Updated on 2024/04/24
博士(農学) ( 2000.3 名古屋大学 )
Environmental Science/Agriculture Science / Plant protection science / 植物病理学
Life Science / Plant molecular biology and physiology
Life Science / Molecular biology
Isolation and characterization of genes from Solanaceae plants for the resistance against potato late blight pathogen, Phytophthora infestans.
Isolation and characterization of genes from symbiotic fungi for the establishment of symbiosis.
植物病原菌の病原性に関する研究
Nagoya University Professor
2023.9
Nagoya University Associate professor
2011.4 - 2023.8
Country:Japan
Nagoya University Assistant Professor
2007.5 - 2011.3
Country:Japan
Nagoya University
1997.4 - 2000.3
Country: Japan
Nagoya University Graduate School, Division of Agriculture
1995.4 - 1997.3
Country: Japan
Nagoya University Faculty of Agriculture
1991.4 - 1995.3
Country: Japan
日本植物病理学会
糸状菌分子生物学研究会
日本植物生理学会
日本植物病理学会報 原著編集委員
2020.1
Committee type:Academic society
Associate editor
2020.1
Committee type:Academic society
日本植物病理学会 編集委員会 編集幹事長
2016.1 - 2017.12
The full-size ABCG transporters Nb-ABCG1 and Nb-ABCG2 Function in Pre- and post-invasion defense against Phytophthora infestans in Nicotiana benthamiana. Reviewed
Shibata Y., Ojika M., Sugiyama A., Yazaki K., Jones D.A., Kawakita K. and Takemoto D.
Plant Cell Vol. 28 page: 1163-1181 2016
VibA, a homologue of a transcription factor for fungal heterokaryon incompatibility, is involved in the antifungal compound production in the plant symbiotic fungus Epichloë festucae. Reviewed
Niones J.T. and Takemoto D.
Eukaryot. Cell Vol. 14 ( 1 ) page: 13-24 2015.1
Polarity proteins Bem1 and Cdc24 are components of the filamentous fungal NADPH oxidase complex. Reviewed
Takemoto D., Kamakura S., Saikia S., Becker Y., Wrenn R., Tanaka A., Sumimoto H. and Scott B.
Proc. Natl. Acad. Sci. USA. Vol. 108 page: 2861-2866 2011.2
A p67Phox-like regulator recruited to control hyphal branching in a fungal-plant mutualistic symbiosis. Reviewed
Vol. 18 ( 10 ) page: 2807-2821 2006.10
Pring, S; Kato, H; Imano, S; Camagna, M; Tanaka, A; Kimoto, H; Chen, PR; Shrotri, A; Kobayashi, H; Fukuoka, A; Saito, M; Suzuki, T; Terauchi, R; Sato, I; Chiba, S; Takemoto, D
PHYSIOLOGIA PLANTARUM Vol. 175 ( 5 ) page: e14052 2023.8
Ashida, A; Camagna, M; Sato, I; Chiba, S; Tanaka, A; Takemoto, D
MICROBIOLOGY RESOURCE ANNOUNCEMENTS Vol. 12 ( 6 ) page: e0025923 2023.6
Bulasag, AS; Camagna, M; Kuroyanagi, T; Ashida, A; Ito, K; Tanaka, A; Sato, I; Chiba, S; Ojika, M; Takemoto, D
FRONTIERS IN PLANT SCIENCE Vol. 14 page: 1177060 2023.6
Ashida, A; Takushi, T; Camagna, M; Sato, I; Chiba, S; Takemoto, D
JOURNAL OF GENERAL PLANT PATHOLOGY Vol. 89 ( 3 ) page: 179 - 184 2023.5
Kato, F; Ando, Y; Tanaka, A; Suzuki, T; Takemoto, D; Ojika, M
BIOSCIENCE BIOTECHNOLOGY AND BIOCHEMISTRY Vol. 87 ( 2 ) page: 208 - 216 2023.1
Kuroyanagi, T; Bulasag, AS; Fukushima, K; Ashida, A; Suzuki, T; Tanaka, A; Camagna, M; Sato, I; Chiba, S; Ojika, M; Takemoto, D
PNAS NEXUS Vol. 1 ( 5 ) page: pgac274 2022.11
Kato, F; Ando, Y; Tanaka, A; Suzuki, T; Takemoto, D; Ojika, M
JOURNAL OF AGRICULTURAL AND FOOD CHEMISTRY Vol. 70 ( 40 ) page: 12878 - 12884 2022.10
Tanaka, A; Takemoto, D; Sato, I; Chiba, S; Gavrilova, O; Gagkaeva, T
MICROBIOLOGY RESOURCE ANNOUNCEMENTS Vol. 11 ( 7 ) page: e0125021 2022.7
Quenu, M; Treindl, AD; Lee, K; Takemoto, D; Thünen, T; Ashrafi, S; Winter, D; Ganley, ARD; Leuchtmann, A; Young, CA; Cox, MP
JOURNAL OF FUNGI Vol. 8 ( 7 ) 2022.7
Recognition of pathogen-derived sphingolipids in <i>Arabidopsis</i>
Kato, H; Nemoto, K; Shimizu, M; Abe, A; Asai, S; Ishihama, N; Matsuoka, S; Daimon, T; Ojika, M; Kawakita, K; Onai, K; Shirasu, K; Yoshida, M; Ishiura, M; Takemoto, D; Takano, Y; Terauchi, R
SCIENCE Vol. 376 ( 6595 ) page: 857 - + 2022.5
Imano, S; Fushimi, M; Camagna, M; Tsuyama-Koike, A; Mori, H; Ashida, A; Tanaka, A; Sato, I; Chiba, S; Kawakita, K; Ojika, M; Takemoto, D
FRONTIERS IN PLANT SCIENCE Vol. 12 page: 821574 2022.1
Tanaka, A; Ryder, MH; Suzuki, T; Uesaka, K; Yamaguchi, N; Amimoto, T; Otani, M; Nakayachi, O; Arakawa, K; Tanaka, N; Takemoto, D
MOLECULAR PLANT-MICROBE INTERACTIONS Vol. 35 ( 1 ) page: 73 - 84 2022.1
Neang, S; Bincader, S; Rangsuwan, S; Keawmanee, P; Rin, S; Salaipeth, L; Das, S; Kondo, H; Suzuki, N; Sato, I; Takemoto, D; Rattanakreetakul, C; Pongpisutta, R; Arakawa, M; Chiba, S
VIRUSES-BASEL Vol. 13 ( 11 ) 2021.11
Pathogen-derived 9-methyl sphingoid base is perceived by a lectin receptor kinase in Arabidopsis.
