東江教授の経歴
2019年 – 九州大学大学院農学研究院 教授
2013年 – 2018年 香川大学, 農学部, 教授
2010年 – 2012年 香川大学, 農学部, 准教授
2007年 – 2010年 鹿児島大学大学院連合農学研究科, 准教授
2007年 – 2010年 佐賀大学大学院農学研究科, 准教授
2007年 – 2010年 佐賀大学農学部, 准教授
2004年 – 2007年 鹿児島大学大学院連合農学研究科, 助教授
2002年 – 2007年 佐賀大学大学院農学研究科, 助教授
1998年 – 2007年 佐賀大学農学部, 助教授
1997年 – 1998年 research fellow of Bio-oriented Technology
1997年 – 1998年 生物系特定産業技術研究推進機構, 研究員
1998年 – associate professor of Saga University
1994年 – 1997年 日本学術振興会, 特別研究員
Research Advancement Institution promotion of science
【アイスプラントのゲノム配列】
Sato, R., Kondo, Y., and Agarie, S. A whole-genome shotgun assembly for genome characterization of the common ice plant (Mesembryanthemum crystallinum L.), 09 September 2022, PREPRINT (Version 1) available at Research Square [https://doi.org/10.21203/rs.3.rs-2013540/v1] PDFはこちら
【塩生植物の好塩性機構】
Tran, D.Q., Konishi, A., Morokuma, M., Toyota, M., and Agarie, S., 2020.
NaCl-stimulated ATP synthesis in mitochondria of a halophyte Mesembryanthemum crystallinum L.. Plant Production Science. 23: 129–135. PDFはこちら.
Tran, D.Q., Konishi, A., Cushman, J.C., Morokuma, M., Toyota, M., and Agarie,
S., 2020. Ion accumulation and expression of ion homeostasis-related genes
associated with halophilism, NaCl-promoted growth in a halophyte Mesembryanthemum crystallinum L. Plant Production Science. 23: 91–102. PDFはこちら.
Sato, R., Tran, D.Q., Yoshida, K., Dang, J., Konishi, A., Ohnishi, S., Cushman, J.C. and Agarie, S. 2022. NaCl-promoted respiration and cell division in halophilism of a halophyte, the common ice plant Mesembryanthemum crystallinum L. Journal of the Faculty of Agriculture, Kyushu University. 67(2):153–164. PDFはこちら
Vu, N.Q.H., Quang, H.T., Hong, H.T.K. and Agarie, S. Microbiology associated with disease on white lotus (Nelumbo nucifera Gaertn.) and application of silver nanoparticles for the control of plant pathogensIn vitro. Journal of the Faculty of Agriculture, Kyushu University. 67(2): 165–172. PDFはこちら
Sato, R., Kondo, Y., and Agarie, S. A whole-genome shotgun assembly for
genome characterization of the common ice plant (Mesembryanthemum crystallinum L.), 09 September 2022, PREPRINT (Version 1) available at Research Square [https://doi.org/10.21203/rs.3.rs-2013540/v1] PDFはこちら
【塩生植物の耐塩性機構】
―塩集積細胞(ブラッダー細胞)の形成関連遺伝子の解析―
Roeurn, S., Hoshino, N., Soejima, K., Inoue, Y., Cushman, J.C., and Agarie,
S., 2016. MYB and HD-ZIP IV homologs related to trichome formation are involved in epidermal bladder
cell development in the halophyte Mesembryanthemum crystallinum L. Plant Production Science. 20: 72–82. PDFはこちら.
Roeurn, S., Hoshino, N., Soejima, K., Inoue, Y., Cushman, J.C., and Agarie,
S., 2016. Suppression subtractive hybridization library construction and
identification of epidermal bladder cell related genes in the common ice
plant, Mesembryanthemum crystallinum L. Plant Production Science. 19: 552–561. PDFはこちら.
―塩集積細胞(ブラッダー細胞)の役割―
Agarie, S., Shimoda, T., Shimizu, Y., Baumann, K., Sunagawa, H., Kondo,
A., Ueno, O., Nakahara, T., Nose, A., and Cushman, J.C., 2007. Salt tolerance,
salt accumulation, and ionic homeostasis in an epidermal bladder-cell less
mutant of the common ice plant Mesembryanthemum crystallinum.Journal of Experimental Botany. 58: 1957–1967. PDFはこちら.
―RNA-Seqを用いたアイスプラント根における遺伝子発現解析―
Tsukagoshi, H., Suzuki, T., Nishikawa, K., Agarie, S., Ishiguro, S., and
Higashiyama, T., 2015. RNA-seq analysis of the response of the halophyte,
Mesembryanthemum crystallinum (ice plant) to high salinity. PLoS One. 10(2): e0118339, eCollection. PDFはこちら.
