent conditions and codes for the alpha subunit of the G protein.
Wherein the nucleic acid molecule may be DNA, such as cDNA, genomic DNA or recombinant DNA; the nucleic acid molecule may also be RNA, such as mRNA or hnRNA, etc.
The nucleotide sequence of the alpha subunit of the G protein of the invention can be readily mutated by one of ordinary skill in the art using known methods, such as directed evolution and point mutation. Those nucleotides which are artificially modified to have 75% or more identity to the nucleotide sequence of the G protein alpha subunit isolated in the present invention are derived from the nucleotide sequence of the present invention and are identical to the sequence of the present invention as long as they encode the G protein alpha subunit and have the function of the G protein alpha subunit.
In the present invention, the term "identity" refers to sequence similarity to a native nucleic acid sequence. "identity" includes a nucleotide sequence having 75% or more, or 85% or more, or 90% or more, or 95% or more identity to the nucleotide sequence of the protein consisting of the amino acid sequence shown in SEQ ID No.2 of the present invention. Identity can be assessed visually or by computer software. Using computer software, the identity between two or more sequences can be expressed in percent (%), which can be used to assess the identity between related sequences.
In order to solve the problems, the invention also provides a method for cultivating the transgenic cucumber.
The method for cultivating the transgenic cucumber comprises the steps of introducing nucleic acid molecules for coding the G protein alpha subunit into the cucumber to obtain the transgenic cucumber; the transgenic cucumber has increased seed germination, increased seedling growth, and/or increased plant cold resistance as compared to the recipient cucumber.
In the present invention, said "introducing a nucleic acid molecule encoding said G protein alpha subunit into cucumber" can be achieved by introducing a recombinant vector into a recipient cucumber; the recombinant vector may be a recombinant plasmid obtained by inserting a nucleic acid molecule encoding the alpha subunit of the G protein into a vector. The recombinant vector can be specifically a recombinant plasmid pBI121-CsGPA 1. The recombinant plasmid expresses a G protein alpha subunit shown in SEQ ID No. 2.
In order to solve the technical problems, the invention also provides a cucumber breeding method.
The cucumber breeding method provided by the invention can comprise the following steps: increasing the content or activity of the G protein alpha subunit in cucumber, thereby increasing germination rate of cucumber seeds, promoting seedling growth and/or improving low temperature resistance of plants.
The invention also provides application of the cucumber low-temperature regulatory protein CsWCOR413PM and the G protein alpha subunit (CsGPA1) in regulation and control of the low-temperature resistance of cucumber plants.
The amino acid sequence of the cucumber low-temperature regulatory protein CsWCOR413PM is shown in SEQ ID No. 4.
The invention also claims the application of the nucleic acid molecule for coding the cucumber low-temperature regulatory protein CsWCOR413PM and the nucleic acid molecule for coding the G protein alpha subunit in regulating and controlling the low-temperature resistance of cucumber plants.
The nucleotide sequence of the coded cucumber low-temperature regulatory protein CsWCOR413PM is shown in SEQ ID No. 3.
The nucleic acid molecules of the alpha subunit of the G protein have the same meaning as above.
Specifically, the regulation and control of cucumber seed germination is to promote cucumber seed germination (such as to improve seed germination rate, especially to promote seed germination rate under dark conditions); the regulation of seedling growth is to promote seedling growth (e.g., induce growth of cotyledons, hypocotyls, and main roots under dark conditions, thereby promoting growth of seedlings); the regulation and control of the low temperature resistance of the plant is to improve the low temperature resistance of the plant.
The invention also claims the application of the G protein alpha subunit or the nucleic acid molecule for coding the G protein alpha subunit in improving the content of cucumber endogenous hormone Salicylic Acid (SA). In particular to the improvement of the salicylic acid content of cucumber hypocotyl.
The research of the invention discovers that the cucumber endogenous gene CsGPA1 can influence the development of cucumber seeds, promote the germination rate of the seeds under the dark condition, and promote the growth of seedlings by inducing the growth of cotyledons, hypocotyls and main roots under the dark condition. CsGPA1 produces positive control of cell elongation by altering the endogenous hormone Salicylic Acid (SA) content, thereby defending against the effects of dark conditions on cell development. The research shows that the CsGPA1 transgenic line overexpressed in dark conditions can promote the differentiation and the elongation of cells in the cortex, the vascular system and the thin-wall tissues of seedlings. Meanwhile, CsGPA1 can regulate the differentiation of cells in cortex and parenchyma tissues and positively regulate the development of hypocotyl of early cucumber seedlings under dark conditions
The research of the invention discovers that cucumber G protein alpha subunit (CsGPA1) participates in low-temperature stress response, and CsGPA1 with low-level expression quantity reduces the low-temperature tolerance of the plant in an interference RNAi strain.
Further research by using the split ubiquitin yeast double hybrid and pull down technology shows that the cucumber low temperature regulatory protein CsWCOR413PM and CsGPA1 interact to cooperatively participate in response to low temperature stress under the stress of low temperature (less than or equal to 6 ℃).
The low temperature of the invention is generally less than or equal to 6 ℃, especially 0-6 ℃.
In the present invention, the transgenic cucumber comprises not only the first generation transgenic plant obtained by transforming the nucleic acid molecule into recipient cucumber, but also its progeny. For transgenic cucumber, the nucleic acid molecule can be propagated in that species, and can also be transferred into other varieties of the same species, including particularly commercial varieties, using conventional breeding techniques.
The transgenic cucumber comprises seeds, callus, complete plants and cells.
Experiments prove that the cucumber G protein alpha subunit and the coding gene thereof can regulate and control seed germination, seedling growth and low temperature resistance of plants of cucumbers. By implementing the method, low-temperature-resistant varieties of cucumbers can be cultivated, and corresponding cultivation technical measures are taken according to the low-temperature-resistant characteristics of the cucumbers, so that the low-temperature harm to the cucumbers is reduced to the maximum extent; the germination rate of cucumber seeds can be improved, and the growth of cucumber seedlings is promoted; the method has important theoretical significance and practical value for relieving or eliminating the low temperature in winter encountered in facility production and improving the yield.
Drawings
FIG. 1 shows the results of cloning of cucumber G protein alpha subunit CsGPA1 cDNA and electrophoresis pattern detection of recombinant plasmid; wherein, FIG. 1A is an RT-PCR clone of CsGPA1 cDNA; FIG. 1B shows PCR detection of CsGPA1-Teasy recombinant bacteria liquid; m represents DNAmarker III (2000 bp); S2-S10 are PCR-specific amplified fragments of CsGPA1, respectively.
