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A quantitative paradigm for water-assisted proton transport through proteins and other confined spaces

Chenghan Li, Gregory A. Voth

2021Proceedings of the National Academy of Sciences47 citationsDOIOpen Access PDF

Abstract

antiporter protein, ClC-ec1. Significant alterations in the conformations and thermodynamics of water wires are uncovered after introducing an excess proton into them. Large barriers in the proton translocation free-energy profiles are found when water wires are defined to be disconnected according to the new CV, even though the pertinent confined space is still reasonably well hydrated and-by the simple measure of the mere existence of a water structure-the proton transport would have been predicted to be facile via that oversimplified measure. In this paradigm, however, the simple presence of water is not sufficient for inferring proton translocation, since an excess proton itself is able to drive hydration, and additionally, the water molecules themselves must be adequately connected to facilitate any successful proton transport.

Topics & Concepts

ProtonProton transportChemical physicsChemistryComputational chemistryPhysicsQuantum mechanicsMolecular Junctions and NanostructuresElectrochemical Analysis and ApplicationsProtein Structure and Dynamics
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