2015年4月現在

氏名

石川 覚(いしかわ さとる) ISHIKAWA, Satoru

所属・職名

土壌環境研究領域 主任研究員

連絡先

isatoru@affrc.go.jp

ReaD 研究者DDB情報

http://jglobal.jst.go.jp/detail.php?JGLOBAL_ID=200901025686539661&t=1&d=1&q=%28205%29%3D1000359549

現在の研究内容

イネのカドミウム、ヒ素、セシウム吸収を低減させる技術の開発を行っている。特に玄米への蓄積に関わる遺伝的・生理的要因を解析し、従来品種よりもカドミウム、ヒ素、セシウム濃度の低い品種の育成を目指している。

最近の業績(2005年以降)

(原著論文)

  1. Abe T., Nonoue, Y., Ono N., Omoteno M., Kuramata M., Fukuoka S., Yamamoto T., Yano M., Ishikawa S. (2013) Detection of QTLs for reducing cadmium content in rice grain by using LAC23/Koshihikari chromosome segment substitution lines. Breed. Sci., accepted.
  2. 安部匡、倉俣正人、岩崎玄行、本間利光、茨木俊行、山本敏央、矢野昌裕、村上政治、石川覚(2013):ガンマ線照射による突然変異育種法を用いた難脱粒性カドミウムファイトレメディエーション用イネ系統「MJ3」および「MA22」の育成、育種学研究(印刷中)
  3. Kuramata M, Abe T, Kawasaki A, Ebana K, Shibaya T,Yano M, Ishikawa S. (2013) Genetic diversity of arsenic accumulation in rice and QTL analysis of methylated arsenic in rice grains. Rice 6, 3
  4. Bolan NS, Makino T, Kunhikrishnan A, Kim P-J, Ishikawa S, Murakami M, Naidu R, Kirkham MB. (2013): Chapter four - Cadmium contamination and its risk management in rice ecosystems, ADVANCES IN AGRONOMY, 119, 183-273
  5. Ishikawa S, Ishimaru Y, Igura M, Kuramata M, Abe T, Senoura T, Hase Y, Arao T, Nishizawa NK, Nakanishi H (2012): Ion-beam irradiation, gene identification, and marker-assisted breeding in the development of low-cadmium rice. Proc Natl Acad Sci U S A, 109(47):19166-19171.
  6. Nouchi I, Hayashi K, Ishikawa S, Ishikawa S, Fukuoka M, Chen CP, Kobayashi K (2012): Overcoming the Difficulties in Collecting Apoplastic Fluid from Rice Leaves by the Infiltration-Centrifugation method. Plant Cell Physiol, 53(9):1659-1668.
  7. 川ア晃, 荒尾知人, 石川覚 (2012) 湛水管理によるカドミウムの米への蓄積軽減とその問題点, 日本衛生学雑誌, 67, 478-483
  8. Yamaguchi N, Ishikawa S, Abe T, Baba K, Arao T, Terada Y(2012): Role of the node in controlling traffic of cadmium, zinc, and manganese in rice. J Exp Bot, 63(7):2729-2737.
  9. Ishimaru Y, Takahashi R, Bashir K, Shimo H, Senoura T, Sugimoto K, Ono K, Yano M, Ishikawa S, Arao T et al (2012): Characterizing the role of rice NRAMP5 in Manganese, Iron and Cadmium Transport. Sci Rep-Uk, 2.
  10. Duan GL, Kamiya T, Ishikawa S, Arao T, Fujiwara T (2012): Expressing ScACR3 in Rice Enhanced Arsenite Efflux and Reduced Arsenic Accumulation in Rice Grains. Plant Cell Physiol, 53(1):154-163.
  11. Uraguchi S, Kamiya T, Sakamoto T, Kasai K, Sato Y, Nagamura Y, Yoshida A, Kyozuka J, Ishikawa S, Fujiwara T (2011): Low-affinity cation transporter (OsLCT1) regulates cadmium transport into rice grains. Proc Natl Acad Sci U S A, 108(52):20959-20964.