FIG. 2 shows the constitutive structure of cucumber G protein alpha subunit CsGPA1 gene.
FIG. 3 shows a plasmid map of pBI-121 (FIG. 3A) and a schematic structural diagram of recombinant plasmid pBI121-CsGPA1 (FIG. 3B).
FIG. 4 shows a pFGC1008 vector map.
FIG. 5 shows the results of CsGPA1 overexpression and the interfering plants obtained; wherein, A: PCR identification of CsGPA1 overexpression vector; b: PCR identification of RNAi interference vectors; c: analyzing the relative expression quantity of CsGPA1 in wild plants, over-expressed plants and interfering plants; d: the growth process of the transgenic plants uses three biological replicates with cucumber TUA gene as internal reference.
FIG. 6 shows seed germination rates and seed thousand grain weight for wild type and cucumber transgenic lines; wherein panel A shows pictures of wild type and cucumber transgenic lines at 0 and 3 days after germination of the seeds. Scale 1 cm. Panel B shows germination rates of wild type and cucumber transgenic lines at 24 and 48 hours. Panel C shows the relative expression of CsGPA1 for 6 days without the transgenic line. Panel D shows thousand kernel weight (g) of seeds from wild type and cucumber transgenic lines. Panel E shows the seed length of the wild type and cucumber transgenic lines. Panel F shows the seed width of the wild type and cucumber transgenic lines. The radicle length of 3mm was considered as seed germination. Three replicates, at least 20 replicates each. WT: a wild type; OE: CsGPA1 overexpression transgenic lines; RNAi CsGPA1 interference strain.
FIG. 7 shows the results of morphological features of seedlings of wild type and cucumber transgenic lines; wherein, the graph A is a phenotype picture of wild type and transgenic seedlings growing for 3 days. Panel B is a picture of the phenotype of wild type and transgenic seedlings grown for 6 days. Scale 1 cm. (Panel A and B) growth conditions: in the dark at 30 ℃,2 layers of filter paper were spread on 9.0cm diameter petri dishes, and 5ml of distilled water was added to each petri dish by a pipette. Wild type (middle), OE (left), and RNAi (right) scale ═ 1 cm. And the elongation value of the radicle is 3mm, and the radicle is regarded as seed germination. Panel C shows hypocotyl length. Panel D shows cotyledon surface area. Panel E shows hypocotyl surface area. Panel F shows the stem thickness. Graph G shows root surface area. Graph H represents the root volume. Graph I represents the root length. Panel J shows the area of the hypocotyl projection. Panel K shows the projected area of cotyledons. The graph L represents the root projected area.
FIG. 8 shows the results of cross-cutting and longitudinal-cutting of hypocotyls of different transgenic seedlings grown for 6 days under dark conditions; wherein, (A) OE # 97, (B) wild type, (C) RNAi # 10 interference strain. (D) An enlarged view of the transection of the hypocotyls of the OE # 97, (E) wild type and (F) RNAi # 10 interfering strains. Scale bar 100 μm. EP, outer toughness; IP, internal firmware; x, xylem; PP, parenchymal cells; BS, bundle sheath. (G) OE # 97, (H) wild type, and RNAi # 10 interfering strains hypocotyl slitting. The dotted line indicates the designated direction. (J) The mean single cell area of the outermost layer of parenchyma cells. (K) Every 0.5mm2Average number of cells (n ═ 3 regions shown in the figure)
FIG. 9 shows the results of cross-cutting and longitudinal-cutting of cotyledons and root tips of different transgenic seedlings grown for 6 days in dark conditions; wherein, (A) OE, (B) wild type, (C) interference (RNAi) strain. (D) Leaf longitudinal cutting of OE strain, (E) leaf longitudinal cutting of wild type strain, (F) leaf longitudinal cutting of interference (RNAi) strain. (G) Root tip longitudinal cutting of OE strains, (H) root tip longitudinal cutting of wild type strains, and (I) root tip longitudinal cutting of interference (RNAi) strains. Scale bar 100 μm.
FIG. 10 shows that CsGPA1 may influence the growth result of cucumber seedling hypocotyl by changing the content of endogenous hormone Salicylic Acid (SA); wherein (A) Salicylic Acid (SA) is assayed by HPLC for the endogenous salicylic acid content of cotyledons of seedlings grown under dark conditions for 6 days and (B) the endogenous salicylic acid content of hypocotyls of seedlings grown under dark conditions for 6 days. (C) (D), (E) and (F) are the expression levels of CsSR1, CsEDS1, CsCBP60g and CsSR1 in cotyledons, hypocotyls and roots of seedlings grown for 6 days under dark conditions, respectively. Three biological replicates using the cucumber CsActin gene as an internal control.
FIG. 11 shows the results of the effect of exogenously administered SA (10. mu. mol/L) on CsGPA1 interference strain hypocotyls.
FIG. 12 is a schematic diagram of the growth and development process of hypocotyl regulated by SA for CsGPA 1.
FIG. 13 shows the effect of cold treatment on wild type cucumber seedling CsGPA1 expression and wild type and transgenic cucumber seedling phenotype; wherein, (A and B) under normal growth conditions, the first three-leaf and one-heart cucumber seedlings are processed at low temperature. (C) Phenotype of first, second and third leaves of WT plants after 60h of low temperature (6 ℃). (D) Phenotype of the first, second and third leaves of RNAi plants after 60h of low temperature (6 ℃). WT, RNAi stands for wild-type and interfering strains, respectively; (E and F) interfering with the analysis of CsGPA1 relative expression quantity and Western blot in transgenic strains (RNAi-9 and RNAi-10); h is hours. Three biological replicates using the cucumber CsActin gene as an internal control.
FIG. 14 shows the results of the effect of cold treatment on wild type and transgenic cucumber seedling-related gene expression; wherein (a) expression of CsGPA1 in leaf blades; (B) expression of CsWCOR413PM in leaf; (C) expression of CsICE1 in leaf; (D) expression of CsCBF1 in leaf; (E) expression of CsCBF3 in leaf; (F) expression of CsRD-29 in leaf; (G) expression of CsHOS1 in leaf; expression levels of genes before and after cold treatment of different plants. WT, RNAi stands for wild-type and interfering strains, respectively; h is hours. Three biological replicates using the cucumber CsActin gene as an internal control.
