WO2015199242A1 - ウイルス抵抗性タバコおよびその作出方法 - Google Patents
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- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01H—NEW PLANTS OR NON-TRANSGENIC PROCESSES FOR OBTAINING THEM; PLANT REPRODUCTION BY TISSUE CULTURE TECHNIQUES
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- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
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Definitions
- the present invention relates to a virus-resistant tobacco and a production method thereof.
- PVY Potato virus Y
- PVY causes a decrease in plant height and gangrene symptoms of the veins, resulting in a reduction in leaf tobacco quality and yield, and severely damages tobacco production all over the world.
- leaf tobacco that has been infected with PVY and whose quality is reduced is used as a raw material, the quality of the tobacco product produced is also greatly reduced.
- Tobacco bushy top virus (hereinafter referred to as TBTV) is a virus belonging to the genus Umbravirus and is known as a causative virus for tobacco bushy top disease occurring in Africa and Asia.
- the virus is permanently transmitted in nature by aphids, causing tobacco stagnation and leaf mottling, resulting in reduced quality and yield.
- tobacco bushy top disease is an important disease in African countries.
- VAM Virgin A mutant
- PVY-Breaking line (sometimes referred to as PVY-Breaking line or PVY-B)
- Non-patent Document 1 tobacco wild species such as Nicotiana africana show resistance to PVY-Breaking strains, but they are not yet in a stage to be used for breeding programs.
- Non-patent Document 2 the search for resistance sources against tobacco bushy top disease was conducted using 43 tobacco varieties and wild Nicotiana species, but none of the tobacco varieties showed resistance, It has been reported that wild species did not show symptoms of viral disease (Non-patent Document 2). However, the mode of inheritance of resistance has not been clarified. Furthermore, when resistance is introduced from wild to cultivated N. tabacum, traits that adversely affect quality and yield can be introduced at the same time. As expected, there is still a long way to go.
- Non-patent Document 3 About half of about 200 known plant virus resistance genes have recessive inheritance (Non-patent Document 3). These are considered to be host factors necessary for virus growth and cell-to-cell transfer. Some of these factors have become apparent from the last decade of research. For example, translation initiation factors such as eIF4E and eIF4G, DEAD-box RNA helicase-like protein (Non-patent document 4), cysteine-rich VPg-interacting protein (Non-patent document 5), Translation elongation factor (Non-patent document 6), etc. has been identified as a recessive virus-resistant genetic factor. Of course, these are not all, and it is considered that there are many other candidates (Non-Patent Document 3). For example, as other candidates, various plant factors related to phloem transport of plant viruses (Non-Patent Document 7). Is mentioned.
- Patent Document 1 describes a method for imparting virus resistance by suppressing the function of the eIF4E gene (excluding eIF (iso) 4E).
- Patent Document 2 describes a mutant having eIF4E or eIF (iso) 4E to which a virus does not act due to a splicing mutation in the eIF4E gene or eIF (iso) 4E gene.
- the mutation is an insertion, deletion, or substitution at a non-coding region of eIF4E or eIF (iso) 4E, or at least one base of a splicing element (exon / intron boundary site ⁇ 10 base region), preferably
- the intron, more preferably the first intron is the object.
- Patent Document 3 discloses a method for selecting a resistant plant against pepper pepper leaf spot disease (Pepper vettle mottle virus, PVMV) by a combination of both eIF4E and eIF (iso) 4E mutations, specifically, eIF4E and eIF ( iso) A method for screening plants that do not express 4E at all and express mutant eIF4E is described.
- PVMV pepper vettle mottle virus
- Non-patent Document 9 Clover yellow vein virus grows in eIF (iso) 4E-deficient Arabidopsis but does not grow in eIF4E-deficient Arabidopsis and, conversely, TuMV grows in eIF4E-deficient Arabidopsis, but eIF (iso) 4E It has been shown that it does not grow in deficient Arabidopsis thaliana (Non-patent Document 10). Furthermore, in order to acquire resistance to PVMV, both eIF4E and eIF (iso) 4E must simultaneously lose their functions (Non-patent Document 11). Examples of recent reviews of translation initiation factors and plant virus resistance include Non-Patent Document 12 and Non-Patent Document 13.
- CMV Cucumber mosaic virus
- RYMV Rice mottle virus
- RNAi RNA interference
- eIF4E1 and eIF4E2 RNA interference
- eIF (iso) 4E RNAi was not resistant to any of these viruses (Non-patent Document 17).
- eIF (iso) 4E of tomato is not related to virus resistance other than the genus Potyvirus (Non-patent Document 17).
- eIF4E has been pointed out to be related to PVY resistance in any plant so far, and no relation to eIF (iso) 4E has been reported.
- eIF (iso) 4E is categorized into the eIF4E family, in plants, the DNA sequence identity between eIF4E and eIF (iso) 4E is generally less than 60%.
- eIF (iso) 4E forms a translation complex different from eIF4E. Specifically, eIF (iso) 4E forms a translation complex called eIF (iso) 4F together with eIF (iso) 4G, and eIF4E forms a translation complex called eIF4F together with eIF4G.
- Non-patent Document 18 In tobacco (Nicotiana tabacum), there is a report that the expression level of eIF4E1 or eIF (iso) 4E is reduced (Non-patent Document 18). In this report, antisense technology is used to repress the transcription of tobacco eIF4E1 or eIF (iso) 4E. And producing tobacco in which the amount of eIF4E1 transcript was suppressed to 30-40% of the control, and tobacco in which the amount of eIF (iso) 4E transcript was suppressed to 60% of the control, and both It is described that the amount of the transcript of eIF4E1 was reduced to 26% of the control and the amount of the transcript of eIF (iso) 4E to 31% of the control.
- Non-patent Document 20 an exhaustive analysis of transcripts of PVY-resistant and PVY-sensitive tobacco found that eIF4E is among the genes with low transcript levels specifically in VAM tobacco. It has been shown that tobacco with mutations becomes PVY resistant (Non-patent Document 20).
- Non-patent Document 21 discloses the nucleotide sequences of eIF4E and eIF (iso) 4E genes in PVY and PepMoV, viruses belonging to the genus Potyvirus that infect tobacco, in varieties resistant to and susceptible to these viruses. As a result, it was shown that there was no association between mutations in both genes and their resistance / susceptibility to viruses.
- mutations were not detected in the eIF4E and eIF (iso) 4E genes of certain PVY resistant varieties, while mutations were found in those of PVY sensitive varieties.
- mutations have been detected in the PVIF resistant varieties of eIF4E and eIF (iso) 4E genes in the same experiment, and it has been considered that the mutations are responsible for the resistance.
- the relationship between Potyvirus resistance and the translation initiation factor is still chaotic.
- Tobacco (Nicotiana tabacum) is a double diploid, and has more genes than normal diploid plants, and there is always one pair of genes from Nicotiana sylvestris and genes from Nicotiana tomentosiformis. To do. That is, at least two sets of homologous genes exist in tobacco. Therefore, the inheritance pattern is more complicated than other diploid plants.
- Arabidopsis thaliana there are three types of eIF4E and one type of eIF (iso) 4E (Non-patent Document 12). It is considered that all translation initiation factors found in Arabidopsis thaliana are present in pairs.
- Non-patent Document 20 Including cap-binding protein that is functionally similar to eIF4E, it has been found that there are at least 12 eIF4E families of tobacco (Non-patent Document 20). If eIF4G and eIF (iso) 4G are included, the number is further increased.
- the present invention has been made in view of the above problems, and has as its main object to provide a cigarette having resistance to viruses and a method for producing the cigarette.
- One aspect of the virus-resistant tobacco according to the present invention has a mutation in the translation initiation factor eIF (iso) 4E gene, and thereby a non-functional translation initiation factor eIF (iso) 4E protein against the virus. Or the expression of the translation initiation factor eIF (iso) 4E gene is suppressed.
- Another aspect of the virus-resistant tobacco according to the present invention is characterized in that the expression level of the translation initiation factor eIF (iso) 4E gene is 20% or less compared to the wild type.
- One aspect of the method for producing a virus-resistant tobacco according to the present invention is to produce a translation initiation factor eIF (iso) 4E protein that is non-functional with respect to a virus, or to express the expression of a translation initiation factor eIF (iso) 4E gene. It is characterized by producing a tobacco having resistance to a virus by introducing a mutation that suppresses it into the translation initiation factor eIF (iso) 4E gene.
- Another aspect of the method for producing a virus-resistant tobacco according to the present invention is to introduce a factor that suppresses the expression level of the translation initiation factor eIF (iso) 4E gene to 20% or less compared to the wild type. It is characterized by producing a cigarette having resistance to the above.
- One embodiment of the polynucleotide for detection according to the present invention is a polynucleotide for detecting a mutation in the tobacco translation initiation factor eIF (iso) 4E gene, and the mutation is a non-functional translation for a virus.
- One aspect of the DNA marker for determining the resistance of tobacco comprises a polynucleotide comprising a continuous base sequence containing a mutation in the translation initiation factor eIF (iso) 4E gene or a complementary sequence thereof,
- the mutation is characterized in that it produces a non-functional translation initiation factor eIF (iso) 4E protein or suppresses the expression of the translation initiation factor eIF (iso) 4E gene.
- a cigarette having resistance to viruses can be provided.
- Virus resistant tobacco and method for producing the same One aspect of the present invention relates to a tobacco (virus resistant tobacco) that is resistant to viruses, and more specifically, a translation initiation factor eIF (iso) 4E gene that is functional to viruses in cells. Relates to a virus-resistant tobacco in which the expression level of (eg, the amount of transcript) is reduced. Another embodiment of the present invention relates to a method for producing a tobacco having resistance to a virus (a method for producing a virus-resistant tobacco). The present invention relates to a method for producing virus-resistant tobacco by reducing the expression level of eIF (iso) 4E gene (for example, the amount of transcript).
- Nicotiana tabacum is a double diploid and has both a genome derived from Nicotiana sylvestris (S type genome) and a genome derived from Nicotiana tomentosiformis (T type genome). Therefore, N. tabacum has two sets of eIF (iso) 4E genes (alleles) with different base sequences. In addition, both the S-type and T-type eIF (iso) 4E genes of N. tabacum have 5 exons and 4 introns, as shown in FIGS. In FIGS. 2 and 3, the numbers shown at the bottom indicate the number of nonsense mutation candidate sites, and the arrows indicate the positions of the primers in the examples.
- SEQ ID NO: 1 GenBank accession number: AY699609
- SEQ ID NO: 2 GenBank accession number: EB683576
- SEQ ID NO: 2 the open reading frame is the 37th to 624th bases.
- amino acid sequence of the S-type wild type eIF (iso) 4E protein is shown in SEQ ID NO: 3.
- SEQ ID NO: 4 An example of the amino acid sequence of the T-type wild-type eIF (iso) 4E protein is shown in SEQ ID NO: 4.
- SEQ ID NO: 5 An example of the mRNA sequence of the S-type wild-type eIF (iso) 4E gene (t in the cDNA sequence is changed to u) is shown in SEQ ID NO: 5.
- SEQ ID NO: 6 An example of the base sequence of the genome of the S-type wild-type eIF (iso) 4E gene is shown in SEQ ID NO: 7.
- SEQ ID NO: 8 An example of the base sequence of the genome of the T-type wild-type eIF (iso) 4E gene is shown in SEQ ID NO: 8.
- the exons are from the 132nd to the 397th base (first exon), from the 1730th to the 1898th base (second exon), from the 2029th to the 2154th base (third exon), from the 4723th It is the 4785th base (4th exon), and the 4893th to 5096th base (5th exon).
- the exons are from the 164th to 382nd bases (first exon), from the 1620th to 1788th bases (second exon), from the 1919th to 2044th bases (third exon), from the 3205th.
- the base sequence of the protein coding region of a plant gene having the same function may vary from about 1% to several percent between cultivars depending on the gene, and several percent to 10% between cultivars and wild relatives. There can be a degree of difference.
- the wild-type eIF (iso) 4E gene prior to the occurrence of mutation includes a gene that generates mRNA consisting of the base sequence shown in SEQ ID NO: 5 or SEQ ID NO: 6, and SEQ ID NO: 3 or SEQ ID NO: A gene encoding eIF (iso) 4E protein consisting of the amino acid sequence shown in FIG.
- the wild-type eIF (iso) 4E gene before the mutation is caused to have a nucleotide sequence of SEQ ID NO: 5 or SEQ ID NO: 6 and 92% or more, preferably 95% or more, more preferably Also included is a gene that encodes a functional eIF (iso) 4E protein that produces 97% or more, more preferably 99% or more of sequence identity.
- the wild-type eIF (iso) 4E gene includes 92% or more, preferably 95% or more, more preferably 97% or more, and further preferably, the amino acid sequence shown in SEQ ID NO: 3 or SEQ ID NO: 4.
- genes that encode functional eIF (iso) 4E proteins with 99% or greater sequence identity are also encompassed.
- the wild-type eIF (iso) 4E gene includes 1 to 50, 1 to 40, 1 to 30, and 1 to 20 nucleotide sequences shown in SEQ ID NO: 5 or SEQ ID NO: 6. 1-15, 1-12, 1-10, 1-8, 1-5, 1-3, 1-2, or 1 base replaced, deleted, inserted and / or Alternatively, a gene encoding mRNA having an added base sequence and encoding a functional eIF (iso) 4E protein is also included.
- the wild-type eIF (iso) 4E gene includes 1 to 20, 1 to 15, 1 to 12, and 1 to 10 in the amino acid sequence shown in SEQ ID NO: 3 or SEQ ID NO: 4. Functional having an amino acid sequence in which 1 to 8, 1 to 5, 1 to 4, 1 to 3, 1 to 2, or 1 amino acid is substituted, deleted, inserted and / or added Also included is the gene encoding the eIF (iso) 4E protein.
- a to B indicating a numerical range is intended to be “A or more and B or less”.
- the wild-type T-type eIF (iso) 4E gene before the occurrence of mutation includes a gene whose cDNA sequence is the sequence of GenBank accession number FN666434.
- This sequence is derived from the T-type eIF (iso) 4E gene derived from the tobacco variety Samsun NN, and the sequence with the T-type eIF (iso) 4E cDNA sequence EB683576 (SEQ ID NO: 2) derived from the tobacco variety K326.
- the identity is 97%.
- the identity of the amino acid sequences of the proteins encoded by these two genes is 97% and the similarity is 99%.
- identity of base sequences refers to the ratio of exactly the same base sequence in a plurality of base sequences.
- amino acid sequence identity refers to the ratio of the exact same amino acid sequence in a plurality of amino acid sequences.
- similarity of amino acid sequences refers to the ratio of amino acid sequences having the same amino acid or similar properties in a plurality of amino acid sequences.
- amino acids of similar nature include, for example, lysine, arginine, and histidine with positively charged residues; aspartic acid and glutamic acid with negatively charged residues; alanine with nonpolar or hydrophobic residues , Valine, leucine, isoleucine, methionine, tryptophan, phenylalanine, and proline; polar but uncharged glycine, serine, threonine, cysteine, tyrosine, asparagine, and glutamine.
