Thermodynamic stability of water molecules in the bacteriorhodopsin proton channel: a molecular dynamics free energy perturbation study.

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Thermodynamic stability of water molecules in the bacteriorhodopsin proton channel: a molecular dynamics free energy perturbation study.

B Roux, M Nina, R Pomès and J C Smith

Départements de physique et chimie, Université de Montréal, Québec, Canada. rouxb@ere.umontreal.ca

ABSTRACT

The proton transfer activity of the light-driven proton pump,bacteriorhodopsin (bR) in the photochemical cycle might implyinternal water molecules. The free energy of inserting watermolecules in specific sites along the bR transmembrane channelhas been calculated using molecular dynamics simulations basedon a microscopic model. The existence of internal hydrationis related to the free energy change on transfer of a watermolecule from bulk solvent into a specific binding site. Thermodynamicintegration and perturbation methods were used to calculatefree energies of hydration for each hydrated model from moleculardynamics simulations of the creation of water molecules intospecific protein-binding sites. A rigorous statistical mechanicalformulation allowing the calculation of the free energy of transferof water molecules from the bulk to a protein cavity is usedto estimate the probabilities of occupancy in the putative bRproton channel. The channel contains a region lined primarilyby nonpolar side-chains. Nevertheless, the results indicatethat the transfer of four water molecules from bulk water tothis apparently hydrophobic region is thermodynamically permitted.The column forms a continuous hydrogen-bonded chain over 12A between a proton donor, Asp 96, and the retinal Schiff baseacceptor. The presence of two water molecules in direct hydrogen-bondingassociation with the Schiff base is found to be strongly favorablethermodynamically. The implications of these results for themechanism of proton transfer in bR are discussed.

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