Abstract
One of the goals of mechanosensitive channel (MSC) studies is to understand the underlying molecular and biophysical mechanisms of the mechano-gating process from force sensing to gate opening. We focus on the latter process and investigate the role of water in the bacterial MSC MscL, which is activated by membrane tension. We analyze the interplay between water and the gate-constituting amino acids, Leu19–Gly26, through molecular dynamics simulations. To highlight the role of water, specifically hydration of the gate, in MscL gating, we restrain lateral movements of the water molecules along the water–vapor interfaces at the top and bottom of the vapor bubble, plugging the closed gate. The gating behaviors in this model and the normal MscL model, in which water movements are unrestrained, are compared. In the normal model, increased membrane tension breaks the hydrogen bond between Leu19 and Val 23 of the inner helix, exposing the backbone carbonyl oxygen of Leu19 to the water-accessible lumen side of the gate. Associated with this activity, water comes to access the vapor region and stably interacts with the carbonyl oxygen to induce a dewetting to wetting transition that facilitates gate expansion toward channel opening. By contrast, in the water-restrained model, carbonyl oxygen is also exposed, but no further conformational changes occur at the gate. This suggests that gate opening relies on a conformational change initiated by wetting. The penetrated water weakens the hydrophobic interaction between neighboring transmembrane inner helices called the “hydrophobic lock” by wedging into the space between their interacting portions.
Highlights
Mechanosensitive channels (MSCs) are major cell mechanosensors that support physiology and life processes in organisms (Levina et al 1999; Batiza et al 2002; Kung 2005)
Visualization of states, molecular modifications, and analysis were conducted in visual molecular dynamics (VMD) using the embedded Tcl script language (Humphrey et al 1996)
Our previous simulation study showed that the channel opening of mechanosensitive channel large conductance (MscL) upon membrane stretch is initiated by tilting down of the transmembrane inner and outer helices (TM1 and TM2, respectively) toward the membrane plane followed by gate expansion (Sawada et al 2012)
Summary
Mechanosensitive channels (MSCs) are major cell mechanosensors that support physiology and life processes in organisms (Levina et al 1999; Batiza et al 2002; Kung 2005). MSCs are implicated in physiological functions such as hearing and touch sensing in animals as well as osmoregulation in bacteria (Martinac et al 1987; Sukharev et al 1993; Booth and Louis 1999; Hamill and Martinac 2001). MSCs were first reported in the 1980s (Hamill 1983; Guharay and Sachs 1984); the crystal structures of MSCs have beeen resolved only for a couple of bacterial MSCs: mechanosensitive channel large conductance (MscL) (Chang et al 1998; Steinbacher et al 2007) and mechanosensitive channel small conductance (MscS) (Bass et al 2002).
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