Visualization of the mechanosensitive ion channel MscS under membrane tension

Mechanosensitive channels sense mechanical forces in cell membranes and underlie many biological sensing processes(1-3). However, how exactly they sense mechanical force remains under investigation(4). The bacterial mechanosensitive channel of small conductance, MscS, is one of the most extensively studied mechanosensitive channels(4-8), but how it is regulated by membrane tension remains unclear, even though the structures are known for its open and closed states(9-11). Here we used cryo-electron microscopy to determine the structure of MscS in different membrane environments, including one that mimics a membrane under tension. We present the structures of MscS in the subconducting and desensitized states, and demonstrate that the conformation of MscS in a lipid bilayer in the open state is dynamic. Several associated lipids have distinct roles in MscS mechanosensation. Pore lipids are necessary to prevent ion conduction in the closed state. Gatekeeper lipids stabilize the closed conformation and dissociate with membrane tension, allowing the channel to open. Pocket lipids in a solvent-exposed pocket between subunits are pulled out under sustained tension, allowing the channel to transition to the subconducting state and then to the desensitized state. Our results provide a mechanistic underpinning and expand on the 'force-from-lipids' model for MscS mechanosensation(4,11). The authors report the structural characterization of the mechanically activated channel MscS in different membrane environments and show how the mechanosensation of MscS can be visualized.

Automated summary

Mechanosensitive channels, such as MscS, play a crucial role in sensing mechanical forces in cell membranes. The structure of MscS in different membrane environments is dynamic and regulated by various associated lipids, including pore lipids, gatekeeper lipids, and pocket lipids. These lipids have distinct roles in MscS mechanosensation by preventing ion conduction in the closed state, stabilizing the closed conformation, and allowing the channel to transition to different states under sustained tension.