- base sequence identity “amino acid sequence identity”, or “amino acid sequence similarity”
- BLAST a sequence analysis (homology search) program BLAST (literature: Altschul et al.
- tobacco includes not only Nicotiana tabacum but also other species of the same Nicotiana genus.
- Other species of the genus Nicotiana include, for example, N. paniculata, N. knightiana, N. solanifolia, N. benavidesii, N. cordifolia, N. raimondii, N. cutleri, N. toticosa, N. tomentosa, N. tomentosiformis , N.phorotophora, N. kawakamii, N. setchellii, N. undulata, N. arentsii, N. wigandioides, N. glutinosa, N. thyrsiflora, N.
- obtusifolia N. palmeri, N. langsdorffii, N. alata, N Forgetiana, N. bonariensis, N. longiflora, N. plumbaginifolia, N. azambujae, N. mutabilis, N. sylvestris, N. repanda, N. stocktonii, N. nesophila, N. nudicaulis, N. noctifloroid, N. acaulis, N. ameghinoi, N. glauca, N. paa, N. acuminata, N. pauciflora, N. attenuata, N. longibracteata, N. miersii, N.
- corymbosa N. linearis, N. spegazzinii, N . Quadrivalvis, N. clevelandii, N. benthamiana, N. umbratica, N. cavicola, N. debneyi, N. gossei, N. amplexicaulis, N. maritima, N. velutina, N. hesperis, N. occidentalis, N. simulans, N. megalosiphon, N. rotundifolia, N. excelsior, N. suaveolens, N. ingulba, N. exigua, N. goodspeedii, N. rosulata, N. fragrans, N. africana, N. burbidgeae, N.
- tobacco also includes tobacco plants, plant tissues (eg, leaves, stems, flowers, roots, reproductive organs, embryos and parts thereof), seedlings and seeds, and dried leaves, stems, flowers. , Roots and seeds, and the like.
- the cDNA sequence of the eIF (iso) 4E gene of these Nicotiana plants is considered to have 90% or more sequence identity with the base sequence shown in SEQ ID NO: 1.
- the base sequence shown in SEQ ID NO: 1 shows 100% sequence identity with the cDNA sequence of the N. sylvestris eIF (iso) 4E gene (excluding introns).
- the nucleotide sequence shown in SEQ ID NO: 2 shows 99% sequence identity with the cDNA sequence of eIF (iso) 4E from N.tomentosiformis (excluding introns).
- the base sequence shown in SEQ ID NO: 1 and the base sequence shown in SEQ ID NO: 2 show 98% and 99% sequence identity with the cDNA sequence of N.
- otophora eIF (iso) 4E respectively (excluding introns).
- the structures of the eIF (iso) 4E gene of N. sylvestris, N. tomentosiformis, and N. otophora are all the same number of exons (5) and the same number of introns (4) as the N. tabacum gene. have.
- the wild-type eIF (iso) 4E gene has the nucleotide sequence shown in SEQ ID NO: 1, and the genome of N. sylvestris, N. tomentosiformis, or N. otophora registered in GenBank (Whole genome shotgun) contigs) by a homology search using the BLAST program or the like.
- the base sequence of the eIF (iso) 4E gene of a plant species derived from a Nicotiana genus plant can be obtained from the genomic DNA of the plant species using, for example, the primer sequences shown in SEQ ID NOs: 25 to 36 by the PCR method using eIF (iso) ) It can be obtained by amplifying the 4E gene and determining the base sequence.
- a BLAST program may be used, or commercially available nucleic acid / amino acid sequence analysis software may be used.
- Viruses to which the virus-resistant tobacco is resistant are not particularly limited.
- viruses belonging to the genus Alfamovirus for example, Alfalfa mosaic virus
- Curtovirus for example, Beet curly top virus
- Begomovirus for example, Tobaccocovirus
- Cucumovirus genus viruses eg Cucumber mosaic virus, and Peanut stunt virus
- Ilarvirus genus viruses eg Tobacco streak virus
- Potyvirus genus viruses eg Potato virus Y (PVY), Tobacco etch virus, Tobacco vein mottling virus) And Tobaccoacvein banding mosaic virus
- Tobamovirus genus virus eg Tobacco mosaic virus
- Tobravirus genus virus eg Tobacco rattle virus
- Necrovirus genus virus eg Tobacco necrosis virus
- Varicosavirus genus virus eg Tobacco stuntvirus
- Genus virus eg Tobacco ringspot virus
- Umbravirus virus eg Tobacco bushy top virus, and Tobacco mottle virus
- Polerovirus virus eg Tobacco vein distorting virus
- Mastrevirus virus eg Tobacco yellow dwarf virus
- Tospovirus virus eg Tomato spotted wilt
- the virus-resistant tobacco according to the present invention may be resistant to one type of virus or may be resistant to multiple types of viruses.
- the virus-resistant tobacco according to the present invention may have a remarkable resistance to a virus belonging to the genus Potyvirus.
- Potato virus Y (PVY) PVY-O strain, PVY-C strain, PVY- It may be resistant to Z strains, PVY-N (including NTN and NW) strains, particularly PVY strains (VAM-Breaking strains) that break the virus resistance of tobacco Virgin A mutant.
- the virus-resistant tobacco according to the present invention may have a remarkable resistance to a virus belonging to the genus Umbravirus, and in particular, may have a resistance to Tobacco bushy top virus (TBTV).
- TBTV Tobacco bushy top virus
- virus resistance refers to the fact that the symptoms that occur in tobacco are delayed or do not occur due to viral infection, as compared with susceptible tobacco varieties. Symptoms occurring in tobacco include growth stagnation, vein gangrene, stem gangrene, leaf vein penetration, and mottling. Alternatively, “virus resistance” refers to inhibition of virus growth or inhibition of viral cell-to-cell migration as compared to susceptible tobacco varieties.
- One aspect of the virus-resistant tobacco according to the present invention has a mutation in the eIF (iso) 4E gene, thereby producing a translation initiation factor eIF (iso) 4E protein that is non-functional for the virus. Or a virus-resistant tobacco in which expression of the translation initiation factor eIF (iso) 4E gene is suppressed.
- mutant refers to point mutations, deletions, insertions, duplications, translocations, and inversions in DNA, and refers to differences from the wild-type base sequence unless otherwise specified.
- the “eIF (iso) 4E gene” refers to not only a coding region encoding an eIF (iso) 4E protein in the genome, but also an intron, a regulatory region, and other untranslated sequences, etc. (Iso) A concept including a non-coding region necessary for expression of 4E protein.
- EIF (iso) 4E protein that is non-functional with respect to a virus refers to an eIF (iso) 4E protein that is not available (at least partially inhibited) when the virus is self-propagating or intercellularly transferred.
- eIF (iso) 4E protein function functions as a translation initiation factor
- a virus is used. Includes both cases where it is not possible.
- the eIF (iso) 4E protein of wild type plants not introduced with mutations
- “Expression level of eIF (iso) 4E gene” refers to the amount of transcription (transcription level or amount of transcript) of eIF (iso) 4E into mRNA and the amount of translation into eIF (iso) 4E protein (translation level or Either or both of the translation products may be used. Therefore, “expression of eIF (iso) 4E is suppressed” means that the transcription is suppressed compared to the wild type and the translation is suppressed compared to the wild type. The case where both transcription and translation are suppressed as compared with the type is also included. Note that “transfer is suppressed” includes the case where the transcript is decomposed.
- N. tabacum is considered to have two sets of S-type and T-type, a total of four (two for S-type and two for T-type) eIF (iso) 4E genes.
- the virus-resistant tobacco preferably has a mutation in at least the S-type eIF (iso) 4E gene.
- the virus-resistant tobacco may have resistance to at least a virus of the genus Umbravirus (eg, TBTV).
- it is preferred that the virus resistant tobacco has a mutation in at least the T-type eIF (iso) 4E gene.
- the virus resistant tobacco may have resistance to at least a virus of the genus Potyvirus (eg, PVY-B strain).
- the virus resistant tobacco has a mutation in both S-type and T-type eIF (iso) 4E genes.
- the virus-resistant tobacco may have resistance to at least both Umbravirus and Potyvirus viruses.
- the mutation in one type may be homo (eg, mutations are present in both of the two SIF type eIF (iso) 4E genes) or heterozygous, but homozygous. It is preferable.
- an example of a virus-resistant tobacco is (a) a wild-type eIF (iso) 4E gene encoding an eIF (iso) 4E protein consisting of the amino acid sequence shown in SEQ ID NO: 3, and (b) an amino acid shown in SEQ ID NO: 3.
- a functional eIF (iso) 4E protein that produces a wild-type eIF (iso) 4E gene or (d) an mRNA having 92% or more sequence identity with the base sequence shown in SEQ ID NO: 5 Has one or more mutations in the wild-type eIF (iso) 4E gene encoding, and is resistant to viruses of the genus Umbravirus Have Another example of virus-resistant tobacco is (a) a wild-type eIF (iso) 4E gene encoding an eIF (iso) 4E protein consisting of the amino acid sequence shown in SEQ ID NO: 4, (b) A wild-type eIF (iso) 4E gene encoding a functional eIF (iso) 4E protein having a sequence
- one eIF (iso) 4E gene may have a plurality of mutations.
- mutation in several eIF (iso) 4E gene may be the same, and may mutually differ.
- the virus-resistant tobacco according to the present invention has a mutation in the coding region, it has a mutation in the amino acid sequence of the eIF (iso) 4E protein. Mutations include substitutions, deletions and insertions.
- the mutation is an amino acid substitution
- the amino acid to be substituted and the amino acid after the substitution are not particularly limited as long as the eIF (iso) 4E protein is rendered non-functional with respect to the virus. For example, non-conservative substitution (Non-conservative substitutions) is preferred.
- Non-conservative substitutions include substitution of an amino acid with another amino acid with a different charge or hydrophobicity (such as substitution of a basic amino acid with an acidic amino acid, or substitution of a polar amino acid with a nonpolar amino acid), and certain amino acids Is substituted with another amino acid having a different side chain.
- the coding region may be a frameshift mutation or a nonsense mutation.
- Nonsense mutations mutations that become stop codons
- the position of the nonsense mutation is preferably in the first exon, the second exon, and / or the third exon, and more preferably in the first exon and / or the second exon.
- the position of the mutation is preferably on the 5 'end side rather than about the 5' end half of the gene.
- the first exon, the second exon, and / or the third exon have a mutation. The closer to the 5 'end, the shorter the normal part of the protein, and the more likely it is to become non-functional against the virus. If there is a mutation in the coding region of all eIF (iso) 4E genes that tobacco has (for example, all four in N. tabacum), the functional eIF (iso) 4E protein against the virus is Not produced at all.
- the virus-resistant tobacco according to the present invention has a mutation in the non-coding region, it does not affect the amino acid sequence of the encoded eIF (iso) 4E protein, but changes the secondary structure of DNA or mRNA. May alter the binding site for the transcriptional or translational machinery, or reduce the tRNA binding efficiency. Thereby, the transcription level can be reduced or the translation level can be reduced.
- the amount of the transcript of the eIF (iso) 4E gene is preferably 20% or less, more preferably 15% or less, even more preferably compared to the wild type. Is 10% or less.
- the amount of the translation product of the eIF (iso) 4E gene is preferably 20% or less, more preferably 15% or less, compared to the wild type, More preferably, it is 10% or less.
- RNA splicing may not function normally due to mutations in the eIF (iso) 4E gene.
- 10 bases before and after GT at the 5 ′ end side of the intron preferably 5 bases, more preferably 1 base, or 10 bases before and after the AG at the 3 ′ end side of the intron, preferably 5 bases, more preferably If there is a mutation at one base, intron excision will not be successful and an abnormal mRNA will be produced to produce a non-functional eIF (iso) 4E protein against the virus, or eIF (iso) Translation of the 4E gene can be suppressed.
- the method for causing a mutation in the eIF (iso) 4E gene is not particularly limited, and a known method can be used.
- mutagen for example, chemical agents such as ethyl methanesulfonic acid (EMS), sodium azide, ethidium bromide, and nitrous acid can be used.
- EMS ethyl methanesulfonic acid
- any chemical agent that causes mutation in tobacco genomic DNA can be used. It is not limited to these.
- mutagens include ⁇ -rays, heavy ion beams, X-rays, neutron beams, and UV, but are not limited to these as long as they cause radiation in tobacco genomic DNA.
- EMS is preferred as the mutagen.
- tissue or organ of tobacco to be treated with mutagen examples include seeds, roots, leaves, flowers and the like, and the type is not particularly limited as long as the plant body can be regenerated, but seeds are preferable.
- the dose of mutagenic chemicals or radiation is determined empirically for each type of plant tissue so that a mutation frequency is obtained that is below the threshold level leading to lethality or reproductive sterility. Is done.
- transposons mobile genetic factors
- the transposon can translocate on the tobacco genome and suppress the function of the eIF (iso) 4E gene.
- a preferred example of such a transposon is tobacco retrotransposon tnt1.
- transposons of other plants can be introduced into tobacco for use. Examples of such transposons include, but are not limited to, corn transposon Ac / Ds, Spm / dSpm, and Mu, rice transposon nDart, and goldfish grass transposon tam.
- a method for producing virus-resistant tobacco having mutations in two sets (four) of eIF (iso) 4E genes tobacco is treated with mutagen as described above, and tobacco is mutated throughout the tobacco genome.
- a mutant population (panel) is created and genomic DNA is extracted.
- a gene-specific primer is used to amplify the eIF (iso) 4E gene from each of the genomic DNA of the panel or from a pool of them, determine the nucleotide sequence of the product, and a strain containing a homozygous mutation To select.
- a strain having a homozygous mutation in the S-type genome and a strain having a homozygous mutation in the T-type genome are respectively obtained, and F 1 is produced by crossing them.
- the inbred progeny (F 2 ) is nurtured, and a strain having a homozygous mutation in both the S-type genome and the T-type genome is obtained from it (obtained with a probability of 1/16 due to two-factor recessiveness) .
- a virus assay is performed to confirm resistance.
- expression analysis of the eIF (iso) 4E gene may be performed using quantitative PCR or the like to confirm that the transcription amount has been reduced.
- a step of producing a tobacco mutant population (panel) in which mutations have occurred in the entire tobacco genome a step of extracting genomic DNA, and a base sequence of the eIF (iso) 4E gene At least one of a step of selecting a strain having a homozygous mutation, and a step of confirming resistance by performing a virus assay.
- the mutation-treated line may be crossed with a line not subjected to mutation treatment at any timing.
- Extraction of genomic DNA from tobacco mutants may be performed based on a known method, and a commercially available extraction kit may be used.
- the genomic DNA may be a crude product or a purified product that has undergone several purification steps.
- the amplification of the polynucleotide can be performed, for example, by PCR, but may be performed by other known gene amplification methods, for example, LCR (ligase chain reaction) method or LAMP (Loop-Mediated Isothermal Amplification) method.