【塩生植物】
ー総説ー
東江栄, 佐藤稜真, 齋藤和幸, 諸隈正裕, 2021. 塩生植物の作物及び遺伝子資源としての可能性. 日本作物学会紀事. 90(4): 373–381.
―シチメンソウ―
Hayakawa, K. and Agarie, S., 2010. Physiological roles of betacyanin in
a halophyte, Suaeda japonica Makino. Plant Production Science. 13: 351–359. PDFはこちら.
早川啓亮, 東江栄, 野瀬昭博, 2008. シチメンソウ(Suaeda japonicaMakino)の光合成速度,クロロフィル蛍光および酸化ストレス耐性に対するベタシアニンの生理作用. 熱帯農業研究. 1: 55–63. PDFはこちら.
―マングローブ―
Okimoto, Y., Nose, A., Ikeda, K., Agarie, S., Oshima, K., Tateda, Y., Ishii,
T., and Nhan, D.D., 2008. An estimation of CO2 fixation capacity in mangrove
forest using two methods of CO2 gas exchange and growth curve analysis.
Wetlands Ecology and Management. 16: 155–171. PDFはこちら.
Okimoto, Y., Nose, A., Katsuta, Y., Tateda, Y., Agarie, S., and Ikeda,
K., 2007. Gas exchange analysis for estimating net CO2 fixation capacity
of mangrove (Rhizophora stylosa) forest in the mouth of river Fukido, Ishigaki Island, Japan.Plant Production Science. 10: 303–313. PDFはこちら.
【耐塩性野生イネ】
仲村一郎, 東江栄, 村山盛一, 飛田哲, 柳原誠司, 川満芳信, 本村恵二, 2005. 塩ストレス下における個葉の光合成特性からみた野生稲O. latifolia Desv.の耐塩性. 熱帯農業. 49: 77–83. PDFはこちら.
仲村一郎, 東江栄, 村山盛一, 飛田哲, 柳原誠司, 川満芳信, 本村恵二, 2005. 生長・乾物生産からみた野生稲Oryza latifolia Desv.の耐塩性. 熱帯農業. 49: 70–76. PDFはこちら.
仲村一郎, 東江栄, 飛田哲, 柳原誠司, 野瀬昭博, 村山盛一, 本村恵二, 2004. 野生稲Oryza latifolia Desv.の葉緑体チラコイド膜の耐塩性. 日本作物学会紀事. 73: 84–92. PDFはこちら.
【CAM型光合成】
―アイスプラント―
Sunagawa, H., Cushman, J, C., and Agarie, S., 2010. Crassulacean acid metabolism
may alleviate production of reactive oxygen species in a facultative CAM
plant, the common ice plant Mesembryanthemum crystallinum L. Plant Production Science. 13: 256–260. PDFはこちら.
Cushman, J.C., Agarie, S., Albion, R.L., Elliot, S.M., Taybi, T., and Borland,
A.M., 2008. Isolation and characterization of mutants of common ice plant
deficient in crassulacean acid metabolism. Plant Physiology. 147: 228–238. PDFはこちら.
―ミトコンドリア―
Hoang, K.M.T., Nose, A., Agarie, S., and Yoshida, T., 2008. Malate metabolism
in Hoya carnosa mitochondria and its role in photosynthesis during CAM
phase III. Journal of Experimental Botany. 59: 1819–1827. PDFはこちら.
Hoang, K.M.T., Nose, A. and Agarie, S., 2005. Oxidations of various substrates
and effects of the inhibitors on purified mitochondria isolated from Kalanchoe pinnata. Biologia Plantarum. 49: 201–208. PDFはこちら.
Hoang, K.M.T., Nose, A., and Agarie, S., 2005. Effects of KCN, SHAM and
oxygen concentrations on respiratory properties of purified mitochondria
isolated from Ananas comosus (Pineapple) and Kalanchoe Daigremontiana. Plant Production Science. 8: 383–392. PDFはこちら.
Hoang, K.M.T., Nose, A., and Agarie, S., 2004. Respiratory properties and
malate metabolism in percoll-purified mitochondria isolated from pineapple,
Ananas comosus (L.) Merr. cv. smooth cayenne. Journal of Experimental Botany. 55: 2201–2211. PDFはこちら.
―高夜温―
Lin, Q., Wang, Y.M., Nose, A., Hong, T.K.H., and Agarie, S., 2008. Effects
of high night temperature on lipid and protein compositions in tonoplasts
isolated from Ananas comosus and Kalanchoe pinnata leaves. Biologia Plantarum. 52. 59–65. PDFはこちら.
