Rchr
J-GLOBAL ID:200901052923278832   Update date: Nov. 17, 2024

Yoshida Ken'ichi

ヨシダ ケンイチ | Yoshida Ken'ichi
Affiliation and department:
Kobe University Graduate School of Science, Technology and Innovation Department of Science, Technology and Innovation

About Kobe University Graduate School of Science, Technology and Innovation Department of Science, Technology and Innovation


Job title: Professor
Other affiliations (1):
  • FEMS  Ambassador
Homepage URL  (1): http://www.research.kobe-u.ac.jp/ans-applmic/index.html
Research field  (3): Applied biofunctional and bioprocess engineering ,  Genomics ,  Applied microbiology
Research keywords  (6): inositol ,  Bacillus subtilis ,  Rhizobia ,  Geobacillus ,  metabolic engineering ,  synthetic biology
Research theme for competitive and other funds  (19):
  • 2018 - 2022 新たなゲノム機能調節機構の解明につながる好熱バチルスの制御因子Crhの解析
  • 2019 - 2021 Transforming functional bacterial communities: how does horizontal genetic transfer impact the functional society of bacteria?
  • 2016 - 2020 "A Sweet and Calorie-free Bacillus!?": Production of L-glucose in B. subtilis
  • 2017 - 2019 細胞内コンビナトリアル・エンザイモロジーによるイノシトール異性体の生産
  • 2014 - 2016 根粒菌のイノシトール合成が担う新たな環境適応機構の発見
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Papers (131):
  • Takahiko Kondo, Surachat Sibponkrung, Panlada Tittabutr, Nantakorn Boonkerd, Shu Ishikawa, Neung Teaumroong, Ken-ichi Yoshida. Bacillus velezensis S141 improves the root growth of soybean under drought conditions. Bioscience, Biotechnology, and Biochemistry. 2024
  • Ken-ichi Yoshida, Kyosuke Yokoyama, Ayşegül Öktem, Shu Ishikawa, Jan Maarten van Dijl, Masato Yotsuya, Ryosuke Sato. Bacillus subtilis grown in a “breathing” vessel without sparger aeration. Bioscience, Biotechnology, and Biochemistry. 2024
  • Ryota Kurashiki, Masahiro Takahashi, Yuta Okumura, Tatsuya Ono, Hirofumi Endo, Kohei Makino, Kaho Fukui, Kyosuke Yokoyama, Shu Ishikawa, Ken-ichi Yoshida, et al. Efficient pathway-driven scyllo -inositol production from myo -inositol using thermophilic cells and mesophilic inositol dehydrogenases: a novel strategy for pathway control. Applied and Environmental Microbiology. 2024. 90. 7
  • Rocío Aguilar Suárez, Michael Kohlstedt, Ayşegül Öktem, Jolanda Neef, Yuzheng Wu, Kaiya Ikeda, Ken-Ichi Yoshida, Josef Altenbuchner, Christoph Wittmann, Jan Maarten van Dijl. Metabolic Profile of the Genome-Reduced Bacillus subtilis Strain IIG-Bs-27-39: An Attractive Chassis for Recombinant Protein Production. ACS Synthetic Biology. 2024. 13. 7. 2199-2214
  • Ken-ichi Yoshida, Michael Bott. Microbial synthesis of health-promoting inositols. Current Opinion in Biotechnology. 2024. 87. 103114-103114
more...
MISC (92):
  • 吉田健一. FEMS2019報告. 生物工学会誌. 2019. 97. 11. 692-693
