WO2010061899A1 - ワクチンを蓄積する形質転換ダイズ植物およびその利用 - Google Patents
ワクチンを蓄積する形質転換ダイズ植物およびその利用 Download PDFInfo
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- WO2010061899A1 WO2010061899A1 PCT/JP2009/069977 JP2009069977W WO2010061899A1 WO 2010061899 A1 WO2010061899 A1 WO 2010061899A1 JP 2009069977 W JP2009069977 W JP 2009069977W WO 2010061899 A1 WO2010061899 A1 WO 2010061899A1
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- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/63—Introduction of foreign genetic material using vectors; Vectors; Use of hosts therefor; Regulation of expression
- C12N15/79—Vectors or expression systems specially adapted for eukaryotic hosts
- C12N15/82—Vectors or expression systems specially adapted for eukaryotic hosts for plant cells, e.g. plant artificial chromosomes (PACs)
- C12N15/8241—Phenotypically and genetically modified plants via recombinant DNA technology
- C12N15/8242—Phenotypically and genetically modified plants via recombinant DNA technology with non-agronomic quality (output) traits, e.g. for industrial processing; Value added, non-agronomic traits
- C12N15/8257—Phenotypically and genetically modified plants via recombinant DNA technology with non-agronomic quality (output) traits, e.g. for industrial processing; Value added, non-agronomic traits for the production of primary gene products, e.g. pharmaceutical products, interferon
- C12N15/8258—Phenotypically and genetically modified plants via recombinant DNA technology with non-agronomic quality (output) traits, e.g. for industrial processing; Value added, non-agronomic traits for the production of primary gene products, e.g. pharmaceutical products, interferon for the production of oral vaccines (antigens) or immunoglobulins
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61K—PREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
- A61K39/00—Medicinal preparations containing antigens or antibodies
- A61K39/0005—Vertebrate antigens
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- A—HUMAN NECESSITIES
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- A61P—SPECIFIC THERAPEUTIC ACTIVITY OF CHEMICAL COMPOUNDS OR MEDICINAL PREPARATIONS
- A61P25/00—Drugs for disorders of the nervous system
- A61P25/28—Drugs for disorders of the nervous system for treating neurodegenerative disorders of the central nervous system, e.g. nootropic agents, cognition enhancers, drugs for treating Alzheimer's disease or other forms of dementia
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- A61P—SPECIFIC THERAPEUTIC ACTIVITY OF CHEMICAL COMPOUNDS OR MEDICINAL PREPARATIONS
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- C07K16/00—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies
- C07K16/18—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies against material from animals or humans
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61K—PREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
- A61K39/00—Medicinal preparations containing antigens or antibodies
- A61K2039/51—Medicinal preparations containing antigens or antibodies comprising whole cells, viruses or DNA/RNA
- A61K2039/517—Plant cells
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- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K2317/00—Immunoglobulins specific features
- C07K2317/10—Immunoglobulins specific features characterized by their source of isolation or production
- C07K2317/13—Immunoglobulins specific features characterized by their source of isolation or production isolated from plants
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K2317/00—Immunoglobulins specific features
- C07K2317/30—Immunoglobulins specific features characterized by aspects of specificity or valency
- C07K2317/34—Identification of a linear epitope shorter than 20 amino acid residues or of a conformational epitope defined by amino acid residues
Definitions
- the present invention relates to a transformed soybean plant characterized by accumulation of an Alzheimer's disease vaccine in seeds, and use thereof.
- Alzheimer's disease is a neurodegenerative disease in which causative substances such as ⁇ amyloid accumulate in the brain and cause damage to nerve cells. While the number of Alzheimer's disease patients is expected to increase with the aging of society, there are almost no preventive drugs or therapeutic drugs, and the development of new preventive drugs, therapeutic drugs, vaccines, etc. is desired.
- Alzheimer's disease vaccines have been developed using ⁇ -amyloid, which is the causative substance, as an antigen, but have been difficult to develop due to problems such as side effects. Therefore, it is necessary to develop a vaccine using ⁇ -amyloid antigen determinant (epitope) having no side effects and to establish a mass production technique.
- Soybean is an endosperm seed that has no endosperm and accumulates its nutrients in the embryo that hits the cotyledon. About 40% of the total seed volume of the embryo is impregnated with stored protein. Therefore, soybean has different properties as a storage tissue compared to other crops that accumulate starch as the main storage substance in endosperm such as rice and corn, and is a suitable crop for producing and accumulating foreign proteins. .
- the major seed storage proteins of soybean are 11S globulin (glycinin) and 7S globulin ( ⁇ -conglycinin).
- the three-dimensional structure and intracellular accumulation mechanism of these seed storage proteins have been elucidated, and the three-dimensional structure can be maintained even when an exogenous gene called a variable region is inserted into the gene encoding these seed storage proteins. It is known that there are sites that are thought to have no effect on the properties of the storage protein.
- a ⁇ -amyloid antigenic determinant is a relatively low molecular weight protein (peptide) generally consisting of several amino acids.
- peptide generally consisting of several amino acids.
- a gene encoding the peptide is introduced into soybean, Even if it was made to accumulate in the seed of converted soybean, it decomposed
- transformed soybeans that accumulate blood pressure lowering peptides (Patent Document 1) and transformed rice that accumulates cedar pollinosis vaccine (Patent Document 2).
- Non-Patent Document 1 transformed soybeans that accumulate blood pressure lowering peptides
- Non-Patent Document 2 transformed rice that accumulates cedar pollinosis vaccine
- Non-Patent Document 2 ⁇ -amyloid-producing potato
- Non-Patent Document 2 ⁇ -amyloid-producing tomato
- kidney beans are plants belonging to legumes together with soybeans, and the protein contained in seeds is 20%.
- Arserin one of its main seed storage proteins, is known to have multiple presences of Arserin 1 to 7, and it is known that the base sequence homology of those structural protein-encoding proteins is very high. ing. The structural analysis of arserin protein has not progressed as much as soybeans, and the three-dimensional structure of arserin 1 and 5 has been revealed.
- prolamin one of the main seed storage proteins of rice, is an indigestible protein and there are several types (10K, 13K, 16K, etc.) of proteins with different molecular weights.
- the three-dimensional structure of prolamin is not clear.
- An object of the present invention is to provide a transformed soybean plant capable of producing and accumulating an Alzheimer's disease vaccine in seeds. Another object of the present invention is to provide a method for producing an Alzheimer's disease vaccine using the transformed soybean.
- the inventors of the present invention have intensively studied to solve the above problems. As a result, succeeded in producing a transformed soybean plant in which a gene encoding a modified seed storage protein in which a gene encoding an Alzheimer's disease vaccine was inserted into a variable region of a gene encoding a wild type seed storage protein was introduced. The Alzheimer's disease vaccine was successfully produced and accumulated in the seeds of the transformed soybean plant.
- the Alzheimer's disease vaccine is a ⁇ amyloid antigen determinant.
- the transformed soybean plant according to [2] comprising a sequence in which 1 to 3 peptides of SEQ ID NO: 3 are linked to the ⁇ amyloid antigen determinant.
- the gene encoding the Alzheimer's disease vaccine wherein the wild-type seed storage protein comprises the amino acid sequence of SEQ ID NO: 37 or an amino acid sequence having 90% or more identity with the amino acid sequence of SEQ ID NO: 37
- the transformed soybean plant according to [5], wherein the variable region into which is inserted is a region encoding an amino acid sequence corresponding to amino acid numbers 149 to 150 and / or amino acid numbers 250 to 251 in SEQ ID NO: 37.
- the gene encoding the Alzheimer's disease vaccine wherein the wild-type seed storage protein comprises the amino acid sequence of SEQ ID NO: 45 or an amino acid sequence having 90% or more identity with the amino acid sequence of SEQ ID NO: 45
- the transformed soybean plant according to [5], wherein the variable region into which is inserted is a region encoding an amino acid sequence corresponding to amino acid numbers 110 to 111 in SEQ ID NO: 45.
- a promoter that induces expression specific to soybean seeds, and a gene encoding an Alzheimer's disease vaccine in the variable region of a gene encoding a wild-type seed storage protein linked downstream of the promoter does not cause a frameshift And a gene encoding the modified seed storage protein inserted as described above.
- the vector according to [14], wherein the promoter is a bean arserin 2 promoter or a soybean 11S globulin A1aB1b subunit promoter.
- the transformed soybean plant of the present invention can highly accumulate an Alzheimer's disease vaccine in its seeds, an Alzheimer's disease vaccine can be efficiently produced using the transformed soybean plant.
- each subunit constituting soybean 11S globulin each subunit constituting soybean 7S globulin, kidney bean arserin, rice prolamin, Rice globulin, as well as seed storage proteins from other crops.
- Preferred wild type seed storage proteins include A1aB1b subunit of soybean 11S globulin, ⁇ subunit or ⁇ subunit of 7S globulin, with A1aB1b subunit of soybean 11S globulin being more preferred.
- amino acid sequence of SEQ ID NO: 2, SEQ ID NO: 37 or SEQ ID NO: 45, or these amino acid sequences are 80% or more, preferably 90% or more, more preferably 95% or more.
- proteins comprising amino acid sequences having identity include proteins comprising amino acid sequences having identity.
- the identity (%) of amino acid sequences refers to the identity (%) of the maximum amino acid sequence obtained by aligning two amino acid sequences to be compared with a gap as necessary.
- Alignment for the purpose of determining amino acid sequence identity can be performed using various methods well known to those skilled in the art, such as publicly available such as BLAST, BLAST-2, ALIGN, or Megalign (DNASTAR) software. Available computer software, commercially available software such as GeneGeWorks 2.5.1 software (Teijin System Technology Co., Ltd.), GENEX-WIN (Software Development Co., Ltd.), and the like can also be used.
- the gene encoding the wild type seed storage protein in the present invention includes a gene encoding each subunit constituting the 11S globulin of soybean, a gene encoding each subunit constituting the 7S globulin of soybean, and a kidney bean arserin.
- Preferred genes include a gene encoding the A1aB1b subunit of soybean 11S globulin and a gene encoding the ⁇ subunit or ⁇ subunit of 7S globulin, and the gene encoding the A1aB1b subunit of soybean 11S globulin. Is more preferable.
- nucleotide sequence of SEQ ID NO: 1, SEQ ID NO: 36 or SEQ ID NO: 44, or these nucleotide sequences and 80% or more, preferably 90% or more, more preferably 95% or more
- a gene containing a nucleotide sequence having the same identity As a gene encoding a wild type seed storage protein, the nucleotide sequence of SEQ ID NO: 1, SEQ ID NO: 36 or SEQ ID NO: 44, or these nucleotide sequences and 80% or more, preferably 90% or more, more preferably 95% or more And a gene containing a nucleotide sequence having the same identity.
- the identity (%) of base sequences refers to the identity (%) of the maximum base sequences obtained by aligning the two base sequences to be compared by introducing a gap as necessary.