FIG. 15 shows the results of the effect of low temperature treatment on lipid peroxidation, antioxidant enzyme system activity and osmotic substance of leaf membranes of wild type and transgenic cucumber seedlings; wherein, (a) relative conductivity; (B) malondialdehyde content; (C) (ii) proline content; (D) soluble protein content; (E) superoxide dismutase activity; (F) peroxidase activity; (G) a catalase activity; WT and RNAi represent wild-type and interfering strains, respectively; h is hours, three biological replicates were used for each experiment and statistical significance was tested by the Duncan method.
FIG. 16 shows the pBT3-N-GPA1 vector construction; wherein, (A) Marker; (B) a library recombination rate identification map; (C) marker; (D) double enzyme digestion identification chart of bait carrier. M: DNA marker; lane1 plasmid after Bglll enzyme digestion; lane2 DNA plasmid.
FIG. 17 shows the growth of pTSU2-APP + pPR3-N on each plate (SD-trp-leu/SD-trp-leu-his/SD-trp-leu-his-ade).
FIG. 18 shows the two-hybrid validation of the interaction of CsGPA1 protein with CsWCOR413PM protein under low temperature (6 ℃) treatment of split ubiquitin yeast; wherein, (A) the line drawing culture is carried out on SD/-Trp-Leu-His +10mmol L3-AT culture medium; (B) detection of beta-galactosidase Activity of the colonies in Panel A; (C) the split ubiquitin was used to detect CsGPA1 and CsWCOR413PM protein interactions.
FIG. 19 shows the alignment of the CsWCOR413PM gene sequences.
FIG. 20 shows the results of a Coomassie blue staining experiment with GST-CsGPA 1.
FIG. 21 shows the results of GST-CsGPA1 and His-CsWCOR413PM protein purification.
FIG. 22 shows Pull down verifies that GST-CsGPA1 and His-CsWCOR413PM proteins interact.
Detailed Description
The following examples further illustrate the present invention but are not to be construed as limiting the invention. Unless otherwise specified, all biochemical reagents used in the examples are commercially available reagents, and the technical means used in the examples are conventional means well known to those skilled in the art.
The cucumber (Cucumis sativus L.) cultivar of "Xintai Mici" is a wild type material used by the invention and a transgenic plant source of overexpression, interference (RNAi) and the like.
The strain is as follows: the strains of Agrobacterium tumefaciens (Agrobacterium tumefaciens) LBA4404 and Escherichia coli (Escherichia coli) DH 5. alpha. for constructing the vectors were obtained from the laboratory. Coli DH5a was used as a transformation host for plasmids, purchased from the washington. Yeast (Saccharomyces cerevisiae) strain MY51 for ubiquitin yeast double-hybrid experiment.
Carrier: pBI121 is a gene overexpression vector, pFGC1008 is an interference RNAi vector, pBT3-N is a ubiquitin fission yeast double-hybrid AD vector, and pGEX4T1 and pET21a are prokaryotic expression vectors.
Enzyme and drug reagents and instrumentation:
restriction enzymes were purchased from NEB and Takara; RNA and DNA extraction kit, DNA gel recovery kit, MS powder, agarose, plant gel and the like used for tissue culture are purchased from the Wash ocean biology company.
PrimeScriptTMRT reverse transcription kit (RR047A) was purchased from Takara corporation, qRT-PCR kitGreen PCR Master Mix and other related reagents are purchased from Dalianbao bioengineering company, and phytohormones and various antibiotics used during tissue culture are purchased from Leibehrs biology company; the phytohormone Salicylic Acid (SA) was purchased from Sigma; other conventional reagents, medicines and the like are all made in China and analyzed.
Biological reagent: LA Taq DNA polymerase, dNTP from NEB company; gel recovery kit was purchased from AXYGEN; the PCR synthetic reagent is purchased from Shanghai Biotechnology engineering company; GUS dye was purchased from Washington, Inc.; all primers used were synthesized by Bomaide.
The test mainly uses instruments and equipment such as a shaking table, a spectrophotometer, a table centrifuge, an incubator, a PCR instrument, a water bath kettle, a-80 ℃ ultra-low temperature refrigerator, an illumination incubator, a fluorescence quantitative PCR instrument, a sample crusher and the like.
HPLC endogenous hormone content determination
1) Instruments, reagents and materials
Agilent 1260 Infinity-6420 liquid chromatography-mass spectrometer. Methanol, formic acid, 6-benzyladenine, indoleacetic acid, abscisic acid, gibberellin, zeatin, salicylic acid and jasmonic acid, and a C18SPE solid phase extraction column. 5% hydrochloric acid methanol solution: firstly measuring 95mL of methanol, adding the methanol into a wide-mouth bottle, then measuring 5mL of hydrochloric acid, adding the hydrochloric acid into the wide-mouth bottle, and uniformly mixing to prepare the composition. Chloroform-methanol solution: 50mL of chloroform solution is measured and added into a wide-mouth bottle, and then 50mL of methanol solution is measured and added into the wide-mouth bottle to be mixed to prepare the composition.
2) Sample analysis method
Chromatographic conditions are as follows: the working temperature of the chromatographic column is 35 ℃; column model Hypersil GOLD C18, size 100 x 2.1mm x 1.9 um; the flow rate was set at 0.2ml per minute; the mobile phase is 30% acetonitrile and 70% water; the sample amount is 2.0 mul;
mass spectrum conditions: the ion source is an ion spray ionization source (ESI) and is used for detecting in a positive ion mode; the working temperature is 300 ℃; the ion injection voltage is 5500V; the pressure is 379 kPa; the source gas is N2A gas; pressure: 241 kPa; gas curtain gas (N)2) The pressure was 69 kPa; the scanning mode is Multiple Reaction Monitoring (MRM); collision gas (N)2) Pressure: the Medium.
3) The sample pretreatment is carried out according to a conventional method.
4) Method for determining relative conductivity (REC) reference Liu et al (2007),
5) determination of membrane lipid peroxidation
The Malondialdehyde (MDA) content was determined with a COMIN MDA test kit according to the instructions on a UV-1800 spectrophotometer.
6) Determination of proline (Pro) and soluble protein (Solution protein) content
Determination of proline content is referred to the method of Shan et al (2007).
7) Determination of antioxidant enzyme Activity
SOD, POD and CAT were measured on a UV-1800 Spectrophotometer (SHIMADZU) using a SOD test cartridge, a CAT test cartridge and a POD test cartridge, respectively, from COMIN corporation, according to the instructions.