Kato H, Nemoto K, Shimizu M, Abe A, Asai S, Ishihama N, Daimon T, Ojika M, Kawakita K., Onai K, Shirasu K, Ishiura M, Takemoto D, Takano Y and Terauchi R
BioRxiv 2021.10
Two structurally different oomycete MAMPs induce distinctive plant immune responses. International coauthorship
Monjil MS, Kato H, Matsuda K, Suzuki N, Tenhiro S, Camagna M, Suzuki T, Tanaka A, Terauchi R, Sato I, Chiba S, Kawakita K, Ojika M and Takemoto D
BioRxiv 2021.10
Katayama, T; Bayram, Ö; Mo, TN; Karahoda, B; Valerius, O; Takemoto, D; Braus, GH; Kitamoto, K; Maruyama, J
MOLECULAR MICROBIOLOGY Vol. 115 ( 4 ) page: 723 - 738 2021.4
Ong, S; Jonson, GB; Calassanzio, M; Rin, S; Chou, C; Oi, T; Sato, I; Takemoto, D; Tanaka, T; Choi, IR; Nign, C; Chiba, S
PATHOGENS Vol. 10 ( 2 ) 2021.2
Effect of flutianil on the morphology and gene expression of powdery mildew
Kimura, S; Shibata, Y; Oi, T; Kawakita, K; Takemoto, D
JOURNAL OF PESTICIDE SCIENCE Vol. 46 ( 1-2 ) page: 206 - 213 2021
Tanaka, A; Kamiya, S; Ozaki, Y; Kameoka, S; Kayano, Y; Sanjay, S; Akano, F; Uemura, A; Takagi, H; Terauchi, R; Maruyama, J; Hammadeh, HH; Fleissner, A; Scott, B; Takemoto, D
MOLECULAR MICROBIOLOGY Vol. 114 ( 4 ) page: 626 - 640 2020.10
Rin, S; Imano, S; Camagna, M; Suzuki, T; Tanaka, A; Sato, I; Chiba, S; Kawakita, K; Takemoto, D
JOURNAL OF GENERAL PLANT PATHOLOGY Vol. 86 ( 5 ) page: 340 - 349 2020.9
Morimura, H; Ito, M; Yoshida, S; Koitabashi, M; Tsushima, S; Camagna, M; Chiba, S; Takemoto, D; Kawakita, K; Sato, I
TOXINS Vol. 12 ( 6 ) 2020.6
Shinjo, R; Tanaka, A; Sugiura, D; Suzuki, T; Uesaka, K; Takebayashi, Y; Kojima, M; Sakakibara, H; Takemoto, D; Kondo, M
PLANT AND SOIL Vol. 450 ( 1-2 ) page: 537 - 555 2020.5
Ichinose, Y; Nishimura, T; Harada, M; Kashiwagi, R; Yamamoto, M; Noutoshi, Y; Toyoda, K; Taguchi, F; Takemoto, D; Matsui, H
PLANT PATHOLOGY JOURNAL Vol. 36 ( 2 ) page: 148 - 156 2020.4
Purev, E; Kondo, T; Takemoto, D; Niones, JT; Ojika, M
MOLECULES Vol. 25 ( 5 ) 2020.3
Camagna, M; Ojika, M; Takemoto, D
PLANT SIGNALING & BEHAVIOR Vol. 15 ( 2 ) page: 1707348 2020.2
Kojima, T; Asakura, N; Hasegawa, S; Hirasawa, T; Mizuno, Y; Takemoto, D; Katou, S
BMC PLANT BIOLOGY Vol. 19 ( 1 ) page: 576 2019.12
Accumulation of agrocinopine-like substrate in Ipomoea batatas
Tanaka, A; Takemoto, D; Suzuki, T; Uesaka, K; Yamaguchi, N; Otani, M; Nakayachi, O; Tanaka, N
MOLECULAR PLANT-MICROBE INTERACTIONS Vol. 32 ( 10 ) page: 55 - 56 2019.10
Three novel deoxynivalenol-degrading bacteria isolated from Poaceae planted soils in Japan.
