Structural and dynamical heterogeneity of water trapped inside Na+-pumping KR2 rhodopsin in the dark state

Abstract

AbstractPhotoisomerisation in retinal leads to a channel opening in the rhodopsins that triggers translocation or pumping of an ion/proton. Crystal structures of rhodopsins contain several structurally conserved water molecules. It has been suggested that water plays an active role in facilitating the ion pumping/translocation process by acting as a lubricant in these systems. In this work, we systematically investigate the localisation, structure, dynamics and energetics of the water molecules along the channel for the resting/dark state of KR2 rhodopsin. Employing several microseconds long atomistic molecular dynamics (MD) simulation of this trans-membrane protein system, we demonstrate the presence of five distinct water containing pockets/cavities separated by gateways controlled by the protein side-chains. There exists a strong hydrogen bonded network involving these buried water molecules and functionally important key residues. We present evidence of significant structural and dynamical heterogeneity in the water molecules present in these cavities with very rare exchange between them. The exchange time-scale of these buried water with bulk has an extremely wide range from tens of nanoseconds to > 1.5μs! The translational and rotational dynamics of buried water are found to be strongly dependent on the protein cavity size and local interactions with classic signature of trapped diffusion and rotational anisotropy.