  12. Takahashi R, Ishimaru Y, Senoura T, Shimo H, Ishikawa S, Arao T, Nakanishi H, Nishizawa NK (2011): The OsNRAMP1 iron transporter is involved in Cd accumulation in rice. J Exp Bot, 62(14):4843-4850.
  13. Kuramata M, Abe T, Matsumoto S, Ishikawa S (2011): Arsenic accumulation and speciation in Japanese paddy rice cultivars. Soil Sci Plant Nutr, 57(2):248-258.
  14. Ishikawa S , Suzui N, Ito-Tanabata S, Ishii S, Igura M, Abe T, Kuramata M, Kawachi N, Fujimaki S (2011): Real-time imaging and analysis of differences in cadmium dynamics in rice cultivars (Oryza sativa) using positron-emitting107Cd tracer. BMC Plant Biol, 11:172.
  15. Abe T, Taguchi-Shiobara F, Kojima Y, Ebitani T, Kuramata M, Yamamoto T, Yano M, Ishikawa S (2011): Detection of a QTL for accumulating Cd in rice that enables efficient Cd phytoextraction from soil. Breed Sci, 61(1):43-51.
  16. 中村卓司, 山本亮, 羽鹿牧太, 石川覚, 中山則和, 高橋幹, 島村聡, 島田信二, 藤森新作, 小松節子 (2011) 品種,土壌pH矯正および耕種条件がダイズ子実カドミウム含有率におよぼす影響, 日本土壌肥料学雑誌, 82(2), 105-113
  17. Kato M, Ishikawa S, Inagaki K, Chiba K, Hayashi H, Yanagisawa S, Yoneyama T (2010): Possible chemical forms of cadmium and varietal differences in cadmium concentrations in the phloem sap of rice plants (Oryza sativa L.). Soil Sci Plant Nutr, 56(6):839-847.
  18. Ishikawa S, Abe T, Kuramata M, Yamaguchi M, Ando T, Yamamoto T, Yano M (2010): A major quantitative trait locus for increasing cadmium-specific concentration in rice grain is located on the short arm of chromosome 7. J Exp Bot, 61(3):923-934.
  19. Arao T, Ishikawa S, Murakami M, Abe K, Maejima Y, Makino T (2010): Heavy metal contamination of agricultural soil and countermeasures in Japan. Paddy Water Environ, 8(3):247-257.
  20. Uraguchi S, Mori S, Kuramata M, Kawasaki A, Arao T, Ishikawa S (2009): Root-to-shoot Cd translocation via the xylem is the major process determining shoot and grain cadmium accumulation in rice. J Exp Bot, 60(9):2677-2688.
  21. Mori S, Uraguchi S, Ishikawa S, Arao T (2009): Xylem loading process is a critical factor in determining Cd accumulation in the shoots of Solanum melongena and Solanum torvum. Environ Exp Bot, 67(1):127-132.
  22. Mori S, Kawasaki A, Ishikawa S, Arao T (2009): A new method for evaluating symplastic cadmium absorption in the roots of Solanum melongena using enriched isotopes Cd-113 and Cd-114. Soil Sci Plant Nutr, 55(2):294-299.
  23. Kuramata M, Masuya S, Takahashi Y, Kitagawa E, Inoue C, Ishikawa S, Youssefian S, Kusano T: Novel Cysteine-Rich Peptides from Digitaria ciliaris and Oryza sativa Enhance Tolerance to Cadmium by Limiting its Cellular Accumulation. Plant Cell Physiol, 50(1):106-117.
