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Confinement of unliganded EGFR by tetraspanin nanodomains gates EGFR ligand binding and signaling

Author

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  • Michael G. Sugiyama

    (Toronto Metropolitan University)

  • Aidan I. Brown

    (Toronto Metropolitan University)

  • Jesus Vega-Lugo

    (UT Southwestern Medical Center)

  • Jazlyn P. Borges

    (Hospital for Sick Children)

  • Andrew M. Scott

    (La Trobe University)

  • Khuloud Jaqaman

    (UT Southwestern Medical Center
    UT Southwestern Medical Center)

  • Gregory D. Fairn

    (Dalhousie University)

  • Costin N. Antonescu

    (Toronto Metropolitan University)

Abstract

The epidermal growth factor receptor (EGFR) is a central regulator of cell physiology. EGFR is activated by ligand binding, triggering receptor dimerization, activation of kinase activity, and intracellular signaling. EGFR is transiently confined within various plasma membrane nanodomains, yet how this may contribute to regulation of EGFR ligand binding is poorly understood. To resolve how EGFR nanoscale compartmentalization gates ligand binding, we developed single-particle tracking methods to track the mobility of ligand-bound and total EGFR, in combination with modeling of EGFR ligand binding. In comparison to unliganded EGFR, ligand-bound EGFR is more confined and distinctly regulated by clathrin and tetraspanin nanodomains. Ligand binding to unliganded EGFR occurs preferentially in tetraspanin nanodomains, and disruption of tetraspanin nanodomains impairs EGFR ligand binding and alters the conformation of the receptor’s ectodomain. We thus reveal a mechanism by which EGFR confinement within tetraspanin nanodomains regulates receptor signaling at the level of ligand binding.

Suggested Citation

  • Michael G. Sugiyama & Aidan I. Brown & Jesus Vega-Lugo & Jazlyn P. Borges & Andrew M. Scott & Khuloud Jaqaman & Gregory D. Fairn & Costin N. Antonescu, 2023. "Confinement of unliganded EGFR by tetraspanin nanodomains gates EGFR ligand binding and signaling," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
  • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-38390-z
    DOI: 10.1038/s41467-023-38390-z
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    References listed on IDEAS

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    1. Inhee Chung & Robert Akita & Richard Vandlen & Derek Toomre & Joseph Schlessinger & Ira Mellman, 2010. "Spatial control of EGF receptor activation by reversible dimerization on living cells," Nature, Nature, vol. 464(7289), pages 783-787, April.
    2. Masato Yasui & Michio Hiroshima & Jun Kozuka & Yasushi Sako & Masahiro Ueda, 2018. "Automated single-molecule imaging in living cells," Nature Communications, Nature, vol. 9(1), pages 1-11, December.
    3. Sarah R. Needham & Selene K. Roberts & Anton Arkhipov & Venkatesh P. Mysore & Christopher J. Tynan & Laura C. Zanetti-Domingues & Eric T. Kim & Valeria Losasso & Dimitrios Korovesis & Michael Hirsch &, 2016. "EGFR oligomerization organizes kinase-active dimers into competent signalling platforms," Nature Communications, Nature, vol. 7(1), pages 1-14, December.
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