Morimura, H; Chiba, S; Takemoto, D; Kawakita, K; Sato, I
MOLECULAR PLANT-MICROBE INTERACTIONS Vol. 32 ( 10 ) page: 25 - 25 2019.10
Imano, S; Kondou, Y; Shibata, Y; Kondo, T; Tanaka, A; Sato, I; Chiba, S; Kageyama, K; Kawakita, K; Takemoto, D
MOLECULAR PLANT-MICROBE INTERACTIONS Vol. 32 ( 10 ) page: 108 - 108 2019.10
Shinjo, R; Tanaka, A; Suzuki, T; Takemoto, D; Kondo, M
MOLECULAR PLANT-MICROBE INTERACTIONS Vol. 32 ( 10 ) page: 192 - 192 2019.10
Kuroyanagi, T; Ojika, M; Suzuki, T; Sato, I; Chiba, S; Kawakita, K; Takemoto, D
MOLECULAR PLANT-MICROBE INTERACTIONS Vol. 32 ( 10 ) page: 40 - 40 2019.10
Mizuno, Y; Imano, S; Camagna, M; Suzuki, T; Tanaka, A; Sato, I; Chiba, S; Kawakita, K; Takemoto, D
JOURNAL OF GENERAL PLANT PATHOLOGY Vol. 85 ( 5 ) page: 347 - 355 2019.9
Mizuno Yuri, Ohtsu Mina, Shibata Yusuke, Tanaka Aiko, Camagna Maurizio, Ojika Makoto, Mori Hitoshi, Sato Ikuo, Chiba Sotaro, Kawakita Kazuhito, Takemoto Daigo
FRONTIERS IN PLANT SCIENCE Vol. 10 page: 222 2019.3
Takemoto Daigo, Shibata Yusuke, Ojika Makoto, Mizuno Yuri, Imano Sayaka, Ohtsu Mina, Sato Ikuo, Chiba Sotaro, Kawakita Kazuhito, Rin Soriya, Camagna Maurizio
JOURNAL OF GENERAL PLANT PATHOLOGY Vol. 84 ( 5 ) page: 312 - 320 2018.9
Measuring Secretion of Capsidiol in Leaf Tissues of Nicotiana benthamiana
Kuroyanagi Teruhiko, Camagna Maurizio, Takemoto Daigo
BIO-PROTOCOL Vol. 8 ( 15 ) page: e2954 2018.8
Hypersensitive Response in Plants Invited Reviewed
Maurizio Camagna, Daigo Takemoto
Encyclopedia of Life Sciences page: 1-7 2018.1
Yuka Kayano, Aiko Tanaka, Daigo Takemoto
PLoS Pathogens Vol. 14 ( 1 ) page: e1006840 2018.1
Green Kimberly A., Becker Yvonne, Tanaka Aiko, Takemoto Daigo, Fitzsimons Helen L., Seiler Stephan, Lalucque Herve, Silar Philippe, Scott Barry
MOLECULAR MICROBIOLOGY Vol. 103 ( 4 ) page: 657 - 677 2017.2
Soriya Rin, Yuri Mizuno, Yusuke Shibata, Mayuka Fushimi, Shinpei Katou, Ikuo Sato, Sotaro Chiba, Kazuhito Kawakita, Daigo Takemoto
Plant Signaling and Behavior Vol. 12 ( 4 ) page: e1300733 2017
Methanol extract of mycelia from Phytophthora infestans-induced resistance in potato. Reviewed
Monjil M.S., Nozawa T., Shibata Y., Takemoto D., Ojika M. and Kawakita K.
C. R. Biol. Vol. 338 ( 5 ) page: 185-196 2015.3
Nucleoporin 75 is involved in the ethylene-mediated production of phytoalexin for the resistance of Nicotiana benthamiana to Phytophthora infestans. Reviewed
Ohtsu M., Shibata Y., Ojika M., Tamura K., Hara-Nishimura I., Mori H., Kawakita K. and Takemoto D.
Mol. Plant-Microbe Interact. Vol. 27 ( 12 ) page: 1318-1330 2014.12
Phytophthora infestans : ジャガイモ疫病菌研究ー過去と現在の概観 Invited Reviewed
秋野聖之、竹本大吾、保坂和良
日本植物病理学会報 Vol. 80 page: 8-15 2014.11
The water extract of Saragassum fusiforme is a potential elicitor of induced resistance in Solanum lycopersicum but not in Nicotiana benthamiana. Reviewed
Sbaihat L, Takemoto D. and Kawakita K.
International Journal of Biosciences and Biotechnology Vol. 2 ( 1 ) page: 11-19 2014.9
Phytophthora infestans: a review of past and current studies on potato late blight. Invited Reviewed
Akino S., Takemoto D. and Hosaka K.
J. Gen. Plant Pathol. Vol. 80 page: 24-37 2014
An isolate of Epichloe festucae, an endophytic fungus of temperate grasses, has growth inhibitory activity against selected grass pathogens Reviewed
Niones J.T., Takemoto D.
J. Gen. Plant Pathol. Vol. in press 2014
Proteomic analysis of S-nitrosylated proteins in potato plant.
Kato H., Takemoto D. and Kawakita K.
Physiol. Plant. Vol. 148 page: 371-386 2013
Bis-aryl methanone compound is a candidate of nitric oxide producing elicitor and induces resistance in Nicotiana benthamiana against Phytophthora infestans. Reviewed
Monjil M.S., Shibata Y., Takemoto D. and Kawakita K.
Nitric Oxide Vol. 29: page: 34-45 2013
Nicotiana benthamiana Calreticulin 3a is required for the ethylene-mediated production of phytoalexins and disease resistance against oomycete pathogen Phytophthora infestans. Reviewed
Matsukawa M., Shibata Y., Ohtsu M., Mizutani A., Mori H., Wang P., Ojika M., Kawakita K. and Takemoto D.
Mol. Plant-Microbe Interact. Vol. 26 page: 880-892 2013
Differential roles of NADPH oxidases and associated regulators in polarized growth, conidiation and hyphal fusion in the symbiotic fungus Epichloë festucae. Reviewed
Kayano Y., Tanaka A., Akano F., Scott B. and Takemoto D.
Fungal Genet. Biol. Vol. 56 page: 87-97 2013
ProA, a transcriptional regulator of fungal fruiting body development, regulates leaf hyphal network development in the Epichloë festucae-Lolium perenne symbiosis.
Tanaka A., Cartwright G.M., Saikia S., Kayano Y., Takemoto D., Kato M., Tsuge T. and Scott B.
Mol Microbiol. Vol. 90 page: 551-568 2013
N-terminal motifs in some plant disease resistance proteins function in membrane attachment and contribute to disease resistance.
Takemoto D., Rafiqi M., Hurley U., Lawrence G.J., Bernoux M., Hardham A.R., Ellis J.G., Dodds P.N. and Jones D.A.
Molecular Plant-Microbe Interactions Vol. 25 ( 3 ) page: 379-392 2012.3
Functional analysis of an indole-diterpene gene cluster for lolitrem B biosynthesis in the grass endosymbiont Epichloë festucae. Reviewed
Saikia S, Takemoto D, Tapper B.A., Lane G.A., Fraser K and Scott B.