―リン酸化―
Theng, V., Agarie, S. and Nose, A., 2008. Regulatory phosphorylation of
phosphoenolpyruvate carboxylase in the leaves of Kalanchoe pinnata, K.daigremontiana and Ananas comosus. Biological Plantarum. 52: 281–290. PDFはこちら.
Theng, V., Agarie, S., and Nose, A., 2007. Regulatory properties of phosphoenolpyruvate
carboxylase in crassulacean acid metabolism plants: diurnal changes in
phosphorylation state and regulation of gene expression. Plant Production Science. 10: 171–181. PDFはこちら.
【アイスプラント】
―食用―
Agarie, S., Kawaguchi, A., Kodera, A., Sunagawa, H., Kojima, H., Nose,
A., and Nakahara, T., 2008. Potential of the common ice plant, Mesembryanthemum crystallinum as a new high-functional food as evaluated by polyol accumulation. Plant Production Science. 12: 37–46. PDFはこちら.
―再分化―
Sunagawa, H., Agarie, S., Umemoto, M., Makishi, Y., and Nose, A., 2007.
Effects of urea-type cytokinins on the adventitious shoots regeneration
from cotyledonary node explant in the common ice plant, Mesembryanthemum crystallinum. Plant Production Science. 10: 47–56. PDFはこちら.
―遺伝子組換え―
Agarie, S., Umemoto, M., Sunagawa, H., Anai, T., and Cushman, J.C., 2020.
An Agrobacterium-mediated transformation via organogenesis regeneration
of a facultative CAM plant, the common ice plant Mesembryanthemum crystallinum L. Plant Production Science. 23: 343–349. PDFはこちら.
―特許―
1.高濃度の鉄及び/又はカルシウムを含有するアイスプラント,並びにその栽培方法及び栽培装置,特願2018-046761 (2018)
2.Method of constructing transgenic ice plant. United States Patent. US
8, 101, 824 (2012).
3.Method of constructing transgenic ice plant. Australia 2005330877 (2011).
4.形質転換アイスプラントの作出方法(PCT出願公開番号WO/2006/112034)(2006).
5.アイスプラントの生育を促進しNa/K含量比を増加させる栽培法(特願2008-104632) (2008).
―品種―
登録品種KA-I243,品種登録番号第26067号(2017).
アイスプラント登録商標
1.クリスタルリーフ(登録番号5063811)
2.バラフ(登録番号5058041)
3.Barafu(登録番号5058042)
【光合成変換―エレオカリス―】
Agarie, S., Kai, M., Takatsuji, H., and Ueno, O., 1997. Expression of C3 and C4 photosynthetic characteristics in the amphibious plant Eleocharis vivipara: structure and analysis of the expression of isogenes for pyruvate, orthophosphate dikinase. Plant Molecular Biology. 34: 363–369. PDFはこちら.
Agarie, S., Kai, M., Takatsuji, H., and Ueno, O., 2002. Environmental and
hormonal regulation of gene expression of C4 photosynthetic enzymes in
the amphibious sedge Eleocharis vivipara. Plant Science. 163: 571–580. PDFはこちら.
【イネC4化】
Agarie, S., Miura, A., Sumikura, R., Tsukamoto, S., Nose, A., Arima, S.,
Matsuoka, M., and Miyao-Tokutomi, M., 2002. Overexpression of C4 PEPC caused
O2-insensitive photosynthesis in transgenic rice plans. Plant Science. 162: 257–265. PDFはこちら.
Fukayama, H., Tsuchida, H., Agarie, S., Nomura, M., Onodera, H., Ono, K.,
Lee, B.H., Hirose, S., Toki, S., Ku, M.S.B., Makino, A., Matsuoka, M.,
and Miyao, M., 2001. Significant accumulation of C4-specific pyruvate,
orthophosphate dikinase in a C3 plant, rice. Plant Physiology. 127: 1136–1146. PDFはこちら.
Agarie, S., Sasaki, H., Matsuoka, M., and Miyao-Tokutomi, M., 2001. Overexpression
of C4 phosophoenolpyruvate carboxylase increased carbon isotope discrimination
in transgenic rice plants. Plant Production Science. 4: 311–312. PDFはこちら.
Tsuchida, H., Tamai, T., Fukayama, H., Agarie, S., Nomura, M., Onodera,
H., Ono, K., Nishizawa, Y., Lee, B.H., Hirose, S., Toki, S., Ku, M.S.B.,
Matsuoka, M., and Miyao, M., 2001. High level expression of C4-specific
NADP-malic enzyme in leaves and impairment of photoautotrophic growth in
a C3 plant, rice. Plant and Cell Physiology. 42: 138–145. PDFはこちら.