- Alignment for the purpose of determining the identity of a base sequence can be performed using various methods well known to those skilled in the art, eg publicly such as BLAST, BLAST-2, ALIGN or Megalign (DNASTAR) software. Available computer software, commercially available software such as GeneGeWorks 2.5.1 software (Teijin System Technology Co., Ltd.), GENEX-WIN (Software Development Co., Ltd.), and the like can also be used.
- the gene encoding a modified seed storage protein in the present invention means that a gene encoding an Alzheimer's disease vaccine does not cause a frame shift in the variable region of a gene encoding a wild type seed storage protein. It is inserted as follows.
- the gene encoding the Alzheimer's disease vaccine was inserted so as not to cause a frameshift” means that the sequence of the modified seed storage protein excluding the amino acid sequence of the Alzheimer's disease corresponds to The gene encoding the Alzheimer's disease vaccine is inserted into the variable region of the gene encoding the wild type seed storage protein so as to be identical to the amino acid sequence of the wild type seed storage protein.
- the gene encoding the Alzheimer's disease vaccine has been inserted means that the gene encoding the Alzheimer's disease vaccine has been inserted without losing the base sequence encoding the variable region, and the variable region is encoded. It also includes that all or part of the base sequence is replaced with a gene encoding an Alzheimer's disease vaccine.
- variable region of a gene encoding a wild-type seed storage protein refers to gene expression as long as it is inserted so as not to cause a frame shift even when a foreign gene is inserted therein.
- the product protein refers to a region that can maintain a stable three-dimensional structure equivalent to a wild-type seed storage protein, thereby maintaining the characteristics of the wild-type seed storage protein.
- the gene encoding the wild type seed storage protein is a gene encoding the A1aB1b subunit of soybean 11S globulin containing the amino acid sequence of SEQ ID NO: 2, it encodes amino acid numbers 20 to 28 of SEQ ID NO: 2.
- Region (variable region I), region encoding amino acid numbers 111 to 128 (variable region II), region encoding amino acid numbers 198 to 216 (variable region III), region encoding amino acid numbers 268 to 315 (variable region) IV), five regions encoding the amino acid numbers 490 to 495 (variable region V) are known as variable regions (FIG. 1).
- the gene encoding the wild type seed storage protein is identical to the amino acid sequence of SEQ ID NO: 2 in which one or more amino acid substitutions, insertions, additions and / or deletions are present in the amino acid sequence of SEQ ID NO: 2.
- a region that encodes an amino acid sequence corresponding to amino acid numbers 20 to 28 of SEQ ID NO: 2 and a region that encodes an amino acid sequence corresponding to amino acid numbers 111 to 128 The region encoding the amino acid sequence corresponding to amino acid numbers 198 to 216, the region encoding the amino acid sequence corresponding to amino acid numbers 268 to 315, and the region encoding the amino acid sequence corresponding to amino acid numbers 490 to 495 are variable regions. .
- corresponding amino acid sequence for a specific amino acid sequence refers to the alignment of two amino acid sequences to be compared with a gap as necessary so that the maximum amino acid sequence identity (%) can be obtained.
- alignment refers to the other partial amino acid sequence corresponding to one specific partial amino acid sequence. Such an amino acid sequence can be easily specified by those skilled in the art.
- the modified seed storage protein is encoded by inserting a gene encoding an Alzheimer's disease vaccine into one or a plurality of variable regions. Genes can be prepared.
- a gene encoding the Alzheimer's disease vaccine is preferably inserted.
- Any of the variable regions II, III, IV, and V can be selected as the variable region, but it is more preferable to insert the variable region into III.
- two or more of the variable regions II, III, IV, and V can be selected as a variable region into which the gene encoding the Alzheimer's disease vaccine is inserted.
- three regions II, III, and IV can be selected. It can be inserted simultaneously, or inserted into four regions II, III, IV and V at the same time.
- the gene encoding the Alzheimer's disease vaccine needs to be introduced so that no frame shift occurs in the base sequence encoding the wild type seed storage protein.
- the gene encoding the kidney bean Arserin 5 containing the amino acid sequence of SEQ ID NO: 37 is used as the gene encoding the wild-type seed storage protein, since the variable region is not known, the A1aB1b subunit It is necessary to estimate the variable region by comparing the DNA sequence to confirm the disordered region, comparing the amino acid sequence and the three-dimensional structure with other similar storage proteins, and confirming the sequence gap and the structural difference. is there. A region encoding amino acid numbers 149 to 150 (variable region A) and / or a region encoding amino acid numbers 250 to 251 (variable region B) specified by such estimation is encoded in the Alzheimer's disease vaccine. It is preferable to insert a gene.
- the gene encoding the wild type seed storage protein is identical to the amino acid sequence of SEQ ID NO: 37 in which one or more amino acid substitutions, insertions, additions and / or deletions are present in the amino acid sequence of SEQ ID NO: 37
- a region encoding an amino acid sequence corresponding to amino acid numbers 149 to 150 of SEQ ID NO: 37, a region encoding an amino acid sequence corresponding to amino acid numbers 250 to 251 It is preferable to insert a gene encoding an Alzheimer's disease vaccine into.
- a gene encoding a prolamin of rice containing the amino acid sequence of SEQ ID NO: 45 is used as a gene encoding a wild-type seed storage protein, since the three-dimensional structure and variable region are not known, the amino acid sequence is It is necessary to estimate the variable region by comparing the gap structure with other similar storage proteins. It is preferable to insert a gene encoding an Alzheimer's disease vaccine into a region (variable region a) encoding amino acid numbers 110 to 111 of SEQ ID NO: 45 specified by such estimation.
- the gene encoding the wild type seed storage protein is identical to the amino acid sequence of SEQ ID NO: 45 in which one or more amino acid substitutions, insertions, additions and / or deletions are present in the amino acid sequence of SEQ ID NO: 45 In the case where it includes a nucleotide sequence encoding an amino acid sequence having the property, it is preferable to insert a gene encoding an Alzheimer's disease vaccine into a region encoding an amino acid sequence corresponding to amino acid numbers 110 to 111 of SEQ ID NO: 45.
- the gene encoding Alzheimer's disease vaccine is not particularly limited as long as it is a DNA encoding a protein or peptide having activity as a vaccine against Alzheimer's disease, but a part of ⁇ amyloid Preferably, it is a DNA encoding a ⁇ amyloid antigenic determinant consisting of a peptide consisting of about 5 to 25 amino acids. Examples of such DNA include DNA encoding the amino acid sequence of SEQ ID NO: 3.
- DNA encoding ⁇ -amyloid or ⁇ -amyloid antigenic determinant is simply screened from the cDNA library based on this base sequence information. Can be separated.
- DNA encoding ⁇ amyloid antigenic determinant can be prepared by chemical synthesis.
- the Alzheimer's disease vaccine can also be expressed by inserting it into the variable region of the gene encoding the seed storage protein in a state where a plurality of genes encoding this vaccine are linked in tandem.
- a gene encoding ⁇ -amyloid antigenic determinant linked to an integer of 1 to 20, preferably an integer of 1 to 5, more preferably an integer of 1 to 3, particularly preferably 2 is variable.
- the region can be inserted so as not to cause a frame shift.
- a base encoding a protease recognition sequence at the 5 'end and / or 3' end of the gene encoding the Alzheimer's disease vaccine Sequences can also be added. This makes it possible to excise the Alzheimer's disease vaccine with a protease from the modified seed storage protein produced in the seed.
- An example of such a protease is thermolysin.
- the vector for gene introduction according to the present invention can have a structure in which a promoter that induces expression specific to soybean seeds is linked upstream of the gene. Furthermore, a terminator can be linked downstream of the gene.
- promoters that induce soybean seed-specific expression include soybean 11S globulin promoter, kidney bean arserin promoter, and the like.
- Terminators include soybean 11S globulin terminator, kidney bean arsin 2 terminator, cauliflower. Examples include the 35S terminator and NOS terminator of mosaic virus.
- the 11S globulin promoter of soybean includes the promoter of soybean 11S globulin A1aB1b subunit consisting of SEQ ID NO: 18, and has at least 95% identity with this sequence as long as it has seed-specific promoter activity. May be.
- Examples of the terminator of soybean 11S globulin include the terminator of soybean 11S globulin A1aB1b subunit consisting of SEQ ID NO: 21, which has 95% or more identity with this sequence as long as it has seed-specific terminator activity. May be.
- Examples of the kidney bean arserin promoter include the kidney bean arserin 2 promoter consisting of base numbers 1399 to 3860 of SEQ ID NO: 56, and have at least 95% identity with this sequence as long as it has seed-specific promoter activity. It may be.
- the terminator of kidney bean arserin includes the terminator of kidney bean arserin 2 consisting of SEQ ID NO: 59, and may have 95% or more identity with this sequence as long as it has seed-specific terminator activity.
- the selection marker gene for selecting a recombinant and a reporter gene for confirming the expression of the introduced gene can be inserted into the vector according to the present invention.
- the selection marker gene include a hygromycin resistance gene and a phosphinothricin resistance gene.
- the reporter gene include a ⁇ -glucuronidase (GUS) gene, a chloramphenicol acetyltransferase (CAT) gene, and a luciferase. (LUC) gene, GFP gene and the like.
- the vector according to the present invention selects the DNA fragment comprising a promoter that induces seed-specific expression, a gene encoding a modified storage protein linked downstream thereof, and a terminator linked downstream thereof. It can also be obtained by inserting into a vector containing a marker gene and / or a reporter gene.
- Soybean plants that can be transformed Soybeans that can be transformed in the present invention include varieties generally used for food, feed, and oil. Further, the transformed soybean preferably lacks a part or all of the endogenous seed storage protein, for example, a part or all of the soybean 11S globulin and / or the soybean 7S globulin. Examples include soybean.
- “partially missing” means that the expression level is lower than that of the wild type, and that only some subunits are completely missing, or only some subunits. The case where the expression level of is less than that of the wild type is also included.
- mutant line EnB1 lacking soybean 11S globulin mutant line QY2 lacking soybean 7S globulin, mutant line QF2 lacking both soybean 11S globulin and soybean 7S globulin, etc. .
- progeny lines by crossing these defective mutant lines with general varieties for example, Jack etc. can also be mentioned.
- transformed soybean plants for example, plant tissues such as roots, stems, leaves, seeds, embryos, ovules, ovary, shoot tips, buds, pollen, etc. Differentiated callus, somatic embryos, plant culture cells such as protoplasts, and the like can be used.
- Introduction of a gene encoding a modified seed storage protein into the above material can be carried out by various methods already reported and established, but the Agrobacterium method, PEG method, electroporation method, particle gun It is preferable to introduce the above-described gene introduction vector using a method, whisker ultrasonic method or the like.
- cells of the transformed soybean plant can be selected using the resistance effect caused by the selection marker gene as an index.
- a transformed soybean plant can be obtained from the selected cells through a step of regenerating the plant reported in each plant species.
