Effect of Ionization State on Voltage-Sensor Structure in Resting State of the Hv1 Channel.

Abstract

Voltage-gated proton-selective channels (Hv1) mediate proton extrusion during intracellular acidification. Hv1 is gated by the proton electrochemical gradient. Intracellular ionizable residues in Hv1 have been proposed to serve as proton-binding sites for pH-dependent gating, but detailed descriptions remain unclear. Here, molecular dynamics (MD) simulations were performed to investigate the effect of ionization states of charged residues on the X-ray structure of Hv1. Modification of the protonation state of acidic residues affected the resting conformation of Hv1 by disrupting salt bridges between S4 and the other segments. Upon protonation, conformational changes enabled the displacement of the S4 arginines toward the extracellular side and increased the mobility of hydrophobic residues at the gate. The aqueous crevice was considerably wider with increased hydration in the pore. Solvation free energies of the pore residues were low at the extra- and intracellular entrances, whereas the narrowest region exhibited the energy barrier for water translocation. Our MD data showed that water molecules in the upper and lower pore oriented differently. In neutral pH, the pore water oriented its dipole pointing away from the voltage-sensing domain center, whereas the opposite direction of the water dipole was observed in acidic pH.