JP2009213447A - PHOTOSENSITIVE GENE Ehd3 OF RICE PLANT AND USE THEREOF - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a new photosensitive gene of a plant which can modify the flowering time of the plant by modifying the photosensitivity of the plant using the gene. <P>SOLUTION: Research has eagerly been conducted to isolate a photosensitivity-associated gene by paying attention to the fact that the development of a convenient method for modifying the heading time of rice plant is especially desired among plants. The base sequence of heading time-associated gene locus Ehd3 which has been identified only in genetic level is isolated/identified by map-based cloning. Further, a method for easily modifying the heading time of rice plant has been developed. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a gene involved in plant photosensitivity and to modification of plant photosensitivity using the gene. The modification of plant photosensitivity is useful in fields such as plant breeding improvement.

  The heading time of rice is mainly determined by photosensitivity that depends on day length and other factors (basic nutrient growth or temperature sensitivity). Genetic analysis of this heading stage has been conducted for a long time, and so far Se1 locus (chromosome 6), E1 locus (chromosome 7), E2 locus (unknown), E3 locus (chromosome 3), or Ef1 locus (10th) Genes related to heading time such as chromosomes) have been found by mutations and mutations inherent in varieties.

  In rice, heading is generally promoted on a short day, while heading is delayed on a long day. Among Japanese cultivars, cultivars in Kyushu and southern Honshu generally have strong photosensitivity, while varieties in Tohoku and Hokkaido are not sensitive or very weak. When rice loses its photosensitivity, the heading time does not change due to changes in day length, and it shows the characteristic of heading after a certain growth period. As described above, the adaptability of rice in terms of the cultivation area and the cultivation time varies greatly depending on the presence or absence of photosensitivity. Therefore, modification of rice photosensitivity has become an important issue in improving rice varieties.

  Conventionally, the modification of heading time in rice varieties improvement has been carried out by (1) selection of early and late lines by crossing and (2) mutagenesis by radiation and chemicals. However, these operations require a long time, and there are many problems such as the inability to predict the degree and direction of mutation.

  By the way, in the field of rice genetics, genes that enhance rice photosensitivity are collectively called “photosensitive genes”. In recent years, DNA markers have been used for genetic analysis of rice, and genetic analysis of traits that follow complex inheritance such as heading time (quantitative trait locus (QTL) mapping) has progressed. Based on this background, genetic identification of genes involved in rice photosensitivity has been advanced (Non-Patent Documents 1 and 2). Among these, four types of QTLs, Hd1, Hd3a, Hd6 and Ehd1 have been isolated and identified at the molecular level (Non-patent Documents 3-6). However, the molecular level of other genes that play an important role in determining the early / late nature of rice varieties has not been elucidated.

  Once rice photosensitivity genes have been isolated, they can be introduced into any cultivar by transformation to modify the photosensitivity of those lines and thereby control the heading time of rice. it is conceivable that. For this reason, it can be said that the breed improvement using the gene is extremely advantageous in comparison with the conventional method in terms of simplicity and certainty.

Prior art document information related to the invention of the present application is shown below.
Yano et al. Plant Physiology 127: 1425-1429, 2001 Izawa et al. International Review of Cytology, 2007 Yano et al., Plant Cell 12: 2473-2484, 2000 Takahashi et al., PNAS 98: 7922-7927, 2001 Kojima et al., Plant Cell Physiol. 43: 1096-1105, 2002 Doi et al. Genes and Development 18: 926-936, 2004

  This invention is made | formed in view of such a condition, The objective is to provide the photosensitive gene of a novel plant. Another object of the present invention is to modify the photosensitivity of a plant using the gene, thereby altering the flowering time of the plant.

  The inventors of the present invention have paid particular attention to rice for which development of a simple method for modifying the heading time is desired among plants, and conducted earnest research to isolate genes involved in the photosensitivity.

  The Ehd3 gene is a causative gene for a very late mutation obtained by irradiation of Tohoku IL9, which introduced rice blast resistance in the rice cultivar Sasanishiki, and sits near the short arm end of chromosome 8 (Matsubara et al., Breeding Studies 8 (Another 1), 2006). In addition, cultivating "Tohoku IL9" and ehd3 mutant line "R0521" under different day length conditions, and examining the number of days to reach, Ehd3 gene has a function to promote heading, mutation It was estimated that the function was deficient in the strain.

  In order to isolate the photosensitive gene Ehd3 whose existence itself has been confirmed but has not yet been identified, the present inventors have first established a backcross progeny of “R0521” and the Indian variety “G4”. The candidate Ehd3 gene region was limited to 37 kb by linkage analysis using generations.

  Furthermore, as a result of analysis of this candidate gene region, a single Ehd3 candidate gene consisting of 2154 kb and 563 amino acids having a PHD finger domain belonging to a group different from the PHD finger domain of another PHD finger family protein whose function has been identified. Successfully released. As a result of a complementation test for this gene, it was confirmed that this gene is an Ehd3 gene having a function of significantly promoting heading under long day conditions.

  That is, the present inventors isolated and identified the base sequence of the heading stage-related locus Ehd3, which had been identified only at the genetic level, by a map-based cloning method. Furthermore, the technique which changes easily the heading time of a rice was developed, and it came to complete this invention by this.

More specifically, the present invention provides the following [1]-[15].
[1] The DNA according to any one of (a) to (d) below, which encodes a plant-derived protein having a function of controlling plant photosensitivity.
(A) DNA encoding a protein comprising the amino acid sequence set forth in SEQ ID NO: 3
(B) DNA containing the coding region of the base sequence described in SEQ ID NO: 1 or 2
(C) DNA encoding a protein having an amino acid sequence in which one or more amino acids are substituted, deleted, inserted and / or added in the amino acid sequence of SEQ ID NO: 3
(D) DNA that hybridizes under stringent conditions with DNA comprising the nucleotide sequence set forth in SEQ ID NO: 1 or 2
[2] The DNA according to [1], which is derived from rice.
[3] The DNA according to any one of (a) to (d) below.
(A) DNA encoding an antisense RNA complementary to the transcription product of DNA according to [1] or [2]
(B) DNA encoding an RNA having ribozyme activity that specifically cleaves the transcript of the DNA of [1] or [2]
(C) DNA encoding an RNA that suppresses the expression of the DNA according to [1] or [2] due to an RNAi effect during expression in a plant cell
(D) DNA encoding an RNA that suppresses the expression of the DNA according to [1] or [2] due to a co-suppression effect during expression in plant cells
[4] The DNA according to any one of [1] to [3], which is used for controlling plant photosensitivity.
[5] The DNA according to any one of (e) to (h) below, which is a mutant of the protein according to [1] and encodes a plant-derived protein that lacks the function of controlling plant photosensitivity.
(E) DNA encoding a protein comprising the amino acid sequence set forth in SEQ ID NO: 6
(F) DNA containing the coding region of the nucleotide sequence set forth in SEQ ID NO: 4 or 5
(G) DNA encoding a protein having an amino acid sequence in which one or more amino acids are substituted, deleted, inserted and / or added in the amino acid sequence of SEQ ID NO: 6
(H) DNA that hybridizes under stringent conditions with DNA comprising the nucleotide sequence set forth in SEQ ID NO: 4 or 5
[6] A vector comprising the DNA according to any one of [1] to [5].
[7] A transformed plant cell carrying the DNA according to any one of [1] to [5] or the vector according to [6].
[8] A transformed plant comprising the transformed plant cell according to [7].
[9] A transformed plant that is a descendant or clone of the transformed plant according to [8].
[10] A propagation material for the transformed plant according to [8] or [9].
[11] A method for producing a transformed plant according to [8] or [9], wherein the DNA according to any one of [1] to [5] or the vector according to [6] is applied to a plant cell. A method comprising introducing and regenerating a plant from the plant cell.
[12] A method for promoting heading of a plant, comprising expressing the DNA according to [1] or [2] in a cell of the plant body.
[13] A method for controlling photosensitivity, which comprises suppressing endogenous expression of the DNA according to [1] or [2] in a plant cell.
[14] The method according to [13], wherein the DNA according to [3] is introduced into a plant.
[15] The method according to any one of [12] to [14], wherein the plant is rice.