- the transformed soybean plant thus obtained is cultivated and the seeds are ripened to obtain the seed of the transformed soybean according to the present invention, and the target Alzheimer's disease vaccine is contained in the transformed seed. can get.
- Whether or not a gene encoding an Alzheimer's disease vaccine has been introduced into a plant body can be confirmed by PCR, Southern hybridization, Northern hybridization, Western blotting, or the like.
- protein is extracted from the seeds of transformed soybean plants, Western blotted, and immunostained using a primary antibody specific for Alzheimer's disease vaccine and a secondary antibody labeled with horseradish peroxidase (HRP), etc.
- HRP horseradish peroxidase
- the performance of the Alzheimer's disease vaccine contained in the modified seed storage protein accumulated in the seeds of the transformed soybean plant can be evaluated using, for example, a disease model mouse that develops Alzheimer's disease.
- a modified seed storage protein containing an Alzheimer's disease vaccine by subcutaneous injection or oral administration, or an Alzheimer's disease vaccine purified by cleaving it with a protease is administered to the model mouse, and the Alzheimer's disease vaccine for the mouse is administered.
- the performance of the Alzheimer's disease vaccine can be evaluated by examining antibody production, ⁇ -amyloid content, brain tissue, and behavioral abnormalities.
- the modified seed storage protein containing the Alzheimer's disease vaccine or the Alzheimer's disease vaccine purified by cleaving it with a protease can also be administered in admixture with adjuvant.
- Alzheimer's disease vaccine is produced by cultivating a large amount of seeds of transformed soybean that accumulates modified seed storage protein containing the vaccine in an outdoor field or an artificially controlled closed-type cultivation facility, and then collecting the seeds. Can be produced in large quantities.
- seeds that accumulate the modified seed storage protein containing the Alzheimer's disease vaccine can be used for the prevention and treatment of Alzheimer's disease as a composition containing the Alzheimer's disease vaccine.
- seeds that have been processed such as pulverization can be in the form of tablets, granules, powders, capsules, beverages, and the like.
- the composition may include a product obtained by extracting and purifying the modified seed storage protein accumulated in the seed.
- the modified seed storage protein containing the target Alzheimer's disease vaccine can be purified by an apparatus such as liquid chromatography.
- the composition includes a purified Alzheimer's disease vaccine by purifying the modified seed storage protein with a protease to remove all or part of the wild type seed storage protein portion from the modified seed storage protein. It may be a thing.
- Example 1 Construction of expression plasmid of modified soybean 11S globulin A1aB1b A gene encoding modified A1aB1b containing a peptide consisting of the amino acid sequence of SEQ ID NO: 3 known as ⁇ amyloid antigenic determinant (hereinafter abbreviated as A ⁇ 4-10 in soybean seeds An expression plasmid for expression was constructed. The procedure is shown in FIG.
- oligonucleotide in which three base sequences encoding A ⁇ 4-10 are linked in tandem and an oligonucleotide consisting of its complementary sequence (antisense strand, SEQ ID NO: 5) are custom-made by Fasmac Co., Ltd.
- the DNA was synthesized using a DNA commissioned synthesis service (the sense strand was called 410F and the antisense strand was called 410R). Subsequently, unless otherwise specified, oligonucleotides were synthesized using the company's custom DNA commissioned synthesis service.
- Each 100 pmol of 410F and 410R was phosphorylated with T4 Polynucleotide Kinase (manufactured by Takara Bio Inc.) in the presence of ATP at a final concentration of 1 mM, mixed with each reaction solution, and heated at 94 ° C. for 10 minutes. Then, it was gradually cooled to 37 ° C. over 1 hour and annealed. In this way, a double-stranded DNA fragment encoding a peptide (A ⁇ 4-10) ⁇ 3) in which three A ⁇ 4-10 were linked was obtained.
- T4 Polynucleotide Kinase manufactured by Takara Bio Inc.
- the known A1aB1b gene (GenBank accession No. AB113349) cDNA is cloned into the SmaI site of pBluescriptII SK (-) (Stratagene). And the DNA fragment obtained by amplification using PCR so that the specific variable region of the gene encoding A1aB1b is at the 5 ′ end and the 3 ′ end, and the above two encoding (A ⁇ 4-10) ⁇ 3
- a plasmid containing the gene encoding the modified A1aB1b was prepared by ligating with the double-stranded DNA fragment. A specific method is shown below.
- a primer set (PS-1) consisting of the primer pair of SEQ ID NOs: 6 and 7 for insertion into the variable region II of the gene encoding A1aB1b of SEQ ID NO: 1, SEQ ID NO: 8 for insertion into the variable region III
- the primer set (PS-4) and the primer set (PS-5) consisting of the primer pair of SEQ ID NOs: 14 and 15 for insertion into the variable region V were prepared in total.
- base substitution for introducing an amino acid substitution is performed immediately after the insertion region so that (A ⁇ 4-10) ⁇ 3 can be excised from the modified A1aB1b protein by thermolysin, a kind of protease. Introduced.
- the base sequence regions of SEQ ID NO: 1 into which DNA encoding (A ⁇ 4-10) ⁇ 3 is inserted are the PS-1 region, PS-2 region, PS-3 region, PS-4, respectively. This area is called the PS-5 area.
- PCR For PCR, 10 ng of pBSK-A1aB1b was used as a template, 50 ⁇ l of reaction solution was used per reaction, denaturation reaction was performed at 94 ° C. for 2 minutes and 1 cycle, denaturation reaction at 94 ° C. for 30 seconds, and annealing at 57 ° C. The extension reaction was carried out for 25 cycles at 30 ° C. for 5 minutes at 68 ° C.
- the reaction solution was 200 ⁇ M dNTP mixed solution, 1.5 mM MgSO 4 solution, 1 ⁇ M each of the above primers, 1 unit of KOD-Plus- (manufactured by Toyobo Co., Ltd.), KOD-Plus-Ver. Contains 2 buffers. Thereafter, PCR was performed using the same composition unless otherwise specified, except for the primers.
- nucleotide sequences of all the genes encoding the modified A1aB1b thus prepared were confirmed. Thereafter, unless otherwise specified, the base sequence was determined using the sequencing service of Fasmac Co., Ltd.
- a modified A1aB1b gene in which a DNA encoding (A ⁇ 4-10) ⁇ 3 is inserted into a plurality of variable regions, the same gene as described above is used with the gene encoding the modified A1aB1b prepared above as a template. PCR was performed using the primer set, the ligation reaction of the obtained DNA fragment and the double-stranded DNA fragment encoding the above (A ⁇ 4-10) ⁇ 3 peptide was repeated, and the gene encoding the modified A1aB1b was Produced.
- a plasmid containing a gene encoding modified A1aB1b in which DNA encoding (A ⁇ 4-10) ⁇ 3 was inserted into a plurality of variable regions of the gene of A1aB1b was prepared.
- Table 1 shows specific insertion regions and names of genes encoding the modified A1aB1b corresponding to them.
- the promoter region and terminator region of the wild-type A1aB1b gene were isolated.
- PCR was performed using 50 ⁇ l of reaction solution per reaction using Misuzu soybean genomic DNA as a template, denaturation reaction was carried out at 94 ° C. for 2 minutes for 1 cycle, denaturation reaction at 94 ° C. for 30 seconds, and annealing at 57 ° C. for 30 seconds. The second and extension reactions were carried out for 25 cycles at 68 ° C. with 2 minutes and 30 seconds as one cycle.
- a 2202 bp promoter fragment (Gy1P) SEQ ID NO: 18
- PCR was performed using 50 ⁇ l of reaction solution per reaction using Misuzu soybean genomic DNA as a template, denaturation reaction was carried out at 94 ° C. for 2 minutes for 1 cycle, denaturation reaction at 94 ° C. for 30 seconds, and annealing at 57 ° C. for 30 seconds.
- the second and extension reactions were performed 25 cycles at 68 ° C. with 1 minute as one cycle. In this way, a 1052 bp terminator fragment (Gy1T) (SEQ ID NO: 21) of the wild type A1aB1b gene was obtained.
- the genes obtained by encoding various modified A1aB1b, Gy1P and Gy1T obtained above are known pUHG vectors (Y. Kita, K. Nishizawa, M Takahashi). , M. Kitayama, M. Ishimoto. (2007) Generative development of sometic embryogenesis and regeneration. Went.
- A1aB1bM2 (SEQ ID NO: 22), A1aB1bM3 (SEQ ID NO: 24), A1aB1bM4-1 (SEQ ID NO: 26), A1aB1bM1 (SEQ ID NO: 28), A1aB1bM5 PCR was performed using (SEQ ID NO: 30) as a template and a primer set consisting of the oligonucleotide pairs of SEQ ID NOs: 32 and 33.
- the DNA fragment, promoter DNA fragment, and terminator DNA fragment of the modified A1aB1b gene were phosphorylated and ligated with a pUHG vector that had been cleaved with SmaI and dephosphorylated with CIAP (manufactured by Takara Bio Inc.). From the obtained clones, clones correctly linked in the order of the Gy1P promoter, the gene encoding the modified A1aB1b, and the Gy1T terminator were selected by analyzing the nucleotide sequence.
- the following five plant transformation vectors (pUHG A1aB1bM1, pUHGA1aB1bM2, pUHGA1aB1bM3, pUHGA1aB1bM4-1, pUHGA1aB1bM5) were constructed in which the gene encoding the modified A1aB1b was expressed in a seed-specific manner.
- Example 2 Construction of a modified kidney bean arserin expression plasmid A gene encoding a modified arserin obtained by inserting a DNA encoding a peptide in which A ⁇ 4-10 is linked in tandem (hereinafter abbreviated as (A ⁇ 4-10) ⁇ 2). An expression plasmid for expression in soybean seeds was constructed.
- variable region of the gene (GenBank accession No. Z50202) (SEQ ID NO: 36) encoding a known kidney bean arserin 5-1 was not clarified, the variable region was estimated.
- the variable region was estimated by comparing the DNA sequence with A1aB1b, it became clear that the disorder region was limited to the C-terminus. Therefore, it was considered possible to insert the peptide sequence at the C-terminus.
- the loop structure consisting of 8 to 10 residues found in phytohemagglutinin is compared with phytohemagglutinin belonging to 2S albumin in the same manner as Arserine. No amino acid number 149) was found behind.
- the nucleotide sequence region of SEQ ID NO: 36 encoding this site was estimated as the variable region A.
- phaseolin which is one of the storage proteins of Arserin 1 and common bean.
- a 7-residue gap was observed after asparagine corresponding to amino acid number 250 in SEQ ID NO: 37. Therefore, the nucleotide sequence region encoding this site (amino acid numbers 250 to 251) was estimated as the variable region B.
- 420F and 420R were phosphorylated with T4 Polynucleotide Kinase (manufactured by Takara Bio Inc.) in the presence of ATP at a final concentration of 1 mM, mixed with each reaction solution, and heated at 94 ° C. for 10 minutes. Then, it was cooled to 37 ° C. in one hour and annealed to obtain a double-stranded DNA fragment encoding (A ⁇ 4-10) ⁇ 2.
