What Really Prevents Proton Transport through Aquaporin? Charge Self-Energy versus Proton Wire Proposals

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What Really Prevents Proton Transport through Aquaporin? Charge Self-Energy versus Proton Wire Proposals

Anton Burykin and Arieh Warshel

Department of Chemistry, University of Southern California, Los Angeles, California

Correspondence: Address reprint requests to Arieh Warshel, Tel.: 213-740-4114; Fax: 213-740-2701; E-mail: warshel{at}usc.edu.

The nature of the control of water/proton selectivity in biologicalchannels is a problem of a fundamental importance. Most studiesof this issue have proposed that an interference with the orientationalrequirements of the so-called proton wire is the source of selectivity.The elucidation of the structures of aquaporins, which haveevolved to prevent proton transfer (PT), provided a clear benchmarkfor exploring the selectivity problem. Previous simulationsof this system have not examined, however, the actual issueof PT, but only considered the much simpler task of the transferof water molecules. Here we take aquaporin as a benchmark andquantify the origin of the water/proton selectivity in thisand related systems. This is done by evaluating in a consistentway the free energy profile for transferring a proton alongthe channel and relating this profile to the relevant PT rateconstants. It is found that the water/proton selectivity iscontrolled by the change in solvation free energy upon movingthe charged proton from water to the channel. The reason forthe focus on the elegant concept of the proton wire and therelated Grotthuss-type mechanism is also considered. It is concludedthat these mechanisms are clearly important in cases with flatfree energy surfaces (e.g., in bulk water, in gas phase waterchains, and in infinitely long channels). However, in casesof biological channels, the actual PT mechanism is much lessimportant than the energetics of transferring the proton chargefrom water to different regions in the channels.

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