CVClient

Masahiro Takeo

  (武尾 正弘)

Profile Information

Affiliation
Professor, Lab. of Bioscience and Biotechnology, Graduate School of Engineering, Department of Applied Chemistry, University of Hyogo
Degree
Master(Engineering)(Osaka University)
Doctor(Engineering)(Osaka University)

J-GLOBAL ID
200901027729174169
researchmap Member ID
1000057675

External link

Research Interests

 2

Papers

 125
  • Ryugo Nishimine, Yuna Kaneko, Shinpei Fujiwara, Daisuke Inoue, Masahiro Takeo, Michihiko Ike
    Journal of Bioscience and Bioengineering, 141(2) 116-124, Feb, 2026  Peer-reviewed
  • Hidehiro Ishizawa, Sunao Noguchi, Miku Kito, Yui Nomura, Kodai Kimura, Masahiro Takeo
    The ISME Journal, 19(1) wraf236, Oct 23, 2025  Peer-reviewed
    Abstract The functions of microbial communities, including substrate conversion and pathogen suppression, arise not as a simple sum of individual species’ capabilities but through complex interspecies interactions. Understanding how such functions arise from individual species and their interactions remains a major challenge, limiting efforts to rationally understand microbial roles in both natural and engineered ecosystems. Because current holistic (meta-omics) and reductionist (isolation- or single-cell-based) approaches struggle to capture these emergent microbial community functions, this study explores an intermediate strategy: analyzing simple sub-community combinations to enable a bottom-up understanding of community-level functions. To examine the validity of this approach, we used a nine-member synthetic microbial community capable of degrading the environmental pollutant aniline, and systematically generated a dataset of 256 sub-community combinations and their associated functions. Analyses using random forest models revealed that the sub-community combinations of just three to four species enabled the quantitative prediction of functions in larger communities (5–9-member; Pearson’s r = 0.78–0.80). Prediction performance remained robust even with limited sub-community data, suggesting applicability to more diverse microbial communities where exhaustive sub-community observation is infeasible. Moreover, interpreting models trained on these simple sub-community combinations enabled the identification of key species and interspecies interactions that strongly influence the overall community function. These findings provide a methodological framework for mechanistically dissecting complex microbial community functions through sub-community-based analysis.
  • 三木悠平, 江口智己, 中村雅基, 石澤秀紘, 武尾正弘, 竹内雅耶, 秦隆志, 西内悠祐, 多田佳織, 鈴木哲
    X線分析の進歩, 56 79-85, Mar, 2025  Peer-reviewed
  • Masahiro Takeo, Seiwa Ohtaki, Hidehiro Ishizawa
    Microbiology Resource Announcements, 14(issue 2) 1-3, Dec 27, 2024  Peer-reviewedLead authorCorresponding author
    ABSTRACT We report the complete genome assembly of a hydroquinonesulfonate-assimilating bacterium, Delftia lacustris strain HQS1. This strain contains one circular chromosome (6,979,964 bp) and one circular plasmid (39,999 bp). The chromosomal sequence contained 6,359 coding sequences and a gene cluster involved in the degradation of gentisate, which is structurally similar to hydroquinonesulfonate.
  • MASAHIRO TAKEO, RYOTA INO, SEIWA OHTAKI, MAYU KUROE, YOTA KOMAKI, HIDEHIRO ISHIZAWA
    Japanese Journal of Water Treatment Biology, 60(4) 73-86, Dec 15, 2024  Peer-reviewedInvitedLead authorCorresponding author

Misc.

 39

Books and Other Publications

 2

Presentations

 165

Teaching Experience

 11

Research Projects

 33