- Plasmid pBSK-Arc5-1 (Agricultural and Food Industry Research Organization, Hokkaido Agricultural Research Center) in which cDNA encoding Arc5-1 is cloned into the SmaI site of pBluescriptII SK (-) (Stratagene) And a DNA fragment obtained by PCR with the amino acid site of a specific variable region of the gene encoding Arc5-1 as a terminal (A ⁇ 4-10) ) A double-stranded DNA fragment encoding ⁇ 2 was ligated to prepare a plasmid containing the gene encoding modified Arc5-1. A specific method is shown below.
- a primer set (PS-A) consisting of a primer pair of SEQ ID NOs: 38 and 39 for insertion into the variable region A of the gene encoding Arc5-1, and SEQ ID NOs: 40 and 41 for insertion into the variable region B
- a base substitution for introducing amino acid substitutions before and after the insertion region was introduced so that A ⁇ 4-10 could be excised from the modified Arc5-1 protein by thermolysin, a kind of protease.
- PS-A region and PS-B region The regions of SEQ ID NO: 36 into which DNA encoding (A ⁇ 4-10) ⁇ 2 is inserted using the above primer sets are referred to as PS-A region and PS-B region, respectively.
- PCR was performed using 10 ng of pBSK-Arc5-1 as a template.
- 50 ⁇ l of reaction solution was used per reaction, denaturation reaction was carried out at 94 ° C. for 2 minutes and after one cycle, denaturation reaction was carried out at 94 ° C. for 30 seconds, annealing at 57 ° C. for 30 seconds, and extension reaction at 68 ° C. for 4 minutes.
- a cycle was performed for 25 cycles.
- the ligation reaction between the thus obtained DNA fragment and the double-stranded DNA fragment encoding the above (A ⁇ 4-10) ⁇ 2 was carried out.
- two types of plasmids containing the gene encoding modified Arc5-1 were prepared by inserting DNA encoding (A ⁇ 4-10) ⁇ 2 into the variable region of the gene encoding Arc5-1.
- Table 2 shows specific insertion regions of DNA encoding (A ⁇ 4-10) ⁇ 2 and names of genes encoding the modified Arc5-1 corresponding to them.
- Arc5M1 and Arc5M2 obtained above and Gy1P and Gy1T of the A1aB1b gene obtained in Example 1 above were linked to a pUHG vector to construct an expression plasmid. went.
- PCR was performed using the above Arc5M1 and Arc5M2 as a template and a primer set consisting of the primer pairs of SEQ ID NOs: 42 and 43.
- the modified Arc5-1 gene DNA fragments, Gy1P and Gy1T were phosphorylated and then ligated with the pUHG vector previously cleaved with SmaI and dephosphorylated.
- plant transformation vectors pUHG Arc5M1 and pUHG Arc5M2 in which the modified Arc5-1 gene was expressed in a seed-specific manner were constructed.
- Example 3 Construction of a modified rice prolamin expression plasmid (A ⁇ 4-10) ⁇ 2 An expression plasmid was constructed to express a gene encoding a modified prolamin into soybean seeds by inserting a DNA encoding DNA.
- variable region of the known gene progenin 10K RP10 encoding gene (GenBank accession No. E09788) (SEQ ID NO: 44) has not been clarified.
- the amino acid sequence of RP10 was compared with the amino acid sequence of zein delta, which is one of the main storage proteins of corn. As a result, an 11-residue gap was observed after lysine corresponding to amino acid number 110 of SEQ ID NO: 45. Therefore, the nucleotide sequence region of SEQ ID NO: 44 encoding this site (amino acid numbers 110 to 111) was estimated as the variable region a.
- the plasmid pBSK-RP10 National Institute of Agriculture and Food Technology
- cDNA encoding RP10 of prolamin 10K of rice has been cloned into the SmaI site of pBluescript II SK (-) (Stratagene)
- the double-stranded DNA fragment encoding (A ⁇ 4-10) ⁇ 2 was ligated to prepare a plasmid containing the gene encoding modified RP10.
- a specific method is shown below.
- a primer set consisting of the primer pairs of SEQ ID NOs: 46 and 47 for insertion into the variable region a of the gene encoding RP10 was prepared.
- a base substitution for introducing amino acid substitutions before and after the insertion region was also introduced so that the A ⁇ 4-10 peptide could be excised from the modified RP10 protein with thermolysin, a kind of protease.
- PCR reaction was performed using 10 ng of pBSK-RP10 as a template.
- 50 ⁇ l of reaction solution was used per reaction, denaturation reaction was performed at 94 ° C. for 2 minutes and 1 cycle, denaturation reaction was performed at 94 ° C. for 30 seconds, annealing was performed at 57 ° C. for 30 seconds, and extension reaction was performed at 68 ° C. 25 cycles were performed with 4 minutes as one cycle.
- Each DNA fragment thus obtained was ligated with the double-stranded DNA fragment encoding (A ⁇ 4-10) ⁇ 2 described above.
- a plasmid (RP10M1) containing a gene encoding modified RP10 in which a DNA encoding (A ⁇ 4-10) ⁇ 2 was inserted into the variable region of the gene encoding RP10 was prepared.
- an expression plasmid was constructed in which the gene encoding the modified RP10 and the Gy1P and Gy1T obtained in Example 1 were linked to a pUHG vector.
- PCR was performed using the above RP10M1 as a template and a primer set consisting of SEQ ID NOs: 48 and 49.
- the DNA fragment encoding the modified RP10, the promoter DNA fragment, and the terminator DNA fragment were subjected to a ligation reaction with a pUHG vector that had been previously cleaved with SmaI and then subjected to a dephosphorylation reaction.
- Example 4 Construction of Various Modified Expression Plasmids Using Arserin 2 Promoter An expression plasmid for expressing the gene encoding the modified A1aB1b prepared in Example 1 in soybean seeds using the bean-derived Arserin 2 promoter was constructed.
- Isolation of kidney bean-derived Arserin 2 promoter 50 ⁇ g of genomic DNA was extracted from 1 g of fresh leaves of kidney bean wild type (line number: G12866) using DNeasy Plant Maxi kit (Qiagen). After digesting 280 ng of the genomic DNA with the restriction enzyme SauIIIAI, dGTP was added, and a one-base extension reaction was performed with klenow enzyme (manufactured by Promega) (first extension reaction).
- PCR was performed using 2.8 ng of genomic DNA linked with the adapter constructed as described above as a template, and using primer WP-1 and primer SP1 attached to Right Walk Kit TM .
- 50 ⁇ L of reaction solution was used per reaction, denaturation reaction was performed at 94 ° C. for 2 minutes for 1 cycle, denaturation reaction at 94 ° C. for 30 seconds, annealing at 65 ° C. for 30 seconds, and extension reaction at 68 ° C. Then, 35 cycles were performed with 5 minutes as one cycle.
- the reaction solution was 200 ⁇ M dNTP mixed solution, 1.5 mM MgSO 4 solution, 1 ⁇ M of each of the above primers, 1 unit of KOD-Plus-Ver.
- the amplified DNA fragment was subjected to phosphorylation with T4 Polynucleotide Kinase (manufactured by Takara Bio Inc.) in the presence of ATP at a final concentration of 1 mM, followed by pBluescript II SK (-) (manufactured by Stratagene) previously treated with SmaI.
- a ligation reaction was performed.
- the reaction product was Arc2P (i), and the nucleotide sequence was determined using DNA sequencing service of Fasmac Co., Ltd. As a result, it was confirmed that a novel region of 844 bp upstream of the start codon of the arserin 2 gene was included.
- a new primer was prepared and a second extension reaction was performed. After digesting 280 ng of the genomic DNA with the restriction enzyme BglII, dGTP was added, and a one-base extension reaction was performed with klenow enzyme (manufactured by Promega). After the reaction, a ligation reaction was carried out with the RWA-1 adapter attached to the Right Walk Kit TM to obtain a PCR template for promoter isolation. Next, based on the known nucleotide sequence of the kidney bean arserin 2 gene (GenBank accession No.
- an oligonucleotide consisting of the nucleotide sequence of SEQ ID NO: 52 (designated as primer secondSP1) was also subjected to the first extension reaction. Based on the obtained base sequence of 844 bp upstream of the start codon, an oligonucleotide (designated as primer secondSP2) having the base sequence of SEQ ID NO: 53 was prepared. Sequence number 52 (primer secondSP1) CAGATTTTTT GCCCTCAAAA TTGATG Sequence number 53 (primer secondSP2) CGGATGTGCG TGGACTACAA GG
- PCR was performed using 2.8 ng of genomic DNA linked with the adapter constructed as described above as a template, and using primer WP-1 and primer secondSP1 attached to Right Walk Kit TM .
- the PCR solution composition and temperature conditions were the same as those in the first extension reaction except for the template and the primer.
- the PCR solution was diluted 100 times, and 1 ⁇ L thereof was used as a template for the second PCR, and PCR was performed using the primer WP-2 and the primer secondSP2 attached to the Right Walk Kit TM .
- the solution composition and temperature conditions for the second PCR are the same as those for the first PCR except for the template and primers.
- the amplified DNA fragment was subjected to phosphorylation with T4 Polynucleotide Kinase (manufactured by Takara Bio Inc.) in the presence of ATP at a final concentration of 1 mM, followed by pBluescript II SK (-) (manufactured by Stratagene) previously treated with SmaI.
- a ligation reaction was performed.
- the reaction product was Arc2P (ii) and the nucleotide sequence was determined.
- a new primer was prepared and the third extension reaction was performed.
- oligonucleotides consisting of the nucleotide sequences of SEQ ID NO: 54 and SEQ ID NO: 55 (named as primer thirdSP1 and primer thirdSP2 respectively) were prepared based on the base sequence of 197 bp obtained by the second extension reaction.
- Sequence number 54 (primer thirdSP1) CGACCTGAAG AACGCAGCGG CGACC Sequence number 55 (primer thirdSP2) TACCAGCAGT TGATGGACAA GATC
- PCR was performed using 2.8 ng of genomic DNA linked with the adapter constructed as described above as a template, and using primer WP-1 and primer thirdSP1 attached to Right Walk Kit TM .
- the PCR solution composition and temperature conditions were the same as those in the first extension reaction except for the template and the primer.
- the reaction solution was diluted 100-fold, and 1 ⁇ L thereof was used as a template for the second PCR, and PCR was performed using the primer WP-2 and the primer thirdSP2 attached to the Right Walk Kit TM .
- the solution composition and temperature conditions for the second PCR are the same as those for the first PCR except for the template and primers.
- the amplified DNA fragment was subjected to phosphorylation with T4 Polynucleotide Kinase (manufactured by Takara Bio Inc.) in the presence of ATP at a final concentration of 1 mM, followed by pBluescript II SK ( ⁇ ) (manufactured by Stratagene) previously treated with SmaI.