FEBS Lett. Vol. 586 page: 2563-2569. 2012
Rose phytoene desaturase gene silencing by apple latent spherical virus vectors. Reviewed
Ito H., Ochiai M., Kato H., Shiratake K., Takemoto D., Otagaki S. and Matsumoto S.
Hortscience Vol. 47 page: 1278-1282. 2012
SGT1 and HSP90 are essential for age-related non-host resistance of Nicotiana benthamiana against the oomycete pathogen Phytophthora infestans Reviewed
Shibata Y., Kawakita K. and Takemoto D.
Physiological and Molecular Plant Pathology Vol. 75 page: 120-128 2011
エンドファイトが産生する生理活性物質の生合成遺伝子とその発現調節 Invited
竹本大吾、田中愛子、Barry Scott
Vol. 61 ( 1 ) page: 13-18 2011
エンドファイトと植物の共生確立機構 Invited
田中愛子、竹本大吾、Barry Scott
Mycotoxins Vol. 61 ( 1 ) page: 19-23 2011
Age-related resistance of Nicotiana benthamiana against hemibiotrophic pathogen Phytophthora infestans requires both ethylene- and salicylic acid-mediated signaling pathways. Reviewed
Shibata Y., Kawakita K. and Takemoto D.
Molecular Plant-Microbe Interactions Vol. 23 ( 9 ) page: 1130-1142 2010
N,N-dimethylsphingosine, an inhibitor of sphingosine kinase, induces phytoalexin production and hypersensitive cell death of Solanaceae plants without generation of reactive oxygen species. Reviewed
Uruma S., Shibata Y., Takemoto D. and Kawakita K.
Journal of General Plant Pathology Vol. 75 page: 257-266 2009
NoxA activation by the small GTPase RacA is required to maintain a mutualistic association between Epichloë festucae and perennial ryegrass. Reviewed
Vol. 68 ( 5 ) page: 1165-1178 2008.5
Rapid and dynamic subcellular reorganaization following mechanical stimulation of Arabidopsis epidermal cells mimics responsed to fungal and oomycete attack. Reviewed
Hardham, A.R, Takemoto D. and White, R.G.
BMC Plant Biology Vol. 8 page: 63 2008
NADPH oxidases in fungi: diverse roles of reactive oxygen species in fungal cellular differentiation. Invited Reviewed
Takemoto D., Tanaka A. and Scott B.
Fungal Genetics and Biology Vol. 44 ( 11 ) page: 1065-1076 2007.11
Cytoskeleton and cell wall function in penetration resistance. Invited Reviewed
Hardham A.R., Jones D.A. and Takemoto D.
Current Opinion in Plant Biology Vol. 10 ( 4 ) page: 342-348 2007.8
Fungal endophyte production of reactive oxygen species is critical for maintaining the mutualistic symbiotic interaction between Epichloe¨ festucae and perennial ryegrass. Invited Reviewed
Scott B., Takemoto D. and Tanaka A.
Plant Signaling and Behavior Vol. 2 ( 3 ) page: 171-173 2007.5
Re-organization of the cytoskeleton and endoplasmic reticulum in the Arabidopsis pen1-1 mutant inoculated with the non-adapted powdery mildew pathogen, Blumeria graminis f. sp. hordei. Reviewed
Takemoto D., Jones D.A. and Hardham A.R.
Molecular Plant Pathology Vol. 7 ( 6 ) page: 553-563 2006.11
Reactive oxygen species play a role in regulating a fungus-perennial ryegrass mutualistic interaction. Reviewed
Tanaka A., Christensen M., Takemoto D., Park P. and Scott B.
Plant Cell Vol. 18 ( 4 ) page: 1052-1066 2006.4
Membrane release and destabilization of Arabidopsis RIN4 following cleavage by Pseudomonas syringae AvrRpt2. Reviewed
Takemoto D. and Jones D.A.
Molecular Plant-Microbe Interactions Vol. 18 ( 12 ) page: 1258-1268 2005.12
Differences in cell death induction by Phytophthora elicitins are determined by signal components downstream of MAP kinase kinase in different species of Nicotiana and cultivars of Brassica rapa and Raphanus sativus. Reviewed
Takemoto D., Hardham A.R. and Jones D.A.
Plant Physiology Vol. 138 ( 3 ) page: 1491-1504 2005.7
The cytoskeleton as a regulator and target of biotic interactions in plants. Invited Reviewed
Takemoto D. and Hardham A.R.
Plant Physiology Vol. 136 ( 4 ) page: 3864-3876 2004.12
Plant innate immunity - direct and indirect recognition of general and specific pathogen-associated molecules. Invited Reviewed
Jones D.A. and Takemoto D.
Current Opinion in Immunology Vol. 16 ( 1 ) page: 48-62 2004.2
Disease stress-inducible genes of tobacco: expression profile of elicitor-responsive genes isolated by subtractive hybridization. Reviewed
Takemoto D., Yoshioka H., Doke N. and Kawakita K.
Physiologia Plantrum Vol. 118 ( 4 ) page: 545-553 2003.8
GFP-tagging of cell components reveals the dynamics of subcellular re-organization in response to infection of Arabidopsis by oomycete pathogen. Reviewed
Takemoto D., Jones D.A. and Hardham A.R.
Plant Journal Vol. 33 ( 4 ) page: 775-792 2003.2
Characterization of elicitor-inducible tobacco genes isolated by differential hybridization.
Takemoto D., Doke N. and Kawakita K.
Journal of General Plant Pathology Vol. 67 ( 2 ) page: 89-96 2001.5
Isolation of the gene for EILP, an elicitor-inducible receptor-like protein, from tobacco by differential display. Reviewed
Takemoto D., Hayashi M., Doke N., Nishimura M. and Kawakita K.