- LCR ligase chain reaction
- LAMP Loop-Mediated Isothermal Amplification
- the primer sequence for amplifying each polynucleotide can be designed, for example, from the base sequence of SEQ ID NO: 7 or from the base sequence of SEQ ID NO: 8. From the homology analysis result of the base sequence of SEQ ID NO: 7 (S-type eIF (iso) 4E gene) and the base sequence of SEQ ID NO: 8 (T-type eIF (iso) 4E gene), first, an S-type specific region And find a T-type specific region. By designing a primer in that region, the S-type and T-type genes can be specifically amplified from the tobacco genome in which S-type and T-type are mixed.
- the site to be designed can be selected from S-type or T-type specific regions, but is preferably an intron, 5 'untranslated region or 3' untranslated region.
- the length of the primer is preferably 15 to 30 bases, particularly preferably 17 to 25 bases.
- the primer sequence may be designed based on the sequence of a region specific to the base sequence of SEQ ID NO: 7, a region specific to the base sequence of SEQ ID NO: 8, or a region common to both base sequences. Moreover, as long as it can function as a primer for amplifying a sequence having a predetermined number of bases including a mutation site, the sequence may contain one or more substitutions, deletions, and / or additions.
- the primer may be labeled with a fluorescent substance or a radioactive substance as necessary.
- each polynucleotide to be amplified is not particularly limited as long as various detection methods described below can be used.
- the length is 20 bases to 5000 bases, more preferably 50 bases to 2000 bases, and still more preferably 100 bases.
- codons that become stop codons when mutated by EMS treatment are CAA (first C is replaced with T), CGA (first C is replaced with T), and TGG (two There are four types: eye G, or third G is replaced with A), and CAG (first C is replaced with T).
- the mutation is one or more mutations shown in the above (1) to (27) of the eIF (iso) 4E gene consisting of the nucleotide sequence shown in SEQ ID NO: 7 in genomic DNA. is there.
- the case where a mutation occurs in any one of (1) to (26) is more preferable, and the case where a mutation occurs in any one of (1) to (24) is more preferable.
- the mutation is one or more mutations shown in the above (1) to (26) of the eIF (iso) 4E gene consisting of the nucleotide sequence shown in SEQ ID NO: 8 in genomic DNA. is there.
- the case where a mutation occurs in any one of (1) to (25) is more preferable, and the case where a mutation occurs in any one of (1) to (23) is more preferable.
- the mutation is (a) a wild-type translation initiation factor encoding a functional translation initiation factor eIF (iso) 4E protein having a sequence identity of 92% or more with the amino acid sequence shown in SEQ ID NO: 3 or SEQ ID NO: 4 an exon of the eIF (iso) 4E gene, or (b) an mRNA having a sequence identity of 92% or more with the base sequence shown in SEQ ID NO: 5 or SEQ ID NO: 6, and a functional translation initiation factor
- One or more mutations shown in the following (1) to (4) may be present in the exon of the wild-type translation initiation factor eIF (iso) 4E gene encoding the eIF (iso) 4E protein; (1) codon CAA C replaced with T, (2) Codon CGA C replaced with T, (3) Codon CAG C replaced with T, (4) Codon TGG G (two G Either one or both) is substituted with A in.
- gene editing technology can also be used.
- the gene editing technique is a technique for introducing a mutation into an arbitrary region of the genome. Examples of such techniques include TALEN (Transcription activator-like effector), CRISPR (Clustered regularly interspaced short palindromic repeat) / CAS, ODM (Oligonucleotide Directed Mutagenesis), and ZFN (Zinc Finger Nuclease).
- ODM and ZFN are described in the document: Lusser et al. (2012) Nature Biotechnology 30: 231-239.
- ZFN application to plants is described in the literature: Duraiuraet al. (2005) Nucleic Acids Res 33: 5978-5990. According to the methods described therein, it is possible to introduce mutations into the eIF (iso) 4E gene.
- TALEN Transcription activator-like effector derived from a phytopathogenic fungus has a structure portion in which 34 amino acids are repeated, and each of the repetitive structures recognizes one base of DNA. There are four types of bases (A, T, G, C) in DNA, and the binding specificity of the DNA sequence is determined by the 13th and 14th amino acids of the TAL effector repeat structure. That is, by selecting the 13th to 14th amino acids of each repeating structure, the TAL effector can be artificially bound to a desired DNA region.
- a product obtained by fusing this TAL effector with an enzyme FokI that exhibits DNA cleavage activity when dimerized is called TAL effector nuclease (TALEN).
- an eIF (iso) 4E-specific nucleotide sequence preferably 15 to 25 bases, more preferably 18 to 22 bases, is preferably designed in the protein coding region. Further, a nucleotide sequence is similarly designed at a location 9 to 15 bases away from there. The part sandwiched between these two nucleotides will be cleaved later.
- the designed nucleotide sequence is searched for homology against known sequence databases such as tobacco (NicotianaNitabacum) or Nicotianasylvestris or Nicotiana tomentosiformis Thus, in addition to the sequence itself, it may be examined whether there is a region having high homology including the sequence.
- sequence database for example, GenBank, EMBL (The European Molecular Biology Loboratory), DDBJ (DNA Data Bank of Japan) or the like can be used.
- BLAST a sequence analysis algorithm
- database sequences include, but are not limited to, Nucleotide Collection (nr / nt), Expressed Sequence Tags (EST), Genomic Survey Sequences (GSS), Whole Genome Shotgun Contigs (WGS), and the like.
- TALE Design TALE gene sequence based on the designed specific nucleotide sequence.
- GoldenGateTALEN Kit Additional nucleotide sequence
- an appropriate linker sequence may be arranged.
- the FokI sequence is listed in a known database.
- the promoter for expressing the TALE / FokI fusion gene in tobacco is preferably a highly expressed promoter, and a constitutive expression promoter such as a promoter of the cauliflower mosaic virus 35S RNA gene, a promoter of the actin gene, and a promoter of the ubiquitin gene; Rubisco small subunit Examples include, but are not limited to, promoters of genes, green tissue specific promoters such as the PPDK gene promoter; and other organ or time specific promoters.
- a desired intron may be placed between the promoter and TALE / FokI.
- the TALE / FokI codon may be optimized as a plant (tobacco) codon. Plant codons are described in known databases such as Codon Usage Database (http://www.kazusa.or.jp/codon/).
- a vector for introducing a TALEN expression cassette into a plant may incorporate an expression cassette of a drug resistance gene (selection marker) for selecting a plant cell into which the expression cassette has been introduced.
- the drug resistance gene may be any drug resistance gene capable of selecting tobacco cells.
- a kanamycin resistance gene neomycin phosphotransferase: NPT-II
- hygromycin resistance gene hygromycin phosphotransferase: HPT
- a promoter will not be specifically limited if it expresses constitutively.
- a right border (RB) sequence and a left border (LB) sequence are arranged at both ends of the T-DNA as T-DNA border sequences.
- Examples of vectors for introducing a TALEN expression cassette into a plant and capable of introducing a gene into tobacco include pBI and pSB (reference: Komari et al. 2006 Methods in Mol. Biol. 343: 15- 41.), pLC system (literature: U.S. Pat. No. 8,298,819), and pGreen (literature: Hellens et al. 2000. Plant Mol. Biol. 42: 819-832.) And the like.
- the method for introducing the TALEN expression cassette into the plant is not particularly limited, and is usually used by those skilled in the art, such as the method using Agrobacterium, the particle gun method, the PEG method, the electroporation method, or the Agroinfiltration method.
- the method to be used may be used.
- the type of tobacco tissue or organ to be introduced is not particularly limited as long as the plant body can be regenerated, and examples thereof include seeds, roots, leaves, and flowers.
- the drug used for selection include, but are not limited to, kanamycin and hygromycin.
- the concentration of the drug can be, for example, 20 mg / mL to 200 mg / mL, and preferably 50 mg / mL to 100 mg / mL.
- a culture medium for growing plant cultures may be a commonly used medium, and examples of inorganic salts include MS and LS.
- sucrose, agar, or plant hormones are added thereto. These use concentrations may be in accordance with protocols usually used by those skilled in the art.
- protoplasts can be used as tissues or organs for gene transfer.
- Protoplasts can be prepared according to conventional methods using cell wall degrading enzymes.
- a transient method can also be used as a gene introduction method.
- the transient assay may be performed using a conventional method such as an electroporation method or a PEG method.
- Other transient assay methods include Agro-infiltration and viral vectors.
- ALSV Apple Latent Spherical Virus
- TRV tobacco Rattle Virus
- the method for analyzing gene expression is not particularly limited, and may be performed by a known method such as Northern hybridization or quantitative PCR.
- the probe used for hybridization is the nucleotide sequence of SEQ ID NO: 1 or a part thereof (for example, SEQ ID NO: 9), the nucleotide sequence of SEQ ID NO: 2 or a part thereof, or substitution or deletion of one or more bases in these.
- a base sequence with insertion can be used, and the length of the probe can be, for example, 20 bases to the entire sequence length.
- RNA for the above expression analysis may be performed by a known method such as guanidine hydrochloride method or SDS-phenol method, or a commercially available kit may be used. Further, mRNA (polyA + RNA) may be further purified from the total RNA.
- Synthesis of cDNA for performing quantitative PCR can be performed by a known method using reverse transcriptase and oligo dT primer or gene-specific primer, and a commercially available kit may be used.
- primers for quantitative PCR can be designed based on SEQ ID NO: 1 or SEQ ID NO: 2.
- the length of the primer is preferably 15 to 30 bases, particularly preferably 17 to 25 bases.
- the length of the amplification sequence targeted by one set of primer sets is not particularly limited, and can be, for example, 40 bases to the entire sequence length, and preferably 50 bases to 500 bases.
- a probe sequence is set in the target sequence in addition to the above primers.
- the length of the target sequence is preferably 40 bases to 200 bases, more preferably 50 bases to 150 bases.
- Reporter dyes for labeling primers and probes include FAM, HEX, TET, and Cyanine5, and quencher dyes include TAMRA, BHQ1, and the like. be able to.
- the gene used as an internal standard for quantitative PCR is not particularly limited as long as it is a constitutively expressed gene, but preferred genes include an elongation factor gene and an actin gene.
- the CRISPR / CAS is as follows.
- the CRISPR / CAS system is a gene editing technique using a guide RNA that recognizes a DNA sequence and a CAS nuclease, and is known to function in plants (Reference: Belhaj et al. (2013) Plant Methods 9). : 39).
- This technique is a technique for cleaving DNA having a desired sequence on the genome, and for the deletion, addition and insertion of the target genome sequence, as with TALEN, it relies on mistakes in the host DNA repair system. .
- a promoter for expressing CAS9 in a plant those that are highly expressed are preferable, and examples thereof include, but are not limited to, the above-described 35S RNA promoter, ubiquitin gene promoter, and PPDK gene promoter.
- a desired intron may be disposed between the promoter and CAS9.
- the base sequence of CAS9 is known.
- the codon of CAS9 may be optimized to the codon of plant (tobacco). Further, a nuclear localization signal NLS (Nuclear localize Signal) may be added to CAS9.
- RNA Design the desired genomic sequence and complementary guide RNA.
- SEQ ID NO: 1 or 2 a nucleotide sequence of preferably 19 to 22 bases, preferably specific to eIF (iso) 4E, is determined in the protein coding region.
- PAM protospacer-adjacent motif
- the designed sequence is subjected to homology search, for example, against a sequence database of tobacco (Nicotianacottabacum) or Nicotiana sylvestris or Nicotiana tomentosiformis, In addition to the sequence itself, it can be examined whether or not there is a highly homologous region including the sequence.
- sequence database and analysis algorithm are the same as described above.
- the sgRNA scaffold sequence is fused to the 3 ′ end side to form sgRNA (guide (g) RNA + gRNA scaffold), and a construct for expressing this sgRNA is prepared.
- a promoter such as RNA polymerase III U6 or U3 can be used as the promoter.
- the completed construct is introduced into tobacco using an appropriate vector, and the recombinant is selected and regenerated.
- a plurality of guide RNAs can be designed inside eIF (iso) 4E, and a construct expressing them can be simultaneously introduced into tobacco.
- a plurality of guide RNA expression cassettes and CAS9 expression cassettes may be simultaneously arranged on one T-DNA.
- protoplasts can be used as a tissue or organ for gene transfer.
- Protoplasts can be prepared according to conventional methods using cell wall degrading enzymes.
- a transient method can be used in addition to the above-described stable transformation method. The transient assay is the same as described in TALEN above.
- virus assay methods include, but are not limited to, a mechanical inoculation method combining a virus solution and a solid powder such as carborundum, an inoculation method using a virus-infected aphid, and the like.
- virus to be used is not particularly limited, and the viruses listed above can be used as viruses that are resistant to virus-resistant tobacco.
- Another aspect of the virus-resistant tobacco according to the present invention is a virus-resistant tobacco in which the expression level of the eIF (iso) 4E gene is 20% or less compared to the wild type.
- the expression level of the tobacco eIF (iso) 4E gene whose expression is suppressed is preferably 15% or less, more preferably 10% or less, when the wild-type expression level is 100%.
- wild type refers to tobacco in which a factor that suppresses the expression of the eIF (iso) 4E gene has not been introduced, and the eIF (iso) 4E gene has no mutation.
- RNA interference RNA interference
- microRNA microRNA
- VIGS ribozyme
- homologous recombination and dominant negative gene.
- a method using expression of the product and the like can be mentioned. Specifically, it is produced by introducing a factor that suppresses the expression level of the eIF (iso) 4E gene to 20% or less, preferably 15% or less, more preferably 10% or less compared to the wild type. be able to.
- RNAi is preferable as a method for suppressing the expression of eIF (iso) 4E.
- the RNAi using the base sequence of the eIF (iso) 4E gene (eg, SEQ ID NO: 1) or a part thereof (eg, SEQ ID NO: 9), or the base sequence of SEQ ID NO: 2 or a part thereof, for example, as a trigger.
- a construct is made, fused with a plant-expressed promoter, and introduced into tobacco using a vector. Then, the virus-resistant tobacco in which the RNAi construct is expressed to suppress the expression of the eIF (iso) 4E gene is obtained. Accordingly, the virus resistant tobacco in one embodiment can retain an RNAi construct for suppressing expression of the eIF (iso) 4E gene.
- the length of the trigger can be, for example, 21 bases to the entire sequence length, but is preferably 50 bases or more, more preferably 100 bases or more.
- the trigger sequence may have one or more base substitutions, deletions or insertions.
- RNAi an RNAi construct in which the trigger sequence is inverted is produced by functionally linking one trigger sequence in the sense direction and the other in the antisense direction.
- a spacer sequence is preferably a sequence not included in the tobacco genome or a region not included in the mature mRNA such as an intron sequence. Examples of such sequences include, but are not limited to, intron sequences such as ⁇ -glucuronidase (GUS) gene and pyruvate dehydrogenase kinase (pdk) and catalase (cat) genes.