Example 1 cloning of the Gene CsGPA1 encoding the alpha subunit of the G protein in Cucumis sativus
1) Obtaining a template
RNA of wild type cucumber leaf is extracted by using an RNA extraction kit (GT2654) and stored in an ultra-low temperature refrigerator (-80 ℃) for standby. Using PrimeScript@The RT reverse transcription kit (RR047A) reverse transcribes the first strand cDNA, which is stored at-20 ℃ until use.
2) Artificially synthesized primer (containing restriction enzyme sites Sma I and Xba I)
Forward amplification primer: GCTCTAGAATGCTGTCTCATTTGAGTAGAAA, respectively;
reverse amplification primer: TCCCCCGGGTCACAATAACCCAGCCTCA, respectively;
taking the cDNA obtained in the step 1) as a template, carrying out PCR amplification by using the primers to obtain a target fragment of the gene (shown in figure 1A), recovering a possible target band, connecting the recovered target band to a T carrier, transforming escherichia coli DH5 alpha competence, carrying out blue-white screening, carrying out sequencing (shown in figure 1B) analysis on a positive E.coli bacterial liquid with correct PCR detection of the bacterial liquid, and obtaining a result that 1 cucumber G protein alpha subunit gene full-length sequence (CsGPA1) is cloned.
Sequence analysis shows that the nucleotide sequence of the gene CsGPA1 has the length of 5879bp, codes 392 amino acids, and has the molecular weight of 44.6 KDa. CsGPA1 contains 13 exons and 12 introns and is located on the fourth chromosome (fig. 2).
The nucleotide sequence of the cucumber G protein alpha subunit gene CsGPA1 is shown in SEQ NO.1, and the amino acid sequence of the cucumber G protein alpha subunit is shown in SEQ NO. 2.
Example 2 obtaining of transgenic cucumber
CsGPA1 transgenic cucumber
1) Construction of recombinant plasmid
The PCR product (amplification-purification) of step 2) of example 1 and the expression vector plasmid pBI121 were subjected to double digestion with specific restriction enzymes (XbaI, Sma I), respectively; and recovering the enzyme digestion product, and then connecting the enzyme digestion product by using ligase to obtain the recombinant plasmid pBI121-CsGPA 1. The structural schematic diagrams of pBI-121 plasmid (FIG. 3A) and recombinant plasmid pBI121-CsGPA1 (FIG. 3B) are shown in FIG. 3.
2) Acquisition of CsGPA1 transgenic cucumber
The recombinant plasmid pBI121-CsGPA1 is transformed into agrobacterium (LBA4404), then the constructed vector is transferred into wild cucumber callus (refer to the method of Sui et al, 2012), a transgenic plant is obtained after tissue culture, and seedlings are moved into a flowerpot of sterile soil for culture, so as to obtain leaves. In addition, transplanting the seedlings into a cultivation greenhouse, and periodically maintaining and managing to obtain transgenic seeds.
(II) CsGPA1-RNAi transgenic cucumber
Artificially synthesizing a primer:
CsGPA1-RNAi-upstream-F:AGGCGCGCCAGTAGATCGGGTGTTTAAGGTATAC Asc I
CsGPA1-RNAi-upstream-R:GATTTAAATTCACAATAACCCAGCCTCAAA Swa I
CsGPA1-RNAi-downstream-F:GACTAGTAGTAGATCGGGTGTTTAAGGTATAC Spe I
CsGPA1-RNAi-downstream-R:CGGGATCC TCACAATAACCCAGCCTCAAA BamH I
using the cDNA obtained in step 1) of example 1 as a template, PCR amplification was performed using the above primers to obtain target fragments of two genes. And (3) carrying out double enzyme digestion treatment on the two target fragments and the plasmid pFGC1008 by using corresponding 2 restriction endonucleases respectively, then purifying and recovering the target fragments and the plasmid fragments required after enzyme digestion, and connecting the two fragments by using a ligase to construct an interference RNAi gene expression vector. Transforming agrobacterium (LBA4404) by the recombinant plasmid, then transferring the constructed vector into wild cucumber callus (refer to the method of Sui et al, 2012), obtaining transgenic plants after tissue culture, and transferring seedlings into a flowerpot in sterile soil for culture to obtain leaves. In addition, transplanting the seedlings into a cultivation greenhouse, and periodically maintaining and managing to obtain transgenic seeds. The pFGC1008 vector is shown in FIG. 4.
(III) identification of transgenic cucumber
And extracting DNA from leaves of the transgenic cucumber plant. Designing different specific primers according to different vector sequences to perform PCR reaction: (overexpressing plants) T CsGPA 1-OE-F: CTCAGAAGACCAAAGGGCA
T CsGPA1-OE-R:CAGATTTCAGAACAGAAGCGT
(interfering with the expression of the plant) T CsGPA 1-RNAi-F: GAGGACACGCTCGAGTATAAGA
T CsGPA1-RNAi-R:GCACAACAGAATTGAAAGCAAA
The results of the assay are shown in FIG. 5.
Positive transgenic plants were tested at the DNA level (FIG. 5C) and RNA level (FIG. 5D). By analyzing the expression level of the gene in the transgenic plant (fig. 5D), the expression level of the CsGPA1 gene in the over-expressed transgenic plant is found to be obviously up-regulated; and the expression level of the CsGPA1 gene is obviously reduced in the interference expression transgenic plant, thereby proving that the exogenous sequence is indeed recombined on the cucumber genome.
According to the gene identification result, wild type, 3 over-expression strains (OE-29, OE-80 and OE-97) and 3 interference transgenic RNAi strains (RNAi-9, RNAi-10 and RNAi-40) are respectively selected as representatives to continue subsequent research.
Example 3 Effect of cucumber G protein alpha subunit Gene CsGPA1 on cucumber seed Germination and cucumber seedling growth and development under dark conditions
To determine whether CsGPA1 affects early growth of cucumber seedlings, seeds and seedlings of cucumber wild type, CsGPA1(OE) overexpression and interference (RNAi) lines were selected as sample material (fig. 6A). After 3 days of treatment of the seeds of the experimental material at 30 ℃ in the dark (suitable conditions for germination of cucumber seeds), differences were found in the sizes and germination rates of the seeds of Wild Type (WT), CsGPA1(OE) overexpression and interference (RNAi) strains (FIG. 6B). Respectively counting the germination rates of seeds of wild type and CsGPA1(OE) overexpression and interference (RNAi) strains treated for 24 hours under the condition, wherein the germination rates of the seeds of WT and OE strains are all 100%; the germination rate of the seeds of the RNAi strain in 24 hours is only 49.3%, and the germination rate reaches 91.67% after 48 hours of treatment (figure 6B). The results indicate that CsGPA1 may play a positive regulatory role in the process of embryo development and seed germination.