- a ligation reaction was performed.
- the reaction product was Arc2P (iii), and the base sequence was determined. As a result, it was confirmed that a novel region of 2819 bp upstream (3860 bp in total) of Arc2P (ii) was included.
- DNA (Arc2P) containing a novel promoter sequence of 3860 bp including the 5′-untranslated region upstream of the initiation codon of the arserin 2 gene was obtained by three extension reactions (SEQ ID NO: 56: of which the promoter region is a base Number 1399-3860).
- kidney bean-derived arserin 2 terminator 280 ng of genomic DNA extracted in (1) above was digested with restriction enzyme NheI, dCTP was added, and a one-base extension reaction was performed with klenow enzyme (manufactured by Promega). After the reaction, a ligation reaction was performed using an RWA-2 adapter attached to the Right Walk Kit TM and Ligation high (manufactured by Toyobo Co., Ltd.) to obtain a PCR template for the isolation of the terminator gene.
- RWA-2 adapter attached to the Right Walk Kit TM and Ligation high manufactured by Toyobo Co., Ltd.
- oligonucleotides consisting of the nucleotide sequences of SEQ ID NO: 57 and SEQ ID NO: 58 (named as primer SP3 and primer SP4, respectively) Produced. Sequence number 57 (primer SP3) CATCAATTTT GAGGGCAAAA AATCTG Sequence number 58 (primer SP4) CGTTCCAACA TCCTCCTCAA CAAGATC
- PCR was performed using 2.8 ng of genomic DNA linked with the adapter constructed as described above as a template, and using primer WP-1 and primer SP3 attached to Right Walk Kit TM .
- 50 ⁇ L of reaction solution was used per reaction, denaturation reaction was performed at 94 ° C. for 2 minutes and 1 cycle, denaturation reaction was performed at 94 ° C. for 30 seconds, annealing was performed at 65 ° C. for 30 seconds, and extension reaction was performed at 68 ° C. Then, 35 cycles were performed with 5 minutes as one cycle.
- the reaction solution was 200 ⁇ M dNTP mixed solution, 1.5 mM MgSO 4 solution, 1 ⁇ M each of the above primers, 1 unit of KOD-Plus-Ver.
- the amplified DNA fragment was subjected to phosphorylation with T4 Polynucleotide Kinase (manufactured by Takara Bio Inc.) in the presence of ATP at a final concentration of 1 mM, followed by pBluescript II SK (-) (manufactured by Stratagene) previously treated with SmaI.
- a ligation reaction was performed.
- the reaction product was Arc2T, and the base sequence was determined. As a result, it was confirmed that a novel region of 795 bp downstream of the stop codon including the 3 ′ untranslated region of the arserin 2 gene was included (SEQ ID NO: 59).
- clones correctly linked in the order of the Arc2P promoter, the gene encoding the modified A1aB1b, and the Arc2T terminator were selected by analyzing the nucleotide sequence.
- the following five plant transformation vectors pUHGA2PA1aB1bM1, pUHGA2PA1aB1bM3, and pUHGA2PA1aB1bM5 in which the gene encoding the modified A1aB1b is expressed in a seed-specific manner under the control of the arserin 2 promoter were constructed.
- a plant transformation vector pUHGA2PRP10M1 in which the gene encoding RP10M1 described above was expressed in a seed-specific manner was constructed.
- Example 5 A known method for introducing a gene encoding a modified seed storage protein into soybean (K. Nishizawa, Y. Kita, M. Kitayama, M. Ishimoto. (2006) expression and stable transformation in soybean.Plant Cell Reports 25: 1355-1361), mutant strains lacking 11S globulin and 7S globulin, major seed storage proteins (Agricultural and Food Industry Technical Research Institute) Organization, Hokkaido Agricultural Research Center) (Y. Kita, K. Nishiz) .. Awa, M Takahashi, M. Kitayama, M.
- Potassium titanate whisker LS20 (manufactured by Titanium Industry Co., Ltd.) was placed in a 1.5 ml tube and allowed to stand for 1 hour, after which ethanol was removed and completely evaporated to obtain a sterilized whisker. 1 ml of sterilized water was put into the tube containing the whisker and stirred well. The whisker and sterilized water were centrifuged and the supernatant water was discarded. The whisker was washed in this way. This whisker washing operation was performed three times. Thereafter, 0.5 ml of a known MS liquid medium was added to the tube to obtain a whisker suspension.
- somatic embryo masses (diameter 3 mm or less) were placed and stirred, and then the mixture was centrifuged at 1000 rpm for 10 seconds to obtain somatic embryo masses and whiskers. Precipitation was carried out, and the supernatant was discarded to obtain a mixture of somatic embryo mass and whisker.
- the tube containing the uniform mixture was centrifuged at 18000 ⁇ g for 5 minutes.
- the centrifuged mixture was shaken again and this operation was repeated three times.
- the somatic embryo mass, whisker, and the tube containing the vector obtained as described above were placed so that the tube was sufficiently immersed in the bathtub of the ultrasonic generator.
- Ultrasonic waves having a frequency of 40 kHz were irradiated at an intensity of 0.25 W / cm 2 for 1 minute.
- the mixture was kept at 4 ° C. for 10 minutes after irradiation.
- the sonicated mixture was washed with the MS liquid medium.
- the treated somatic embryo mass is cultured with a known somatic embryo growth liquid medium by shaking for 1 week (100 rpm), followed by hygromycin B (15 mg / l) (Roche Diagnostics, Mannheim, Germany). And cultured for 1 week in fresh somatic embryo growth liquid medium. Furthermore, after culturing for 4 weeks in a somatic embryo growth liquid medium containing 30 mg / l hygromycin B (changing the medium every week), it was selected for 1 week in a somatic embryo growth liquid medium containing 45 mg / l hygromycin B. Culture was performed. In addition, the gene transfer was performed on 12 microtubes for each vector.
- somatic embryo mass resistant to hygromycin was transferred to a known somatic embryo maturation liquid medium, and the somatic embryo was matured by continuing shaking culture (100 rpm) for 4 weeks.
- Mature somatic embryos were placed in a sterile petri dish for 3 to 5 days, dried, and then transferred to a known germinating solid medium. After germination culture for 7 to 10 days, it was transferred to a known rooting medium to grow germinating seedlings. After the roots and shoots grew, the plants were transferred to pots containing soil and maintained at high humidity until acclimated.
- Example 6 Production of transgenic soybean plant introduced with modified seed storage protein gene
- six transformed soybean plants introduced with A1aB1BM1 in the Jack cultivar six transformants introduced with A1aB1bM2, and traits introduced with A1aB1bM3
- Five transformants, five transformants introduced with A1aB1bM4-1, and nine transformants introduced with A1aB1bM5 were produced.
- three transformed soybean plants introduced with Arc5M1, three transformed plants introduced with Arc5M2, and two transformed soybean plants introduced with RP10M1 were produced.
- Example 7 Evaluation of accumulated amount of A ⁇ 4-10 in transformed soybean seeds Total protein was extracted from the transformed soybean seeds obtained in Example 6 above, and the amount of A ⁇ 4-10 accumulated was determined by Western blotting using a specific antibody against A ⁇ 4-10. It was evaluated with. Quantitative analysis was carried out for lines with particularly high accumulation.
- A1aB1bM1, A1aB1bM3, and A1aB1bM5 which had a high accumulation amount, were transformed soybean seeds (lines No. 10-2, No. a-2, No. 6-6) and A1aB1bM1 were seed storage protein-deficient varieties.
- the amount of accumulation in the transformed soybean seeds (line No. 16-2) introduced into was measured and shown in Table 3.
- Table 4 shows the results of Western blot analysis for measuring the amount of modified seed storage protein accumulated in transformed soybeans into which A1aB1BM3 (a gene into which one A ⁇ 4-10 had been inserted) was introduced into a seed storage protein-deficient variety. It was shown to.
- Example 8 Effect test of modified seed storage protein A1aB1bM1 prepared in Example 1 was expressed in E. coli by a known method for production.
- an E. coli expression plasmid pETA1aB1bM1 was prepared by ligating A1aB1bM1 to a pET21-d vector (Novagen).
- the pETA1aB1bM1 was introduced into E. coli AD494 (manufactured by Novagen) by a conventional method, and the above recombinant E. coli was cultured at 37 ° C. for 18 ml in a known TB medium (containing 15 mg / l kanamycin final and 50 mg / l carbenesillin final). After 10 hours, 10 ml of the culture solution was added to 1000 ml of production medium of known LB medium (containing 15 mg / l kanamycin final, 50 mg / l carbenesillin final and 500 mM sodium chloride final), and cultured at 37 ° C. for 2 hours. It was.
- IPTG IPTG was added at a final concentration of 1 mM and cultured at 20 ° C. for 48 hours. After culturing, E. coli cells were collected at 8000 rpm for 15 minutes. A soluble protein fraction was extracted from the recovered cells using BugBuster Protein Extraction Reagent (manufactured by Novagen). A recombinant protein (A1aB1bM1 protein) encoded by A1aB1bM1 was purified from the obtained soluble protein fraction using Ni-NTA His ⁇ Bind Resins (Novagen).
- A1aB1bM1 carrying ⁇ -amyloid antigenic determinant (A ⁇ 4-10) was dissolved in physiological saline, and subcutaneously injected (3 g) at 4-week-old Alzheimer's disease model mouse (TgCRND8) at 1-week intervals. Administration).
- a group encoding wild-type A1aB1b that was not modified was expressed in E. coli in the same manner as described above, and the obtained wild-type A1aB1b was administered as a control group.
- Blood was collected from mice 9 weeks after administration, and antibody production against A ⁇ 4-10 was confirmed by a known ELISA sandwich method.
- the A1aB1bM1 protein administration group clearly showed an antibody titer compared to the A1aB1b protein administration group. An increase was observed, confirming the vaccine effect of the recombinant protein encoded by A1aB1bM1.
- Example 9 Thermal stability of modified seed storage protein in soybean seeds Thermal stability of modified seed storage protein in seeds by various heat treatments on the transformed soybean seeds obtained in Example 6 above A test was conducted. 1) Roasting treatment of transformed soybean seeds After pulverizing A1aB1bM3 transformed soybean seeds, 10 mg of the pulverized product was treated at 100 ° C. for 10 minutes in an autoclave sterilizer, and then the method described in Example 7 above. The total protein was extracted with, and the accumulated amount of A ⁇ 4-10 present in the seeds was evaluated by Western blotting using a specific antibody against A ⁇ 4-10.
- the amount of A ⁇ 4-10 accumulated in the seeds was evaluated by Western blotting using a specific antibody against A ⁇ 4-10.
- a signal band corresponding to A ⁇ 4-10 was confirmed in the roasting treatment zone and the boiled treatment zone, and the amount thereof was the same as that in the non-heat treatment zone, and the heat stability of the modified seed storage protein in the seeds was improved. It was confirmed (FIG. 8).