- GUS ⁇ -glucuronidase
- pdk pyruvate dehydrogenase kinase
- cat catalase
- promoters for transcription of RNAi constructs in plants include constitutive expression promoters such as cauliflower mosaic virus 35S RNA gene promoter, actin gene promoter, and ubiquitin gene promoter; Rubisco small subunit gene promoter, And green tissue-specific promoters such as and the PPDK gene promoter; and other organ or time-specific promoters.
- the promoter is preferably a promoter expressed in a virus-infected tissue.
- examples of the terminator include a cauliflower mosaic virus 35S RNA or 19S RNA gene terminator, a nopaline synthase gene terminator, and the like, but are not limited to these as long as they function in plants.
- a vector for introducing an RNAi expression cassette into a plant may incorporate a drug resistance gene expression cassette for selecting plant cells into which the expression cassette has been introduced.
- the drug resistance gene may be any drug resistance gene capable of selecting tobacco cells.
- a kanamycin resistance gene neomycin phosphotransferase: NPT-II
- hygromycin resistance gene hygromycin phosphotransferase: HPT
- the promoter is not particularly limited as long as it also expresses constitutively.
- RNAi expression cassette and the selection marker expression cassette must be present in T-DNA.
- a right border (RB) sequence and a left border (LB) sequence are arranged at both ends of the T-DNA as T-DNA border sequences.
- an expression cassette for fluorescent protein may be placed in T-DNA.
- the fluorescent protein include, but are not limited to, green fluorescent protein (GFP) and yellow fluorescent protein (YFP).
- GFP green fluorescent protein
- YFP yellow fluorescent protein
- a preferred fluorescent protein is GFP.
- the fluorescence can be observed with an image analyzer.
- Examples of vectors for introducing RNAi expression cassettes into plants and capable of introducing genes into tobacco include pBI and pSB systems (reference: Komari et al. 2006 Methods in Mol. Biol. 343: 15- 41.), pLC system (literature: US Pat. No. 8,298,819), pGreen (literature: Hellens et al. 2000 Plant Mol. Biol. 42: 819-832.), PHellsgate (literature: Wesley et al. 2001 Plant) J 27: 581-590.) And pSP231 (Document: International Publication No. 2011/102394), but not limited thereto.
- the method for introducing an RNAi expression cassette into a plant is not particularly limited, and is usually used by those skilled in the art, such as the method using Agrobacterium described above, the particle gun method, the PEG method, the electroporation method, or the agroinfiltration method. What is necessary is just to use the method to do.
- the type of tobacco tissue or organ to be introduced is not particularly limited as long as the plant body can be regenerated, and examples thereof include seeds, roots, leaves, and flowers.
- the drug used for selection include, but are not limited to, kanamycin and hygromycin.
- the concentration of the drug can be, for example, 20 mg / mL to 200 mg / mL, and preferably 50 mg / mL to 100 mg / mL.
- a culture medium for growing plant cultures may be a commonly used medium, and examples of inorganic salts include MS and LS.
- sucrose, agar, or plant hormones are added thereto. These use concentrations may be in accordance with protocols usually used by those skilled in the art.
- the method for analyzing gene expression and the virus assay method are as described above.
- the present invention also provides a method of conferring virus resistance to tobacco.
- a mutation that produces a non-functional translation initiation factor eIF (iso) 4E protein for the virus or suppresses expression of the translation initiation factor eIF (iso) 4E gene is translated into a translation initiation factor eIF.
- (Iso) To confer virus resistance to tobacco by introduction into the 4E gene. For methods for introducing such mutations, see [1. Virus resistant tobacco and its production method] column.
- the factor that suppresses the expression level of the translation initiation factor eIF (iso) 4E gene to 20% or less, preferably 15% or less, more preferably 10% or less compared to the wild type.
- the virus resistance is imparted to tobacco. For the method of introducing such factors, see [1. Virus resistant tobacco and its production method] column.
- a DNA marker can be developed using a mutation generated on the tobacco eIF (iso) 4E gene, and can be used for marker breeding.
- a “DNA marker” is a tool for detecting a difference (mutation or polymorphism) in DNA base sequence between varieties or individuals, or a difference between them, and a base serving as a mark for identifying a variety or individual Refers to a sequence difference (mutation or polymorphism) or a tool for detecting the difference.
- a marker that can be used for identifying the causative mutation can be designed on the eIF (iso) 4E gene. Since the relationship between the mutation and virus resistance is not broken by genetic separation, precise marker breeding is possible. If the presence or absence of this mutation is detected, it is not necessary to confirm the virus resistance once at a time when the mating is repeated.
- Extraction of genomic DNA from tobacco may be based on a conventional method, and a commercially available extraction kit may be used, but is not particularly limited.
- the genomic DNA may be a crude product or a purified product that has undergone several purification steps.
- a technique for detecting the presence or absence of a mutation for example, a technique that applies hybridization of a nucleic acid (also referred to as “polynucleotide”) using RFLP or single-stranded DNA as a probe, and amplification of a polynucleotide such as PCR, etc.
- PCR amplification of a polynucleotide
- the polynucleotide can be amplified by, for example, the PCR method, but may be performed by other known gene amplification methods, for example, the LCR method, the SDA (Strand Displacement Amplification) method, the LAMP method, or the like.
- the length of each polynucleotide to be amplified is not particularly limited as long as various detection methods described below can be used.
- the length is preferably 40 bases to 5000 bases, and preferably 100 bases to 1000 bases. Is more preferably 100 bases to 700 bases, and even more preferably 100 bases to 500 bases.
- the primer sequence for amplifying each polynucleotide is preferably designed so as to sandwich or include the mutation site, but the position for designing the primer sequence is not particularly limited.
- the length of the primer is preferably 15 to 30 bases, particularly preferably 17 to 25 bases.
- the sequence may contain one or more substitutions, deletions, and / or additions.
- the primer may be labeled with a fluorescent substance or a radioactive substance as necessary.
- the detected mutation is a mutation that causes production of non-functional eIF (iso) 4E protein or suppresses expression of the eIF (iso) 4E gene. Specific examples are given in [1. Virus resistant tobacco and its production method] column.
- a method (CAPS (Cleaved Amplified) for determining the presence or absence of cleavage after treatment with a restriction enzyme that specifically recognizes the sequence at the mutation site (sequence before mutation or sequence after mutation) on the amplified polynucleotide. Polymorphic Sequence) method).
- a dCAPS (derived CAPS) method in which a restriction enzyme recognition site is produced by a primer set including a deliberately designed mismatch primer may be used.
- An example of such a primer set is shown in SEQ ID NO: 45 as a primer for detecting a C ⁇ T mutation at the 330th base of the base sequence of the S-type eIF (iso) 4E gene shown in SEQ ID NO: 7.
- Examples include, but are not limited to, a nucleic acid consisting of a base sequence and a nucleic acid set consisting of the base sequence shown in SEQ ID NO: 46.
- mismatched primers such as the base sequence shown in SEQ ID NO: 46, amplification efficiency may not be good.
- a primer having no mismatches is designed at a site outside the target sequence (in the above case, for example, a set of nucleic acid primers consisting of the nucleotide sequences shown in SEQ ID NOs: 25 and 26), PCR is performed once in advance, a part of the PCR product is used as a template, and reamplified with a mismatch primer, and the obtained PCR product Mutations may be detected by treating with a restriction enzyme.
- a primer set containing the said mismatch primer as a primer for detecting the G-> A variation
- examples include, but are not limited to, a nucleic acid set consisting of the base sequence shown in No. 47 and a nucleic acid set consisting of the base sequence shown in SEQ ID No. 48.
- amplification efficiency may not be good.
- a primer having no mismatch is designed at a site outside the target sequence (in the above case, for example, a set of nucleic acid primers consisting of the nucleotide sequences shown in SEQ ID NOS: 31 and 32), PCR is performed once in advance, a part of the PCR product is used as a template, and reamplified with a mismatch primer, and the obtained PCR product Mutations may be detected by treating with a restriction enzyme.
- primer sequences can be designed via the web (reference: Neff et al. (2002) Web-based primer design for single nucleotide polymorphism analysis. TRENDS in Genetics 18: 613-615).
- a mismatch primer is used in the dCAPS method
- a DNA polymerase having no proofreading activity is preferable.
- such a DNA polymerase includes TaKaRa Taq TM (Takara Bio Inc.).
- a restriction enzyme cleavage site is inserted near the 3 ′ end of the primer, the presence or absence of cleavage is detected as a difference in the length of the primer.
- the analysis method is not particularly limited, and for example, PCR using the TaqMan (registered trademark) probe method, MassARRAY (registered trademark) analysis which is a measurement technique using TOF-MS, or the like can be used.
- a primer sequence is designed by partially including the sequence of the mutation site (pre-mutation sequence and / or post-mutation sequence), and amplified by the PCR method, etc. Detection method (allyl-specific PCR method).
- a primer for example, as a primer for detecting a C ⁇ T mutation at the 330th base in the base sequence of the S-type eIF (iso) 4E gene shown in SEQ ID NO: 7, the base shown in SEQ ID NO: 37
- examples include, but are not limited to, a nucleic acid set consisting of a sequence and a nucleic acid set consisting of a base sequence shown in SEQ ID NO: 39.
- a nucleic acid primer consisting of the base sequence shown in SEQ ID NO: 38 specific to the base sequence before mutation can be used as a control.
- a nucleic acid comprising the base sequence shown in SEQ ID NO: 40 examples include, but are not limited to, a nucleic acid set consisting of the base sequence shown in SEQ ID NO: 42.
- a nucleic acid primer having the base sequence shown in SEQ ID NO: 41 specific to the base sequence before mutation can be used as a control.
- the position is preferably at the end or between several bases from the end.
- a target mutation is introduced near the 3 'end of the primer, a wild-type sequence without mutation may be amplified in addition to the mutant-type sequence.
- a mismatch other than the target mismatch is introduced at the same position in the mutant detection primer and the wild type detection primer (for example, the bases shown in lower case letters of SEQ ID NOs: 38, 39, 41 and 42).
- PCR may be performed to obtain mutant or wild type specific amplification.
- a primer for the gene that is an internal standard for PCR (for example, consisting of the nucleotide sequences shown in SEQ ID NOs: 43 and 44) is added to the PCR reaction solution. Also good.
- JPO website ⁇ http://www.jpo.go.jp/shiryou/s_sonota/hyoujun_gijutsu/kakusan/0025.html >.
- gene mutation detection and analysis methods are described in detail in the following document: JPO website ⁇ http://www.jpo.go.jp/shiryou/s_sonota/hyoujun_gijutsu/kakusan/0028 .html>.
- literature Agarwal et al. (2008) Advances in molecular marker techniques and their applications in plant sciences. Plant Cell Rep. 27: 617-631., Neff et al. (1998) dCAPS, a simple technique for the gen You may also refer to of single nucleotide polymorphisms: experimental applications in Arabidopsis thaliana genetics. Plant J. 14: 387-392.
- the present invention provides a polynucleotide for detecting a mutation in the eIF (iso) 4E gene.
- the mutation is a mutation that produces a non-functional eIF (iso) 4E protein with respect to a virus or suppresses expression of the eIF (iso) 4E gene. Specific examples are given in [1. Virus resistant tobacco and its production method] column.
- one form of the detection polynucleotide is a nucleic acid primer or a set of nucleic acid primers.
- the set of nucleic acid primers may be a set of nucleic acid primers sandwiching the mutation, or a set of nucleic acid primers including a polynucleotide comprising a continuous base sequence containing the mutation or a complementary sequence thereof.
- Another form of the detection polynucleotide is a nucleic acid probe that hybridizes to a continuous base sequence containing the mutation or a complementary sequence thereof.
- the present invention also provides a method for determining the resistance of tobacco to viruses, characterized in that the mutation in the eIF (iso) 4E gene in the genomic DNA of tobacco is used as an indicator of virus resistance. provide.
- the present invention also provides a kit for determining the resistance of a cigarette to viruses, comprising a set of nucleic acid primers for detecting the mutation in the eIF (iso) 4E gene.
- the present invention also provides a kit for determining the resistance of tobacco to viruses, comprising a probe that hybridizes to a continuous nucleotide sequence containing the mutation in the eIF (iso) 4E gene or a complementary sequence thereof. To do.
- the present invention also provides a method for breeding virus-resistant tobacco, comprising a selection step of selecting tobacco resistant to viruses using the determination method.
- the present invention also provides an inspection step for examining the presence or absence of the mutation in genomic DNA using the detection polynucleotide in tobacco, and selecting the tobacco in which the mutation is detected in the inspection step as a virus-resistant tobacco.
- the present invention also provides a DNA marker for determining resistance to tobacco, which comprises a polynucleotide comprising a continuous base sequence containing the mutation in the eIF (iso) 4E gene or a complementary sequence thereof. .
- Leaf tobacco produced by cultivating the virus-resistant tobacco of the present invention does not suffer from diseases caused by the virus (for example, PVY strain or TBTV that breaks the virus resistance of Virgin A mutant). Therefore, especially when cultivated in an environment where the disease occurs, quality deterioration is reduced and high quality compared with leaf tobacco produced by cultivating tobacco that is not virus resistant. As a result, higher quality tobacco products can be produced.
- diseases caused by the virus for example, PVY strain or TBTV that breaks the virus resistance of Virgin A mutant. Therefore, especially when cultivated in an environment where the disease occurs, quality deterioration is reduced and high quality compared with leaf tobacco produced by cultivating tobacco that is not virus resistant. As a result, higher quality tobacco products can be produced.
- Leaf tobacco refers to raw tobacco leaves that have been harvested and dried and used as a raw material for the manufacture of tobacco products.
- tobacco products refers to cigarettes (with and without filters) (CIGARETTE), cigars (CIGAR), cigarillos (CIGARILLO), snus (SNUS), snuff (SNUFF), chewing tobacco, electronic cigarettes, etc. .
- the present invention provides leaf tobacco produced from the above virus-resistant tobacco.
- the present invention also provides a tobacco product containing the above leaf tobacco as a raw material.
- One aspect of the virus-resistant tobacco according to the present invention has a mutation in the translation initiation factor eIF (iso) 4E gene, and thereby a non-functional translation initiation factor eIF (iso) 4E protein against the virus. Or the expression of the translation initiation factor eIF (iso) 4E gene is suppressed.
- the mutation is preferably a nonsense mutation.
- the mutation is (a) initiation of translation of a wild type encoding a translation initiation factor eIF (iso) 4E protein consisting of the amino acid sequence shown in SEQ ID NO: 3 or SEQ ID NO: 4.
- the mutation is shown in the following (1) to (27) of the translation initiation factor eIF (iso) 4E gene consisting of the nucleotide sequence shown in SEQ ID NO: 7 in genomic DNA.
- the mutation is shown in the following (1) to (26) of the translation initiation factor eIF (iso) 4E gene consisting of the nucleotide sequence shown in SEQ ID NO: 8 in genomic DNA.
- the mutation is (a) a wild-type translation initiation factor eIF (iso) encoding a translation initiation factor eIF (iso) 4E protein consisting of the amino acid sequence shown in SEQ ID NO: 3.
- the virus may be a virus Umbravirus genus.