Plant and Cell Physiology Vol. 41 ( 4 ) page: 458-464 2000.4
Molecular cloning of a defense-response-related cytochrome P450 gene from tobacco. Reviewed
Takemoto D., Hayashi M., Doke N., Nishimura M. and Kawakita K.
Plant and Cell Physiology Vol. 40 ( 12 ) page: 1232-1242 1999.12
Effect of cytochalasin D on defense responses of potato tuber discs treated with hyphal wall components of Phytophthora infestans. Reviewed
Takemoto D., Maeda H., Yoshioka H., Doke N. and Kawakita K.
Plant Science Vol. 141 ( 2 ) page: 219-226 1999.2
Involvement of actin filament association in hypersensitive reactions in potato cells. Reviewed
Furuse K., Takemoto D., Doke N. and Kawakita K.
Physiological and Molecular Plant Pathology Vol. 54 ( 1/2 ) page: 51-61 1999.1
Identification of chitinase and osmotin-like protein as actin-binding proteins in suspension-cultured potato cells. Reviewed
Takemoto D., Furuse K., Doke N. and Kawakita K.
Plant and Cell Physiology Vol. 38 ( 4 ) page: 441-448 1997.4
植物病理学(第2版) Reviewed
眞山滋志、土佐幸雄 編( Role: Joint author , 第8章)
文英堂出版 2020.3 ( ISBN:4830041382 )
植物たちの戦争―病原体との5億年のサバイバルレース Reviewed
竹本大吾( Role: Joint author , 第5章 植物と微生物の寄生と共生をめぐる「共進化」)
講談社 2019.3 ( ISBN:978-4-06-515216-4 )
ナス科植物の生産する抗菌物質(ファイトアレキシン)の多様性と病害防除
竹本大吾、今野沙弥香、芦田晃、Maurizio Camagna( Role: Joint author)
作物生産と土づくり 日本土壌協会 2023.3
飯塚りえ( Role: Supervisor (editorial))
ヘルシスト 2022.7
植物と病原菌の相互作用におけるファイトアレキシンの役割
竹本大吾・黒柳輝彦・柴田裕介・Abriel Bulasag・水野邑里・大津美奈・今野沙弥香・Soriya Rin・Maurizio Camagna・田中愛子・ 佐藤育男・千葉壮太郎・川北一人・小鹿 一( Role: Joint author)
日本植物病理学会 2021.9
Belowground and aboveground strategies of plant resistance against Phytophthora species. In Belowground defense strategies in plants (Kazan K. and Vos C. Eds.), Book series `Signaling and communication in plants'.
Daigo Takemoto and Yuri Mizuno( Role: Joint author)
Springer 2016
Particle bombardment-mediated transient expression to identify localization signals in plant disease resistance proteins and target sites for the proteolytic activity of pathogen effectors.
Takemoto D., Jones D.A.( Role: Joint author)
Methods Mol. Biol. 2014
イネ科牧草に共生する epichloae エンドファイトの 共生時に機能する遺伝子群の機能解析
竹本大吾、榧野友香、勝又美穂、尾崎よしの、赤野史岳、Barry Scott、 田中愛子( Role: Joint author)
日本植物病理学会 2013
Regulation and functional analysis of bioprotective metabolite genes from the grass symbiont Epichloë festucae.
Scott B., Wrenn R.E., May K.J., Takemoto D., Young C.A., Tanaka A., Fleetwood D.J. and Johnson R.D.( Role: Joint author)
Springer Netherlands 2009
NOと植物の感染防御応答
川北一人、加藤大明、樹神博士、柴田裕介、竹本大吾( Role: Joint author)
羊土社 2009
牧草共生糸状菌の共生確立機構 活性酸素生成の役割について
竹本大吾、田中愛子、Barry Scott( Role: Joint author)
日本植物病理学会 2008
Dynamic subcellular responses in plants during interactions with fungi and Oomycetes.
Hardham, A.R. and Takemoto, D.( Role: Joint author)
ISMP-MI 2006
灰色かび病菌が多様な植物に感染する機構の解析 Invited
竹本大吾
日本農薬学会第49回大会 2024.3.15 日本農薬学会
灰色かび病菌の感染の仕組み解明 -「RNA 農薬」の開発を目指す- Invited
竹本大吾
令和4年度 植物防疫試験研究推進会議研究会 2024.3.7 農研機構
ベンサミアナの病原性卵菌および糸状菌に対する非宿主抵抗性に必須な抗菌性ペプチドNbSAR8.2mの活性に必要なアミノ酸配列の解析 International coauthorship
令和5年度植物感染生理談話会 2023.9 日本植物病理学会
植物と病原菌の相互作用におけるファイトアレキシンの役割 Invited
竹本大吾
令和3年度植物感染生理談話会 2021.9.2 日本植物病理学会
ジャガイモのリシチン解毒に関与するCytochrome P450遺伝子StSPHの単離
カマーニャ マウリツィオ・小鹿 一・竹本大吾
令和2年度日本植物病理学会関西部会 2020.11.7 日本植物病理学会
イネ科植物共生糸状菌Epichloë festucaeからの抗菌物質生合成酵素遺伝子eplsの単離
竹本大吾・プレブエンケ・近藤竜彦・ニオネス ジェニファー・小鹿一
令和2年度 日本植物病理学会 2020.3.19 日本植物病理学会
病虫害発生を記録するアプリケーションの開発 Invited
竹本大吾
令和元年度 東海植物病学研究会 2019.12.6
イネ科牧草に共生するエンドファイトに関する研究 Invited
竹本大吾
令和元年度 愛知県農学系4機関研究交流会 2019.11.25 愛知県農学系4機関
ナス科植物による抗菌物質の生産と病原菌によるその分解について
竹本大吾
2019年度次世代バレイショセミナー 2019.11.9 バレイショ遺伝資源開発学講座
Dynamic reorganization of Epichloë genome after parasexual recombination. Invited International conference
Takemoto D.
