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A conserved PLPLRT/SD motif of STING mediates the recruitment and activation of TBK1

Author

Listed:
  • Baoyu Zhao

    (Texas A&M University)

  • Fenglei Du

    (Texas A&M University)

  • Pengbiao Xu

    (Texas A&M University)

  • Chang Shu

    (Texas A&M University)

  • Banumathi Sankaran

    (Lawrence Berkeley National Laboratory)

  • Samantha L. Bell

    (Texas A&M University Health Science Center)

  • Mengmeng Liu

    (Texas A&M University Health Science Center)

  • Yuanjiu Lei

    (Texas A&M University Health Science Center)

  • Xinsheng Gao

    (Texas A&M University Health Science Center)

  • Xiaofeng Fu

    (Florida State University)

  • Fanxiu Zhu

    (Florida State University)

  • Yang Liu

    (Texas A&M University)

  • Arthur Laganowsky

    (Texas A&M University)

  • Xueyun Zheng

    (Texas A&M University)

  • Jun-Yuan Ji

    (Texas A&M University Health Science Center)

  • A. Phillip West

    (Texas A&M University Health Science Center)

  • Robert O. Watson

    (Texas A&M University Health Science Center)

  • Pingwei Li

    (Texas A&M University)

Abstract

Nucleic acids from bacteria or viruses induce potent immune responses in infected cells1–4. The detection of pathogen-derived nucleic acids is a central strategy by which the host senses infection and initiates protective immune responses5,6. Cyclic GMP-AMP synthase (cGAS) is a double-stranded DNA sensor7,8. It catalyses the synthesis of cyclic GMP-AMP (cGAMP)9–12, which stimulates the induction of type I interferons through the STING–TBK1–IRF-3 signalling axis13–15. STING oligomerizes after binding of cGAMP, leading to the recruitment and activation of the TBK1 kinase8,16. The IRF-3 transcription factor is then recruited to the signalling complex and activated by TBK18,17–20. Phosphorylated IRF-3 translocates to the nucleus and initiates the expression of type I interferons21. However, the precise mechanisms that govern activation of STING by cGAMP and subsequent activation of TBK1 by STING remain unclear. Here we show that a conserved PLPLRT/SD motif within the C-terminal tail of STING mediates the recruitment and activation of TBK1. Crystal structures of TBK1 bound to STING reveal that the PLPLRT/SD motif binds to the dimer interface of TBK1. Cell-based studies confirm that the direct interaction between TBK1 and STING is essential for induction of IFNβ after cGAMP stimulation. Moreover, we show that full-length STING oligomerizes after it binds cGAMP, and highlight this as an essential step in the activation of STING-mediated signalling. These findings provide a structural basis for the development of STING agonists and antagonists for the treatment of cancer and autoimmune disorders.

Suggested Citation

  • Baoyu Zhao & Fenglei Du & Pengbiao Xu & Chang Shu & Banumathi Sankaran & Samantha L. Bell & Mengmeng Liu & Yuanjiu Lei & Xinsheng Gao & Xiaofeng Fu & Fanxiu Zhu & Yang Liu & Arthur Laganowsky & Xueyun, 2019. "A conserved PLPLRT/SD motif of STING mediates the recruitment and activation of TBK1," Nature, Nature, vol. 569(7758), pages 718-722, May.
    • Handle: RePEc:nat:nature:v:569:y:2019:i:7758:d:10.1038_s41586-019-1228-x
    DOI: 10.1038/s41586-019-1228-x
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    Cited by:

    1. Tomalika R. Ullah & Matt D. Johansen & Katherine R. Balka & Rebecca L. Ambrose & Linden J. Gearing & James Roest & Julian P. Vivian & Sunil Sapkota & W. Samantha N. Jayasekara & Daniel S. Wenholz & Vi, 2023. "Pharmacological inhibition of TBK1/IKKε blunts immunopathology in a murine model of SARS-CoV-2 infection," Nature Communications, Nature, vol. 14(1), pages 1-13, December.
    2. Matteo Gentili & Bingxu Liu & Malvina Papanastasiou & Deborah Dele-Oni & Marc A. Schwartz & Rebecca J. Carlson & Aziz M. Al’Khafaji & Karsten Krug & Adam Brown & John G. Doench & Steven A. Carr & Nir , 2023. "ESCRT-dependent STING degradation inhibits steady-state and cGAMP-induced signalling," Nature Communications, Nature, vol. 14(1), pages 1-22, December.
    3. Haruka Kemmoku & Kanoko Takahashi & Kojiro Mukai & Toshiki Mori & Koichiro M. Hirosawa & Fumika Kiku & Yasunori Uchida & Yoshihiko Kuchitsu & Yu Nishioka & Masaaki Sawa & Takuma Kishimoto & Kazuma Tan, 2024. "Single-molecule localization microscopy reveals STING clustering at the trans-Golgi network through palmitoylation-dependent accumulation of cholesterol," Nature Communications, Nature, vol. 15(1), pages 1-17, December.
    4. Yaling Dou & Rui Chen & Siyao Liu & Yi-Tsang Lee & Ji Jing & Xiaoxuan Liu & Yuepeng Ke & Rui Wang & Yubin Zhou & Yun Huang, 2023. "Optogenetic engineering of STING signaling allows remote immunomodulation to enhance cancer immunotherapy," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
    5. Xudong Chen & Min Xie & Sensen Zhang & Marta Monguió-Tortajada & Jian Yin & Chang Liu & Youqi Zhang & Maeva Delacrétaz & Mingyue Song & Yixue Wang & Lin Dong & Qiang Ding & Boda Zhou & Xiaolin Tian & , 2023. "Structural basis for recruitment of TASL by SLC15A4 in human endolysosomal TLR signaling," Nature Communications, Nature, vol. 14(1), pages 1-13, December.
    6. Remzi Onur Eren & Göksu Gökberk Kaya & Robin Schwarzer & Manolis Pasparakis, 2024. "IKKε and TBK1 prevent RIPK1 dependent and independent inflammation," Nature Communications, Nature, vol. 15(1), pages 1-18, December.
    7. Wei-Wei Luo & Zhen Tong & Pan Cao & Fu-Bing Wang & Ying Liu & Zhou-Qin Zheng & Su-Yun Wang & Shu Li & Yan-Yi Wang, 2022. "Transcription-independent regulation of STING activation and innate immune responses by IRF8 in monocytes," Nature Communications, Nature, vol. 13(1), pages 1-15, December.
    8. Bao-cun Zhang & Marlene F. Laursen & Lili Hu & Hossein Hazrati & Ryo Narita & Lea S. Jensen & Aida S. Hansen & Jinrong Huang & Yan Zhang & Xiangning Ding & Maimaitili Muyesier & Emil Nilsson & Agniesz, 2024. "Cholesterol-binding motifs in STING that control endoplasmic reticulum retention mediate anti-tumoral activity of cholesterol-lowering compounds," Nature Communications, Nature, vol. 15(1), pages 1-17, December.

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