To further clarify the potential impact of endogenous CsGPA1 on seed development and seedling morphology. The physiological characteristics (thousand kernel weight and kernel length/width) of the WT, OE and RNAi strain seeds were determined separately, and the germination rate and physiological characteristics of the seeds showed that: compared with Wild Type (WT), the over-expression of CsGPA1 can significantly promote the development of seeds, the thousand seed weight of the seeds is heavier, and the seeds are bigger and more full. Thus further increasing seed yield (FIGS. 6D-F).
Meanwhile, morphological characteristics (length, stem thickness, surface area, projected area and volumes of cotyledon, hypocotyl and root) of WT, OE and RNAi strains grown for 6 days under a dark 30 ℃ condition were compared. The results show that: the surface area, projected area and volume of cotyledons, hypocotyls and roots of seedlings of the OE strain are larger than those of WT and RNAi strains; hypocotyl stems were thicker (FIG. 7A-L). Seedlings overexpressing CsGPA1 had larger cotyledons, longer hypocotyls and more lateral roots. Therefore, overexpression of CsGPA1 can promote the development of cucumber seedlings under dark conditions. The above data indicate that endogenous CsGPA1 can affect cucumber seed development and promote seedling growth by inducing the growth of cotyledons, hypocotyls and main roots in the dark. Root length, surface area, projected area and volume were analyzed using WinRHIO 2007 software (LC4800-II LA2400, Saint Foy, Canada).
To determine whether CsGPA1 affected seedling growth by affecting cell differentiation and elongation. Avoid the influence of light on the test results, selecting hypocotyls of WT, OE and RNAi strains seedlings growing for 6 days under dark conditions, in which phenotypic differences can be seen significantly, as test materials, respectively (FIGS. 8A-L). Paraffin sections of seedling hypocotyls cut transversely and longitudinally were observed under a microscope to compare the sizes of the epidermis, parenchyma, vascular bundles and outer tough cells of WT, OE and RNAi strains, respectively. Comparison of hypocotyl cross sections of seedlings of different lines shows that OE hypocotyl ectodermal cells are larger compared to WT. Further observation and finding; OE hypocotyls had more epidermal and xylem cells, and a more porous cell layer (cortex, parenchyma, vascular bundle and intrinsic toughness) compared to WT seedling hypocotyls (fig. 8A, D and G); in contrast, observation of the cross section of the hypocotyl of the RNAi strain revealed smaller epiblast cells and fewer epidermal and xylem cells (FIGS. 8B, E and H), with a tighter cell layer (cortex, parenchyma, vascular bundle and endoblast) (FIGS. 8C, F, I, J and K).
The longitudinal sections of cotyledons and paraffin sections of seedlings of WT, OE and RNAi strains and of the main root grown for 6 days under dark conditions were further observed under a microscope. The results show that: compared to the WT and RNAi strain taproots, OE cells elongate relatively fast, cells are larger and cell numbers are smaller; in contrast, RNAi has slower rates of differentiation and elongation of the main root and cotyledon cells. The results are shown in FIGS. 9A-I. The results show that: it is likely that lines with larger cotyledons, longer hypocotyls and a greater number of lateral roots were obtained due to the fact that overexpression of GPA1 promoted differentiation and elongation of the cells. Whereas RNAi strains show smaller cotyledons, shorter hypocotyls and a smaller number of lateral roots due to reduced cell differentiation and elongation. Therefore, CsGPA1 may be a positive regulator in the differentiation and elongation of seedling cells under dark conditions, and the overexpression of CsGPA1 promotes the differentiation and elongation of cells, thereby promoting the growth of seedlings.
Example 4
To further clarify how CsGPA1 regulates the growth of cucumber hypocotyls in the dark, whether by influencing the cucumber seedling endogenous hormone levels, the endogenous Salicylic Acid (SA) content of cucumber wild-type and transgenic lines was continuously determined and compared. Compared with WT, the cotyledon and hypocotyl of cucumber seedling have the same content trend, and the salicylic acid content of OE strain is increased, and the salicylic acid content of RNAi strain is reduced. Meanwhile, the salicylic acid content of hypocotyls of WT and RNAi strains were similar, whereas OE strain was slightly elevated.
To further clarify whether the expression of SA-related genes caused changes in SA levels, the expression levels of SA-related synthetic genes (CsSID2, CsSR1(CAMTA3), CsCBP60g, CsEDS1) were examined for cotyledons, hypocotyls, and roots of seedlings of WT, OE, and RNAi strains grown for 6 days under dark conditions. Compared with the expression level of WT cotyledons, CsSR1 of hypocotyl and root in RNAi strain was up-regulated, and the expression level of OE strain CsSR1 was down-regulated. CsSID2, CsCBP60g and CsEDS1 were inhibited in the water average in cotyledons, hypocotyls and roots of the RNAi lines, and the OE line promoted the expression of three genes, especially in cotyledons of the OE line (FIGS. 10A-F).
In order to determine whether exogenous salicylic acid can restore the phenomenon that the transgenic plant lacking CsGPA1 inhibits the growth of cucumber seedlings, before a germination experiment, seeds of RNAi transgenic lines are soaked for 4 hours by using exogenous SA (10 mu mol/L), and wild type and RNAi transgenic lines are soaked for 4 hours by using clear water as a control. The hypocotyl lengths of the seeds 3 days and 6 days after germination were measured in normal darkness at 30 ℃. The results show that: 3 days after germination, the phenomenon of cucumber seedling growth inhibition due to the deletion of CsGPA1 in transgenic plants can be recovered after seed soaking by using exogenous SA. The results show that: high levels of CsGPA1 expression are essential for young cotyledon development. CsGPA1 may positively regulate cell elongation by altering SA production, thereby defending against the effects of dark conditions on cell development. The results are shown in FIG. 11. A schematic diagram of the CsGPA1 in SA-regulated hypocotyl growth development process is shown in FIG. 12.