Four decades of symbiosis: Barry Scott Retirement Symposium 2019.9.10
BcCPDH1 is involved in the detoxification of sesquiterpenoid phytoalexin capsidiol, and specifically required for the pathogenicity of Botrytis cinerea on Nicotiana species. International conference
Kuroyanagi T., Ojika M., Suzuki T., Sato I., Chiba S., Kawakita K. and Takemoto D.
XVIII International Congress on Molecular Plant-Microbe Interactions 2019.7.14 The International Society for Molecular Plant-Microbe Interactions
バレイショおよびナス科植物の疫病菌抵抗性に機能する遺伝子群の機能解析
竹本大吾
2017年度次世代バレイショセミナー 2017.11.18 バレイショ遺伝資源開発学講座
イネ科植物共生糸状菌の人工的なハイブリッド菌株作出とその性状解析 Invited
竹本大吾
第38回 糸状菌遺伝子研究会例会 2017.6.23 糸状菌遺伝子研究会
Novel nuclear protein, NsiA, and its interacting transcription factor Ste12 and MAP kinase Mak2 mediate balanced symbiotic infection of endophytic fungus Epichloë festucae in perennial ryegrass. International coauthorship International conference
Kamiya S., Ozaki Y., Okamura A., Kameoka S., Kayano Y., Saikia S., Scott B., Maruyama J., Tanaka A. and Takemoto D.
XVII International Congress on Molecular Plant-Microbe Interactions 2016.7.17
糸状菌のNADPH oxidaseを介した活性酸素生成による、有性生殖、形態形成および植物への感染の制御 Invited
竹本大吾
第38回分子生物学会年会・第88回生化学会大会合同大会 2015.12.1 分子生物学会
宿主特異性を決定する多様な機構 Invited
竹本大吾
日本植物病理学会創立100周年記念シンポジウム 2015.3.27 日本植物病理学会
イネ科牧草に共生する糸状菌エンドファイトの共 生確立に関わる遺伝子群の機能解析
竹本大吾
2013 年度土壌肥料学会
イネ科牧草に共生する epichloae 属エンドファイト の共生時に機能する遺伝子群の解析
竹本大吾
平成 25 年度植物感染生理談 話会
牧草共生糸状菌 epichloae エンドファイトの共生に関わる遺伝子群の機能解析
竹本大吾
第 12 回糸状菌分子生物学コンファレンス
Imaging of pathogenic and symbiotic fungi in culture and during infection. International conference
Takemoto D.
XV International Congress on Molecular Plant-Microbe Interactions
エンドファイトが産生する生理活性物質の生合成遺伝子とその発現調節
竹本大吾、田中愛子、Barry Scott
日本マイコトキシン学会 第68回学術講演会
Reactive oxygen as a signal in grass-epichloë symbiosis.
Joint Meeting of the Mycological Society of America and of the International Symposium on Fungal Endophytes of Grasses
Identification of new components of the fungal Nox complex. International conference
Gordon Research Conference on Nox family NADPH oxidase.
牧草共生糸状菌の共生確立機構 活性酸素の役割について
日本植物病理学会 平成20年度感染生理談話会
Identification of new components of the fungal NADPH oxidase complex in the endophytic fungus Epichloë festucae International conference
Gordon Research Conferences of Cellular & Molecular Fungal Biology
牧草共生糸状菌の共生確立における活性酸素の役割
第61回日本酸化ストレス学会学術集会
牧草共生糸状菌Epichroe festucaeの共生確立における活性酸素生成の役割
医学生物学電子顕微鏡技術学会 第24回学術講演会および総会
Dynamic subcellular responses in plants during interactions with fungal and oomycete pathogens
Dynamics of Biological Networks in and around Plant Cells
牧草共生糸状菌Epichroe festucaeの共生確立における活性酸素生成の役割
第28回日本植物病理学会関西地区若手の会
Dynamic subcellular reorganization in response to infection of Arabidopsis by oomycete pathogens. International conference
8th International Congress of Plant Pathology
Functional analysis of a secretory peptide involved in induction of plant disease resistance
Grant number:130658 2013 - 2015
Grant type:Competitive
Grant amount:\1500000 ( Direct Cost: \1500000 )
牧草共生菌の共生確立に必須な新奇核タンパク質NsiAの機能解析
2012 - 2013
豊秋奨学会研究費助成
Grant type:Competitive
Grant amount:\700000
イネ科植物に共生する糸状菌の抗菌性物 質生合成遺伝子の単離と植物病害防除への利用
2011.10 - 2012.10
発酵研究所 一般研究助成
竹本大吾
Grant type:Competitive
植物病原性糸状菌および卵菌の病原性発現における活性酸素生成の役割
2011 - 2012
ノバルティス研究奨励金
竹本大吾
Authorship:Principal investigator
Grant amount:\1000000
ナス科植物特異的な病害抵抗性ペプチドの機能解析と耐病性育種への応用
Grant number:23K26905 2024.2 - 2027.3
科学研究費助成事業 基盤研究(B)
竹本 大吾
Authorship:Principal investigator
Grant amount:\12220000 ( Direct Cost: \9400000 、 Indirect Cost:\2820000 )
Diversification of biosynthetic pathways for phytoalexins in Solanaceae plants
Grant number:23KF0146 2023.9 - 2026.3
Grants-in-Aid for Scientific Research Grant-in-Aid for JSPS Fellows
CAMAGNA MAURIZIO
Authorship:Principal investigator
Grant amount:\3000000 ( Direct Cost: \3000000 )
ナス科植物特異的な病害抵抗性ペプチドの機能解析と耐病性育種への応用
Grant number:23H02212 2023.4 - 2027.3
科学研究費助成事業 基盤研究(B)
竹本 大吾
Authorship:Principal investigator
Grant amount:\18590000 ( Direct Cost: \14300000 、 Indirect Cost:\4290000 )
本研究では、SAR8.2遺伝子群の非宿主抵抗性における機能の解析およびその抵抗性 品種育成への応用を目指して、以下の3つの点を明らかにすることを目指す。
1) SAR8.2が病原菌の何を標的として抵抗性を発揮しているのか?
