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The role of TIR domain-containing proteins in bacterial defense against phages

Author

Listed:
  • Shuangshuang Wang

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Sirong Kuang

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Haiguang Song

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Erchao Sun

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Mengling Li

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Yuepeng Liu

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Ziwei Xia

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Xueqi Zhang

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Xialin Wang

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Jiumin Han

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Venigalla B. Rao

    (The Catholic University of America)

  • Tingting Zou

    (Huazhong Agricultural University)

  • Chen Tan

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

  • Pan Tao

    (Huazhong Agricultural University
    Hubei Hongshan Lab
    Huazhong Agricultural University)

Abstract

Toll/interleukin-1 receptor (TIR) domain-containing proteins play a critical role in immune responses in diverse organisms, but their function in bacterial systems remains to be fully elucidated. This study, focusing on Escherichia coli, addresses how TIR domain-containing proteins contribute to bacterial immunity against phage attack. Through an exhaustive survey of all E. coli genomes available in the NCBI database and testing of 32 representatives of the 90% of the identified TIR domain-containing proteins, we found that a significant proportion (37.5%) exhibit antiphage activities. These defense systems recognize a variety of phage components, thus providing a sophisticated mechanism for pathogen detection and defense. This study not only highlights the robustness of TIR systems in bacterial immunity, but also draws an intriguing parallel to the diversity seen in mammalian Toll-like receptors (TLRs), enriching our understanding of innate immune mechanisms across life forms and underscoring the evolutionary significance of these defense strategies in prokaryotes.

Suggested Citation

  • Shuangshuang Wang & Sirong Kuang & Haiguang Song & Erchao Sun & Mengling Li & Yuepeng Liu & Ziwei Xia & Xueqi Zhang & Xialin Wang & Jiumin Han & Venigalla B. Rao & Tingting Zou & Chen Tan & Pan Tao, 2024. "The role of TIR domain-containing proteins in bacterial defense against phages," Nature Communications, Nature, vol. 15(1), pages 1-13, December.
  • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-51738-3
    DOI: 10.1038/s41467-024-51738-3
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    References listed on IDEAS

    as
    1. Gaëlle Hogrel & Abbie Guild & Shirley Graham & Hannah Rickman & Sabine Grüschow & Quentin Bertrand & Laura Spagnolo & Malcolm F. White, 2022. "Cyclic nucleotide-induced helical structure activates a TIR immune effector," Nature, Nature, vol. 608(7924), pages 808-812, August.
    2. Donghyun Ka & Hyejin Oh & Eunyoung Park & Jeong-Han Kim & Euiyoung Bae, 2020. "Structural and functional evidence of bacterial antiphage protection by Thoeris defense system via NAD+ degradation," Nature Communications, Nature, vol. 11(1), pages 1-8, December.
    3. Samuel J. Hobbs & Tanita Wein & Allen Lu & Benjamin R. Morehouse & Julia Schnabel & Azita Leavitt & Erez Yirmiya & Rotem Sorek & Philip J. Kranzusch, 2022. "Phage anti-CBASS and anti-Pycsar nucleases subvert bacterial immunity," Nature, Nature, vol. 605(7910), pages 522-526, May.
    4. Benjamin R. Morehouse & Apurva A. Govande & Adi Millman & Alexander F. A. Keszei & Brianna Lowey & Gal Ofir & Sichen Shao & Rotem Sorek & Philip J. Kranzusch, 2020. "STING cyclic dinucleotide sensing originated in bacteria," Nature, Nature, vol. 586(7829), pages 429-433, October.
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