- the Umbravirus genus virus is preferably Tobaccobbushy top virus.
- the mutation is (a) a wild-type translation initiation factor eIF (iso) encoding a translation initiation factor eIF (iso) 4E protein consisting of the amino acid sequence shown in SEQ ID NO: 4.
- the virus may be a virus Potyvirus genus.
- the above-mentioned virus belonging to the genus Potyvirus is preferably a line of Potato virus Y, which breaks the virus resistance of Virgin A mutant of tobacco.
- Another aspect of the virus-resistant tobacco according to the present invention is characterized in that the expression level of the translation initiation factor eIF (iso) 4E gene is 20% or less compared to the wild type.
- the expression level is more preferably 10% or less compared to the wild type.
- an RNAi construct for suppressing the expression of the translation initiation factor eIF (iso) 4E gene may be retained.
- One aspect of the method for producing a virus-resistant tobacco according to the present invention is to produce a translation initiation factor eIF (iso) 4E protein that is non-functional with respect to a virus, or to express the expression of a translation initiation factor eIF (iso) 4E gene. It is characterized by producing a tobacco having resistance to a virus by introducing a mutation that suppresses it into the translation initiation factor eIF (iso) 4E gene.
- the mutation is preferably a nonsense mutation.
- the mutation is caused by ethylmethanesulfonic acid.
- the mutation is a wild type encoding a translation initiation factor eIF (iso) 4E protein consisting of the amino acid sequence shown in (a) SEQ ID NO: 3 or SEQ ID NO: 4.
- the mutation is the following (1) to (27) of the translation initiation factor eIF (iso) 4E gene consisting of the nucleotide sequence shown in SEQ ID NO: 7 in genomic DNA.
- the mutation is the following (1) to (26) of the translation initiation factor eIF (iso) 4E gene consisting of the base sequence shown in SEQ ID NO: 8 in genomic DNA.
- Another aspect of the method for producing a virus-resistant tobacco according to the present invention is to introduce a factor that suppresses the expression level of the translation initiation factor eIF (iso) 4E gene to 20% or less compared to the wild type. It is characterized by producing a cigarette having resistance to the above.
- the factor is preferably an RNAi construct.
- the virus is preferably a virus belonging to the genus Potyvirus.
- the virus belonging to the genus Potyvirus is more preferably Potato virus Y.
- the virus belonging to the genus Potyvirus is a line of Potato virus Y, and is a strain that breaks the virus resistance of tobacco Virgin A mutant (VAM tobacco). More preferred.
- the virus is preferably a virus belonging to the genus Umbravirus.
- the Umbravirus genus virus is more preferably Tobaccobbushy top virus.
- One embodiment of the polynucleotide for detection according to the present invention is a polynucleotide for detecting a mutation in the tobacco translation initiation factor eIF (iso) 4E gene, and the mutation is a non-functional translation for a virus.
- the mutation is preferably a nonsense mutation.
- the mutation is (a) initiation of wild-type translation encoding a translation initiation factor eIF (iso) 4E protein consisting of the amino acid sequence shown in SEQ ID NO: 3 or SEQ ID NO: 4.
- the mutation is shown in the following (1) to (27) of the translation initiation factor eIF (iso) 4E gene consisting of the nucleotide sequence shown in SEQ ID NO: 7 in genomic DNA.
- the mutation is shown in the following (1) to (26) of the translation initiation factor eIF (iso) 4E gene consisting of the nucleotide sequence shown in SEQ ID NO: 8 in genomic DNA.
- One embodiment of the polynucleotide for detection according to the present invention is a set of nucleic acid primers sandwiching the mutation, or a set of nucleic acid primers including a polynucleotide comprising a continuous base sequence containing the mutation or a complementary sequence thereof.
- the presence or absence of the mutation in genomic DNA is examined using the detection polynucleotide according to any one of claims 27 to 32.
- the method includes an inspection step and a selection step of selecting, as a virus-resistant tobacco, the tobacco in which the mutation is detected in the inspection step.
- One aspect of the DNA marker for determining the resistance of tobacco comprises a polynucleotide comprising a continuous base sequence containing a mutation in the translation initiation factor eIF (iso) 4E gene or a complementary sequence thereof,
- the mutation is characterized in that it produces a non-functional translation initiation factor eIF (iso) 4E protein or suppresses the expression of the translation initiation factor eIF (iso) 4E gene.
- BLAST analysis using WGS (Whole-genome shotgun contigs) in the GenBank database revealed that eIF (iso) 4E whose accession number is AY699609 is derived from Nicotiana sylvestris. Further, two NicoBank accession numbers EB683576 (SEQ ID NO: 2) and FN666434 were identified as Nicotiana tabacum eIF (iso) 4E derived from Nicotiana menttomentosiformis. These genes or their sequence information were used in the following experiments.
- FN666434 is a sequence derived from the T-type eIF (iso) 4E gene derived from tobacco variety Samsun NN, and the sequence identity with the above-described sequence of T-type eIF (iso) 4E derived from tobacco variety K326 (EB683576) is 97%. The identity of the amino acid sequences of the proteins encoded by these two genes was 97%, and the similarity was 99%. These sequence differences were thought to be due to differences between the cultivars from which they were derived. Further, the DNA sequence identity between the S-type eIF (iso) 4E (AY699609) and the T-type eIF (iso) 4E (EB683576) was 91%.
- amino acid sequence of S-type eIF (iso) 4E (SEQ ID NO: 3) and the amino acid sequence of T-type eIF (iso) 4E (SEQ ID NO: 4) were 91% and the similarity was 96%. It was.
- nucleic acid / amino acid sequence analysis software GENETYX registered trademark (ver. 12) (Genetics) was used.
- RNAi constructs In order to produce eIF4E1 expression-suppressed tobacco and eIF (iso) 4E expression-suppressed tobacco, RNAi constructs using the internal sequences of these genes as a trigger were constructed.
- primers that specifically amplify the trigger sequence (SEQ ID NO: 11) of eIF4E1 and the trigger sequence (SEQ ID NO: 9) of eIF (iso) 4E were prepared (Table 1).
- a CACC sequence for use in cloning described later is added to the 5 'end of the FW primer of each gene.
- PCR product (about 320 bp for eIF4E1 and about 310 bp for eIF (iso) 4E) was purified using MiniElute PCR Purification kit (Qiagen), and then vector pENTR TM / D-TOPO (registered trademark) (Life Technologies) Cloned into. After confirming the base sequence of the insert, RNAi vector pSP231 (reference: International Publication No. 2011/102394) is used using GateWay (registered trademark) LR Clonase (registered trademark) II Enzyme mix (Life Technologies). The insert was cloned.
- pSP231 is a vector in which a GFP (Green-fluorescent protein gene) expression cassette is inserted into the SacI site of pHellsgate 12 (reference: Wesley et al., 2001, Plant J., 27, 581-590).
- GFP Green-fluorescent protein gene
- This is a binary vector in which an inverted repeat is driven by a cauliflower mosaic virus 35 SRNA gene promoter, which is an RNAi sequence sandwiching the pdk / cat intron. After cloning into pSP231, the RNAi trigger sequence and its orientation were confirmed and used as the final RNAi construct.
- the prepared RNAi construct was introduced into Agrobacterium LBA4404 strain by electroporation.
- Tobacco transformation Tobacco transformation was performed by a conventional method (leaf disc method). The tobacco variety Petit Havana SR1 was used.
- the selection of recombinants was performed on a medium containing 50 mg / L kanamycin in an LS medium containing Cefotaxime and a plant hormone at the above concentrations.
- Shoots re-differentiated from the selected recombinants were rooted in a rooting medium (LS solid medium containing 1.5% sucrose, 0.3% gellan gum, and Cefotaxime and kanamycin at the above concentrations).
- the resulting recombinant tobacco was grown in a greenhouse.
- amplification reaction was performed using TaqMan Fast Advanced Master mix (Life technologies). The reaction conditions were 50 ° C.
- StepOne Software v2.2 (Life technologies) was used.
- the elongation factor1-alpha (EF1- ⁇ ) gene was used as an internal standard for PCR, and the relative gene expression level of the target gene was calculated by comparison with the expression level of this gene.
- Non-recombinant tobacco (SR1) was used as a control.
- the amount of the transcript of the tobacco eIF4E1 gene into which the RNAi construct of eIF4E1 was introduced, and the amount of the transcript of the tobacco eIF (iso) 4E gene into which the RNAi construct of eIF (iso) 4E was introduced were expressed in the control expression. It was much lower than the amount.
- lines that had a high degree of transcription repression at the time of transformation in eIF4E1, # 1, # 2, # 3, # 7, and # 8 (1%, 1%, 1%, 36%, %, And three lines of # 1, # 7 and # 15 (4%, 6% and 5% expression levels of SR1, respectively) were selected in eIF (iso) 4E.
- RNAi constructs In young plants, those that emit strong GFP fluorescence are homozygous for RNAi constructs, those that do not have any fluorescence are null-separated lines for RNAi constructs (no RNAi constructs are present), and those that emit weak fluorescence are hemizygous for RNAi constructs It was judged as a strain. Three weeks after sowing, the plants were transferred to a greenhouse, replanted in culture soil and grown.
- RNA was extracted from the leaves of the recombinant tobacco as described above to synthesize cDNA, and used as a template for real-time PCR.
- Real-time PCR was also performed as described above, using the EF1- ⁇ gene as an internal standard and non-recombinant tobacco (SR1) as a control plant.
- PVY-N Virus inoculation test of recombinant tobacco plants with suppressed transcription initiation factor transcription
- TBTV Tobacco bushy top virus
- PVY-B is a virus strain isolated at the Japan Tobacco Inc. Leaf Tobacco Research Institute, and is a VAM breaking strain that causes gangrene symptoms in the existing tobacco variety Varigin A mutant that is PVY resistant.
- TBTV is a virus of the genus Umbravirus that causes mottling symptoms on tobacco leaves.
- As an inoculum diseased leaves of yellow seed Tsukuba No. 1 infected with each virus were used. Variety Tsukuba No.
- the collected diseased leaves were ground with 0.01 N phosphate buffer in a mortar.
- the ground solution was smeared with carborundum on the half leaf of the largest leaf (fourth or fifth from the bottom) of the tobacco seedling one week after transplantation. Then, it was cultivated in a greenhouse and observed for timely disease symptoms.
- Table 3 shows the virus inoculation test results of eIF (iso) 4E function-suppressed tobacco.
- Example 2 Selection of eIF (iso) 4E tobacco mutant
- S-type eIF (iso) 4E AY699609
- T-type eIF (iso) 4E EB683576
- sequence of the eIF (iso) 4E gene portion is represented by SEQ ID NO: 7 (genomic sequence of S-type eIF (iso) 4E gene) and SEQ ID NO: 8 (genome of T-type eIF (iso) 4E gene). Sequence). Both sequences are genomic sequences from tobacco variety K326.
- FIG. 2 shows a schematic diagram of the exon / intron structure of the S-type eIF (iso) 4E gene.
- FIG. 3 shows a schematic diagram of the exon / intron structure of the T-type eIF (iso) 4E gene. 2 and 3, the numbers described in the lower part indicate the number of candidate sites of nonsense mutations that can be caused by the G to A mutation or the C to T mutation caused by the EMS treatment, and the arrows in the examples The position of the primer is indicated.
- the number of bases that can become a stop codon due to the mutation from G to A or C to T caused by the EMS treatment is 12 (the 270th position of SEQ ID NO: 7).
- the first exon has 11 (the 264th eye C of the sequence number 8, the 289th G, the 290th G, the 298th G, the 299th G, 315 th C, 328 th G, 329 th G, 342 th C, 379 th G, 380 th G), 7 in the second exon (1630 th C, 1703 th G, 1704 G, 1736th G, 1737th G, 1778th G, 1779th G), 5 for the 3rd exon (1940th C, 1994th C, 2013th G, 2014th) G, 2042nd C), 2 for the 4th exon (3224th G, 3225th G), and 1 for the 5th exon (3406th C).
- PCR was performed to confirm the base sequence of the product.
- PCR was performed in a 20 ⁇ L reaction system using 5 ng of tobacco (variety Tsukuba No. 1) genome.
- Tks Gflex TM DNA Polymerase (Takara Bio Inc.) was used. The reaction was carried out 40 times after a cycle of 94 ° C. for 30 seconds, 60 ° C. for 30 seconds and 72 ° C. for 1 minute 30 seconds at 94 ° C. for 2 minutes. As a result, only a product having a desired length was obtained, and the base sequence could be confirmed. That is, S type-specific and T-type specific eIF (iso) 4E gene regions were successfully amplified from the tobacco genome using the above primers.
- Genomic DNA is extracted from an individual having a mutation caused by EMS treatment, and S-type-specific and T-type-specific eIF (iso) 4E gene regions are amplified by PCR using the above primers, and the base sequence of the amplified product is determined.
- S-type-specific and T-type-specific eIF (iso) 4E gene regions are amplified by PCR using the above primers, and the base sequence of the amplified product is determined.
- an eIF (iso) 4E tobacco mutant in which a stop codon was generated in the first exon, the second exon, or the third exon was selected.
- a tobacco mutant panel prepared by Nagima et al. (Reference: 2011 Annual Meeting of the Japanese Society for Plant Pathology, P234, Production of Tobacco Mutant Panel) was selected.
- This panel shows that the seeds (thousands) of tobacco varieties Tsukuba No. 1 were subjected to EMS treatment as a mutagen treatment, and the mutant self-pollinated progeny seeds (M2 bulk) obtained for each individual grown (M1 generation) Seeds) and a set of bulk DNA extracted from the seedlings of 8 individual strains sowed and grown with these M2 seeds.
- Samples in which a nonsense mutation (mutation in which a stop codon occurred) were detected were 4 samples in Exon 1 (295th, 394th or 395th G of SEQ ID NO: 7 was mutated to A, and 330th C was mutated to T), One sample of Exon 2 and Exon 3 (1814th G of SEQ ID NO: 7 was mutated to A).
- M2 seeding the strain (M2) in which 330th C is mutated to T, extracting DNA from 24 individuals and determining the base sequence, individuals having the target mutation homozygous (eIF (iso)) 11 individuals of 4E_S type mutant homozygote) were obtained.
- T-type mutant of eIF (iso) 4E gene Selection of T-type mutant of eIF (iso) 4E gene
- DNA sample DNA samples for 1974 strains
- T-type eIF (iso) 4E-Exon 1 combination 1 SEQ ID NOs: 31 and 32
- T-type eIF (iso) 4E -PCR was performed using Exon 2 & 3 combination 2 (SEQ ID NO: 34 and 36).
- mutations were detected in 43 samples (38 locations) for Exon 1 and 66 samples (55 locations) for Exon 2 and Exon 3. All mutations were heterozygous.
- Samples in which a nonsense mutation was detected were 5 samples in Exon 1 (289th, 299, 328, 329, or 380th G of SEQ ID NO: 8 was mutated to A), 4 samples in Exon 2 and Exon3 (1704 in SEQ ID NO: 8) The 3rd G was mutated to A, and the 1737th G was mutated to A).