  According to the present invention, it was possible to establish a new modification method of heading stage by utilizing the isolated Ehd3 gene. That is, the isolated and identified heading-promoting gene Ehd3 is an essential factor for promoting heading under short-day conditions, natural day length conditions during the Japanese rice cultivation period in summer, and particularly under long-day conditions.

By using the heading-promoting gene Ehd3 isolated in the present invention, it is considered that the heading time of rice can be easily changed and it can contribute to the breeding of rice varieties adapted to different regions.
Specifically, the heading delay of rice can be achieved by controlling the expression of the Ehd3 gene by transformation of an RNAi construct or the like. The period required for transformation is extremely short compared to gene transfer by mating, and the heading time can be modified without changing other traits.

[Embodiment of the Invention]
The present invention provides a novel plant photosensitivity gene Ehd3 and a method for controlling plant photosensitivity using the gene. The base sequence of the genomic DNA of the Ehd3 gene of rice “Tohoku IL9”, whose relationship with photosensitivity has been clarified by the present inventors, is shown in SEQ ID NO: 1, and the base sequence of cDNA in SEQ ID NO: 2, The amino acid sequence of the protein encoded by the gene is shown in SEQ ID NO: 3. In addition, the base sequence of the genomic DNA of the Ehd3 gene of the rice ehd3 mutant “R0521” is SEQ ID NO: 4, the base sequence of the cDNA is SEQ ID NO: 5, and the amino acid sequence of the protein encoded by these genes is sequenced. Number: 6

  In the base sequence of genomic DNA described in SEQ ID NO: 1, positions 1374 to 1611 are 5 ′ untranslated regions, positions 1612 to 1713, positions 1858 to 2061, positions 2151 to 2471, positions 3382 to 3471, Positions 3657 to 3701 and 3791 to 4720 are the coding region, and positions 4721 to 4942 are the 3 ′ untranslated region. In addition, the Ehd3 gene of the rice ehd3 mutant line “R0521” has a structure in which a stop codon appears due to a frame shift due to deletion of 11 bp from position 3967 to position 3977 in SEQ ID NO: 1, and all subsequent amino acids are not translated. It has become.

  The rice quantitative trait locus (QTL) Ehd3 has been known as a locus involved in rice photosensitivity so far that it exists in one of the large regions near the short arm end of rice chromosome 8. It was done. The present inventors have narrowed down the region where the Ehd3 gene is present near the end of the short arm of chromosome 8 by using a map-based cloning technique, and finally succeeded in identifying it as a single gene.

The present invention relates to a plant-derived Ehd gene having a function of controlling plant photosensitivity.
Specifically, the Ehd gene of the present invention includes a DNA described in any one of (a) to (d) below, which encodes a plant-derived protein having a function of promoting plant photosensitivity.
(A) DNA encoding a protein comprising the amino acid sequence set forth in SEQ ID NO: 3.
(B) DNA containing the coding region of the base sequence described in SEQ ID NO: 1 or 2.
(C) DNA encoding a protein having an amino acid sequence in which one or more amino acids are substituted, deleted, inserted and / or added in the amino acid sequence set forth in SEQ ID NO: 3.
(D) A DNA that hybridizes under stringent conditions with a DNA comprising the nucleotide sequence set forth in SEQ ID NO: 1 or 2.

The protein encoded by the Ehd3 gene of the present invention has a unique structure having three PHD finger domains on the C-terminal side. Analysis of the PHD finger domains present in the Ehd3 gene of the present invention revealed that these PHD finger domains belong to a group different from the PHD finger domains of other PHD finger family proteins whose functions have been identified so far. (Fig. 5). It has been clarified that PHD finger proteins whose functions have been confirmed so far are involved in pollen formation. From this, it can be said that the Ehd3 protein of the present invention has a function different from these PHD finger proteins.
By using the Ehd3 gene of the present invention, for example, it is possible to prepare a recombinant protein or to produce a transformed plant with altered photosensitivity.

  In the present invention, the plant from which the gene of the present invention is derived is not particularly limited. Examples thereof include monocotyledonous plants such as pearl millet and dicotyledonous plants such as rapeseed, soybean, cotton, tomato and potato. Examples of flowering plants include chrysanthemum, roses, carnations, and cyclamen, but are not limited thereto. The plant from which the gene of the present invention is derived is preferably a monocotyledonous plant, more preferably rice.

  The "Ehd3 gene" of the present invention is not particularly limited as long as it can encode "Ehd3 protein". "Ehd3 gene" includes genomic DNA, chemically synthesized DNA, etc. in addition to cDNA. It is. Moreover, as long as the Ehd3 gene encodes the Ehd3 protein, DNA having an arbitrary base sequence based on the degeneracy of the genetic code is included.

  The coding region of the gene of the present invention is, for example, positions 1612 to 1713, positions 1858 to 2061, positions 2151 to 2471, positions 3382 to 3471, positions 3657 to 3701 in the nucleotide sequence set forth in SEQ ID NO: 1. And positions 3791 to 4720, positions 239 to 1930 in the base sequence described in SEQ ID NO: 2, positions 1612 to 1713, positions 1858 to 2061, positions 2151 to 2471 in the base sequence described in SEQ ID NO: 4. , Positions 3382 to 3471, 3657 to 3701 and 3791 to 3970, and the region of positions 239 to 1180 in the base sequence of SEQ ID NO: 5.

  Preparation of genomic DNA and cDNA can be performed by those skilled in the art using conventional means. For genomic DNA, for example, genomic DNA is extracted from a plant, a genomic library (vectors such as plasmids, phages, cosmids, BACs, PACs, etc. can be used), expanded, and Ehd3 gene (for example, The clone can be obtained and prepared by colony hybridization or plaque hybridization using a probe prepared based on the DNA described in SEQ ID NO: 1 or 2. It is also possible to prepare a primer specific to the Ehd3 gene and perform PCR using this primer. In addition, for example, cDNA is synthesized based on mRNA extracted from a plant, inserted into a vector such as λZAP to create a cDNA library, developed, and colony hybridization in the same manner as described above. Alternatively, it can be prepared by performing plaque hybridization or by performing PCR.