- ⁇ -amyloid antigenic determinant form A ⁇ 4-10 amino acid sequence peptide (P1), amino acid sequence peptide (P2) in which P1 is linked in tandem, and P1 in three in tandem
- P3 amino acid sequence peptide having the amino acid sequence (P3) was synthesized using a peptide commissioned synthesis service.
- KLH-P1, KLH-P2, and KLH-P3, in which the carrier protein key-limpet-hemocyanin (KLH, Mw.1000000) is bound to the N-terminal side of peptides P1, P2, and P3 with cysteine (Cys) as a crosslink was made.
- KLH-P1, KLH-P2, and KLH-P3 are dissolved in physiological saline, and administered to a 4-week-old mouse (BALBc) five times at weekly intervals by subcutaneous injection (3 animals / group). Went. Blood was collected from mice 9 weeks after administration, and antiserum was collected. The obtained antiserum was affinity purified to produce purified antibodies against KLH-P1, KLH-P2, and KLH-P3.
- Alzheimer's disease vaccine can be produced and accumulated in soybean seeds as a fusion protein with seed storage proteins such as soybean 11S globulin and 7S globulin, kidney bean arserin, and rice prolamin.
- Alzheimer's disease vaccines can be produced and supplied in large quantities for the prevention and treatment of Alzheimer's disease.
Abstract
Description
その結果、野生型種子貯蔵タンパク質をコードする遺伝子の可変領域にアルツハイマー病ワクチンをコードする遺伝子が挿入された改変型種子貯蔵タンパク質をコードする遺伝子が導入された形質転換ダイズ植物の作製に成功し、該形質転換ダイズ植物の種子中でアルツハイマー病ワクチンを生産させ、蓄積させることに成功した。
[1]改変型種子貯蔵タンパク質をコードする遺伝子が導入された形質転換ダイズ植物であって、該改変型種子貯蔵タンパク質をコードする遺伝子は、野生型種子貯蔵タンパク質をコードする遺伝子の可変領域にアルツハイマー病ワクチンをコードする遺伝子がフレームシフトを生じないように挿入されたものであり、該改変型種子貯蔵タンパク質は種子中で発現して蓄積することを特徴とする、形質転換ダイズ植物。
[2]前記アルツハイマー病ワクチンが、βアミロイド抗原決定基であることを特徴とする、[1]に記載の形質転換ダイズ植物。
[3]βアミロイド抗原決定基が配列番号3のペプチドが1~3個連結された配列からなる、[2]に記載の形質転換ダイズ植物。
[4]前記形質転換ダイズ植物は、内在性のダイズ11Sグロブリン及び/又はダイズ7Sグロブリンを欠損していることを特徴とする[1]~[3]のいずれかに記載の形質転換ダイズ植物。
[5]前記野生型種子貯蔵タンパク質が、ダイズ11SグロブリンのA1aB1bサブユニット、インゲンマメのアルセリン又はイネのプロラミンであることを特徴とする、[1]~[4]のいずれかに記載の形質転換ダイズ植物。
[6]前記野生型種子貯蔵タンパク質が、配列番号2のアミノ酸配列、又は配列番号2のアミノ酸配列と90%以上の同一性を有するアミノ酸配列を含むものであり、前記アルツハイマー病ワクチンをコードする遺伝子が挿入された可変領域が、配列番号2におけるアミノ酸番号111~128、アミノ酸番号198~216、アミノ酸番号268~315、及びアミノ酸番号490~495に相当するアミノ酸配列の群から選択される1つ又は複数のアミノ酸配列をコードする領域である、[5]に記載の形質転換ダイズ植物。
[7]前記野生型種子貯蔵タンパク質が、配列番号37のアミノ酸配列、又は配列番号37のアミノ酸配列と90%以上の同一性を有するアミノ酸配列を含むものであり、前記アルツハイマー病ワクチンをコードする遺伝子が挿入された可変領域が、配列番号37におけるアミノ酸番号149~150及び/またはアミノ酸番号250~251に相当するアミノ酸配列をコードする領域である、[5]に記載の形質転換ダイズ植物。
[8]前記野生型種子貯蔵タンパク質が、配列番号45のアミノ酸配列、又は配列番号45のアミノ酸配列と90%以上の同一性を有するアミノ酸配列を含むものであり、前記アルツハイマー病ワクチンをコードする遺伝子が挿入された可変領域が、配列番号45におけるアミノ酸番号110~111に相当するアミノ酸配列をコードする領域である、[5]に記載の形質転換ダイズ植物。
[9]前記改変型種子貯蔵タンパク質をコードする遺伝子はインゲンマメのアルセリン2プロモーターまたはダイズの11SグロブリンのA1aB1bサブユニットプロモーターによって発現制御された、[1]~[8]のいずれかに記載の形質転換ダイズ植物。
[10][1]~[9]のいずれかに記載の形質転換ダイズ植物の細胞。
[11][1]~[9]のいずれかに記載の形質転換ダイズ植物の種子。
[12][11]に記載の種子を加工してなる、ダイズ種子加工品。
[13][1]~[9]のいずれかに記載の形質転換ダイズ植物を用いて、該形質転換ダイズ植物の種子中でアルツハイマー病ワクチンを生産する方法。
[14]ダイズ種子特異的な発現を誘導するプロモーターと、該プロモーターの下流に連結された、野生型種子貯蔵タンパク質をコードする遺伝子の可変領域にアルツハイマー病ワクチンをコードする遺伝子がフレームシフトを生じないように挿入された改変型種子貯蔵タンパク質をコードする遺伝子とを含むベクター。
[15]前記プロモーターはインゲンマメのアルセリン2プロモーターまたはダイズの11SグロブリンのA1aB1bサブユニットプロモーターである、[14]に記載ベクター、を提供する。
本発明における野生型種子貯蔵タンパク質としては、ダイズの11Sグロブリンを構成する各サブユニット、ダイズの7Sグロブリンを構成する各サブユニット、インゲンマメのアルセリン、イネのプロラミン、イネのグロブリン、更には他の作物の種子貯蔵タンパク質が挙げられる。好ましい野生型種子貯蔵タンパク質としては、ダイズの11SグロブリンのA1aB1bサブユニット、7Sグロブリンのαサブユニットもしくはβサブユニットが挙げられるが、ダイズの11SグロブリンのA1aB1bサブユニットがより好ましい。
本発明における改変型種子貯蔵タンパク質をコードする遺伝子とは、野生型種子貯蔵タンパク質をコードする遺伝子の可変領域にアルツハイマー病ワクチンをコードする遺伝子がフレームシフトを生じないように挿入されたものである。
本発明においてアルツハイマー病ワクチンをコードする遺伝子とは、アルツハイマー病に対するワクチンとしての活性を有するタンパク質又はペプチドをコードするDNAであれば特に限定はされないが、βアミロイドの一部を構成する、約5~25アミノ酸から成るペプチドからなるβアミロイド抗原決定基をコードするDNAであることが好ましい。このようなDNAとして、例えば配列番号3のアミノ酸配列をコードするDNA等が挙げられる。
本発明に係る遺伝子導入用のベクターは、該遺伝子の上流にダイズ種子特異的な発現を誘導するプロモーターを連結した構造にすることができる。さらに、該遺伝子の下流にターミネーターを連結させることもできる。
ダイズの11Sグロブリンのプロモーターとしては、配列番号18からなるダイズの11SグロブリンA1aB1bサブユニットのプロモーターが挙げられ、種子特異的プロモーター活性を有する限り、この配列と95%以上の同一性を有するものであってもよい。ダイズの11Sグロブリンのターミネーターとしては、配列番号21からなるダイズの11SグロブリンA1aB1bサブユニットのターミネーターが挙げられ、種子特異的ターミネーター活性を有する限り、この配列と95%以上の同一性を有するものであってもよい。
インゲンマメのアルセリンのプロモーターとしては、配列番号56の塩基番号1399~3860からなるインゲンマメアルセリン2のプロモーターが挙げられ、種子特異的プロモーター活性を有する限り、この配列と95%以上の同一性を有するものであってもよい。インゲンマメのアルセリンのターミネーターとしては、配列番号59からなるインゲンマメアルセリン2のターミネーターが挙げられ、種子特異的ターミネーター活性を有する限り、この配列と95%以上の同一性を有するものであってもよい。
本発明において形質転換され得るダイズには、一般に食用、飼料、油用として利用されている品種が含まれる。また、形質転換されるダイズは、内在性の種子貯蔵タンパク質の一部又は全部が欠損していることが好ましく、例えば、ダイズ11Sグロブリン及び/又はダイズ7Sグロブリンの一部又は全部が欠損しているダイズが挙げられる。ここで、「一部か欠損している」とは、野生型に比べて発現量が少ないことの他、一部のサブユニットのみが完全に欠損している場合や、一部のサブユニットのみの発現量が野生型に比べて少ない場合も含まれる。具体的には、ダイズ11Sグロブリンを欠損している変異系統EnB1、ダイズ7Sグロブリンを欠損している変異系統QY2、ダイズ11Sグロブリン及びダイズ7Sグロブリンの両方を欠損している変異系統QF2などが挙げられる。さらに、これらの欠損変異系統と一般的な品種(例えばJack等)との交配による後代系統も挙げられる。
形質転換ダイズ植物を作製するための材料として、例えば、根、茎、葉、種子、胚、胚珠、子房、茎頂、葯、花粉等の植物組織やその切片、未分化のカルス、不定胚、プロトプラスト等の植物培養細胞等を用いることができる。
なお、以下の実施例で行われる実験操作の手順は、特に記述しない限り、「Molecular Cloning」 第2版 (J. Sambrookら、Cold Spring Habor Laboratory press, 1989年発行)に記載される方法に従っている。
改変型ダイズ11SグロブリンA1aB1bの発現プラスミドの構築
βアミロイド抗原決定基として知られる配列番号3のアミノ酸配列からなるペプチド(以下Aβ4-10と略す)を含む改変型A1aB1bをコードする遺伝子をダイズ種子中で発現させるための発現プラスミドを構築した。手順を図2に示した。
改変型インゲンマメのアルセリンの発現プラスミドの構築
