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Single-molecule localization microscopy reveals STING clustering at the trans-Golgi network through palmitoylation-dependent accumulation of cholesterol

Author

Listed:
  • Haruka Kemmoku

    (Tohoku University)

  • Kanoko Takahashi

    (Tohoku University)

  • Kojiro Mukai

    (Tohoku University)

  • Toshiki Mori

    (Gifu University)

  • Koichiro M. Hirosawa

    (Gifu University)

  • Fumika Kiku

    (University of Tokyo)

  • Yasunori Uchida

    (Tohoku University)

  • Yoshihiko Kuchitsu

    (Tohoku University)

  • Yu Nishioka

    (Carna Biosciences, Inc.)

  • Masaaki Sawa

    (Carna Biosciences, Inc.)

  • Takuma Kishimoto

    (Hokkaido University Graduate School of Life Science)

  • Kazuma Tanaka

    (Hokkaido University Graduate School of Life Science)

  • Yasunari Yokota

    (Gifu University)

  • Hiroyuki Arai

    (University of Tokyo)

  • Kenichi G. N. Suzuki

    (Gifu University
    National Cancer Center Research Institute)

  • Tomohiko Taguchi

    (Tohoku University)

Abstract

Stimulator of interferon genes (STING) is critical for the type I interferon response to pathogen- or self-derived DNA in the cytosol. STING may function as a scaffold to activate TANK-binding kinase 1 (TBK1), but direct cellular evidence remains lacking. Here we show, using single-molecule imaging of STING with enhanced time resolutions down to 5 ms, that STING becomes clustered at the trans-Golgi network (about 20 STING molecules per cluster). The clustering requires STING palmitoylation and the Golgi lipid order defined by cholesterol. Single-molecule imaging of TBK1 reveals that STING clustering enhances the association with TBK1. We thus provide quantitative proof-of-principle for the signaling STING scaffold, reveal the mechanistic role of STING palmitoylation in the STING activation, and resolve the long-standing question of the requirement of STING translocation for triggering the innate immune signaling.

Suggested Citation

  • 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.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-023-44317-5
    DOI: 10.1038/s41467-023-44317-5
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    References listed on IDEAS

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    1. Kai Simons & Elina Ikonen, 1997. "Functional rafts in cell membranes," Nature, Nature, vol. 387(6633), pages 569-572, June.
    2. Guijun Shang & Conggang Zhang & Zhijian J. Chen & Xiao-chen Bai & Xuewu Zhang, 2019. "Cryo-EM structures of STING reveal its mechanism of activation by cyclic GMP–AMP," Nature, Nature, vol. 567(7748), pages 389-393, March.
    3. Madelyn E. McCauley & Jacqueline Gire O’Rourke & Alberto Yáñez & Janet L. Markman & Ritchie Ho & Xinchen Wang & Shuang Chen & Deepti Lall & Mengyao Jin & A. K. M. G. Muhammad & Shaughn Bell & Jesse La, 2020. "C9orf72 in myeloid cells suppresses STING-induced inflammation," Nature, Nature, vol. 585(7823), pages 96-101, September.
    4. Kojiro Mukai & Emari Ogawa & Rei Uematsu & Yoshihiko Kuchitsu & Fumika Kiku & Takefumi Uemura & Satoshi Waguri & Takehiro Suzuki & Naoshi Dohmae & Hiroyuki Arai & Anthony K. Shum & Tomohiko Taguchi, 2021. "Homeostatic regulation of STING by retrograde membrane traffic to the ER," Nature Communications, Nature, vol. 12(1), pages 1-9, December.
    5. Hiroki Ishikawa & Glen N. Barber, 2008. "Erratum: STING is an endoplasmic reticulum adaptor that facilitates innate immune signalling," Nature, Nature, vol. 456(7219), pages 274-274, November.
    6. 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.
    7. Conggang Zhang & Guijun Shang & Xiang Gui & Xuewu Zhang & Xiao-chen Bai & Zhijian J. Chen, 2019. "Structural basis of STING binding with and phosphorylation by TBK1," Nature, Nature, vol. 567(7748), pages 394-398, March.
    8. Simone M. Haag & Muhammet F. Gulen & Luc Reymond & Antoine Gibelin & Laurence Abrami & Alexiane Decout & Michael Heymann & F. Gisou van der Goot & Gerardo Turcatti & Rayk Behrendt & Andrea Ablasser, 2018. "Targeting STING with covalent small-molecule inhibitors," Nature, Nature, vol. 559(7713), pages 269-273, July.
    9. Hiroki Ishikawa & Zhe Ma & Glen N. Barber, 2009. "STING regulates intracellular DNA-mediated, type I interferon-dependent innate immunity," Nature, Nature, vol. 461(7265), pages 788-792, October.
    10. Hiroki Ishikawa & Glen N. Barber, 2008. "STING is an endoplasmic reticulum adaptor that facilitates innate immune signalling," Nature, Nature, vol. 455(7213), pages 674-678, October.
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    Cited by:

    1. Alberto Iannuzzo & Selket Delafontaine & Rana El Masri & Rachida Tacine & Giusi Prencipe & Masahiko Nishitani-Isa & Rogier T. A. Wijck & Farzana Bhuyan & Adriana A. Jesus Rasheed & Simona Coppola & Pa, 2024. "Autoinflammatory patients with Golgi-trapped CDC42 exhibit intracellular trafficking defects leading to STING hyperactivation and ER stress," Nature Communications, Nature, vol. 15(1), pages 1-15, December.

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