Signatures of Mechanosensitive Gating

TL;DR

This paper discusses a method using micropipette-aspirated single-particle tracking to infer the gating mechanisms of mechanosensitive channels by analyzing their diffusion behavior under membrane tension.

Contribution

It introduces an indirect assay to determine the gating mechanism and physical properties of mechanosensitive channels without requiring protein structure data.

Findings

Identifies three distinct diffusion-tension signatures for different gating mechanisms.

Demonstrates how physical moduli relate to channel gating behavior.

Discusses advantages and limitations of the proposed method.

Abstract

The question of how mechanically-gated membrane channels open and close is notoriously difficult to address, especially if the protein structure is not available. This perspective highlights the relevance of micropipette-aspirated single-particle tracking--- used to obtain a channel's diffusion coefficient, $D$, as a function of applied membrane tension, $\sigma$--- as an indirect assay for determining functional behaviour in mechanosensitive channels. Whilst ensuring that the protein remains integral to the membrane, such methods can be used to identify not only the gating mechanism of a protein, but also associated physical moduli, such as torsional- and dilational-rigidity, which correspond to the protein's effective shape change. As an example, three distinct $D$ versus $\sigma$ "signatures" are calculated, corresponding to gating by dilation, gating by tilt, and a combination of both dilation and tilt. Both advantages and disadvantages of the approach are discussed.