  Furthermore, since the Ehd3 gene is considered to exist widely in the plant kingdom, the Ehd3 gene includes homologous genes existing in various plants. Here, the “homologous gene” refers to a gene encoding a protein functionally equivalent to the Ehd3 gene product in rice in various plants. Examples of such proteins include, but are not limited to, Ehd3 protein mutants, alleles, variants, homologs, partial peptides of Ehd3 protein, or fusion proteins with other proteins.

  The Ehd3 protein variant in the present invention is a naturally occurring protein consisting of an amino acid sequence in which one or more amino acids are substituted, deleted, inserted, and / or added in the amino acid sequence shown in SEQ ID NO: 3. And a protein functionally equivalent to the protein consisting of the amino acid sequence set forth in SEQ ID NO: 3. A protein encoded by naturally-occurring DNA that hybridizes under stringent conditions with a DNA comprising the nucleotide sequence set forth in SEQ ID NO: 1 or 2, wherein the amino acid sequence set forth in SEQ ID NO: 1 or 2 A protein that is functionally equivalent to a protein consisting of can also be cited as a variant of the Ehd3 protein.

  In the present invention, the number of amino acids to be mutated is not particularly limited, but is usually within 30 amino acids, preferably within 15 amino acids, and more preferably within 5 amino acids (for example, within 3 amino acids). The amino acid residue to be mutated is preferably mutated to another amino acid in which the properties of the amino acid side chain are conserved. For example, amino acid side chain properties include hydrophobic amino acids (A, I, L, M, F, P, W, V), hydrophilic amino acids (R, D, N, C, E, Q, G, H, K, S, T, Y), an amino acid having an aliphatic side chain (A, V, L, I, P), an amino acid having a hydroxyl group-containing side chain (S, T), an amino acid having a sulfur atom-containing side chain ( C, M), amino acids with carboxylic acid and amide-containing side chains (D, N, E, Q), amino acids with base-containing side chains (R, K, H), amino acids with aromatic-containing side chains (F , Y, W) can be mentioned (the parentheses represent single letter symbols of amino acids). It is already known that a polypeptide having an amino acid sequence modified by deletion, addition and / or substitution by one or more amino acid residues to a certain amino acid sequence maintains its biological activity. Yes.

  In the present invention, “functionally equivalent” means that the target protein has a biological function or biochemical function equivalent to that of the Ehd3 protein. In the present invention, examples of the biological function and biochemical function of the Ehd3 protein include photosensitivity. Biological properties include the specificity of the site to be expressed and the expression level.

  Methods well known to those skilled in the art for isolating homologous genes include hybridization techniques (Southern, EM, Journal of Molecular Biology, Vol. 98, 503, 1975) and polymerase chain reaction (PCR) techniques (Saiki). , RK, et al. Science, vol. 230, 1350-1354, 1985, Saiki, RK et al. Science, vol. 239, 487-491, 1988). That is, for those skilled in the art, an oligonucleotide that specifically hybridizes to the Ehd3 gene using the nucleotide sequence of the Ehd3 gene (for example, the DNA described in either SEQ ID NO: 1 or 2) or a part thereof as a probe. As a primer, isolating a homologous gene of the Ehd3 gene from various plants is usually possible.

  In order to isolate DNA encoding such a homologous gene, a hybridization reaction is usually carried out under stringent conditions. Those skilled in the art can appropriately select stringent hybridization conditions. For example, pretreatment overnight at 42 ° C. in a hybridization solution containing 25% formamide, 50% formamide under more severe conditions, 4 × SSC, 4OmM Hepes pH7.0, 10 × Denhardt's solution, 20 μg / ml denatured salmon sperm DNA. After hybridization, a labeled probe is added and hybridization is performed by incubating overnight at 42 ° C. The cleaning solution and temperature conditions for the subsequent cleaning are about 1xSSC, 0.1% SDS, 37 ° C, more severe conditions are about 0.5xSSC, 0.1% SDS, 42 ° C, and more severe conditions are about 0.2xSSC. , 0.1% SDS, about 65 ° C. ”. Thus, isolation of DNA having high homology with the probe sequence can be expected as the conditions for washing hybridization are more severe. However, combinations of the above SSC, SDS, and temperature conditions are exemplary, and those skilled in the art will understand the above or other factors that determine the stringency of hybridization (eg, probe concentration, probe length, hybridization reaction). It is possible to achieve the same stringency as above by appropriately combining the time and the like.

  The homology of the isolated DNA is at least 50% or more, more preferably 70% or more, more preferably 90% or more (for example, 95%, 96%, 97%, 98%, 99%) in the entire amino acid sequence. And the like). Sequence homology can be determined using BLASTN (nucleic acid level) and BLASTX (amino acid level) programs (Altschul et al. J. Mol. Biol., 215: 403-410, 1990). The program is based on the algorithm BLAST by Karlin and Altschul (Proc. Natl. Acad. Sci. USA, 87: 2264-2268, 1990, Proc. Natl. Acad. Sci. USA, 90: 5873-5877, 1993). Yes. When analyzing a base sequence by BLASTN, parameters are set to score = 100 and wordlength = 12, for example. Further, when the amino acid sequence is analyzed by BLASTX, the parameters are, for example, score = 50 and wordlength = 3. When the amino acid sequence is analyzed using the Gapped BLAST program, it can be performed as described in Altschul et al. (Nucleic Acids Res. 25: 3389-3402, 1997). When using BLAST and Gapped BLAST programs, the default parameters of each program are used. Specific methods of these analysis methods are known.

The present invention also provides a DNA as described in any one of (a) to (d) below for use in controlling the photosensitivity of a plant.
(A) DNA encoding antisense RNA complementary to the transcription product of Ehd3 gene
(B) DNA encoding an RNA having ribozyme activity that specifically cleaves the transcript of the Ehd3 gene
(C) DNA encoding RNA that suppresses the expression of the Ehd3 gene due to the RNAi effect during expression in plant cells
(D) DNA encoding an RNA that suppresses the expression of the Ehd3 gene due to a co-suppression effect during expression in plant cells

In the present invention, the plant that suppresses the expression of the Ehd3 gene is not particularly limited, and a desired plant that is desired to control the photosensitivity of the plant can be used. However, crops are preferable from an industrial viewpoint. There are no particular restrictions on useful crops, but examples include monocotyledonous plants such as rice, corn, wheat, barley, oat, pearl barley, Italian ryegrass, perennial ryegrass, timothy, meadow fescue, millet, millet, sugarcane, pearl millet, and rapeseed. And dicotyledonous plants such as soybean, cotton, tomato and potato.
These DNAs used for controlling photosensitivity are useful for delaying heading by controlling photosensitivity, for example, in useful crops.

  As used herein, “suppression of Ehd3 gene expression” includes suppression of gene transcription and suppression of protein translation. Also included is a decrease in expression as well as complete cessation of DNA expression.