Aβ4-10がタンデムに2つ連なったペプチド(以降(Aβ4-10)×2と略す)をコードするDNAを挿入してなる改変型アルセリンをコードする遺伝子をダイズ種子中で発現させるための発現プラスミドを構築した。
具体的な方法を以下に示す。
改変型イネのプロラミンの発現プラスミドの構築
(Aβ4-10)×2をコードするDNAを挿入してなる改変型プロラミンをコードする遺伝子をダイズ種子中で発現させるための発現プラスミドを構築した。
具体的な方法を以下に示す。
アルセリン2プロモーターによる各種改変型発現プラスミドの構築
実施例1で作成した改変型A1aB1bをコードする遺伝子をインゲンマメ由来のアルセリン2プロモーターによりダイズ種子中で発現させるための発現プラスミドを構築した。
(1)インゲンマメ由来アルセリン2プロモーターの単離
インゲンマメ野生種(系統番号:G12866)の生葉1gからDNeasy Plant Maxi kit(キアゲン社製)を用いてゲノミックDNA50μgを抽出した。
280ngの上記ゲノミックDNAを制限酵素SauIIIAIで消化した後、dGTPを加え、klenow enzyme(プロメガ社製)により1塩基伸長反応を行った(第1回伸長反応)。その後、RightWalk KitTM付属のRWA-1アダプターとLigation high(東洋紡績社製)を用いて連結反応を行い、アルセリン2遺伝子の上流域のDNAを単離するためのPCRの鋳型とした。
次に、公知のインゲンマメアルセリン2遺伝子のcDNAの塩基配列(GenBank accession No.M28470)に基づき、配列番号50及び配列番号51の塩基配列からなるオリゴヌクレオチド(それぞれプライマーSP1及びプライマーSP2と命名)を、株式会社ファスマックのカスタム合成受託サービスを利用して作製した。
配列番号50(プライマーSP1) TTGGTTTTGT TGAACGTCTC GAC
配列番号51(プライマーSP2) GGTGAGAAGC ACAAGGAAGA GG
PCR終了後、反応液を100倍に希釈し、その1μLを2回目のPCRの鋳型とし、RightWalk KitTM付属のプライマーWP-2及びプライマーSP2を用いてPCRを行った。なお、2回目のPCRの溶液組成及び温度条件は、鋳型とプライマー以外、1回目のPCRと同条件で行った。
増幅されたDNA断片は、最終濃度1mMのATP存在下でT4 Polynucleotide Kinase(タカラバイオ社製)でリン酸化反応を行った後、予めSmaIで処理したpBluescriptII SK(-)(ストラタジーン社製)と連結反応を行った。
この反応産物を、Arc2P(i)とし、株式会社ファスマックのDNAシーケンシングサービスを用いて塩基配列を決定した。その結果、アルセリン2遺伝子の開始コドンの上流844bpの新規な領域を含むことを確認した。
280ngの上記ゲノミックDNAを制限酵素BglIIで消化した後、dGTPを加え、klenow enzyme(プロメガ社製)により1塩基伸長反応を行った。反応後、RightWalk KitTM付属のRWA-1アダプターと連結反応を行い、プロモーター単離のためのPCRの鋳型とした。
次に、公知のインゲンマメアルセリン2遺伝子のcDNAの塩基配列(GenBank accession No.M28470)に基づき、配列番号52の塩基配列からなるオリゴヌクレオチド(プライマーsecondSP1と命名)を、また第一回伸長反応で得られた開始コドンの上流844bpの塩基配列に基づき配列番号53の塩基配列からなるオリゴヌクレオチド(プライマーsecondSP2と命名)を作製した。
配列番号52(プライマーsecondSP1) CAGATTTTTT GCCCTCAAAA TTGATG
配列番号53(プライマーsecondSP2) CGGATGTGCG TGGACTACAA GG
反応終了後、上記PCR液を100倍に希釈し、その1μLを2回目のPCRの鋳型とし、RightWalk KitTM付属のプライマーWP-2及びプライマーsecondSP2を用いてPCRを行った。なお、2回目のPCRの溶液組成及び温度条件は、鋳型とプライマー以外、1回目のPCRと同条件である。
増幅されたDNA断片は、最終濃度1mMのATP存在下でT4 Polynucleotide Kinase(タカラバイオ社製)でリン酸化反応を行った後、予めSmaIで処理したpBluescriptII SK(-)(ストラタジーン社製)と連結反応を行った。
反応産物を、Arc2P(ii)とし塩基配列を決定した。次に、さらに上流域を単離するため、新たなプライマーを作製し第三回目となる伸長反応を行った。
280ngの上記ゲノミックDNAを制限酵素XbaIで消化した後、dCTPを加え、klenow enzyme(プロメガ社製)により1塩基伸長反応を行った。反応後、RightWalk KitTM付属のRWA-2アダプターと連結反応を行い、プロモーター単離のためのPCRの鋳型とした。
次に、第二回伸長反応で得られた197bpの塩基配列に基づき、配列番号54及び配列番号55の塩基配列からなるオリゴヌクレオチド(それぞれプライマーthirdSP1及びプライマーthirdSP2と命名)を作製した。
配列番号54(プライマーthirdSP1) CGACCTGAAG AACGCAGCGG CGACC
配列番号55(プライマーthirdSP2) TACCAGCAGT TGATGGACAA GATC
反応終了後、上記反応液を100倍に希釈し、その1μLを2回目のPCRの鋳型とし、RightWalk KitTM付属のプライマーWP-2及びプライマーthirdSP2を用いてPCRを行った。なお、2回目のPCRの溶液組成及び温度条件は、鋳型とプライマー以外、1回目のPCRと同条件である。
増幅されたDNA断片は、最終濃度1mMのATP存在下でT4 Polynucleotide Kinase(タカラバイオ社製)でリン酸化反応を行った後、予めSmaIで処理したpBluescriptII SK(-)(ストラタジーン社製)と連結反応を行った。
この反応産物を、Arc2P(iii)とし、塩基配列を決定した。その結果、Arc2P(ii)の上流2819bp(合計3860bp)の新規な領域を含むことを確認した。以上、三回の伸長反応によってアルセリン2遺伝子の開始コドンの上流5′側非翻訳領域を含む3860bpの新規なプロモーター配列を含むDNA(Arc2P)を取得した(配列番号56:このうちプロモーター領域は塩基番号1399~3860)。
上記(1)で抽出したゲノミックDNA280ngを制限酵素NheIで消化した後、dCTPを加え、klenow enzyme(プロメガ社製)により1塩基伸長反応を行った。反応後、RightWalk KitTM付属のRWA-2アダプターとLigation high(東洋紡績社製)を用いて連結反応を行い、ターミネーター遺伝子の単離のためのPCRの鋳型とした。
次に、公知のインゲンマメアルセリン2遺伝子のcDNAの塩基配列(GenBank accession No.M28470)に基づき、配列番号57及び配列番号58の塩基配列からなるオリゴヌクレオチド(それぞれプライマーSP3及びプライマーSP4と命名)を作製した。
配列番号57(プライマーSP3)CATCAATTTT GAGGGCAAAA AATCTG
配列番号58(プライマーSP4)CGTTCCAACA TCCTCCTCAA CAAGATC
PCR終了後、反応液を100倍に希釈し、その1μLを2回目のPCRの鋳型とし、RightWalk KitTM付属のプライマーWP-2及びプライマーSP4を用いてPCRを行った。なお、2回目のPCRの溶液組成及び温度条件は、鋳型とプライマー以外、1回目のPCRと同条件で行った。
増幅されたDNA断片は、最終濃度1mMのATP存在下でT4 Polynucleotide Kinase(タカラバイオ社製)でリン酸化反応を行った後、予めSmaIで処理したpBluescriptII SK(-)(ストラタジーン社製)と連結反応を行った。
反応産物を、Arc2Tとし、塩基配列を決定した。その結果、アルセリン2遺伝子の3’側非翻訳領域を含む終止コドンの下流795bpの新規な領域を含むことを確認した(配列番号59)。
改変型A1aB1bをコードする遺伝子を種子で発現させるため、実施例1で得られた各種改変型A1aB1bをコードする遺伝子、Arc2PおよびArc2Tを公知のpUHGベクター(前述)図3)に連結し、発現プラスミドの構築を行った。
改変型A1aB1b遺伝子のDNA断片、プロモーターDNA断片、ターミネーターDNA断片はリン酸化反応後、あらかじめSmaIで切断後CIAP(タカラバイオ社製)で脱リン酸化反応を行ったpUHGベクターと連結反応を行った。得られたクローンからArc2Pプロモーター、改変型A1aB1bをコードする遺伝子、Arc2Tターミネーターの順に正しく連結されたクローンを、塩基配列を解析することによって選択した。
こうして、改変型A1aB1bをコードする遺伝子がアルセリン2プロモーターの制御下で種子特異的に発現する以下の植物形質転換ベクター5種(pUHGA2PA1aB1bM1、pUHGA2PA1aB1bM3、pUHGA2PA1aB1bM5)を構築した。
また、同様にして前述のRP10M1をコードする遺伝子が種子特異的に発現する植物形質転換ベクターpUHGA2PRP10M1を構築した。
改変型種子貯蔵タンパク質をコードする遺伝子のダイズへの導入
公知の方法(K. Nishizawa, Y. Kita, M. Kitayama, M. Ishimoto. (2006) A red fluorescent protein, DsRed2, as a visual reporter for transient expression and stable transformation in soybean. Plant Cell Reports 25:1355-1361)により、ダイズ品種Jackおよび主要な種子貯蔵タンパク質である11Sグロブリン及び7Sグロブリンを欠損する変異系統(独立行政法人農業・食品産業技術総合研究機構、北海道農業研究センター保有)(Y. Kita,K. Nishizawa,M Takahashi, M. Kitayama, M. Ishimoto. (2007)Genetic improvement of somatic embryogenesis and regeneration in soybean and transformation of the improved breeding lines. Plant Cell Reports 26:439-447)の未熟種子から誘導された不定胚塊(直径3mm以下)30個を1.5ml用のチューブに加え、ウイスカー超音波法(特許第3312867号)により遺伝子導入操作を行った。
改変型種子貯蔵タンパク質遺伝子を導入した形質転換ダイズ植物の作出
このようにしてJack品種にA1aB1BM1を導入した形質転換ダイズ植物を6個体、A1aB1bM2を導入した形質転換体を6個体、A1aB1bM3を導入した形質転換体を5個体、A1aB1bM4-1を導入した形質転換体を5個体、A1aB1bM5を導入した形質転換体を9個体作出した。さらに、Arc5M1を導入した形質転換ダイズ植物を3個体、Arc5M2を導入した形質転換体を3個体、RP10M1を導入した形質転換ダイズ植物を2個体作出した。
