研究者業績

Shinya Ohata

  (大畑 慎也)

Profile Information

Affiliation
Associate Professor, Musashino University
Degree
Ph.D. (Pharmaceutical Sciences)(The University of Tokyo)

J-GLOBAL ID
201101082570695641
researchmap Member ID
B000003295

External link

Papers

 27
  • Kazuki Ishikawa, Nao Kamiya, Masaki Ishii, Takashi Yaguchi, Koji Ichinose, Shinya Ohata
    Advances in Microbiology, 14(9) 448-467, Sep 29, 2024  Peer-reviewedLast authorCorresponding author
  • Sachiko Toma-Fukai, Yutaro Nakamura, Akihiro Kawamoto, Hikaru Shimizu, Koki Hayama, Ruri Kojima, Kanami Yoshimura, Masaki Ishii, Mika Hirose, Toshiaki Teratani, Shinya Ohata, Takayuki Kato, Hironari Kamikubo, Toshimasa Itoh, Kengo Tomita, Toshiyuki Shimizu
    bioRχiv, Sep 17, 2024  
    The spatial and temporal control of protein is essential for normal cellular function. Proteins working in the nucleus have nuclear localization signal (NLS) sequences and are escorted into the nucleus by cognate nuclear transport receptors. A wealth of experimental data about NLS has been accumulated, and nuclear transportation mechanisms are established at the biochemical and structural levels. The peroxisome proliferator-activated receptors (PPARs) are ligand-dependent transcription factors that control various biological responses. We recently reported that the transportation of PPARg is mediated by Transportin-1, but PPARg lacks a typical NLS sequence recognized by Transportin-1. Moreover, the recognition mechanism remains largely unknown. In this study, we determined the Cryo-EM structure of PPARg in complex with Transportin-1 and revealed that Transportin-1 gripped the folded DNA binding domain and the Hinge region of PPARg, indicating that PPARg recognizes a folded domain with an extended region as a nuclear localization signal, not a canonical unstructured signal sequence, confirmed by the mutation analyses in vitro and in cultured cells. Our study is the first snapshot structure working in nuclear transportation, not in transcription, of PPARg.
  • Masaki Ishii, Tsuyoshi Yamada, Shinya Ohata
    AMB Express, 14 96, Aug 31, 2024  Peer-reviewedLast authorCorresponding author
  • Masaki Ishii, Yasuhiko Matsumoto, Tsuyoshi Yamada, Hideko Uga, Toshiaki Katada, Shinya Ohata
    iScience, 27(6) 110139, Jun 21, 2024  Peer-reviewedLast authorCorresponding author
  • Masaki Ishii, Tsuyoshi Yamada, Kazuki Ishikawa, Koji Ichinose, Michel Monod, Shinya Ohata
    Antimicrobial Agents and Chemotherapy, 68(5) e0160923, May 2, 2024  Peer-reviewedLast authorCorresponding author
    ABSTRACT The increasing prevalence of dermatophyte resistance to terbinafine, a key drug in the treatment of dermatophytosis, represents a significant obstacle to treatment. Trichophyton rubrum is the most commonly isolated fungus in dermatophytosis. In T. rubrum , we identified TERG_07844, a gene encoding a previously uncharacterized putative protein kinase, as an ortholog of budding yeast Saccharomyces cerevisiae polyamine transport kinase 2 (Ptk2), and found that T. rubrum Ptk2 (TrPtk2) is involved in terbinafine tolerance. In both T. rubrum and S. cerevisiae , Ptk2 knockout strains were more sensitive to terbinafine compared with the wild types, suggesting that promotion of terbinafine tolerance is a conserved function of fungal Ptk2. Pma1 is activated through phosphorylation by Ptk2 in S. cerevisiae . Overexpression of T. rubrum Pma1 (TrPma1) in T. rubrum Ptk2 knockout strain (ΔTrPtk2) suppressed terbinafine sensitivity, suggesting that the induction of terbinafine tolerance by TrPtk2 is mediated by TrPma1. Furthermore, omeprazole, an inhibitor of plasma membrane proton pump Pma1, increased the terbinafine sensitivity of clinically isolated terbinafine-resistant strains. These findings suggest that, in dermatophytes, the TrPtk2-TrPma1 pathway plays a key role in promoting intrinsic terbinafine tolerance and may serve as a potential target for combinational antifungal therapy against terbinafine-resistant dermatophytes.

Misc.

 28
  • Masaki Ishii, Tsuyoshi Yamada, Shinya Ohata
    bioRχiv, Apr 19, 2024  Last authorCorresponding author
  • Masaki Ishii, Yasuhiko Matsumoto, Tsuyoshi Yamada, Hideko Uga, Toshiaki Katada, Shinya Ohata
    bioRχiv, Mar 5, 2024  Last authorCorresponding author
  • Masaki Ishii, Tsuyoshi Yamada, Michel Monod, Shinya Ohata
    bioRχiv, Dec 8, 2023  Last authorCorresponding author
    The increasing prevalence of dermatophyte resistance to terbinafine, a key drug in the treatment of dermatophytosis, represents a significant obstacle to treatment.Trichophyton rubrumis the most commonly isolated fungus in dermatophytosis. InT. rubrum, we identified TERG_07844, a gene encoding a previously uncharacterized putative protein kinase, as an ortholog of budding yeastSaccharomyces cerevisiaepolyamine transport kinase 2 (Ptk2) and found thatT. rubrumPtk2 (TrPtk2) is involved in terbinafine tolerance. In bothT. rubrumandS. cerevisiae, Ptk2 knockout strains were more sensitive to terbinafine compared to the wild types, suggesting that promotion of terbinafine tolerance is a conserved function of fungal Ptk2. TheT. rubrumPtk2 knockout strain (ΔTrPtk2) was sensitive to omeprazole, an inhibitor of plasma membrane proton pump Pma1, which is activated through phosphorylation by Ptk2 inS. cerevisiae. Overexpression ofT. rubrumPma1 (TrPma1) in ΔTrPtk2 suppressed terbinafine sensitivity, suggesting that the induction of terbinafine tolerance by TrPtk2 is mediated by TrPma1. Furthermore, omeprazole increased the terbinafine sensitivity of clinically isolated terbinafine-resistant strains. These findings suggest that, in dermatophytes, the TrPtk2-TrPma1 pathway plays a key role in promoting intrinsic terbinafine tolerance and may serve as a potential target for combinational antifungal therapy against terbinafine-resistant dermatophytes.
  • Shinya Ohata
    Advances in Pharmaceutical Sciences, 39 17-28, Mar 15, 2023  Invited

Presentations

 86

Teaching Experience

 29

Research Projects

 10

Social Activities

 1