  One embodiment of the “DNA used to suppress the expression of the Ehd3 gene” is a DNA encoding an antisense RNA complementary to the Ehd3 gene. The antisense effect in plant cells was demonstrated for the first time when antisense RNA introduced by electroporation using a transient gene expression method exerts an antisense effect in plants (Ecker and Davis, Proc. Natl Acad. USA, 83: 5372, 1986). Subsequently, tobacco and petunia have also been reported to decrease the expression of target genes by the expression of antisense RNA (Krol et. Al., Nature 333: 866, 1988), and currently suppress gene expression in plants. Established as a means to

  There are several factors as described below for the action of an antisense nucleic acid to suppress the expression of a target gene. Inhibition of transcription by triplex formation, suppression of transcription by hybridization with a site where an open loop structure is locally created by RNA polymerase, transcription inhibition by hybridization with RNA that is undergoing synthesis, intron and exon Of splicing by hybrid formation at the junction with the protein, suppression of splicing by hybridization with the spliceosome formation site, suppression of transition from the nucleus to the cytoplasm by hybridization with mRNA, hybridization with capping sites and poly (A) addition sites Splicing suppression by formation, translation initiation suppression by hybridization with the translation initiation factor binding site, translation suppression by hybridization with the ribosome binding site near the initiation codon, peptization by hybridization with the mRNA translation region and polysome binding site For example, inhibition of gene chain elongation is prevented, and hybridization between nucleic acid and protein interaction sites is performed. They inhibit transcription, splicing, or translation processes and suppress target gene expression (Hirashima and Inoue, "Neurochemistry Experiment Course 2, Nucleic Acid IV Gene Replication and Expression", edited by the Japanese Biochemical Society, Tokyo Kagaku Dojin , pp.319-347, 1993).

  The antisense sequence used in the present invention may suppress the expression of the target gene by any of the actions described above. In one embodiment, if an antisense sequence complementary to the untranslated region near the 5 ′ end of the mRNA of the gene is designed, it will be effective for inhibiting translation of the gene. However, sequences complementary to the coding region or the 3 ′ untranslated region can also be used. As described above, a DNA containing an antisense sequence of a non-translated region as well as a translated region of a gene is also included in the antisense DNA used in the present invention. The antisense DNA to be used is linked downstream of a suitable promoter, and preferably a sequence containing a transcription termination signal is linked on the 3 ′ side.

  Antisense DNA can be prepared by, for example, the phosphorothioate method (Stein, Nucleic Acids Res., 16: 3209-3221, 1988) based on the sequence information of DNA described in SEQ ID NO: 1 or 2. Is possible. The prepared DNA can be transformed into a desired plant by a known method. The sequence of the antisense DNA is preferably a sequence complementary to the transcription product of the endogenous gene of the plant to be transformed, but may not be completely complementary as long as the gene expression can be effectively inhibited. . The transcribed RNA preferably has a complementarity of 90% or more (eg, 95%, 96%, 97%, 98%, 99% or more) to the transcript of the target gene. In order to effectively inhibit the expression of the target gene using the antisense sequence, the length of the antisense DNA is at least 15 bases or more, preferably 100 bases or more, more preferably 500 bases or more. is there. Usually, the length of the antisense DNA used is shorter than 5 kb, preferably shorter than 2.5 kb.

  Suppression of endogenous Ehd3 gene expression can also be performed using a DNA encoding a ribozyme. A ribozyme refers to an RNA molecule having catalytic activity. Some ribozymes have a variety of activities. Among them, research on ribozymes as enzymes that cleave RNA has made it possible to design ribozymes for site-specific cleavage of RNA. Some ribozymes have a group I intron type or a size of 400 nucleotides or more like M1RNA contained in RNaseP, but some have an active domain of about 40 nucleotides called hammerhead type or hairpin type ( Makoto Koizumi and Eiko Otsuka, Protein Nucleic Acid Enzymes, 35: 2191, 1990).

  For example, the self-cleaving domain of hammerhead ribozyme cleaves on the 3 ′ side of C15 of G13U14C15, but it is important for U14 to form a base pair with A at position 9, and the base at position 15 is In addition to C, it has been shown to be cleaved by A or U (Koizumi et. Al., FEBS Lett. 228: 225, 1988). If the ribozyme substrate binding site is designed to be complementary to the RNA sequence near the target site, it is possible to create a restriction enzyme-like RNA-cleaving ribozyme that recognizes the UC, UU, or UA sequence in the target RNA. (Koizumi et.al., FEBS Lett. 239: 285, 1988, Makoto Koizumi and Eiko Otsuka, Protein Nucleic Acid Enzyme, 35: 2191, 1990, Koizumi et. Al., Nucleic. Acids. Res. 17: 7059, 1989).

  Hairpin ribozymes are also useful for the purposes of the present invention. Hairpin ribozymes are found, for example, in the minus strand of satellite RNA of tobacco ring spot virus (Buzayan, Nature 323: 349, 1986). It has been shown that this ribozyme can also be designed to cause target-specific RNA cleavage (Kikuchi and Sasaki, Nucleic Acids Res. 19: 6751, 1992, and Hiroshi Kikuchi, Chemistry and Biology 30: 112, 1992).

  A ribozyme designed to cleave the target is linked to a promoter such as the cauliflower mosaic virus 35S promoter and a transcription termination sequence so that it is transcribed in plant cells. However, at that time, if an extra sequence is added to the 5 ′ end or 3 ′ end of the transcribed RNA, the ribozyme activity may be lost. In such a case, in order to accurately cut out only the ribozyme part from the RNA containing the transcribed ribozyme, another trimming ribozyme that acts in cis for trimming is placed on the 5 'side or 3' side of the ribozyme part. (Taira et.al., Protein Eng. 3: 733, 1990, Dzianott and Bujarski, Proc. Natl. Acad. Sci. USA, 86: 4823, 1989, Grosshans and Cech, Nucleic Acids Res. 19 : 3875, 1991, Taira et. Al., Nucleic Acids Res. 19: 5125, 1991).

  In addition, such structural units can be arranged in tandem so that multiple sites in the target gene can be cleaved, thereby further enhancing the effect (Yuyama et al., Biochem. Biophys. Res. Commun. 186: 1271 , 1992). Such a ribozyme can be used to specifically cleave the transcription product of the target gene in the present invention, thereby suppressing the expression of the gene.

  Suppression of endogenous gene expression can also be achieved by “co-suppression” resulting from transformation of DNA having a sequence identical or similar to the target gene sequence. “Co-suppression” refers to a phenomenon in which the expression of both a foreign gene and a target endogenous gene to be introduced is suppressed when a gene having the same or similar sequence as that of the target endogenous gene is introduced into a plant by transformation. Say. Details of the mechanism of co-suppression are not clear, but are often observed in plants (Curr. Biol. 7: R793, 1997, Curr. Biol. 6: 810, 1996).

  For example, in order to obtain a plant body in which the Ehd3 gene is co-suppressed, a vector DNA prepared so that the Ehd3 gene or a DNA having a similar sequence can be expressed is transformed into the target plant, and the resulting plant is obtained. A plant having an Ehd3 mutant trait may be selected from the body. The gene used for co-suppression need not be completely the same as the target gene, but is at least 70% or more, preferably 80% or more, more preferably 90% or more (for example, 95%, 96%, 97%, 98 %, 99% or more).