  24. Khan MSH, Tawaraya K, Sekimoto H, Koyama H, Kobayashi Y, Murayama T, Chuba M, Kambayashi M, Shiono Y, Uemura M, Ishikawa S, Wagatsuma T (2009): Relative abundance of Delta(5)-sterols in plasma membrane lipids of root-tip cells correlates with aluminum tolerance of rice. Physiologia Plantarum 2009, 135(1):73-83.
  25. Akhter A, Khan MSH, Hiroaki E, Tawaraya K, Rao IM, Wenzl P, Ishikawa S, Wagatsuma T (2009): Greater contribution of low-nutrient tolerance to sorghum and maize growth under combined stress conditions with high aluminum and low nutrients in solution culture simulating the nutrient status of tropical acid soils. Soil Sci Plant Nutr, 55(3):394-406.
  26. Murakami M, Ae N, Ishikawa S, Ibaraki T, Ito M (2008): Phytoextraction by a high-Cd-accumulating rice: Reduction of Cd content of soybean seeds. Environmental Science & Technology, 42(16):6167-6172.
  27. Hayashi K, Hiradate S, Ishikawa S, Nouchi I (2008): Ammonia exchange between rice leaf blades and the atmosphere: Effect of broadcast urea and changes in xylem sap and leaf apoplastic ammonium concentrations. Soil Sci Plant Nutr, 54(5):807-818.
  28. Murakami M, Ae N, Ishikawa S (2007): Phytoextraction of cadmium by rice (Oryza sativa L.), soybean (Glycine max (L.) Merr.), and maize (Zea mays L.). Environmental Pollution, 145(1):96-103.
  29. Ishikawa S, Ae N, Murakami M, Wagatsuma T (2006): Is Brassica juncea a suitable plant for phytoremediation of cadmium in soils with moderately low cadmium contamination? Possibility of using other plant species for Cd-phytoextraction. Soil Sci Plant Nutr, 52(1):32-42.
  30. Arao T, Ishikawa S (2006): Genotypic differences in cadmium concentration and distribution of soybean and rice. Jarq-Japan Agricultural Research Quarterly, 40(1):21-30.
  31. Wagatsuma T, Uemura M, Mitsuhashi W, Maeshima M, Ishikawa S, Kawamura T, Murayama T, Shiono Y, Khan SH, Tawaraya K (2005): A new and simple technique for the isolation of plasma membrane lipids from root-tips. Soil Sci Plant Nutr, 51(1):135-139.
  32. Wagatsuma T, Ishikawa S, Uemura M, Mitsuhashi W, Kawarnura T, Khan MSH, Tawaraya K (2005): Plasma membrane lipids are the powerful components for early stage aluminum tolerance in triticale. Soil Sci Plant Nutr, 51(5):701-704.
  33. Ishikawa S, Ae N, Yano M (2005): Chromosomal regions with quantitative trait loci controlling cadmium concentration in brown rice (Oryza sativa). New Phytol, 168(2):345-350.
  34. Ishikawa S, Ae N, Sugiyama M, Murakami M, Arao T (2005): Genotypic variation in shoot cadmium concentration in rice and soybean in soils with different levels of cadmium contamination. Soil Sci Plant Nutr, 51(1):101-108.