- the strain (M2) in which the 299th G was mutated to A DNA was extracted from 24 individuals and the nucleotide sequence was determined.
- an individual having the target mutation homozygous eIF (iso) 4E_T type mutation
- Eight homozygotes were obtained.
- DNA extraction was performed as follows. A tobacco leaf sample (1 cm ⁇ 1 cm) is placed in a 2 mL tube, and 400 ⁇ L of an extract (composition is 200 mM Tris-HCl (pH 7.5), 250 mM NaCl, 25 mM EDTA, 0.5% SDS) and 200 ⁇ L Protein Precipitation Solution. (QIAGEN) was added, and then metal corn was added for crushing, followed by centrifugation at 13,000 rpm for 10 minutes. 300 ⁇ L of the supernatant was transferred to a new 1.5 mL tube, and 800 ⁇ L of 100% ethanol was added and mixed by inversion. After centrifugation at 15000 rpm for 10 minutes, the supernatant was completely removed. After confirming that the pellet was dry, 50 ⁇ L of TE (10 mM Tris-HCl (pH 7.5), 1 mM EDTA) was added.
- composition is 200 mM Tris-HCl (pH 7.5), 250 mM NaCl
- An ASP (Allele Specific primer) marker was designed as a PCR marker.
- a primer in which a single nucleotide polymorphism (SNP) is arranged on the 3 ′ end side of the primer sequence is designed so that a PCR product can be obtained only from a sample having a specific polymorphism, and a mismatch from other samples. This is a marker utilizing the fact that a PCR product cannot be obtained.
- the prepared primers are as shown in Table 5.
- a primer mix for detecting a wild type (WT) eIF (iso) 4E gene without mutation was prepared.
- the composition is such that F and R of eIF (iso) 4E_S_WT are 10 ⁇ M each, F and R of eIF (iso) 4E_T_WT are 10 ⁇ M each, Nia2 gene (control, literature: Vincentz and Caboche (1991) Constitutive expression of nitrate reductase allows normal growth F and R of EMBO J. 10: 1027-1035.) are 1 ⁇ M each.
- a primer mix for detecting a mutant (Mut) eIF (iso) 4E gene was prepared.
- composition is such that F and R of eIF (iso) 4E_S_Mut are 10 ⁇ M each, F and R of eIF (iso) 4E_T_Mut are 10 ⁇ M each, and F and R of the Nia2 gene (control) are 1 ⁇ M each.
- Each of these primer mixes was subjected to PCR for detecting wild-type (WT) eIF (iso) 4E gene and PCR for detecting mutant-type (Mut) eIF (iso) 4E gene. PCR conditions are as follows.
- PCR was carried out in a 10 ⁇ L system by mixing 1 ⁇ L of a DNA solution adjusted to 5 ng / ⁇ L, 1 ⁇ L of a WT or Mut detection primer mix, 3 ⁇ L of sterilized water, and 5 ⁇ L of Multiplex PCR 2 ⁇ Master Mix (QIAGEN). PCR was performed at 95 ° C. for 15 minutes once, 94 ° C. for 30 seconds, 59 ° C. for 1 minute 30 seconds, and 72 ° C. for 1 minute 40 times and 72 ° C. for 10 minutes once. PCR products were detected by electrophoresis using QIAxcel (Qiagen).
- genotype ssTT no amplification product is seen with eIF (iso) 4E_S_WT primer, amplification product is detected with eIF (iso) 4E_T_WT, and amplification product is detected with eIF (iso) 4E_S_Mut, but not with eIF (iso) 4E_T_Mut
- genotype ssTT only the S-side was mutated.
- the genotype sst was a mutant type on both the S side and the T side. Note that the faint band seen in the rightmost lane (for Mut detection, SSTT) in FIG. 4 was considered to be an artifact.
- both eIF (iso) 4E_ST homozygous mutants S / T bilateral mutant homozygote, genotype is sst
- control eIF (iso) 4E_wild type individuals S / T bilateral wild type individuals, genotype SSTT
- eIF (iso) 4E_S variant and eIF (iso) 4E_T variant The above-mentioned eIF (iso) 4E_S type mutant (having a homozygous mutation in the S type eIF (iso) 4E gene.
- the genotype is ssTT), or the eIF (iso) 4E_T type mutant (T type eIF (iso) )
- the 4E gene has a homozygous mutation.
- the genotype was SStt), and seeds were propagated by obtaining progeny progeny. Part of the obtained progeny seeds is grown, DNA is extracted as described above, polymorphism analysis is performed using a DNA marker, and it is confirmed that each of the S-side and T-side mutations is homozygous. did.
- these seeds confirmed to be mutated are eIF (iso) 4E_S type mutant NtS1 and eIF (iso) 4E_T type NtT1, and the National Institute of Technology and Evaluation, Biological Information Center (Japan) 292-0818, Kisarazu City, Chiba Prefecture, Kazusa Kamashika 2-5-8, Room 120).
- the accession numbers are FERM BP-22284 (trust date: February 25, 2015) and FERM BP-22285 (trust date: February 25, 2015), respectively.
- a dCAPS marker was developed as a DNA marker with higher detection accuracy for detecting a polymorphism of the eIF (iso) 4E gene.
- the polymorphism can be discriminated by detecting the difference in fragment length after the restriction enzyme treatment. This is called a CAPS marker or PCR-RFLP marker.
- This mutation occurring in the eIF (iso) 4E gene (S-type, 330th C in SEQ ID NO: 7 is mutated to T, 299th G in SEQ ID NO: 8 is mutated to A in T-type) This sequence did not contain a restriction enzyme recognition sequence.
- a restriction enzyme site was artificially introduced near the SNP (single nucleotide polymorphism) when designing primers used in PCR.
- SNP single nucleotide polymorphism
- a mutation of two nucleotides was required to become a restriction site (Nla III: CATG for S type, Mbo I: GATC for T type) in the mutant type gene, but a restriction site in the wild type gene.
- a single base mutation was enough to become. Therefore, in this example, a dCAPS marker was prepared by introducing a single nucleotide mutation so that it was cut with the restriction enzyme in the wild type but not with the mutant type. In this case, the difference in fragment length is detected as a difference corresponding to the length of the primer.
- the prepared primers are as shown in Table 6.
- the next base of CaT on the 3 ′ end side is G in the wild-type template DNA and Nla III site (CATG), but is A in the mutant template DNA, and is a restriction site.
- the next base of GAt on the 3 ′ end side is C in the wild type template DNA and Mbo I site (GATC), but is T in the mutant template DNA, which is a restriction site.
- GTC wild type template DNA and Mbo I site
- PCR was performed using genomic DNA as a template using Tks Gflex TM DNA Polymerase (manufactured by Takara Bio Inc.) having proofreading activity, and no polymorphism was detected in the product subjected to restriction enzyme treatment.
- Tks Gflex TM DNA Polymerase manufactured by Takara Bio Inc.
- no polymorphism was detected in the product subjected to restriction enzyme treatment.
- TaKaRa Taq TM Takara Bio
- eIF (iso) 4E_S is cleaved with the restriction enzyme NlaIII only when it contains a wild-type SNP
- eIF (iso) 4E_T is cleaved with the restriction enzyme MboI only when it contains a wild-type SNP. so that in, it was designed a mismatch in the primer of the 2 nd PCR.
- primer concentrations were prepared so that 1 [mu] M, the buffer used was attached to the enzyme.
- PCR was performed at 94 ° C. for 2 minutes once, 94 ° C. for 30 seconds, 52 ° C. for 30 seconds, and 72 ° C. for 30 seconds for 40 cycles and 72 ° C. for 90 seconds once.
- 2 nd PCR product of eIF (iso) 4E_S was treated with Nla III (New England Biolabs, Inc.).
- 2 nd PCR product of eIF (iso) 4E_T were treated with the Mbo I (Takara Bio).
- the genotype of a sample that did not cleave with the eIF (iso) 4E_S primer and cleaved with the eIF (iso) 4E_T primer is ssTT
- cleaved with the eIF (iso) 4E_S primer and eIF (iso) 4E_T primer The genotype of the sample that does not cleave with the primer is SStt
- the genotype of the sample that cleaves with both primers is SSTT
- the genotype of the sample that does not cleave with both primers is sstt
- this dCAPS marker can also be used to identify the genotype of an individual in which a mutation has occurred in the tobacco eIF (iso) 4E gene, like the above ASP marker.
- EIF (iso) 4E_S type mutant (ssTT), eIF (iso) 4E_T type mutant (SStt), eIF (iso) 4E_ST both homo mutants (sstt), and eIF (iso) 4E_ RNA was extracted from the wild type strain (SSTT) in the same manner as described above, cDNA was synthesized, and quantitative PCR was performed.
- SEQ ID NOs: 19, 20, and 21 shown in Table 2 were used for the S-type eIF (iso) 4E gene.
- SEQ ID NOs: 49, 50 and 51 shown in Table 6 were newly designed and used in experiments.
- the expression level of the eIF (iso) 4E gene is shown as a relative expression level when the average value of the transcript amount of the strain having the genotype SSTT is 1.
- the horizontal axis shows the genotype of each mutant, and the number of individuals analyzed is shown in parentheses.
- the vertical axis represents the relative average value of the transcript amount in the line having each genotype, and the bar represents the standard deviation.
- the amount of transcript of S-type eIF (iso) 4E gene was 73% of the control, whereas no transcript of T-type eIF (iso) 4E gene was detected.
- SStt specifically suppresses the expression of T-type eIF (iso) 4E gene
- ssTT specifically suppresses the expression of S-type eIF (iso) 4E gene
- sstt specifically suppresses S-type and T-type. It was revealed that the expression of both types of eIF (iso) 4E genes was suppressed.
- NMD nonsense-mediated mRNA-decay
- Virus inoculation test to eIF (iso) 4E tobacco mutant Individuals 2 weeks after transplantation to the culture medium were inoculated with PVY-B (Potato virus Y VAM breaking strain) or TBTV (Tobacco bushy top virus). The production of the virus inoculation source and the method of inoculating tobacco were carried out in the same manner as in Example 1. After inoculation, the plant was cultivated in a greenhouse and observed for symptoms as appropriate. Tables 8 and 9 show the virus inoculation test results of eIF (iso) 4E function-deficient mutant tobacco.
- a strain in which only T-type eIF (iso) 4E is deficient eIF (iso) 4E_T mutant strain, a homozygous mutation in the T-type eIF (iso) 4E gene, the genotype is SStt
- eIF (iso) 4E_T mutant strain a homozygous mutation in the T-type eIF (iso) 4E gene, the genotype is SStt
- eIF (iso) 4E_wild-type strain, the cultivar TN90 and the S-type eIF (iso) 4E are functionally deficient (eIF (iso) 4E_S-type). It is a mutant strain and has a homozygous mutation in the S-type eIF (iso) 4E gene (genotype is ssTT).
- PVY-B mainly uses T-type eIF (iso) 4E for the expression of disease symptoms such as proliferation and cell-to-cell migration, and the pathogenesis is suppressed by T-type eIF (iso). It was considered possible by suppressing the expression of 4E.
- a line in which only S-type eIF (iso) 4E is deficient is an eIF (iso) 4E_wild-type line (SSTT), cultivars TN90 and T-type.
- the pathogenesis was greatly suppressed as compared with a strain in which only eIF (iso) 4E was deficient in function (eIF (iso) 4E_T type mutant strain, SStt). From this, it is inferred that TBTV mainly uses S-type eIF (iso) 4E for symptom expression such as proliferation and cell-to-cell migration, and pathogenesis is suppressed by S-type eIF (iso) 4E. It was considered possible by suppressing the expression. In addition, no growth inhibition was observed in eIF (iso) 4E function-suppressed tobacco.
- PVY-B resistance can be imparted by suppressing the function of tobacco translation initiation factor eIF (iso) 4E, and by suppressing only T-type eIF (iso) 4E. It was shown that there is.
- TBTV resistance can be imparted by suppressing the function of tobacco translation initiation factor eIF (iso) 4E, and it can be achieved by suppressing only S-type eIF (iso) 4E. It was.
- the present invention can be used for tobacco breeding.