  Furthermore, suppression of the expression of the endogenous gene in the present invention can also be achieved by transforming a gene having a dominant negative trait of the target gene into a plant. A gene having a dominant negative trait refers to a gene having a function of eliminating or reducing the activity of an endogenous wild-type gene inherent in a plant by expressing the gene.

  Another embodiment of the “DNA used for suppressing the expression of the Ehd3 gene” is a DNA encoding a dsRNA complementary to a transcription product of an endogenous Ehd3 gene. RNAi is a phenomenon in which, when a double-stranded RNA (hereinafter dsRNA) having the same or similar sequence as a target gene sequence is introduced into a cell, the expression of the introduced foreign gene and target endogenous gene are both suppressed. When dsRNA of about 40 to several hundred base pairs is introduced into a cell, RNaseIII-like nuclease called Dicer having a helicase domain is present in the presence of ATP, and dsRNA is about 21 to 23 base pairs from the 3 ′ end. Cut out and produce siRNA (short interference RNA). A protein specific to this siRNA binds to form a nuclease complex (RISC: RNA-induced silencing complex). This complex recognizes and binds to the same sequence as siRNA, and cleaves the mRNA of the target gene at the center of siRNA by RNaseIII-like enzyme activity. In addition to this pathway, the antisense strand of siRNA binds to mRNA and acts as a primer for RNA-dependent RNA polymerase (RsRP) to synthesize dsRNA. It is also considered that this dsRNA becomes Dicer's substrate again to generate new siRNA and amplify the action.

  The RNA of the present invention can be expressed from an antisense coding DNA that encodes an antisense RNA to any region of the target gene mRNA and a sense code DNA that encodes a sense RNA of any region of the target gene mRNA. . Moreover, dsRNA can also be produced from these antisense RNA and sense RNA.

  When the dsRNA expression system of the present invention is retained in a vector or the like, the antisense RNA and sense RNA are expressed from the same vector, and the antisense RNA and sense RNA are expressed from different vectors, respectively. There is. For example, antisense RNA and sense RNA can be expressed from the same vector as antisense RNA in which an antisense coding DNA and a promoter capable of expressing a short RNA such as polIII are linked upstream of the sense coding DNA. An expression cassette and a sense RNA expression cassette can be constructed, respectively, and these cassettes can be inserted into the vector in the same direction or in the opposite direction. It is also possible to construct an expression system in which the antisense code DNA and the sense code DNA are arranged in opposite directions so as to face each other on different strands. In this configuration, one double-stranded DNA (siRNA-encoding DNA) in which an antisense RNA coding strand and a sense RNA coding strand are paired is provided, and antisense RNA and sense RNA from each strand are provided on both sides thereof. A promoter is provided oppositely so that it can be expressed. In this case, in order to avoid adding an extra sequence downstream of the sense RNA and antisense RNA, a terminator is provided at the 3 ′ end of each strand (antisense RNA coding strand, sense RNA coding strand). It is preferable to provide. As this terminator, a sequence in which four or more A (adenine) bases are continued can be used. Moreover, in this palindromic style expression system, it is preferable that the types of the two promoters are different.

  In addition, as a configuration for expressing antisense RNA and sense RNA from different vectors, for example, antisense coding DNA and an antisense in which a promoter capable of expressing a short RNA such as polIII is linked upstream of sense coding DNA. An RNA expression cassette and a sense RNA expression cassette can be constructed, and these cassettes can be held in different vectors.

  In the RNAi of the present invention, siRNA may be used as dsRNA. “SiRNA” means a double-stranded RNA consisting of short strands that are not toxic in cells, for example, 15 to 49 base pairs, preferably 15 to 35 base pairs, and more preferably 21 Can be ~ 30 base pairs. Alternatively, the siRNA to be expressed is transcribed and the length of the final double-stranded RNA portion is, for example, 15 to 49 base pairs, preferably 15 to 35 base pairs, more preferably 21 to 30 base pairs. be able to. The DNA used for RNAi need not be completely identical to the target gene, but has at least 70% or more, preferably 80% or more, more preferably 90% or more, most preferably 95% or more sequence homology. .

The part of the double-stranded RNA in which the RNAs in dsRNA are paired is not limited to a perfect pair, but mismatch (corresponding base is not complementary), bulge (no base corresponding to one strand) ) Or the like may include an unpaired portion. In the present invention, both bulges and mismatches may be included in the double-stranded RNA region where RNAs in dsRNA pair with each other.
The present invention includes Ehd3 mutants that lack the function of controlling plant photosensitivity.

  The Ehd3 mutant is produced by introducing a mutation by substituting an amino acid residue in the amino acid sequence of the Ehd3 protein. Specifically, the secondary structure of the amino acid sequence of the Ehd3 protein is predicted using a known molecular modeling program such as WHAT IF (Vriend et al., J. Mol. Graphics (1990) 8, 52-56). Further, it is performed by evaluating the influence on the whole of the amino acid residue to be substituted. After determining the appropriate replacement amino acid residue, each vector is inserted into the Ehd3 mutant by using a vector containing the nucleotide sequence encoding the Ehd3 protein as a template, so that the amino acid is replaced by the usual PCR method. The encoding gene is obtained.

More specifically, the Ehd3 mutant of the present invention is an Ehd3 mutant that lacks a function of controlling plant photosensitivity, and encodes a plant-derived protein, as described in (e) to (h) below. Mention may be made of the DNA described.
(E) DNA encoding a protein comprising the amino acid sequence set forth in SEQ ID NO: 6
(F) DNA containing the coding region of the nucleotide sequence set forth in SEQ ID NO: 4 or 5
(G) DNA encoding a protein having an amino acid sequence in which one or more amino acids are substituted, deleted, inserted and / or added in the amino acid sequence of SEQ ID NO: 6
(H) DNA that hybridizes under stringent conditions with DNA comprising the nucleotide sequence set forth in SEQ ID NO: 4 or 5

In the Ehd3 mutant, a stop codon appeared due to a frameshift due to an 11 bp deletion in the PHD finger domain closest to the N-terminus, and all regions containing the PHD finger domain were lost, thereby controlling photosensitivity (Figs. 3 and 4).
For example, by changing the Ehd3 gene of a useful crop to an Ehd3 mutant, heading delay can be achieved.

  The present invention also provides a vector containing the Ehd3 gene or a DNA that suppresses the expression of the Ehd3 gene, and a transformed plant cell.

  The vector of the present invention includes a vector constructed for inducing the above-mentioned RNAi. Since the vector of the present invention contains the DNA of the present invention, when introduced into a cell, single-stranded RNA formed by transcription in the cell paired within the molecule to form dsRNA. A vector constructed for inducing such RNAi can consequently induce transcriptional activation of the endogenous gene.

  As the vector of the present invention, in addition to the above-mentioned vector used for the transcriptional activation of the endogenous gene, a vector for expressing the DNA of the present invention in a cell for preparing a transformant, for example, for preparing a transformed plant body Also included are vectors for expressing the DNA of the present invention in plant cells. The vector used for the transformation of plant cells is not particularly limited as long as the inserted gene can be expressed in the cells. For example, a plasmid, a phage, or a cosmid can be exemplified.