Example 5 Regulation of Low temperature stress by cucumber G protein alpha subunit Gene (CsGPA1)
Referring to the results of expression analysis, two interfering lines that most differed in the expression level of CsGPA1 gene from the wild type were selected as research materials (CsGPA1-RNAi-9 and CsGPA1-RNAi-10), respectively, and the biological function of CsGPA1 was studied by treating cucumber seedlings of the interfering lines until 3 mature leaves were grown (FIGS. 13A and B) under continuous (day and night) low temperature conditions (6 ℃ C.) (FIG. 13). The results of the study show that when the transgenic cucumber plants are subjected to continuous low temperature (6 ℃) for 60 hours, compared with wild-type plant leaves, the CsGPA1-RNAi interfered transgenic cucumber plants have more obvious droop and wilting phenotypes in the leaves (the first leaf, the second leaf and the third leaf) at the seedling stage, and the leaf morphology of the transgenic plants over-expressed by CsGPA1 is basically normal. Cucumber seedling leaves showed significant wilting and sagging (fig. 13C and D).
Whether CsGPA1 plays a regulating role in low-temperature response is researched, and the expression levels of CsGPA1, CsWCOR413PM, a low-temperature channel CBF gene and a downstream target gene thereof in leaves of wild-type and interference (RNAi) strains are determined (figure 14). The research shows that the expression levels of CsGPA1 and CsWCOR413PM genes in leaves of wild-type and interference (RNAi) strains generally show a trend of increasing before decreasing, and reach the highest level when the leaves are treated at low temperature for 24h (FIGS. 14A and B); the expression quantity of CsICE1, CsCBF1, CsCBF3 and CsRD-29 genes in the leaves of the wild type and the interference (RNAi) strains are consistent in change trend, the general trends are respectively ascending and descending, and the interference (RNAi) strains are lower than the wild type. Among them, the expression levels of the CsICE1 and CsCBF1 genes were highest at 6h, the CsCBF3 gene at 12h, and the CsRD-29 gene at 3h (FIGS. 14C-F). The CsHOS1 gene expression level increased during the cold treatment and reached a maximum at 60h, and the interference (RNAi) lines were higher than the wild type throughout the treatment (FIG. 14G).
During the cold treatment, the relative conductivity (FIG. 15A) and the malondialdehyde content (FIG. 15B) in the leaves of both wild-type and interfering (RNAi) lines showed a tendency to increase. Compared with the wild type, the relative conductivity and the malonaldehyde content in the leaves of the interference (RNAi) strain are both obviously increased, and the oxidative damage to cell membranes in the leaves of the seedlings of the interference (RNAi) strain caused by continuous low-temperature stress is probably larger; in contrast, the osmoregulators (proline and soluble protein) in the leaves of the interfering (RNAi) lines were significantly reduced (fig. 15C and D). Meanwhile, the activities of antioxidant enzymes (SOD, POD and CAT) in the leaves of the seedlings are measured, and the activities of the antioxidant enzymes are gradually increased on the whole, and the activities of the SOD, POD and CAT in the leaves of an interference (RNAi) strain are obviously lower than those of wild type (FIG. 15E, F and G). The result shows that compared with the wild type, the low temperature stress causes more damage to the seedling leaves of the interference (RNAi) strain, and the low temperature resistance of the interference (RNAi) strain is reduced.
Example 6 interaction of cucumber G protein alpha subunit Gene (CsGPA1) with CsWCOR413PM for the control of Low temperature stress
In order to further determine the molecular action mechanism of the cucumber CsGPA1 gene participating in low-temperature signal transduction, a cucumber split ubiquitin yeast library is constructed and the interaction protein of CsGPA1 is screened. The results of the formaldehyde denaturing gel electrophoresis of total RNA from cucumber leaf sections show that the RNA integrity is good, no DNA and protein pollution is caused, and the requirements for constructing the cNDA library are met (FIG. 16A). The dscDNA amplified by PCR after reverse transcription, digested and purified is in smear in 1.0% agarose gel, is distributed and concentrated between 250-2000 bp, and is suitable for constructing cDNA library (FIG. 16B, library insert identification). The cDNA and Sfi I cleavage products of pPR3-N vector were identified by PCR (FIG. 16D).
The constructed pBT3-N-GPA1 and pPR3-N are transformed into NMY51 yeast strains, the yeast strains grow on a non-selective medium SD-trp-leu, and no significant growth is generated on selective media SD-trp-leu-his and SD-trp-leu-his-ade, so that the bait protein has no self-activation, the background value is weak, and subsequent experiments can be carried out (the result is shown in figure 17).
The method is characterized in that the method comprises the following steps of preparing competence by using NMY51 yeast which expresses pBT3-N-GPA1 and is verified by self activation, transferring library plasmids into NMY51 yeast cells, uniformly coating a uniformly mixed transformation solution on SD/-leu/-trp/-his triple-deficient culture medium, sealing a culture dish by using a sealing film, inversely placing the culture dish in a constant-temperature culture box at 30 ℃ for culturing for 3-4 days, and transferring the colony clone of the cultured monoclonal yeast to a new SD/-leu/-trp/-his/-ade/X-gal quadruple deficient culture medium for culturing to observe the growth condition, and repeating the transfer culture for three times. Finally, 11 monoclonal yeast strains that could survive normally and develop color were obtained. Yeast plasmids were extracted, and the 11 pPR3-N plasmids obtained: pPR3-N-Y2, pPR3-N-Y4, pPR3-N-Y6, pPR3-N-Y8, pPR3-N-Y10, pPR3-N-Y12, pPR3-N-Y17, pPR3-N-Y19, pPR3-N-Y21, pPR3-N-Y22 and pPR3-N-Y2-2 were tested in a one-to-one rotation with plasmid pBT3-N-GPA1, respectively (coated screening plates SD/-Leu/-Trp/-His/-Ade/X-gal) to verify that the results are all positive (i.e. blue clones are grown on the screening plates). It is demonstrated that pPR3-N-Y2, pPR3-N-Y4, pPR3-N-Y6, pPR3-N-Y8, pPR3-N-Y10, pPR3-N-Y12, pPR3-N-Y17, pPR3-N-Y19, pPR3-N-Y21, pPR3-N-Y22 and pPR3-N-Y2-2 all interact with CsGPA1 (FIGS. 18A and B). The 11 plasmids were sequenced to obtain the insert sequences. Through the balst alignment, the cucumber plasma membrane low-temperature regulation protein CsWCOR413PM related to low temperature is screened out. Using the split ubiquitin yeast two-hybrid approach, it was further verified whether CsGPA1 interacted with CsWCOR413 PM. The yeast two-hybrid experiment color development result shows that CsGPA1 and CsWCOR413PM can directly interact (FIG. 18C).