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Abstract
Description
本発明の一態様は、ウイルスに対して抵抗性を有するタバコ(ウイルス抵抗性タバコ)に関し、より具体的には、細胞内における、ウイルスに対して機能的な翻訳開始因子eIF(iso)4E遺伝子の発現量(例えば、転写物の量)が減少した、ウイルス抵抗性タバコに関する。また、本発明の別の一態様は、ウイルスに対して抵抗性を有するタバコを作出する方法(ウイルス抵抗性タバコ作出方法)に関し、より具体的には、細胞内における、ウイルスに対して機能的なeIF(iso)4E遺伝子の発現量(例えば、転写物の量)を減少させることによって、ウイルス抵抗性タバコを作出する方法に関する。
本発明に係るウイルス抵抗性タバコの一態様は、eIF(iso)4E遺伝子に変異を有しており、それによって、ウイルスに対して非機能的な翻訳開始因子eIF(iso)4Eタンパク質を生産するか、または翻訳開始因子eIF(iso)4E遺伝子の発現が抑制されているウイルス抵抗性タバコである。
(1)市販のシーケンサー等を利用し、各ポリヌクレオチドの塩基配列を直接読み取ることによって変異の有無を検出する方法。
(2)SSCP(Single Strand Conformation Polymorphism:一本鎖高次構造多型)法を用いて変異の有無を検出する方法。
本発明に係るウイルス抵抗性タバコの別の一態様は、eIF(iso)4E遺伝子の発現量が野生型と比較して20%以下であるウイルス抵抗性タバコである。発現が抑制されたタバコのeIF(iso)4E遺伝子の発現量は、野生型の発現量を100%とした場合、好ましくは15%以下、より好ましくは10%以下である。ここで、「野生型」とは、eIF(iso)4E遺伝子の発現を抑制させる因子が導入されておらず、かつ、eIF(iso)4E遺伝子に変異を有していないタバコを指す。
本発明はまた、タバコにウイルス抵抗性を付与する方法を提供する。
本発明では、タバコeIF(iso)4E遺伝子上に生じた変異を利用してDNAマーカーを開発することができ、それをマーカー育種に活用することができる。「DNAマーカー」とは、品種間または個体間におけるDNAの塩基配列の違い(変異または多型)、またはその違いを検出するためのツールであり、品種または個体を識別するための目印となる塩基配列の違い(変異または多型)、またはその違いを検出するためのツールのことを指す。eIF(iso)4E遺伝子における変異が確定し、その変異によってウイルスに抵抗性となることが確認された場合、その変異が生じたタバコ変異体を、当該ウイルス抵抗性の育種母本として利用することができる。その際、既に抵抗性に係る原因変異が分っているため、原因変異の識別に利用可能なマーカーをeIF(iso)4E遺伝子上に設計することができる。当該変異とウイルス抵抗性との関係が遺伝的分離によって切れることがないため、精密なマーカー育種が可能となる。この変異の有無を検出すれば、交配等を繰り返した際に、一回一回ウイルス抵抗性を確認する必要がない。
(1)市販のシーケンサー等を利用し、増幅したポリヌクレオチドの塩基配列を直接読み取ることによって変異の有無を検出する方法。
(2)SSCP(Single Strand Conformation Polymorphism)法を用いて、増幅したポリヌクレオチド上の変異の有無を検出する方法。
(3)増幅したポリヌクレオチドに対して、変異箇所の配列(変異前の配列または変異後の配列)を特異的に認識する制限酵素による処理後に、切断の有無により判定する方法(CAPS(Cleaved Amplified Polymorphic Sequence)法)。その他、意図的に設計したミスマッチプライマーを含むプライマーセットによって制限酵素認識部位を作製するdCAPS(derived CAPS)法を用いてもよい。そのようなプライマーセットとしては、例えば、配列番号7に示すS型のeIF(iso)4E遺伝子の塩基配列の330番目の塩基のC→T変異を検出するためのプライマーとして、配列番号45に示す塩基配列からなる核酸および配列番号46に示す塩基配列からなる核酸のセットが挙げられるが、これらに限定されない。また、配列番号46に示す塩基配列のように、ミスマッチプライマーを使用した場合、増幅効率が良くない場合があるが、そのような場合、標的配列の外側の部位にミスマッチのないプライマーを設計し(上記の場合、例えば配列番号25および26に示す塩基配列からなる核酸プライマーのセット)、予めPCRを一度行い、そのPCR産物の一部を鋳型に、ミスマッチプライマーで再増幅し、得られたPCR産物を制限酵素で処理することで変異を検出してもよい。
(4)変異部分に特異的にハイブリダイズするプローブを設計し、ハイブリダイズさせることで変異の有無を確認する方法。
(5)変異箇所の配列(変異前の配列および/または変異後の配列)を一部に含ませてプライマー配列を設計し、PCR法等によって増幅させることにより、増幅の有無によって変異の有無を検出する方法(アリル特異的PCR法)。そのようなプライマーとしては、例えば、配列番号7に示すS型のeIF(iso)4E遺伝子の塩基配列の330番目の塩基のC→T変異を検出するためのプライマーとして、配列番号37に示す塩基配列からなる核酸および配列番号39示す塩基配列からなる核酸のセットが挙げられるが、これらに限定されない。この場合、コントロールとして、例えば変異前の塩基配列に特異的な配列番号38に示す塩基配列からなる核酸プライマーを用いることができる。
本発明のウイルス抵抗性タバコを栽培して生産される葉たばこは、当該ウイルス(例えば、Virgin A mutantのウイルス抵抗性を打破するPVY系統またはTBTV)が引き起こす病気に罹患しない。そのため、特に当該病気が発生する環境下で栽培された場合において、ウイルス抵抗性でないタバコを栽培して生産される葉たばこと比較して、品質低下が軽減され高品質である。その結果、より高品質のたばこ製品を生産することができる。
このように、課題を解決するために、本願発明者らは、鋭意検討を重ねた結果、タバコにおいてeIF(iso)4Eの機能を抑制することにより、そのタバコがPVY-breaking系統およびTBTVに抵抗性となることを初めて見出した。さらに、タバコゲノムに存在する2組のeIF(iso)4E遺伝子の片方が、PVY-breaking系統に対する抵抗性に関係し、もう片方がTBTVに対する抵抗性に関係することを解明し、それら片側の遺伝子の機能を抑制することで、それぞれのウイルスに対する抵抗性を付与できることを見出した。また、eIF(iso)4E機能抑制タバコには生育阻害が起きないことを確認し本発明を完成した。
(遺伝子の取得)
公知データベースの検索を行い、タバコ(Nicotiana tabacum)の翻訳開始因子eIF4E1(GenBankアクセッション番号:AY702653)のcDNA塩基配列(配列番号10)、およびeIF(iso)4E(GenBankアクセッション番号:AY699609)のcDNA塩基配列(配列番号1)を取得した。
eIF4E1発現抑制タバコ、およびeIF(iso)4E発現抑制タバコを作出するため、これら遺伝子の内部配列をトリガーとするRNAiコンストラクトを構築した。
タバコの形質転換は常法(リーフディスク法)で行った。タバコ品種はPetit Havana SR1を用いた。
組換えタバコについて、eIF4E1またはeIF(iso)4E遺伝子の発現を調査するため、各遺伝子の塩基配列に基づき、リアルタイムPCR用のプライマー/プローブを設計した(表2)。また各組換えタバコの葉よりRNeasy Plant Mini Kit(QIAGEN社)を用いてTotal RNAを抽出した。得られたRNAからPrime Script reagent Kit(タカラバイオ株式会社)を用いてcDNAを合成し、リアルタイムPCRの鋳型とした。リアルタイムPCRではTaqMan Fast Advanced Master mix(Life technologies社)を用いて増幅反応を行った。反応条件は50℃ 2分間、95℃ 20秒間の後、95℃ 1秒、60℃20秒のサイクルを40回とした。発現解析はStepOne Software v2.2(Life technologies社)を用いた。PCRの内部標準としてelongation factor1-alpha(EF1-α)遺伝子を使用し、この遺伝子の発現量との比較で、標的遺伝子の相対的な遺伝子発現量を算出した。対照として非組換えタバコ(SR1)を用いた。
形質転換当代で転写抑制度合が高かったeIF4E1の5系統、およびeIF(iso)4Eの3系統の種子を、LS固形培地(3%ショ糖、0.8%寒天を含む)上に無菌的に播種した。発芽、生育した幼植物体のGFP蛍光をFluor Imager 595(Molecular Dynamics社)を用いて測定した。上述の通り、コンストラクト導入に用いているpSP231はT-DNA領域上のRNAi発現カセットの隣に、35Sプロモーター-GFP発現カセットが配置されている。幼植物体において、強いGFP蛍光を発するものをRNAiコンストラクトについてホモ接合系統、全く蛍光がないものをRNAiコンストラクトについてヌル分離系統(RNAiコンストラクトが存在しない)、弱い蛍光を発するものをRNAiコンストラクトについてヘミ接合系統と判断した。播種後3週の植物を温室に移し、培土に植え替え、育成した。
各組換えタバコ系統の次世代におけるeIF(iso)4E遺伝子の発現を調査するため、上述のようにして組換えタバコの葉よりRNAを抽出してcDNAを合成し、リアルタイムPCRの鋳型とした。リアルタイムPCRも上述の通り行い、内部標準としてEF1-α遺伝子を用い、対照植物として非組換えタバコ(SR1)を用いた。
培土への移植後10日の個体に、PVY(PVY-N)、PVY-B、またはTBTV(Tobacco bushy top virus)を接種した。PVY-Bは日本たばこ産業株式会社葉たばこ研究所で分離されたウイルス系統で、PVY抵抗性であるタバコ既存品種Virgin A mutantに壊疽症状を発生させるVAM breaking系統である。TBTVは、Umbravirus属のウイルスで、タバコの葉にモットリング症状を引き起こす。接種源には、各ウイルスが感染し発病した黄色種つくば1号の罹病葉を使用した。品種つくば1号は、PVY、PVY-B、およびTBTVに罹病性の品種であり、接種により明瞭な病徴を示す。採種した罹病葉を乳鉢中で0.01Nリン酸緩衝液とともに磨砕した。その磨砕液を移植1週間後のタバコ苗の最大葉(下から4枚目または5枚目)の半葉にカーボランダムを用いて塗抹接種した。その後、温室内で栽培し、適時病徴を観察した。
(eIF(iso)4Eタバコ変異体の選抜)
S型のeIF(iso)4E(AY699609)とT型のeIF(iso)4E(EB683576)のmRNA配列を用いて、GenBankデータベースのNicotiana tabacumのWhole Genome Shotgun Contigsを検索した結果、イントロン領域以外のタンパクコード領域において100%の配列同一性を示すゲノム配列が取得された(S型のアクセッション番号はAWOJ01412288、T型のアクセッション番号はAWOJ01054542)。これらの配列のうち、eIF(iso)4E遺伝子部分の配列を、配列番号7(S型のeIF(iso)4E遺伝子のゲノム配列)および配列番号8(T型のeIF(iso)4E遺伝子のゲノム配列)に示した。両配列はタバコ品種K326由来のゲノム配列である。
上記DNAサンプル(1974系統分のDNAサンプル)を鋳型に、表4のプライマーのうち、S型eIF(iso)4E-Exon 1 組合せ1(配列番号25および26)、およびS型eIF(iso)4E-Exon 2&3 組合せ1(配列番号28および29)を使ってPCRを行った。得られたPCR産物の塩基配列を決定したところ、Exon 1では58サンプル(50か所)、Exon 2とExon 3では計58サンプル(45か所)で変異が検出された。変異はいずれもヘテロ接合であった。ナンセンス変異(ストップコドンが生じた変異)が検出されたサンプルは、Exon 1で4サンプル(配列番号7の295、394または395番目のGがAに変異、330番目のCがTに変異)、Exon 2とExon 3で1サンプル(配列番号7の1814番目のGがAに変異)であった。これらのうち、330番目のCがTに変異した系統(M2)を播種し、24個体からDNAを抽出し、塩基配列を決定した結果、目的の変異をホモ接合で有する個体(eIF(iso)4E_S型変異ホモ個体)が11個体得られた。
上記DNAサンプル(1974系統分のDNAサンプル)を鋳型に、表4のプライマーのうち、T型eIF(iso)4E-Exon 1 組合せ1(配列番号31および32)、およびT型eIF(iso)4E-Exon 2&3 組合せ2(配列番号34および36)を使ってPCRを行った。上記と同様に、得られたPCR産物の塩基配列を決定したところ、Exon 1では43サンプル(38か所)、Exon 2とExon 3では計66サンプル(55か所)で変異が検出された。変異はいずれもヘテロ接合であった。ナンセンス変異が検出されたサンプルは、Exon 1で5サンプル(配列番号8の289、299、328、329または380番目のGがAに変異)、Exon 2とExon3で4サンプル(配列番号8の1704番目のGがAに変異したものが3つ、1737番目のGがAに変異したものが1つ)であった。これらのうち、299番目のGがAに変異した系統(M2)について24個体からDNAを抽出し、塩基配列を決定した結果、目的の変異をホモ接合で有する個体(eIF(iso)4E_T型変異ホモ個体)が8個体得られた。
上記eIF(iso)4E_S型変異ホモ個体とeIF(iso)4E_T型変異ホモ個体とを交配した。この交配によって、eIF(iso)4EのS側の遺伝子座およびT側の遺伝子座の両方において、野生型(変異がない)と変異型とをヘテロ接合で保有するF1系統を作出した。F1系統を自家受粉(自殖)させ、F2系統を得た。このF2系統においては、S型とT型の両方について変異をホモに持つ個体の割合の理論値は1/16である。F2系統を播種し、700個体からDNAを抽出した。
上述のeIF(iso)4E_S型変異体(S型のeIF(iso)4E遺伝子にホモ型の変異を有する。遺伝子型はssTT)、またはeIF(iso)4E_T型変異体(T型のeIF(iso)4E遺伝子にホモ型の変異を有する。遺伝子型はSStt)を育成し、自殖後代を得ることで種子の増殖を行った。得られた後代種子については一部を育成し、上記のようにDNAを抽出して、DNAマーカーを用いた多型解析を実施し、S側またはT側の変異をそれぞれホモで有することを確認した。
eIF(iso)4E遺伝子の多型を検出するための、より検出の確度が高いDNAマーカーとして、dCAPSマーカーを開発した。制限酵素の認識配列に多型が存在する場合には、制限酵素処理後の断片長の違いを検出することによって多型を判別することができるが、これをCAPSマーカー、PCR-RFLPマーカーと呼ぶ。eIF(iso)4E遺伝子に生じた今回の変異(S型では配列番号7の330番目のCがTに変異、T型では配列番号8の299番目のGがAに変異)の場合、SNP周辺の配列が制限酵素の認識配列を含まなかった。そのため、PCRで用いるプライマーを設計する際に、SNP(一塩基多型)近傍に人工的に制限酵素サイトを導入した。今回利用した変異においては、変異型遺伝子では制限サイト(S型ではNla III:CATG、T型ではMbo I:GATC)となるには二塩基の変異が必要であった一方で、野生型遺伝子では制限サイトとなるには一塩基の変異で足りた。したがって、本実施例では、一塩基変異導入することで、野生型では制限酵素で切れて、変異型では切れないような、dCAPSマーカーを作製した。なおこの場合、断片長の差はプライマーの長さ分の差として検出される。作製したプライマーは表6の通りである。
各種eIF(iso)4Eタバコ変異体について、eIF(iso)4E遺伝子の転写解析を行った。DNAマーカーで選抜された、eIF(iso)4E_S型変異体(ssTT)、eIF(iso)4E_T型変異体(SStt)、eIF(iso)4E_ST両ホモ変異体(sstt)、およびeIF(iso)4E_野生型系統(SSTT)から、上述と同様にRNAを抽出し、cDNAを合成して、定量PCRを行った。プライマー/プローブセットは、S型のeIF(iso)4E遺伝子用には、表2に示した配列番号19、20および21を用いた。また、T型eIF(iso)4E遺伝子用には、表6に示した配列番号49、50および51を新たに設計し、実験に供試した。
培土への移植後2週間の個体に、PVY-B(Potato virus Y のVAM breaking系統)、またはTBTV(Tobacco bushy top virus)を接種した。ウイルス接種源の作製およびタバコへの接種方法は、実施例1と同様の方法で実施した。接種後、温室内で栽培し、適宜病徴を観察した。eIF(iso)4E機能欠損変異体タバコのウイルス接種試験結果を表8および表9に示す。
なお、eIF(iso)4E機能抑制タバコに、生育阻害は一切見られなかった。
FERM BP-22285
Claims (34)
- 翻訳開始因子eIF(iso)4E遺伝子に変異を有しており、それによって、ウイルスに対して非機能的な翻訳開始因子eIF(iso)4Eタンパク質を生産するか、または翻訳開始因子eIF(iso)4E遺伝子の発現が抑制されていることを特徴とする、ウイルス抵抗性タバコ。
- 上記変異はナンセンス変異であることを特徴とする、請求項1に記載のウイルス抵抗性タバコ。