  The “plant cell” includes various forms of plant cells such as suspension culture cells, protoplasts, leaf sections, callus and the like.

  The vector of the present invention may contain a promoter for constitutively or inducibly expressing the DNA of the present invention.

  Those skilled in the art can appropriately prepare a vector having a desired DNA by a general genetic engineering technique. Usually, various commercially available vectors can be used.

  The vector of the present invention is also useful for retaining or expressing the DNA of the present invention in a host cell.

  The DNA in the present invention is usually carried (inserted) into an appropriate vector and introduced into a host cell. That is, the present invention provides a host cell carrying the DNA or vector of the present invention. The vector is not particularly limited as long as it can stably hold the inserted DNA. For example, if Escherichia coli is used as a host, a pBluescript vector (Stratagene) is preferred as a cloning vector, but commercially available. Various vectors can be used. An expression vector is particularly useful when a vector is used for the purpose of introducing and expressing the DNA of the present invention into a cell having an endogenous gene. The expression vector is not particularly limited as long as it is a vector that expresses DNA in vitro, in E. coli, in cultured cells, or in an individual organism. For example, pBEST vector (manufactured by Promega) or E. coli is used in in vitro expression. PET vector (manufactured by Invitrogen) if present, pME18S-FL3 vector (GenBank Accession No. AB009864) for cultured cells, pME18S vector (Mol Cell Biol. 8: 466-472 (1988)) for individual organisms, plants If it is an individual, a pBINPLUS vector (van Engelen, FA et al., (1995). PBINPLUS: an improved plant transformation vector based on pBIN19. Transgenic Res. 4, 288-290.) May be exemplified. The DNA of the present invention can be inserted into a vector by a conventional method (Molecular Cloning, 5.61-5.63), for example, by a ligase reaction using a restriction enzyme site.

  There is no restriction | limiting in particular as said host cell, According to the objective, various host cells are used. Examples of cells for expressing the DNA of the present invention include bacterial cells (eg, Streptococcus, Staphylococcus, E. coli, Streptomyces, Bacillus subtilis), insect cells (eg, Drosophila S2, Spodoptera SF9), animal cells ( Examples: CHO, COS, HeLa, C127, 3T3, BHK, HEK293, Bowes melanoma cells) and plant cells.

In addition, as a method for expressing the DNA of the present invention in vivo, the DNA of the present invention is incorporated into an appropriate vector, for example, polyethylene glycol method, electroporation method, Agrobacterium method, liposome method, cationic liposome method. , Calcium phosphate precipitation method, electric pulse perforation method (electroporation) (Current protocols in Molecular Biology edit. Ausubel et al. (1987) Publish. John Wiley & Sons. Section 9.1-9.9), lipofection method (GIBCO-BRL) ), A method of introducing into a living body by a method known to those skilled in the art, such as a microinjection method and a particle gun method.
Administration into a plant may be an ex vivo method or an in vivo method.

  In addition, when the DNA of the present invention is introduced into a plant body, the DNA can be directly introduced into a plant cell using a microinjection method, an electroporation method, a polyethylene glycol method, etc. It can also be introduced into a plant cell indirectly via a virus or bacterium capable of infecting a plant as a vector. Examples of such viruses include cauliflower mosaic virus, tobacco mosaic virus, gemini virus and the like as typical viruses, and Agrobacterium and the like as bacteria. When introducing a gene into a plant by the Agrobacterium method, a commercially available plasmid can be used. As a method for introducing the DNA of the present invention into a plant body using such a vector, the leaf disk method (Jorgensen, RA et al., (1996), preferably introducing a gene via Agrobacterium. ). Chalcone synthase cosuppression phenotypes in petunia flowers: comparison of sense vs. antisense constructs and single-copy vs. complex T-DNA sequences. Plant Mol. Biol. 31, 957-973.).

  These transformation methods described above are preferably selected as appropriate depending on the type of plant or the like that serves as the host (for example, monocotyledonous plants or dicotyledonous plants).

  In the present invention, the “plant” is not particularly limited, but monocotyledonous plants such as rice, corn, wheat, barley, oat, pearl barley, Italian ryegrass, perennial ryegrass, timothy, meadow fescue, millet, millet, sugarcane, pearl millet, etc. And dicotyledonous plants such as rapeseed, soybean, cotton, tomato and potato. Examples of flower plants include chrysanthemum, roses, carnations, and cyclamen.

  The present invention also provides a plant cell carrying the DNA of the present invention or the vector of the present invention. Furthermore, this invention provides the transformed plant body containing the plant cell of this invention. The cells into which the DNA of the present invention or the vector of the present invention is introduced include plant cells for producing transformed plants. There is no restriction | limiting in particular as a plant cell.

  The plant cells of the present invention include cultured cells as well as cells in the plant body. Also included are protoplasts, shoot primordia, multi-buds, and hairy roots.

  Regeneration of plant bodies from transformed plant cells can be performed by methods known to those skilled in the art depending on the type of plant cells. For example, with regard to the technique for producing a transformed plant body, a method for regenerating a plant body by introducing a gene into protoplasts using polyethylene glycol, a method for regenerating a plant body by introducing a gene into protoplasts using an electric pulse, or a gene for cells by a particle gun method. Can be mentioned, and a method for regenerating a plant body and a method for regenerating a plant body by introducing a gene via Agrobacterium are not particularly limited. Some techniques have already been established and are widely used in the technical field of the present invention. In the present invention, these methods can be suitably used.

  In order to efficiently select plant cells transformed by introduction of a vector containing the DNA of the present invention, the above recombinant vector contains an appropriate selection marker gene or is introduced into a plant cell together with a plasmid vector containing a selection marker gene. It is preferable to do. Selectable marker genes used for this purpose include, for example, the neomycin phosphotransferase gene that is resistant to the antibiotics kanamycin or gentamicin, the hygromycin phosphotransferase gene that is resistant to hygromycin, and the acetyl that is resistant to the herbicide phosphinothricin. Examples include transferase genes.

Plant cells into which the recombinant vector has been introduced are placed on a known selection medium containing a suitable selection agent according to the type of the introduced selection marker gene and cultured. As a result, transformed plant cultured cells can be obtained.
Transformed plant cells can regenerate plant bodies by redifferentiation. The method of redifferentiation varies depending on the type of plant cell. For example, the method of Fujimura et al. (Plant Tissue Culture Lett. 2:74 (1995)) can be used for rice, and Shillito et al. (Bio / Technology 7) for maize. : 581 (1989)) and Gorden-Kamm et al. (Plant Cell 2: 603 (1990)), and for potatoes, Visser et al. (Theor. Appl. Genet 78: 594 (1989)). In the case of tobacco, the method of Nagata and Takebe (Planta 99:12 (1971)) can be cited, and in the case of Arabidopsis, the method of Akama et al. (Plant Cell Reports 12: 7-11 (1992)) can be cited as eucalyptus. Then, the method of Toi et al. (Japanese Patent Laid-Open No. 8-89113) can be mentioned.

