Mechanosensitive pore opening of a prokaryotic voltage-gated sodium channel

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Abstract

Voltage-gated ion channels orchestrate electrical activities that drive mechanical functions in contractile tissues such as the heart and gut. In turn, contractions change membrane tension and impact ion channels. Voltage-gated ion channels are mechanosensitive, but the mechanisms of mechanosensitivity remain poorly understood. Here, we leverage the relative simplicity of NaChBac, a prokaryotic sodium channel from Bacillus halodurans, to investigate its mechanosensitivity. In whole-cell experiments on heterologously transfected HEK293 cells, shear stress reversibly altered the kinetic properties of NaChBac and increased its maximum current, comparably to the mechanosensitive eukaryotic sodium channel NaV1.5. In single-channel experiments, patch suction reversibly increased the open probability of a NaChBac mutant with inactivation removed. A simple kinetic mechanism featuring a mechanosensitive pore opening transition explained the overall response to force, whereas an alternative model with mechanosensitive voltage sensor activation diverged from the data. Structural analysis of NaChBac identified a large displacement of the hinged intracellular gate, and mutagenesis at the hinge abolished NaChBac mechanosensitivity, further supporting the proposed mechanism. Overall, our results suggest that NaChBac responds to force because its pore is intrinsically mechanosensitive. This mechanism may apply to other voltage-gated ion channels, including NaV1.5.

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