(著書)

  1. 牧野知之, 石川覚, 村上政治 (2012) 第4章 アジアの米を土壌汚染から守れ, シリーズ21世紀の農学 環境の保全と修復に貢献する農学研究 日本農学会編, 養賢堂, 65-84
  2. T. Watanabe, M.S.H. Kkan, I. M. Rao, J. Wasaki, T. Shinano, M. Ishitani, H. Koyama, S. Ishikawa, K. Tawaraya, M. Nanamori, N. Ueki, T. Wagatsuma (2011) Physiological and biochemical mechanisms of plant adaptation to low-fertility acid soils of the tropics: The case of brachiariagrasses, PRINCIPLES, APPLICATION AND ASSESSMENT IN SOIL SCIENCE, INTECH WEB. ORG, 87-116
  3. S. Ishikawa, Adu-Gyamfi, J.J., Nakamura, T., Yoshihara, T., Watanabe, T., and Wagatsuma, T. (2002): Genotypic variability in phosphorus solubilizing activity of root exudates by pigeonpea grown in low-nutrient environments. In Adu-Gyamfi JJ (Ed) Food Security in Nutrient-Stressed Environments: Exploiting Plants’ Genetic Capabilities. Kluwer Academic Publishers, Dordrecht, The Netherlands, pp111-121.
  4. Adu-Gyamfi, J.J., Ishikawa S., Nakamura T., and Nakano H. (2002): Genotypic variability and physiological characteristics of crop plants adapted to low-nutrient environments. In Adu-Gyamfi JJ (Ed) Food Security in Nutrient-Stressed Environments: Exploiting Plants’ Genetic Capabilities. Kluwer Academic Publishers, Dordrecht, The Netherlands, pp 67-79.
  5. Nakamura T., Adu-Gyamfi, J.J., Yamamoto A, Ishikawa, S., Nakano H., and Ito O. (2002): Varietal differences in root growth as related to nitrogen uptake by sorghum plants in low-nitrogen environment. In Adu-Gyamfi JJ (Ed) Food Security in Nutrient-Stressed Environments: Exploiting Plants’ Genetic Capabilities. Kluwer Academic Publishers, Dordrecht, The Netherlands, pp 103-110.
  6. Wagatsuma, T., Ishikawa, S., and Ofei-Manu, P. (2001): The role of the outer surface of the plasma membrane in aluminum tolerance. In Ae N et al. (Eds) Plant Nutrient Acquisition - New Perspectives. Springer-Verlag, Tokyo, pp. 159-184.

(その他)

  1. 石川覚(2013)イオンビーム照射による低カドミウム米の開発、Isotope News, (社)アイソトープ協会、2013年5月号 No.709、2-5
  2. 石川覚(2013)カドミウムフリー米の開発-イオンビームによる重金属トランスポーターの変異-、化学と生物、51 (4), 203-204
  3. 石川覚、荒尾知人、西澤直子、中西啓仁(2013)低カドミウムコシヒカリの原因遺伝子を発見、JATAFFジャーナル、(社)農林水産・食品産業技術振興協会、vol. 1, No. 4, 32-35
  4. 石川覚, 安部匡 (2012) イネを用いたカドミウム汚染土壌の浄化, 放射線と産業, (財)放射線利用振興協会, 132, 12-17
  5. 川ア晃, 河野憲治, 永井孝志, 小野恭子, 青木政典, 亀和田國彦, 渡辺和彦, 後藤逸男, 石川覚 (2012) 農業環境の重金属問題をリスクの視点から見つめる, 日本土壌肥料学雑誌, (社)日本土壌肥料学会, 83(3), 344-350
  6. 山口紀子, 高田裕介, 林健太郎, 石川覚, 倉俣正人, 江口定夫, 吉川省子, 坂口敦, 朝田景, 和穎朗太, 牧野知之, 赤羽幾子, 平舘俊太郎 (2012) 土壌-植物系における放射性セシウムの挙動とその変動要因(総説), 農業環境技術研究所報告, (独)農業環境技術研究所, 第31号:75-129
  7. 荒尾知人, 牧野知之, 村上政治, 石川覚, 阿部薫 (2010) カドミウム汚染農耕地土壌対策技術の開発, 農業技術, (財)農業技術協会, 65(6), 205-222
  8. 荒尾知人・加藤英孝・牧野知之・赤羽幾子・鈴木克拓・天知誠吾・山口紀子・高橋嘉夫・石川覚・川ア晃・松本真悟・前島勇治・村上政治・門倉雅史・堀田博 (2009)水田土壌及び水稲における化学形態別ヒ素の動態に関する最近の研究動向(総説). 農業環境技術研究所報告, (独)農業環境技術研究所, 26, 93-103.
  9. 石川覚 (2008): 農用地における重金属汚染土壌の対策技術の最前線 7. 水稲のカドミウム吸収抑制技術、日本土壌肥料学雑誌、79, 408-416

(国際特許)