In addition, the presence of introduced foreign DNA in a transformed plant that has been regenerated and cultivated in this way can be analyzed by a known PCR method or Southern hybridization method, or by analyzing the base sequence of the DNA in the plant body. Can be confirmed.
In this case, extraction of DNA from the transformed plant body can be performed according to a known method of J. Sambrook et al. (Molecular Cloning, 2nd edition, Cold Spring Harbor Laboratory Press, 1989).

  When the foreign gene comprising the DNA of the present invention present in the regenerated plant body is analyzed using the PCR method, the amplification reaction is performed using the DNA extracted from the regenerated plant body as a template as described above. In addition, an amplification reaction is carried out in a reaction mixture in which the DNA of the present invention or a synthesized oligonucleotide having a base sequence appropriately selected according to the base sequence of the DNA modified according to the present invention is used as a primer. You can also In the amplification reaction, DNA denaturation, annealing, and extension reactions are repeated several tens of times to obtain an amplification product of a DNA fragment containing the DNA sequence of the present invention. When the reaction solution containing the amplification product is subjected to, for example, agarose electrophoresis, it is possible to confirm that the amplified DNA fragments are fractionated and the DNA fragments correspond to the DNA of the present invention.

  Once a transformed plant into which the DNA of the present invention is introduced into the genome is obtained, offspring can be obtained from the plant by sexual reproduction or asexual reproduction. It is also possible to obtain a propagation material (for example, seeds, fruits, cuttings, tubers, tuberous roots, strains, callus, protoplasts, etc.) from the plant body, its descendants or clones, and mass-produce the plant body based on them. Is possible. The present invention includes plant cells into which the DNA or vector of the present invention has been introduced, plant bodies containing the cells, progeny and clones of the plant bodies, and propagation materials for the plant bodies, their progeny, and clones. These plant cells, plants containing the cells, progeny and clones of the plants, and propagation materials of the plants, their progeny and clones can be used in methods for controlling the photosensitivity of plants. .

  In the present invention, the photosensitivity of a plant can be enhanced by promoting the expression of the plant Ehd3 gene. Plants produced by the method of the present invention can promote heading in useful crops, for example.

  Furthermore, DNA encoding antisense RNA, DNA encoding dsRNA, and DNA encoding RNA having ribozyme activity used to suppress the expression of plant endogenous Ehd3 gene based on sequence information of Ehd3 gene Furthermore, it is possible to prepare DNA encoding RNA having a co-suppression effect. The produced DNA can be used to delay plant heading.

  EXAMPLES Hereinafter, the present invention will be described more specifically with reference to examples, but the present invention is not limited to these examples.

[Example 1] About the Ehd3 gene Ehd3, a causative gene of the extremely late mutation obtained by irradiating "Tohoku IL9" with rice blast resistance introduced into the rice cultivar Sasanishiki, Located on chromosome 8 (FIG. 2A), it was revealed that the wild type gene promotes heading. Linkage analysis using a small segregated population revealed that the Ehd3 gene is located between SRM (Simple Sequence Repeats) markers RM6369 and RM1019 and RM6356 and co-segregated with RM1381 (Matsubara et al., Breeding) Academic Research 8 (Another 1), 2006). However, with this linkage analysis accuracy, it has been difficult to isolate and identify genes by map-based cloning. “Tohoku IL9” and ehd3 mutant line “R0521” were cultivated under different day length conditions and their earliest days were examined. In “R0521”, “Tohoku IL9” was observed under short day conditions and natural day length conditions. The heading was delayed for about 22 days from the “No.” and the heading was continued for 365 days under long day conditions, but the heading did not occur (Fig. 1) (Matsubara et al., Breeding Research 8 (Another 1), 2006). Therefore, it was estimated that the wild-type gene Ehd3 has a function of promoting heading, and the mutant line lacks that function.

[Example 2] High-precision linkage analysis Detailed linkage analysis of the Ehd3 region was performed using a large-scale segregation population essential for map-based cloning. As the group for linkage analysis, the first generation of the backcross progeny of “R0521” and Indian type “G4 (Guang Lu Ai 4)” was used. From the backcross progeny, individuals were selected in which the Ehd3 region became heterozygous and most of the other genomic regions (about 75%) were replaced with “R0521”. SSR marker RM6369 (primer 5'-AGCTAGCTTCACCTACCTACCTCACC-3 '(SEQ ID NO: 7) and 5'-ATGGTCATGTCGTTGGTTTGC-3' (SEQ ID NO: 8) that sandwich Ehd3 from 3214 progeny progeny of the selected individuals (corresponding to F2 population) ) And RM6356 (Primers 5'-GAGACTTGGCGACTCTGATCTGC-3 '(SEQ ID NO: 9) and 5'-TGATCTCCTCCTCCTTCGTCTACC-3' (SEQ ID NO: 10)) are used to select individuals with recombinant chromosomes generated near Ehd3 did. The phenotype of the Ehd3 locus was determined by the F3 generation progeny test. That is, 40 self-propagating progenies of the selected individuals (F2) were cultivated in an experimental field in Tsukuba City, and the phenotype of the Ehd3 locus was determined from the segregation status of arrival days within each line. As a result of linkage analysis, Ehd3 was positioned between InDel (Insertion / Deletion) markers AP3909-1 and AP3909-7, and there were 7 and 1 recombination individuals between each marker and Ehd3 locus (FIG. 2B). . AP3909-2, AP3909-5 and AP3909-6 were co-separated and finally the Ehd3 gene candidate region was limited to about 37 kb (FIG. 2B).

[Example 3] Identification of candidate genes
Confirmation of the predicted gene and similarity analysis of the known Nipponbare genome sequence for the Ehd3 gene candidate region of about 37 kb and its upstream and downstream revealed that there were four genes in the region. (Figure 2C). For "Tohoku IL9" and "R0521", the entire genome base sequence of the 37 kb Ehd3 gene candidate region was decoded and compared. The only difference between the two was in the coding region of the predicted gene PHD (Plant Homeo Domain) finger family protein gene. Therefore, when the total length of the cDNA of “Tohoku IL9” was determined for the predicted PHD finger family protein gene and compared with the genomic base sequence, this gene consists of 6 exons, and the total length of the transcription region is 2154 bp, It encoded a protein of 563 amino acids (FIG. 3). In addition, it has a unique structure with three PHD finger domains on the C-terminal side, and by phylogenetic analysis, the three PHD finger domains of Ehd3 are combined with the PHD finger domains of other PHD finger family protein genes whose functions have been identified. Was found to belong to another group (Figure 5). In the Ehd3 mutant “R0521”, it was found that a stop codon appeared due to a frameshift due to the 11 bp deletion in the PHD finger domain closest to the N-terminus, and the entire region containing the PHD finger domain was lost ( 2C, 3 and 4). From these results, this gene was used as a candidate for Ehd3 and the subsequent analysis was performed.