- 上記変異は、(a)配列番号3もしくは配列番号4に示すアミノ酸配列からなる翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、(b)配列番号3もしくは配列番号4に示すアミノ酸配列と92%以上の配列同一性を有する機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、(c)配列番号5もしくは配列番号6に示す塩基配列からなるmRNAが生成される野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、または(d)配列番号5もしくは配列番号6に示す塩基配列と92%以上の配列同一性を有するmRNAが生成されるものであり、かつ機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソンにおける、下記(1)~(4)に示す1つ以上の変異であることを特徴とする、請求項1または2に記載のウイルス抵抗性タバコ;
(1)コドンCAAのCがTに置換、(2)コドンCGAのCがTに置換、(3)コドンCAGのCがTに置換、(4)コドンTGGのG(2つのGのうちの何れか一方または両方)がAに置換。 - 上記変異は、ゲノムDNAにおける、配列番号7に示す塩基配列からなる翻訳開始因子eIF(iso)4E遺伝子の下記(1)~(27)に示す1つ以上の変異であることを特徴とする、請求項1~3の何れか一項に記載のウイルス抵抗性タバコ;
(1)270番目のCがTに置換、(2)295番目のGがAに置換、(3)296番目のGがAに置換、(4)304番目のGがAに置換、(5)305番目のGがAに置換、(6)315番目のCがTに置換、(7)330番目のCがTに置換、(8)343番目のGがAに置換、(9)344番目のGがAに置換、(10)357番目のCがTに置換、(11)394番目のGがAに置換、(12)395番目のGがAに置換、(13)1740番目のCがTに置換、(14)1813番目のGがAに置換、(15)1814番目のGがAに置換、(16)1846番目のGがAに置換、(17)1847番目のGがAに置換、(18)1888番目のGがAに置換、(19)1889番目のGがAに置換、(20)2050番目のCがTに置換、(21)2104番目のCがTに置換、(22)2123番目のGがAに置換、(23)2124番目のGがAに置換、(24)2152番目のCがTに置換、(25)4742番目のGがAに置換、(26)4743番目のGがAに置換、(27)4926番目のCがTに置換。 - 上記変異は、ゲノムDNAにおける、配列番号8に示す塩基配列からなる翻訳開始因子eIF(iso)4E遺伝子の下記(1)~(26)に示す1つ以上の変異であることを特徴とする、請求項1~3の何れか一項に記載のウイルス抵抗性タバコ;
(1)264番目のCがTに置換、(2)289番目のGがAに置換、(3)290番目のGがAに置換、(4)298番目のGがAに置換、(5)299番目のGがAに置換、(6)315番目のCがTに置換、(7)328番目のGがAに置換、(8)329番目のGがAに置換、(9)342番目のCがTに置換、(10)379番目のGがAに置換、(11)380番目のGがAに置換、(12)1630番目のCがTに置換、(13)1703番目のGがAに置換、(14)1704番目のGがAに置換、(15)1736番目のGがAに置換、(16)1737番目のGがAに置換、(17)1778番目のGがAに置換、(18)1779番目のGがAに置換、(19)1940番目のCがTに置換、(20)1994番目のCがTに置換、(21)2013番目のGがAに置換、(22)2014番目のGがAに置換、(23)2042番目のCがTに置換、(24)3224番目のGがAに置換、(25)3225番目のGがAに置換、(26)3406番目のCがTに置換。 - 上記変異は、(a)配列番号3に示すアミノ酸配列からなる翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子、(b)配列番号3に示すアミノ酸配列と92%以上の配列同一性を有する機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子、(c)配列番号5に示す塩基配列からなるmRNAが生成される野生型の翻訳開始因子eIF(iso)4E遺伝子、または(d)配列番号5に示す塩基配列と92%以上の配列同一性を有するmRNAが生成されるものであり、かつ機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子における1つ以上の変異であり、
上記ウイルスは、Umbravirus属のウイルスであることを特徴とする、請求項1~4の何れか一項に記載のウイルス抵抗性タバコ。 - 上記Umbravirus属のウイルスは、Tobacco bushy top virusであることを特徴とする、請求項6に記載のウイルス抵抗性タバコ。
- 上記変異は、(a)配列番号4に示すアミノ酸配列からなる翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子、(b)配列番号4に示すアミノ酸配列と92%以上の配列同一性を有する機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子、(c)配列番号6に示す塩基配列からなるmRNAが生成される野生型の翻訳開始因子eIF(iso)4E遺伝子、または(d)配列番号6に示す塩基配列と92%以上の配列同一性を有するmRNAが生成されるものであり、かつ機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子における1つ以上の変異であり、
上記ウイルスは、Potyvirus属のウイルスであることを特徴とする、請求項1~3および5の何れか一項に記載のウイルス抵抗性タバコ。 - 上記Potyvirus属のウイルスは、Potato virus Yの一系統であって、タバコのVirgin A mutantのウイルス抵抗性を打破する系統であることを特徴とする、請求項8に記載のウイルス抵抗性タバコ。
- 翻訳開始因子eIF(iso)4E遺伝子の発現量が野生型と比較して20%以下であることを特徴とする、ウイルス抵抗性タバコ。
- 上記発現量は野生型と比較して10%以下であることを特徴とする、請求項10に記載のウイルス抵抗性タバコ。
- 翻訳開始因子eIF(iso)4E遺伝子の発現を抑制するためのRNAiコンストラクトを保持することを特徴とする、請求項10または11に記載のウイルス抵抗性タバコ。
- ウイルスに対して非機能的な翻訳開始因子eIF(iso)4Eタンパク質を生産するか、または翻訳開始因子eIF(iso)4E遺伝子の発現を抑制する変異を翻訳開始因子eIF(iso)4E遺伝子に導入することによって、ウイルスに対して抵抗性を有するタバコを作出することを特徴とする、ウイルス抵抗性タバコ作出方法。
- 上記変異はナンセンス変異であることを特徴とする、請求項13に記載のウイルス抵抗性タバコ作出方法。
- エチルメタンスルホン酸によって上記変異を生じさせることを特徴とする、請求項13または14に記載のウイルス抵抗性タバコ作出方法。
- 上記変異は、(a)配列番号3もしくは配列番号4に示すアミノ酸配列からなる翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、(b)配列番号3もしくは配列番号4に示すアミノ酸配列と92%以上の配列同一性を有する機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、(c)配列番号5もしくは配列番号6に示す塩基配列からなるmRNAが生成される野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、または(d)配列番号5もしくは配列番号6に示す塩基配列と92%以上の配列同一性を有するmRNAが生成されるものであり、かつ機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソンにおける、下記(1)~(4)に示す1つ以上の変異であることを特徴とする、請求項13~15の何れか一項に記載のウイルス抵抗性タバコ作出方法;
(1)コドンCAAのCがTに置換、(2)コドンCGAのCがTに置換、(3)コドンCAGのCがTに置換、(4)コドンTGGのG(2つのGのうちの何れか一方または両方)がAに置換。 - 上記変異は、ゲノムDNAにおける、配列番号7に示す塩基配列からなる翻訳開始因子eIF(iso)4E遺伝子の下記(1)~(27)に示す1つ以上の変異であることを特徴とする、請求項13~16の何れか一項に記載のウイルス抵抗性タバコ作出方法;
(1)270番目のCがTに置換、(2)295番目のGがAに置換、(3)296番目のGがAに置換、(4)304番目のGがAに置換、(5)305番目のGがAに置換、(6)315番目のCがTに置換、(7)330番目のCがTに置換、(8)343番目のGがAに置換、(9)344番目のGがAに置換、(10)357番目のCがTに置換、(11)394番目のGがAに置換、(12)395番目のGがAに置換、(13)1740番目のCがTに置換、(14)1813番目のGがAに置換、(15)1814番目のGがAに置換、(16)1846番目のGがAに置換、(17)1847番目のGがAに置換、(18)1888番目のGがAに置換、(19)1889番目のGがAに置換、(20)2050番目のCがTに置換、(21)2104番目のCがTに置換、(22)2123番目のGがAに置換、(23)2124番目のGがAに置換、(24)2152番目のCがTに置換、(25)4742番目のGがAに置換、(26)4743番目のGがAに置換、(27)4926番目のCがTに置換。 - 上記変異は、ゲノムDNAにおける、配列番号8に示す塩基配列からなる翻訳開始因子eIF(iso)4E遺伝子の下記(1)~(26)に示す1つ以上の変異であることを特徴とする、請求項13~16の何れか一項に記載のウイルス抵抗性タバコ作出方法;
(1)264番目のCがTに置換、(2)289番目のGがAに置換、(3)290番目のGがAに置換、(4)298番目のGがAに置換、(5)299番目のGがAに置換、(6)315番目のCがTに置換、(7)328番目のGがAに置換、(8)329番目のGがAに置換、(9)342番目のCがTに置換、(10)379番目のGがAに置換、(11)380番目のGがAに置換、(12)1630番目のCがTに置換、(13)1703番目のGがAに置換、(14)1704番目のGがAに置換、(15)1736番目のGがAに置換、(16)1737番目のGがAに置換、(17)1778番目のGがAに置換、(18)1779番目のGがAに置換、(19)1940番目のCがTに置換、(20)1994番目のCがTに置換、(21)2013番目のGがAに置換、(22)2014番目のGがAに置換、(23)2042番目のCがTに置換、(24)3224番目のGがAに置換、(25)3225番目のGがAに置換、(26)3406番目のCがTに置換。 - 翻訳開始因子eIF(iso)4E遺伝子の発現量を野生型と比較して20%以下に抑制させる因子を導入することによって、ウイルスに対して抵抗性を有するタバコを作出することを特徴とする、ウイルス抵抗性タバコ作出方法。
- 上記発現量を野生型と比較して10%以下に抑制させる因子をタバコに導入することを特徴とする、請求項19に記載のウイルス抵抗性タバコ作出方法。
- 上記因子はRNAiコンストラクトであることを特徴とする、請求項19または20に記載のウイルス抵抗性タバコ作出方法。
- 上記ウイルスは、Potyvirus属のウイルスであることを特徴とする、請求項13~21の何れか一項に記載のウイルス抵抗性タバコ作出方法。
- 上記Potyvirus属のウイルスは、Potato virus Yであることを特徴とする、請求項22に記載のウイルス抵抗性タバコ作出方法。
- 上記Potyvirus属のウイルスは、Potato virus Yの一系統であって、タバコのVirgin A mutantのウイルス抵抗性を打破する系統であることを特徴とする、請求項22に記載のウイルス抵抗性タバコ作出方法。
- 上記ウイルスは、Umbravirus属のウイルスであることを特徴とする、請求項13~21の何れか一項に記載のウイルス抵抗性タバコ作出方法。
- 上記Umbravirus属のウイルスは、Tobacco bushy top virusであることを特徴とする、請求項25に記載のウイルス抵抗性タバコ作出方法。
- タバコの翻訳開始因子eIF(iso)4E遺伝子における変異を検出するためのポリヌクレオチドであって、当該変異は、ウイルスに対して非機能的な翻訳開始因子eIF(iso)4Eタンパク質を生産するか、または翻訳開始因子eIF(iso)4E遺伝子の発現を抑制する変異であることを特徴とする、検出用ポリヌクレオチド。
- 上記変異はナンセンス変異であることを特徴とする、請求項27に記載の検出用ポリヌクレオチド。
- 上記変異は、(a)配列番号3もしくは配列番号4に示すアミノ酸配列からなる翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、(b)配列番号3もしくは配列番号4に示すアミノ酸配列と92%以上の配列同一性を有する機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、(c)配列番号5もしくは配列番号6に示す塩基配列からなるmRNAが生成される野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソン、または(d)配列番号5もしくは配列番号6に示す塩基配列と92%以上の配列同一性を有するmRNAが生成されるものであり、かつ機能的な翻訳開始因子eIF(iso)4Eタンパク質をコードする野生型の翻訳開始因子eIF(iso)4E遺伝子のエキソンにおける、下記(1)~(4)に示す1つ以上の変異であることを特徴とする、請求項27または28に記載の検出用ポリヌクレオチド;
(1)コドンCAAのCがTに置換、(2)コドンCGAのCがTに置換、(3)コドンCAGのCがTに置換、(4)コドンTGGのG(2つのGのうちの何れか一方または両方)がAに置換。 - 上記変異は、ゲノムDNAにおける、配列番号7に示す塩基配列からなる翻訳開始因子eIF(iso)4E遺伝子の下記(1)~(27)に示す1つ以上の変異であることを特徴とする、請求項27~29の何れか一項に記載の検出用ポリヌクレオチド;
(1)270番目のCがTに置換、(2)295番目のGがAに置換、(3)296番目のGがAに置換、(4)304番目のGがAに置換、(5)305番目のGがAに置換、(6)315番目のCがTに置換、(7)330番目のCがTに置換、(8)343番目のGがAに置換、(9)344番目のGがAに置換、(10)357番目のCがTに置換、(11)394番目のGがAに置換、(12)395番目のGがAに置換、(13)1740番目のCがTに置換、(14)1813番目のGがAに置換、(15)1814番目のGがAに置換、(16)1846番目のGがAに置換、(17)1847番目のGがAに置換、(18)1888番目のGがAに置換、(19)1889番目のGがAに置換、(20)2050番目のCがTに置換、(21)2104番目のCがTに置換、(22)2123番目のGがAに置換、(23)2124番目のGがAに置換、(24)2152番目のCがTに置換、(25)4742番目のGがAに置換、(26)4743番目のGがAに置換、(27)4926番目のCがTに置換。 - 上記変異は、ゲノムDNAにおける、配列番号8に示す塩基配列からなる翻訳開始因子eIF(iso)4E遺伝子の下記(1)~(26)に示す1つ以上の変異であることを特徴とする、請求項27~29の何れか一項に記載の検出用ポリヌクレオチド;
(1)264番目のCがTに置換、(2)289番目のGがAに置換、(3)290番目のGがAに置換、(4)298番目のGがAに置換、(5)299番目のGがAに置換、(6)315番目のCがTに置換、(7)328番目のGがAに置換、(8)329番目のGがAに置換、(9)342番目のCがTに置換、(10)379番目のGがAに置換、(11)380番目のGがAに置換、(12)1630番目のCがTに置換、(13)1703番目のGがAに置換、(14)1704番目のGがAに置換、(15)1736番目のGがAに置換、(16)1737番目のGがAに置換、(17)1778番目のGがAに置換、(18)1779番目のGがAに置換、(19)1940番目のCがTに置換、(20)1994番目のCがTに置換、(21)2013番目のGがAに置換、(22)2014番目のGがAに置換、(23)2042番目のCがTに置換、(24)3224番目のGがAに置換、(25)3225番目のGがAに置換、(26)3406番目のCがTに置換。 - 上記変異を挟む核酸プライマーのセット、または、上記変異を含む連続した塩基配列もしくはその相補配列からなるポリヌクレオチドを含む核酸プライマーのセットであることを特徴とする、請求項27~31の何れか一項に記載の検出用ポリヌクレオチド。
- タバコにおいて、ゲノムDNAにおける上記変異の有無を、請求項27~32の何れか一項に記載の検出用ポリヌクレオチドを利用して検査する検査工程と、
上記検査工程において上記変異が検出されたタバコをウイルス抵抗性タバコとして選抜する選抜工程とを含むことを特徴とする、ウイルス抵抗性タバコ選抜方法。 - 翻訳開始因子eIF(iso)4E遺伝子における変異を含む連続した塩基配列またはその相補配列からなるポリヌクレオチドを含んでおり、当該変異は、ウイルスに対して非機能的な翻訳開始因子eIF(iso)4Eタンパク質を生産するか、または翻訳開始因子eIF(iso)4E遺伝子の発現を抑制する変異であることを特徴とする、ウイルスに対するタバコの抵抗性の判定用DNAマーカー。
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