Ku, M.S.B., Agarie, S., Nomura, M., Fukayama, H., Tsuchida, H., Ono, K.,
Hirose, S., Toki, S., Miyao, M., and Matsuoka, M., 1999. High-level expression
of maize phosphoenolpyruvate carboxylase in transgenic rice plants. Nature Biotechnology. 17: 76–80. PDFはこちら.
【ケイ酸の効果】
Ueno, O. and Agarie, S., 2005. Silica deposition in cell walls of the stomatal
apparatus of rice leaves. Plant Production Science. 8: 71–73. PDFはこちら.
Agarie, S., Uchida, H., Agata, W., and Kaufman, P.B., 1999. Effects of
silicon on stomatal blue-light response in rice (Oryza sativa L.). Plant Production Science. 2: 232–234. PDFはこちら.
Agarie, S., Agata, W., and Kaufman, P.B., 1998. Involvement of silicon
in the senescence of rice leaves. Plant Production Science. 1: 104–105. PDFはこちら.
Agarie, S., Hanaoka, N., Ueno, O., Miyazaki, A., Kubota, F., Agata, W.,
and Kaufman, P.B., 1998. Effects of silicon on tolerance to water deficit
and heat stress in rice plants (Oryza sativa L.), monitored by electrolyte leakage. Plant Production Science. 1: 96–103. PDFはこちら.※こちらの論文は, Plant Production Science(PPS)に投稿された論文において、「過去3年間(2022年6月14日現在)で最も引用された論文」の第4位にランクインしました。
Agarie, S., Uchida, H., Agata, W., Kubota, F., and Kaufman, P.B., 1998.
Effects of silicon on transpiration and leaf conductance in rice plants
(Oryza sativaL.). Plant Production Science. 1: 89–95. PDFはこちら.※こちらの論文は, Plant Production Science(PPS)に投稿された論文において、「過去3年間(2022年6月14日現在)で最も引用された論文」の第8位にランクインしました。
Ueno, O., and Agarie, S., 1997. The intercellular distribution of glycine
decarboxylase in leaves of cassava in relation to the photosynthetic mode
and leaf anatomy. Japanese Journal of Crop Science. 66: 268–278. PDFはこちら.
Agarie, S., Agata, W., Uchida, H., Kubota, F., and Kaufman, P.B., 1996.
Function of silica bodies in the epidermal system of rice (Oryza sativa L.): testing the window hypothesis. Journal of Experimental Botany. 47: 655–660. PDFはこちら.
東江栄, 1994. 水稲の光合成・蒸散および乾物生産におけるケイ酸の生理的作用に関する研究. 博士論文. 九州大学(農博甲第597号). 閲覧時はこちらへアクセス(国立国会図書館デジタルコレクション).
東江栄, 縣和一, 窪田文武, Peter B. Kaufman, 1992. 水稲の光合成・乾物生産に対するケイ酸の生理的役割,第1報ケイ酸および遮光処理の影響.
日本作物学会紀事. 61: 200–206. PDFはこちら.
<その他>
【シンポジウム】
第253回日本作物学会講演会. ミニシンポジウム3要旨. 作物の新しい耐塩性機構. オーガナイザー 東江栄. 日本作物学会紀事. 91: 257. PDFはこちら
【書籍】
東江栄, 上田晃弘, 菊田真由美, 齋藤和幸, 諏訪竜一, 富永るみ, 長岡俊徳, 2021. 植物バイオサイエンス. 共立出版. ご購入はこちら→ Amazon 楽天 ヨドバシカメラ
【ヒシ】
Arima, S., Hoque, M.A., and Agarie, S., 1999. Comparison of growth and
yield performance of several water chestnut species collected from southwestern
Japan and middle China. Plant Production Science. 2: 273–278. PDFはこちら.
【窒素固定】
Suzuki, A., Suriyagoda, L., Shigeyama, T., Tominaga, A., Sasaki, M., Hiratsuka,
Y., Yoshinaga, A., Arima, S., Agarie, S., Sakai, T., Inada, S., Jikumaru,
Y., Kamiya, Y., Uchiumi, T., Abe, M., Hashiguchi, M., Akashi, R., Sato,
S., Kaneko, T., Tabata, S., and Hirsch, A.M., 2011. Lotus japonicus nodulation is photomorphogenetically controlled by sensing the red/far
red (R/FR) ratio through jasmonic acid (JA) signaling. Proceedings of the national academy of sciences of the United States of
America(PNAS). 108: 16837–16842. PDFはこちら.