  • Takenaka Shinji, Senba Hironori, Tanaka Kosei, Yoshida Ken-Ichi, Koyama Dai, Doi Mikiharu. 2P-043 Characterization of aspartic proteases from Aspergillus repens and Aspertic glaucus. 2015. 67. 185-185
  • Ozeki Takahiro, Tanaka Kosei, Yoshida Ken-ichi, Takenaka Shinji. 2P-041 Characterization of internal substrate and acetyl-CoA binding sites in Nacetyltransferase from Chryseobacterium sp. 5-3B. 2015. 67. 185-185
  • Takeuchi Daiki, Tsuge Yota, Okai Naoko, Tanaka Kosei, Yoshida Ken-Ichi, Takenaka Shinji. 2P-042 Cloning, heterologous expression, and enzymatic characterization of bacterial diamine transaminases. 2015. 67. 185-185
  • Nishihata Shogo, Tanaka Kosei, Takenaka Shinji, Yoshida Ken-ichi. 2P-013 Phasin genes involved in PHB accumulation in Bradyrhizobium japonicum. 2015. 67. 178-178
more...
Patents (10):
  • グラム陽性菌の形質転換法
  • アセトイン産生細胞および当該細胞を用いたアセトインの製造方法
  • シロ-イノシトール産生細胞および当該細胞を用いたシロ-イノシトール製造方法(米)
  • 好熱性微生物の形質転換方法
  • シロ-イノシトール産生細胞および当該細胞を用いたシロ-イノシトール製造方法
more...
Books (6):
  • Escherichia coli and Bacillus subtilis; the frontiers of molecular microbiology revisited
    Research Signpost 2012
  • 遺伝子工学と未来社会 「遺伝子工学」
    化学同人 2012
  • バイオコンバージョンによって効率的にビタミンを作る-イノシトール 「微生物機能学」
    三共出版 2012
  • Inositol derivatives stimulate glucose transport in muscle cells, in “Animal Cell Technology: Basic & Applied Aspects, Vol. 15, Eds. by, Koji Ikura, Masaya Nagao, Akira Ichikawa, Kiichiro Teruya and Sanetaka Shirahata, pp. 225-231.
    Springer 2011
  • δin L6 myotubes, in "Animal Cell Technology: Basic & Applied Aspects", Vol. 16, Eds. by, Masamichi Kamihira, Yoshinori Katakura, and Akira Ito, pp.327-331, 2010.
    Springer 2010
more...
Lectures and oral presentations  (221):
  • 枯草菌接合伝達プラスミドpLS20の伝達効率の再評価
    (日本農芸化学会 2021年度西日本・中四国・関西支部 合同大会 2021)
  • Monitoring NADPH Levels by Luciferase Luminescence in Bacillus subtilis
    (Metabolic Engineering 14 2021)
  • グラム陽性細菌の接合プラスミドpLS20の接合伝達ダイナミクスの解明
    (日本農芸化学会 2021年度大会 2021)
  • Aeribacillus pallidus PI8の耐熱性バクテリオシン生合成に関わる遺伝子群
    (第15回日本ゲノム微生物学会年会 2021)
  • Application of the Gram-positive conjugative plasmid pLS20 for rapid and easy transformation of intra- and inter-species
    (FEMS ONLINE CONFERENCE ON MICROBIOLOGY 2020 2020)
more...
Education (1):
  • - 1993 Kyoto University
Professional career (2):
  • 農学修士 (京都大学)
  • 博士(農学) (京都大学)
Awards (6):
  • 2023/11 - 兵庫県 兵庫県科学賞
  • 2019/01 - FEMS Honorary FEMS Ambassador
  • 2014/03 - 日本農芸化学会 日本農芸化学会論文賞2013 Award for Excellence to Authors Publishing in Bioscience, Biotechnology, and Biochemistry in 2013
  • 2009/03 - 日本農芸化学会 日本農芸化学会論文賞2008 Award for Excellence to Authors Publishing in Bioscience, Biotechnology, and Biochemistry in 2008
  • 2009/03 - 日本農芸化学会 日本農芸化学会英文誌Bioscience, Biotechnology, and Biochemistry論文賞 Identification of Two Major Ammonia-Releasing Reactions Involved in Secondary Natto Fermentation
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