The Pull down technique was used to further verify whether CsGPA1 interacted with CsWCOR413 PM. The PCR identified positive strains of the recombinant plasmid bacterial liquid are sent to a sequencing company for sequence determination, the sequencing result is compared with sequence information provided by a client, and the homology of the sequence comparison result is 100 percent as shown in the figure (figure 19). It can be seen in the experimental results of coomassie brilliant blue (fig. 20): GST line was electrophoresed using a GST tag protein alone, and GST-CsGPA1line was loaded and electrophoresed using purified fusion protein GST-CsGPA 1. In correspondence with the subsequent Immunblotting results, the His-CsWCOR413PM fusion protein was co-incubated, and a subsequent pull-down test (FIG. 21). The Input band was loaded with His-CsWCOR413PM purified protein as a positive control band in Immunoblotting (Immunoblotting-IB). In pulldown, GST and GST-CsGPA1 proteins were incubated with His-CsWCOR413PM proteins at the same time, and GST beads were bound to the protein complex after incubation, followed by washing. The sample was subjected to IB to see whether the protein complex contained His-CsWCOR413PM protein. No band of His-CsWCOR413PM recombinant protein was observed in the GST line, indicating that the GST protein did not bind to His-CsWCOR413PM recombinant protein. On the band of GST-CsGPAl, a distinct His-CsWCOR413PM band was observed, indicating that there was an interaction between GST-CsGPA1 recombinant protein and His-CsWCOR413PM recombinant protein. The experimental results are shown in fig. 20 and 22.
Although the invention has been described in detail hereinabove with respect to a general description and specific embodiments thereof, it will be apparent to those skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.
Sequence listing
<110> vegetable and flower institute of Chinese academy of agricultural sciences
Application of <120> G protein alpha subunit in regulation and control of cucumber seed germination, seedling growth and low temperature resistance of plants
<141>2018-12-13
<160>14
<170>SIPOSequenceListing 1.0
<210>1
<211>1188
<212>DNA
<213> cucumber (Cucumis sativus L.)
<400>1
actagtatgc tgtctcattt gagtagaaat atgggcttac tctgcagcag aaatcgtcat 60
tacaacgaac aagatgctga agagaagacg caggctgcag aaatagagag gcggattgaa 120
caagaaacag aggctgaaaa acatatacaa aaacttcttc tgcttggtgc tggagagtct 180
gggaaatcta caatttttaa gcagataaaa ttgttgttcc aaactgggtt tgatgaggca 240
gagcttaaga gctatattcc agtcattcat gcaaatgtgt atcagactat aaaagtatta 300
catgatggtt cgaaggagct tgctcaaaat gataaagagt tcacgaagta tgttttatcc 360
agtgaaaata aggatattgg tgagaaatta tcggatatcg gaggtagatt ggattacccg 420
cgtttgacta gggagcgtgc acaggatata gagactcttt ggaaagatgc tgcgattcag 480
gaaacgtatt ctcgtggaaa tgaactacag gttccagatt gcacacaata tttcatggaa 540
aatttgcaaa gattatctga tgcaaattat attccaacta aggaggatgt actttatgca 600
agagtccgca caactggtgt tgttgaaatc cagtttagcc ccgttggtga aaataaaaag 660
agtggcgaag tatatagact gtttgatgtt ggtggacaga gaaatgagag gagaaaatgg 720
attcatcttt ttgaaggtgt tacagcagta atcttttgtg ctgctattag tgagtatgat 780
caaacacttt ttgaggatga acagaagaac cgaatgatgg agacgaagga actttttgag 840
tgggttctga aacaagagtg ttttgagaaa acgtcattta tgctttttct caacaaattc 900
gatatcttcg agaaaaaggt tctaaaagtc cctctcagtg tgtgtgaatg gttcaatgat 960
tatcagccgg tttcgactgg aaaacaggag atcgagcatg cctatgagtt cgtgaagaaa 1020
aaattcgagg agttatattt taagagcacg gcaccggatc gagtagatcg ggtgtttaag 1080
gtatacagaa ctactgctct tgatcagaaa cttgtaaaga aaacgttcaa gctcgtagat 1140
gaaactttga ggcggcgaaa tctctttgag gctgggttat tgggtacc 1188
<210>2
<211>391
<212>PRT
<213> cucumber (Cucumis sativus L.)
<400>2
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His Tyr Asn Glu Gln Asp Ala Glu Glu Lys Thr Gln Ala Ala Glu Ile
20 25 30
Glu Arg Arg Ile Glu Gln Glu Thr Glu Ala Glu Lys His Ile Gln Lys
35 40 45
Leu Leu Leu Leu Gly Ala Gly Glu Ser Gly Lys Ser Thr Ile Phe Lys
50 55 60
Gln Ile Lys Leu Leu Phe Gln Thr Gly Phe Asp Glu Ala Glu Leu Lys
65 70 75 80
Ser Tyr Ile Pro Val Ile His Ala Asn Val Tyr Gln Thr Ile Lys Val
85 90 95
Leu His Asp Gly Ser Lys Glu Leu Ala Gln Asn Asp Lys Glu Phe Thr
100 105 110
Lys Tyr Val Leu Ser Ser Glu Asn Lys Asp Ile Gly Glu Lys Leu Ser
115 120 125
Asp Ile Gly Gly Arg Leu Asp Tyr Pro Arg Leu Thr Arg Glu Arg Ala
130 135 140
Gln Asp Ile Glu Thr Leu Trp Lys Asp Ala Ala Ile Gln Glu Thr Tyr
145 150 155 160
Ser Arg Gly Asn Glu Leu Gln Val Pro Asp Cys Thr Gln Tyr Phe Met
165 170 175
Glu Asn Leu Gln Arg Leu Ser Asp Ala Asn Tyr Ile Pro Thr Lys Glu
180 185 190
Asp Val Leu Tyr Ala Arg Val Arg Thr Thr Gly Val Val Glu Ile Gln
195 200 205
Phe Ser Pro Val Gly Glu Asn Lys Lys Ser Gly Glu Val Tyr Arg Leu
210 215 220
Phe Asp Val Gly Gly Gln Arg Asn Glu Arg Arg Lys Trp Ile His Leu
225 230 235 240
Phe Glu Gly Val Thr Ala Val Ile Phe Cys Ala Ala Ile Ser Glu Tyr
245 250 255
Asp Gln Thr Leu Phe Glu Asp Glu Gln Lys Asn Arg Met Met Glu Thr
260 265 270
Lys Glu Leu Phe Glu Trp Val Leu Lys Gln Glu Cys Phe Glu Lys Thr
275 280 285
Ser Phe Met Leu Phe Leu Asn Lys Phe Asp Ile Phe Glu Lys Lys Val
290 295 300
Leu Lys Val Pro Leu Ser Val Cys Glu Trp Phe Asn Asp Tyr Gln Pro
305 310 315 320
Val Ser Thr Gly Lys Gln Glu Ile Glu His Ala Tyr Glu Phe Val Lys
325 330 335
Lys Lys Phe Glu Glu Leu Tyr Phe Lys Ser Thr Ala Pro Asp Arg Val
340 345 350
Asp Arg Val Phe Lys Val Tyr Arg Thr Thr Ala Leu Asp Gln Lys Leu
355 360 365
Val Lys Lys Thr Phe Lys Leu Val Asp Glu Thr Leu Arg Arg Arg Asn
370 375 380
Leu Phe Glu Ala Gly Leu Leu
385390
<210>3
<211>618
<212>DNA
<213> cucumber (Cucumis sativus L.)