また、前記11Sグロブリン及び7Sグロブリンを欠損する変異系統(以下、種子貯蔵タンパク質欠損品種という)にA1aB1bM1を導入した形質転換ダイズ植物を12個体、RP10M1を導入した形質転換ダイズ植物を6個体作出した。
さらに種子貯蔵タンパク質欠損品種にA1aB1bM3を導入した形質転換ダイズ植物を5個体、作出した。
さらに、種子貯蔵タンパク質欠損品種にA2PA1aB1bM1を導入した形質転換体を8個体、A2PA1aB1bM3を導入した形質転換体を33個体、A2PA1aB1bM5を導入した形質転換体を32個体、A2PRP10M1を導入した形質転換体を9個体作出した。
これらの形質転換ダイズの植物体は環境湿度に適応させた後、10000lx、16時間日長の環境下で栽培を継続し、すべての個体から種子を収穫した。こうして、形質転換ダイズ植物のT1世代の種子を得た。
形質転換ダイズ種子におけるAβ4-10の蓄積量の評価
上記実施例6で得た形質転換ダイズ種子より全タンパク質を抽出し、Aβ4-10の蓄積量をAβ4-10に対する特異抗体を用いたウエスタンブロッティング法で評価した。特に蓄積量の高い系統については、定量解析を行った。
形質転換ダイズ種子より抽出した全タンパク質20μgをSDS-PAGEで分離し、Aβ4-10に対する特異抗体を反応させた後、ECL Advance Western Blotting Detection Kit(GEヘルスケアバイオサイエンス株式会社製)を用いて検出を行った。化学発光像を、LAS4000miniPR(富士フィルム社製)で取り込んだ後、同機付属の解析ソフトウェアMultiGageを用いて定量解析を行った。定量の標品としては、大腸菌発現系で作製したHis・Tag連結組換えタンパク質A1aB1bM1を用いた。
さらに、A1aB1BM3(Aβ4-10が1個挿入されている遺伝子)を種子貯蔵タンパク質欠損品種に導入した形質転換ダイズにおける改変型種子貯蔵タンパク質の蓄積量の測定をウエスタンブロット解析により行った結果を表4に示した。
形質転換ダイズ種子より抽出した全タンパク質20μgをSDS-PAGEで分離し、Aβ4-10に対する特異抗体で反応を行った後、ECL Advance Western Blotting Detection Kit(GEヘルスケアバイオサイエンス株式会社製)を用いてウエスタンブロット検出を行った結果、Arc5M1を導入した形質転換ダイズ種子(系統2-1)およびArc5M2導入した形質転換ダイズ種子(系統2-2)にAβ4-10ペプチドに相当するシグナルバンドが確認でき、Aβ4-10の蓄積が確認できた(図5)。
RP10M1形質転換ダイズ種子(系統1-1、4-2)より抽出した全タンパク質20μgをSDS-PAGEで分離し、Aβ4-10に対する特異抗体で反応を行った後、ECL Advance Western Blotting Detection Kit(GEヘルスケアバイオサイエンス株式会社製)を用いてウエスタンブロット検出を行った結果、PR10M1を導入した形質転換ダイズ種子の各系統にAβ4-10ペプチドに相当するシグナルバンドが確認でき、Aβ4-10ペプチドの蓄積が確認できた(図6)。
同様に、種子貯蔵タンパク質欠損品種に導入したRP10M1形質転換ダイズ種子にAβ4-10ペプチドに相当するシグナルバンドが確認でき、Aβ4-10ペプチドの蓄積が確認できた。その際の蓄積量は、No.1-1系統で約380μg/g種子であった。
形質転換ダイズ種子より抽出した全タンパク質20μgをSDS-PAGEで分離し、実施例7の1)と同様の方法で検出を行った。
その結果、上記実施例6で得た形質転換ダイズ種子の各系統にAβ4-10に相当するシグナルバンドが確認でき、Aβ4-10の蓄積が確認できた(図7)。
また、シグナルバンドの強度から推定される種子貯蔵タンパク質欠損品種へ導入した形質転換ダイズ種子中のAβ4-10蓄積量は、当該A2PA1aB1bM1(系統4-6)は、A1aB1bM1(系統7-1)と比べてほぼ同等であって、Jack品種に導入したA1aB1bM1(系統8-1)と比べて明らかに蓄積量は多いことが確認できた(図7)。
改変型種子貯蔵タンパク質の効果検定
前記実施例1で作製したA1aB1bM1を公知の方法により大腸菌に発現させて生産した。
上記実施例6で得た形質転換ダイズ種子に対して各種熱処理を行い、種子中の改変型種子貯蔵タンパク質の熱安定性について試験を行った。
1)形質転換ダイズ種子の焙煎処理区
A1aB1bM3形質転換ダイズ種子を粉砕した後、粉砕物の10mgをオートクレーブ滅菌装置にて100℃で10分間の処理を行い、その後上記実施例7に記載の方法で全タンパク質を抽出し、種子中の存在するAβ4-10の蓄積量をAβ4-10に対する特異抗体を用いたウエスタンブロッティング法で評価した。
2)形質転換ダイズ種子の水煮処理区
A1aB1bM3形質転換ダイズ種子を粉砕した後、粉砕物の10mgに対し30μlの蒸留水を加えて攪拌した後、オートクレーブ滅菌装置にて100℃で10分間の処理を行い、その後上記実施例7に記載の方法で全タンパク質を抽出し、種子中の存在するAβ4-10の蓄積量をAβ4-10に対する特異抗体を用いたウエスタンブロッティング法で評価した。
3)形質転換ダイズ種子からのタンパク質抽出液の加熱処理区
A1aB1bM3形質転換ダイズ種子を粉砕した後、実施例7に記載の方法で全タンパク質を抽出し、その後オートクレーブ滅菌装置にて100℃で10分間の処理を行った。その後上記種子中の存在するAβ4-10の蓄積量をAβ4-10に対する特異抗体を用いたウエスタンブロッティング法で評価した。
その結果、焙煎処理区および水煮処理区においてAβ4-10に相当するシグナルバンドが確認でき、その量は熱無処理区と同等であり、種子中の改変型種子貯蔵タンパク質の熱安定性が確認できた(図8)。
Aβ4-10をコードするアミノ酸配列のペプチド(P1)、P1をタンデムに2つ連結したアミノ酸配列のペプチド(P2)、さらにP1をタンデムに3つ連結したアミノ酸配列のペプチド(P3)をペプチド受託合成サービスを利用して合成した。
P1 :FRHDSGY(配列番号3)
P2 :FRHDSGY FRHDSGY(配列番号60)
P3 :FRHDSGY FRHDSGY FRHDSGY(配列番号61)
次にペプチドP1、P2、P3のN末側にキャリアタンパクのkey-limpet-hemocyanin(KLH、Mw.1000000)をシステイン(Cys)を架橋として結合させたKLH-P1、KLH-P2、KLH-P3を作製した。
これらKLH-P1、KLH-P2、KLH-P3の50μgを生理食塩水に溶解して、生後4週齢のマウス(BALBc)に1週間間隔で5回、皮下注射(3匹/区)による投与を行った。投与9週後のマウスから血液を採取して、抗血清を採取した。得られた抗血清をアフィニティー精製して、KLH-P1、KLH-P2、KLH-P3に対する精製抗体を作製した。
市販の合成Aβ42の400、1000ピコモルをSDS-PAGEで泳動し、上記のKLH-P1、KLH-P2、KLH-P3に対する上記の精製抗体を反応させた後、ECL Advance Western Blotting Detection Kit(GEヘルスケアバイオサイエンス株式会社製)を用いて検出を行った。化学発光像を、LAS4000miniPR(富士フィルム社製)で取り込んだ後、Aβ42との結合性についてシグナル強度の比較を行った。その結果、KLH-P2のシグナル強度がKLH-P1、KLH-P3よりも明らかに強く、Aβ4-10をコードするアミノ酸配列のペプチドをタンデムに2つ連結することによりAβに対する抗体価の高い特異的抗体が得られることがわかった。(図9)
Claims (15)
- 改変型種子貯蔵タンパク質をコードする遺伝子が導入された形質転換ダイズ植物であって、該改変型種子貯蔵タンパク質をコードする遺伝子は、野生型種子貯蔵タンパク質をコードする遺伝子の可変領域にアルツハイマー病ワクチンをコードする遺伝子がフレームシフトを生じないように挿入されたものであり、該改変型種子貯蔵タンパク質は種子中で発現して蓄積することを特徴とする、形質転換ダイズ植物。
- 前記アルツハイマー病ワクチンが、βアミロイド抗原決定基であることを特徴とする、請求項1に記載の形質転換ダイズ植物。
- βアミロイド抗原決定基が配列番号3のペプチドが1~3個連結された配列からなる、請求項2に記載の形質転換ダイズ植物。
- 前記形質転換ダイズ植物は、内在性のダイズ11Sグロブリン及び/又はダイズ7Sグロブリンを欠損していることを特徴とする請求項1~3のいずれか一項に記載の形質転換ダイズ植物。
- 前記野生型種子貯蔵タンパク質が、ダイズ11SグロブリンのA1aB1bサブユニット、インゲンマメのアルセリン又はイネのプロラミンであることを特徴とする、請求項1~4のいずれか一項に記載の形質転換ダイズ植物。
- 前記野生型種子貯蔵タンパク質が、配列番号2のアミノ酸配列、又は配列番号2のアミノ酸配列と90%以上の同一性を有するアミノ酸配列を含むものであり、前記アルツハイマー病ワクチンをコードする遺伝子が挿入された可変領域が、配列番号2におけるアミノ酸番号111~128、アミノ酸番号198~216、アミノ酸番号268~315、及びアミノ酸番号490~495に相当するアミノ酸配列の群から選択される1つ又は複数のアミノ酸配列をコードする領域である、請求項5に記載の形質転換ダイズ植物。
- 前記野生型種子貯蔵タンパク質が、配列番号37のアミノ酸配列、又は配列番号37のアミノ酸配列と90%以上の同一性を有するアミノ酸配列を含むものであり、前記アルツハイマー病ワクチンをコードする遺伝子が挿入された可変領域が、配列番号37におけるアミノ酸番号149~150及び/またはアミノ酸番号250~251に相当するアミノ酸配列をコードする領域である、請求項5に記載の形質転換ダイズ植物。
- 前記野生型種子貯蔵タンパク質が、配列番号45のアミノ酸配列、又は配列番号45のアミノ酸配列と90%以上の同一性を有するアミノ酸配列を含むものであり、前記アルツハイマー病ワクチンをコードする遺伝子が挿入された可変領域が、配列番号45におけるアミノ酸番号110~111に相当するアミノ酸配列をコードする領域である、請求項5に記載の形質転換ダイズ植物。
- 前記改変型種子貯蔵タンパク質をコードする遺伝子はインゲンマメアルセリン2のプロモーターまたはダイズの11SグロブリンA1aB1bサブユニットのプロモーターによって発現制御された、請求項1~8のいずれか一項に記載の形質転換ダイズ植物。
- 請求項1~9のいずれか一項に記載の形質転換ダイズ植物の細胞。
- 請求項1~9のいずれか一項に記載の形質転換ダイズ植物の種子。
- 請求項11に記載の種子を加工してなる、ダイズ種子加工品。
- 請求項1~9のいずれか一項に記載の形質転換ダイズ植物を用いて、該形質転換ダイズ植物の種子中でアルツハイマー病ワクチンを生産する方法。
- ダイズ種子特異的な発現を誘導するプロモーターと、該プロモーターの下流に連結された、野生型種子貯蔵タンパク質をコードする遺伝子の可変領域にアルツハイマー病ワクチンをコードする遺伝子がフレームシフトを生じないように挿入された改変型種子貯蔵タンパク質をコードする遺伝子とを含むベクター。
- 前記プロモーターはインゲンマメアルセリン2のプロモーターまたはダイズの11SグロブリンA1aB1bサブユニットのプロモーターである、請求項14に記載ベクター。
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