<p>TRPM5 is a Ca<sup>2+</sup>-activated monovalent cation channel essential for taste perception, insulin secretion and gastrointestinal chemosensation. Canonical TRPM5 activation requires Ca<sup>2+</sup> binding at two distinct sites: an agonist site within the lower vestibule of the S1–S4 pocket in the transmembrane domain (Ca<sub>TMD</sub>) and a modulatory site in the intracellular domain (Ca<sub>ICD</sub>) that tunes voltage dependence and agonist sensitivity. Here we characterize CBTA as a noncalcium agonist that binds to the upper vestibule of the S1–S4 pocket, directly above Ca<sub>TMD</sub>. CBTA alone mimics the dual role of Ca<sub>TMD</sub> and Ca<sub>ICD</sub>, merging agonist activation with voltage modulation. CBTA also renders TRPM5 supersensitive to Ca<sup>2+</sup>, synergistically hyperactivating the channel even at near-resting Ca<sup>2+</sup> levels. We further demonstrate that the inhibitor triphenylphosphine oxide binds the same site but stabilizes a nonconductive state. These opposing effects reveal the upper S1–S4 pocket as a multifunctional regulatory hub integrating activation, inhibition and modulation in TRPM5.</p><p></p>

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A single allosteric site merges activation, modulation and inhibition in TRPM5

  • Zheng Ruan,
  • Junuk Lee,
  • Yangyang Li,
  • Ian J. Orozco,
  • Juan Du,
  • Wei Lü

摘要

TRPM5 is a Ca2+-activated monovalent cation channel essential for taste perception, insulin secretion and gastrointestinal chemosensation. Canonical TRPM5 activation requires Ca2+ binding at two distinct sites: an agonist site within the lower vestibule of the S1–S4 pocket in the transmembrane domain (CaTMD) and a modulatory site in the intracellular domain (CaICD) that tunes voltage dependence and agonist sensitivity. Here we characterize CBTA as a noncalcium agonist that binds to the upper vestibule of the S1–S4 pocket, directly above CaTMD. CBTA alone mimics the dual role of CaTMD and CaICD, merging agonist activation with voltage modulation. CBTA also renders TRPM5 supersensitive to Ca2+, synergistically hyperactivating the channel even at near-resting Ca2+ levels. We further demonstrate that the inhibitor triphenylphosphine oxide binds the same site but stabilizes a nonconductive state. These opposing effects reveal the upper S1–S4 pocket as a multifunctional regulatory hub integrating activation, inhibition and modulation in TRPM5.