In sensory neurons, mechanotransduction is sensitive, fast and requires
mechanosensitive ion channels. Here we develop a new method to directly monitor
mechanotransduction at defined regions of the cell-substrate interface. We show that
molecular-scale (~13 nm) displacements are sufficient to gate
mechanosensitive currents in mouse touch receptors. Using neurons from knockout
mice, we show that displacement thresholds increase by one order of magnitude in the
absence of stomatin-like protein 3
(STOML3). Piezo1 is the founding member of a class of
mammalian stretch-activated ion channels, and we show that STOML3, but not other stomatin-domain
proteins, brings the activation threshold for Piezo1 and Piezo2 currents down to ~10 nm.
Structure–function experiments localize the Piezo modulatory activity of
STOML3 to the stomatin domain,
and higher-order scaffolds are a prerequisite for function. STOML3 is the first potent modulator of Piezo
channels that tunes the sensitivity of mechanically gated channels to detect
molecular-scale stimuli relevant for fine touch.
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