[Example 4] Proof of function of Ehd3 candidate gene For transformation, the entire length of the PHD finger protein gene and an approximately 5.7 kb Japanese cultivar "Nipponbare" including the 5 'upstream region 1.2 kb and the 3' downstream region 0.3 kb were derived. Genomic fragments were used. The reason for using “Nipponbare” is that it already had a genomic library and that the corresponding 5.7 kb nucleotide sequence was exactly the same as “Tohoku IL9”. Primer pair Ehd3- for amplifying the nucleotide sequence in the Ehd3 gene candidate region against a PAC library (Baba et al., Bulletin of the NIAR 14: 41-49, 2000) created from genomic DNA of Nipponbare 2U / 1L (5'-CCAGCGACATCATGCCAAAA-3 '(SEQ ID NO: 11) and 5'-CAGTCGCAGATCCAGCCTCC-3' (SEQ ID NO: 12)) and Ehd3-50U / 59L (5'-GTCAACACTCACCACAAATATCA-3 '(SEQ ID NO: 13) and 5′-AATGGTTTGGTTGATCCTGAAGC-3 ′ (SEQ ID NO: 14)) were screened to select PAC clones covering Ehd3 candidate genes. A KpnI-DraI 5.7 kb fragment (Fig. 3) containing the candidate gene region was excised from the selected clone and incorporated into Ti-plasmid vector pPZP2H-lac (Fuse et al. Plant Biotechnology 18: 219-222, 2001). It was introduced into the ehd3 mutant line “R0521” via um. Redifferentiated plants were quickly transferred to a growth chamber under long-day conditions (14.5 hours light) and grown, and the number of days required for heading was investigated. In the transformation generation (T0), individuals (10 individuals) into which only the vector was introduced did not head for more than 200 days, whereas individuals (1 to 8 copies introduced, 24 individuals) into which the 5.7 kb fragment was introduced Heading occurred by 83 days after transplantation (FIG. 6). This proved that the 5.7 kb fragment containing the PHD finger gene has an Ehd3 gene action that significantly delays heading under long-day conditions.
From the above results, it was determined that the candidate gene identified by the map-based cloning method was the rice heading promoting gene Ehd3.

It is a figure and a photograph which show the influence which late mutant ehd3 has on heading. Left: Current varieties Tohoku IL9 and its ehd3 mutant R0521, natural day length (field), short day condition (10 hours light / 14 hours dark, day temperature 28 ° C / night temperature 24 ° C) and long day conditions (14.5 (Daylight / 9.5 hours dark, day temperature 28 ° C / night temperature 24 ° C). Right: Tohoku IL9 and R0521 phenotypes under natural day length conditions. It is a figure which shows the positional cloning of Ehd3 gene. A: The Ehd3 gene is present near the end of the long arm of chromosome 8 of rice. B: The gene candidate region was limited to about 37 kb by high-precision linkage analysis. C: Comparing the entire nucleotide sequence in the gene candidate region between the current cultivar and the mutant, one of the predicted genes, the PHD-finger family protein coding region has an 11 bp deletion in the mutant, and the other regions There was no sequence difference. It is a figure which shows the structure of an Ehd3 candidate gene. This gene belonging to the PHD (Plant Homeo Domain) -finger protein family consists of 6 exons, the transcription region has a total length of 2154 bp, and encodes a protein of 563aa with 3 PHD-finger domain structures at the C-terminal side. It was. The 11 bp deletion in the mutant is present in the front part of the first PHD-finger domain, and the structure of the latter half of the gene containing the PHD-finger domain is completely lost due to the appearance of a stop codon immediately after the frameshift. Estimated. It is a comparison figure of Ehd3 amino acid sequence. Ehd3 is the sequence of the current variety Tohoku IL9, and ehd3 is the sequence of mutant R0521. Δ represents the position of the 11 bp deletion of R0521, and * represents the stop codon. It is a figure which shows the phylogenetic tree of the PHD-finger domain of rice and Arabidopsis. A phylogenetic analysis of the PHD-finger domain was performed for the PHD-finger protein and Ehd3-like genes that have been reported so far. Since Ehd3 has three PHD-finger domains, it is shown as branch numbers 1, 2, and 3 from the N-terminal side. It is a figure which shows a complementarity test and the earliest days of a transgenic present generation individual (T0). Only the 5.7 kb Nipponbare genome fragment or vector containing about 1.5 kb upstream of the PHD-finger gene and transcription start site was introduced into the ehd3 mutant line R0521, and the redifferentiated plants were cultivated in a long-day condition meteorological device. When the number of days until transplanting was investigated, all heads introduced with the 5.7 kb genomic fragment showed enhanced heading under long-day conditions.

Claims (15)

The DNA according to any one of (a) to (d) below, which encodes a plant-derived protein having a function of controlling plant photosensitivity.
(A) DNA encoding a protein comprising the amino acid sequence set forth in SEQ ID NO: 3
(B) DNA containing the coding region of the base sequence described in SEQ ID NO: 1 or 2
(C) DNA encoding a protein having an amino acid sequence in which one or more amino acids are substituted, deleted, inserted and / or added in the amino acid sequence of SEQ ID NO: 3
(D) DNA that hybridizes under stringent conditions with DNA comprising the nucleotide sequence set forth in SEQ ID NO: 1 or 2   The DNA according to claim 1, which is derived from rice. The DNA according to any one of (a) to (d) below.
(A) DNA encoding an antisense RNA complementary to the transcription product of the DNA according to claim 1 or 2
(B) DNA encoding an RNA having ribozyme activity that specifically cleaves the transcript of the DNA of claim 1 or 2
(C) DNA encoding RNA that suppresses the expression of DNA according to claim 1 or 2 due to RNAi effect during expression in plant cells
(D) DNA encoding an RNA that suppresses the expression of the DNA according to claim 1 or 2 due to a co-suppression effect during expression in plant cells   The DNA according to any one of claims 1 to 3, which is used for controlling the photosensitivity of a plant. The DNA according to any one of (e) to (h) below, which is a mutant of the protein according to claim 1 and encodes a plant-derived protein lacking the function of controlling plant photosensitivity.
(E) DNA encoding a protein comprising the amino acid sequence set forth in SEQ ID NO: 6
(F) DNA containing the coding region of the nucleotide sequence set forth in SEQ ID NO: 4 or 5
(G) DNA encoding a protein having an amino acid sequence in which one or more amino acids are substituted, deleted, inserted and / or added in the amino acid sequence of SEQ ID NO: 6
(H) DNA that hybridizes under stringent conditions with DNA comprising the nucleotide sequence set forth in SEQ ID NO: 4 or 5   A vector comprising the DNA according to any one of claims 1 to 5.   A transformed plant cell carrying the DNA according to any one of claims 1 to 5 or the vector according to claim 6.   A transformed plant comprising the transformed plant cell according to claim 7.   A transformed plant that is a descendant or clone of the transformed plant according to claim 8.   The propagation material of the transformed plant body of Claim 8 or 9.   A method for producing a transformed plant according to claim 8 or 9, wherein the DNA according to any one of claims 1 to 5 or the vector according to claim 6 is introduced into a plant cell, and the plant cell is used. A method comprising a step of regenerating a plant body.   A method for promoting heading of a plant, comprising expressing the DNA according to claim 1 or 2 in cells of the plant body.   A method for controlling photosensitivity, comprising suppressing endogenous expression of the DNA according to claim 1 or 2 in a plant cell.   The method according to claim 13, wherein the DNA according to claim 3 is introduced into a plant.   The method according to any one of claims 12 to 14, wherein the plant is rice.