2) ナス科由来の多様なSAR8.2遺伝子は、どのような病原菌の抵抗性に寄与しているのか?
3) 野生種 Solanum属由来のSAR8.2相同遺伝子は抵抗性育種の資源となりうるのか?
Grant number:22K19176 2022.6 - 2025.3
科学研究費助成事業 挑戦的研究(萌芽)
竹本 大吾
Authorship:Principal investigator
Grant amount:\6240000 ( Direct Cost: \4800000 、 Indirect Cost:\1440000 )
極めて広い宿主範囲をもつ多犯性の病原菌が知られている。代表的な多犯性植物病原菌である灰色かび病菌 (Botrytis cinerea) は、果物、野菜を含む400種以上の植物に感染することが報告されている。この様な多犯性の病原菌はどの様な感染戦略で、多様な植物の抵抗性を打破して感染を確立しているのだろうか? 本研究では、1) 灰色かび病菌の抗菌物質の解毒化や耐性化に必要な遺伝子群の機能解析、2) 灰色かび病菌が植物の抗菌物質を認識するメカニズムの解明、3) 灰色かび病菌の病原性関連遺伝子群の起源の解析、を進めることで、多犯性病原菌のもつ特異な感染機構とその進化機構を解明する。
極めて広い宿主範囲をもつ多犯性の病原菌が知られている。代表的な多犯性植物病原菌である灰色かび病菌(Botrytis cinerea)は、果物、 野菜を含む1400種以上の植物に感染することが報告されている。この様な多犯性の病原菌はどの様な感染戦略で、多様な植物の抵抗性を打破して感染を確立しているのだろうか? 本研究では、1) 灰色かび病菌の抗菌物質の解毒化や耐性化に必要な遺伝子群の機能解析、2) 灰色かび病菌が植物の抗菌物質を認識するメカニズムの解明、3) 灰色かび病菌の病原性関連遺伝子群の起源の解析、を進めることで、多犯性病原菌のもつ特異な感染機構とその進化機構を解明する。本年度は、灰色かび病菌にジャガイモ由来のリシチン、ブドウ由来のレスベラトロール、ピーマン由来のカプシジオールなどを処理した灰色かび病菌のRNAseq解析から、それぞれに応答して活性化される遺伝子群の機能解析を進めた。特にカプシジオールを脱水素により解毒化するBcCPDHとリシチンを排出するトランスポーターであるBcAtrBの機能解析を進め、これらが標的となるファイトアレキシンを生産する植物への感染時に特異的に機能する病原性因子であることを明らかとした。また、リシチンを酸化反応によって解毒化する複数の酵素遺伝子を特定した。さらに、BcCPDH相同遺伝子の真菌での分布、灰色かび病菌と他のBotrytis属菌のゲノム比較により、BcCPDH遺伝子が遺伝子水平移行によって灰色かび病菌にもたらされたことを示した。
本年度は、灰色かび病菌がカプシジオールやリシチンなどのナス科植物が生産するファイトアレキシンに対抗して解毒および排出する機構を解明することができた。また、病原性遺伝子の灰色かび病菌および近縁種における分布の解析、灰色かび病菌と近縁種のゲノム比較による特異的遺伝子のリスト化およびそれら遺伝子の発現解析、灰色かび病菌のアグロバクテリウムを介した形質転換法の確立など、今後の計画に必要なデータ解析および実験手法の確立がおおよそ完了した。これらの進行状況から、おおむね順調に進展している、と判断した。
引き続き、1) 灰色かび病菌の抗菌物質の解毒・耐性化に必要な遺伝子群の機能解析、2) 灰色かび病菌が植物の抗菌物質を認識するメカニズムの解明、3) 灰色かび病菌の病原性関連遺伝子群の起源の解析の3つの目標を軸に研究を進める。
1) 上記のファイトアレキシンに加えて、アブラナ科植物のブラシニン、マメ科植物のグリセオリン処理した灰色かび病菌のRNAseq解析も完了している。そこで、これら2種のファイトアレキシンの解毒化や耐性化に必要な遺伝子群の機能解析も進める。これまでと同様にa. 抗菌物質耐性の無いエンドファイト菌に候補遺伝子を導入、抗菌物質の解毒・耐性化における機能の調査する、b. 候補遺伝子の破壊株を作出し、抗菌物質耐性および病原性における役割を評価する、という2つの実験法を併用する。
2) カプシジオール応答性遺伝子のプロモーター活性をLucマーカーで検出する形質転換体を既に作出している。この形質転換体を用いて、カプシジオール応答性が低下した変異株を単離し、灰色かび病菌が植物の抗菌物質 を認識する機構を明らかにする。本年確立したアグロバクテリウムを用いた形質転換法を用いて、カプシジオール応答に必要な情報伝達因子の遺伝子を単離する。
3) 計画1-2で単離した病原性因子が進化の過程でどのように獲得されたかを明らかにするため、灰色かび病菌に近縁な多犯性病原菌である菌核病菌 Sclerotinia sclerotiorumや特定の植物種に感染する同属のBotrytis菌における相同遺伝子の分布を調査する。a. 近縁種間で保存されている垂直伝播によって維持されてきた遺伝子群については、遺伝子座の構造比較解析を行う。b. 遠縁の微生物から水平伝播によって獲得された遺伝子は、その起源と移行した時代を明らかにする。これらの解析から、灰色かび病菌が多犯性菌となった進化プロセスの解明を目指す。
広範な病原性卵菌の感染を抑制するナス科植物特異的な分泌タンパク質の機能解析
Grant number:20H02985 2020.4 - 2024.3
科学研究費助成事業 基盤研究(B)
竹本 大吾, 近藤 竜彦, 田中愛子
Authorship:Principal investigator
Grant amount:\17420000 ( Direct Cost: \13400000 、 Indirect Cost:\4020000 )
ジャガイモ疫病菌は、世界4大作物の1つであるジャガイモの最重要病原菌である。これまでに、ジャガイモと同じナス科植物で、ジャガイモ疫病菌に対して抵抗性を示すベンサミアナから、疫病菌抵抗性に必須な機能未知な分泌タンパク質SAR8.2m遺伝子を単離した。本研究では、この分泌タンパク質の植物の病害抵抗性における役割を解明するともに、SAR8.2mの導入による高耐病性のジャガイモの作出を試みる。
Grant number:18H03943 2018.4 - 2023.3
Grants-in-Aid for Scientific Research Grant-in-Aid for Scientific Research (A)
OJIKA Makoto
Authorship:Coinvestigator(s)
The project aimed to elucidate the biosynthetic enzymes and receptors of the mating hormones (α1 and α2) that control the sexual reproduction of Phytophthora, a crop disease fungus. Regarding biosynthetic enzymes, RNA-Seq was used to narrow down the cytochrome P450 (CYP) genes, which show differences in gene expression level between the A1 and A2 mating types. We succeeded in identifying 11-hydroxylase as one of the biosynthetic genes for α2 (=11,16-dihydroxyphytol). On the other hand, the receptors were narrowed down by structural similarity and nuclear receptors, etc., and one receptor candidate pair (94% homology) was found. The regulators of asexual reproduction that are responsible for the rapid epidemic was also investigated.