<400>3
actagtatgg tgaaacccaa ccacttgaaa atggtgacgg attctgacgc tgccgatctc 60
atttcctctg atctccggga actcggtaac gctgctagaa agcttgctac acacgctgtt 120
aagctcggtg cttcgggttt tactgcttct tttctccaat ggattgcttc ctttgctgct 180
atttacttgt tgattttgga tcggacgaac tggaagacga atatccttac ttcattgttg 240
attccgtaca ttttctttag tcttcccggt gtgatcttcg gttttttcag gggagagttt 300
ggaaaatggg ttgccgtcat tgctgttgtg ctccgtctct tcttcccgcg acgatttcca 360
gattggcttg aattgcctgg agctttgata cttctcattg tggtggctcc aagtttgttt 420
gccaagacca taagaaacga tcccatcgga gaagcaatct gtttgatcat atcatgctat 480
ttactgcaag aacacatcag agcctctggt ggattcagaa actcattcac aaaagcgaat 540
ggcatctcga acaccatcgg catcatcctt ctcttcgttt tccctgtctg ggcactggta 600
ctccgtgttc ttggtacc 618
<210>4
<211>202
<212>PRT
<213> cucumber (Cucumis sativus L.)
<400>4
Met Val Lys Pro Asn His Leu Lys Met Val Thr Asp Ser Asp Ala Ala
1 5 10 15
Asp Leu Ile Ser Ser Asp Leu Arg Glu Leu Gly Asn Ala Ala Arg Lys
20 25 30
Leu Ala Thr His Ala Val Lys Leu Gly Ala Ser Gly Phe Thr Ala Ser
35 40 45
Phe Leu Gln Trp Ile Ala Ser Phe Ala Ala Ile Tyr Leu Leu Ile Leu
50 55 60
Asp Arg Thr Asn Trp Lys Thr Asn Ile Leu Thr Ser Leu Leu Ile Pro
65 70 75 80
Tyr Ile Phe Phe Ser Leu Pro Gly Val Ile Phe Gly Phe Phe Arg Gly
85 90 95
Glu Phe Gly Lys Trp Val Ala Val Ile Ala Val Val Leu Arg Leu Phe
100 105 110
Phe Pro Arg Arg Phe Pro Asp Trp Leu Glu Leu Pro Gly Ala Leu Ile
115 120 125
Leu Leu Ile Val Val Ala Pro Ser Leu Phe Ala Lys Thr Ile Arg Asn
130 135 140
Asp Pro Ile Gly Glu Ala Ile Cys Leu Ile Ile Ser Cys Tyr Leu Leu
145 150 155 160
Gln Glu His Ile Arg Ala Ser Gly Gly Phe Arg Asn Ser Phe Thr Lys
165 170 175
Ala Asn Gly Ile Ser Asn Thr Ile Gly Ile Ile Leu Leu Phe Val Phe
180 185 190
Pro Val Trp Ala Leu Val Leu Arg Val Leu
195 200
<210>5
<211>30
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>5
gctctagaat gctgtctcat ttgagtagaa 30
<210>6
<211>28
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>6
tcccccgggt cacaataacc cagcctca 28
<210>7
<211>34
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>7
aggcgcgcca gtagatcggg tgtttaaggt atac 34
<210>8
<211>30
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>8
gatttaaatt cacaataacc cagcctcaaa 30
<210>9
<211>32
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>9
gactagtagt agatcgggtg tttaaggtat ac 32
<210>10
<211>29
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>10
cgggatcctc acaataaccc agcctcaaa 29
<210>11
<211>19
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>11
ctcagaagac caaagggca 19
<210>12
<211>21
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>12
cagatttcag aacagaagcg t 21
<210>13
<211>22
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>13
gaggacacgc tcgagtataa ga 22
<210>14
<211>22
<212>DNA
<213> Artificial Sequence (Artificial Sequence)
<400>14
gcacaacaga attgaaagca aa 22
Claims (4)
1. The application of cucumber G protein alpha subunit in improving the low temperature resistance of cucumber plants; wherein, the amino acid sequence of the G protein alpha subunit is shown as SEQ ID No. 2.
2. Use of a nucleic acid molecule encoding the alpha subunit of a G protein according to claim 1 for increasing the cold resistance of a cucumber plant.
3. Use according to claim 2, wherein the nucleotide sequence of the nucleic acid molecule encoding the α -subunit of the G protein is as shown in SEQ ID No. 1.
4. A method for producing a transgenic cucumber comprising the step of introducing into cucumber a nucleic acid molecule encoding the G protein a subunit of claim 1 or a nucleic acid molecule encoding the G protein a subunit of claim 3, resulting in a transgenic cucumber; compared with acceptor cucumber, the transgenic cucumber has improved plant low temperature resistance.
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
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CN202010947886.6A CN112029794B (en) | 2018-12-13 | 2018-12-13 | Application of G protein alpha subunit in improving cucumber endogenous hormone salicylic acid content |
CN202010949153.6A CN112028979B (en) | 2018-12-13 | 2018-12-13 | Method for improving low temperature resistance of cucumber plant |
CN201811525835.3A CN109354618B (en) | 2018-12-13 | 2018-12-13 | Application of G protein alpha subunit in regulation and control of cucumber seed germination, seedling growth and plant low temperature resistance |
Applications Claiming Priority (1)
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