Functional analysis of plant effectors produced by Solanaceae plants
Grant number:17H03771 2017.4 - 2021.3
Grants-in-Aid for Scientific Research Grant-in-Aid for Scientific Research (B)
Takemoto Daigo
Authorship:Principal investigator
Grant amount:\17160000 ( Direct Cost: \13200000 、 Indirect Cost:\3960000 )
The potato blight pathogen, Phytophthora infestans, is the most important pathogen of potato. Solanaceae model plant, mature Nicotiana benthamiana shows resistance to potato blight. In this study, we analyzed the function of the secreted protein SAR8.2m, which is essential for the resistance of N. benthamiana against P. infestans. SAR8.2m-silenced N. benthamiana showed significant reduction of resistance against various Phytophthora spp. Generation of reactive oxygen species and induction of hypersensitive cell death during pathogen infection were markedly reduced in the SAR8.2m silenced plant. Using the yeast two hybrid screening, candidate targets of SAR8.2m in P. infestans were isolated.
Investigation on the plant mechanisms for PAMPs recognition derived from oomycete pathigens
Grant number:17H03963 2017.4 - 2020.3
Kawakita Kazuhito
Authorship:Coinvestigator(s)
testPlants induce resistance to various microorganisms by recognizing conserved components derived from microorganisms. It has been reported that the common structure of bacteria and fungi has the activity of inducing resistance in a wide range of plant species, but there are few studies on oomycetes such as Phytophthora and Pythium species, which contain important pathogens. In this study, a ceramide compound as an elicitor that induces active oxygen production and a diacylglycerol analog as an elicitor having phytoalexin production-inducing activity were obtained from Phytophthora infestans. In addition, the obtained elicitors were found not only in P. infestans but also in other oomycetes, indicating that elicitors isolated are PAMPs of oomycete pathogens.
Use of parasexal cycle of Epichloe endophyte for artificial production of beneficial strains
Grant number:16KT0145 2016.7 - 2019.3
Daigo Takemoto
Authorship:Principal investigator
Grant amount:\4680000 ( Direct Cost: \3600000 、 Indirect Cost:\1080000 )
Epichloe endophytes systemically colonize the intercellular spaces of grasses to establish a symbiotic association. Colonization by epichloae endophytes confers various benefits on host plant growth and fitness to environmental conditions through the enhancement of plant resistance to a range of biotic and abiotic stresses, including drought, disease and herbivores. In this study, Epichloe isolates are used to investigate the role of parasexal recombination for the emergence of new isolates and evolution of endophytes. We successfully produced hybrid isolates which have variety of characteristics inherited from parents isolates (same or different Epichloe species). We developed the method to produced artificial hybrid strains via parasexal recombination with no transformation markers using a toxic gene as negative marker gene.
Functional analysis of a secretory peptide SAR8.2 on induced disease resistance of Solanaceae plants
Grant number:26292024 2014.4 - 2018.3
Takemoto Daigo
Authorship:Principal investigator
Grant amount:\13130000 ( Direct Cost: \10100000 、 Indirect Cost:\3030000 )
Nicotiana benthamiana is resistant to the potato blight pathogen, Phytophthora infestans. Screening using virus-induced gene silencing identified NbSAR8.2m, a secretory peptide, as an essential factor for the resistance. NbSAR8.2m-silenced plant is highly susceptible to P. infestans, leading systemic infection of the pathogen. In contrast, silencing of NbSAR8.2m showed no effect on the resistance to other pathogens, indicating that NbSAR8.2m is specifically involved in the resistance to P. infestans. While induction of cell death is impaired in NbSAR8.2m-silenced plants during the infection of P. infestans. Production of reactive oxygen species (ROS) was suppressed in SAR8.2m-silenced plants during the infection of P. infestans, but ROS production induced by elicitor was comparable between control and NbSAR8.2m-silenced plants. These results suggested that NbSAR8.2m may suppress the effectors activity of P. infestans.
ナス科植物に特異的な病害抵抗性誘導ペプチドSAR8.2の機能解析
2014.4 - 2017.3
科学研究費補助金 基盤研究(B)
Authorship:Principal investigator
疑似有性生殖による植物共生糸状菌の進化機構の解明とその利用
2013.4 - 2015.3
科学研究費補助金
Authorship:Principal investigator
植物病原性糸状菌および卵菌の病原性発現における活性酸素生成の役割
2008.4 - 2009.3
科学研究費補助金 若手研究(B),課題番号:20780032
竹本 大悟
Authorship:Principal investigator
資源生物科学セミナー
2009
