Proton Transport Behavior Through the Influenza A M2 Channel: Insights from Molecular Simulation

doi:10.1529/biophysj.107.105742

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Biophys. J. BioFAST: First Published August 10, 2007. doi:10.1529/biophysj.107.105742
© 2007 by the Biophysical Society.

A more recent version of this article appeared on November 15, 2007.

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CHANNELS, RECEPTORS, AND ELECTRICAL SIGNALING

Proton Transport Behavior Through the Influenza A M2 Channel: Insights from Molecular Simulation

Hanning Chen ¹, Yujie Wu ¹ and Gregory A. Voth ¹^*

¹ University of Utah

^* To whom correspondence should be addressed. E-mail: voth{at}chem.utah.edu.

Submitted on February 1, 2007
Revised on March 29, 2007
Accepted on 25 July 2007

Abstract
The structural properties of the influenza A virus M2 trans-membranechannel in dimyristoylphosphatidylcholine (DMPC) bilayer foreach of the four protonation states of the proton-gating His37tetrad, and their effects on proton transport for this low-pHactivated, highly proton-selective channel, are studied by classicalmolecular dynamics with the multistate empirical valence bond(MS-EVB) methodology. The excess proton permeation free energyprofile and maximum ion conductance calculated from the MS-EVBsimulation data combined with Poisson-Nernst-Planck (PNP) theoryindicates that the triply protonated His37 state is the mostlikely open state via a significant side chain conformationalchange of the His37 tetrad. This proposed open state of M2 hasa calculated proton permeation free energy barrier of 7 kcal/moland a maximum conductance of 53 pS, compared to the experimentalvalue of 6 pS. By contrast, the maximum conductance for Na⁺is calculated to be four orders of magnitude lower, in reasonableagreement with the experimentally observed proton selectivity.The pH value to activate the channel opening is estimated tobe 5.5 from dielectric continuum theory, which is also consistentwith experimental results. The present study further revealsthat the Ala29 residue region is the primary binding site forthe anti-flu drug amantadine (AMT), probably because that domainis relatively spacious and hydrophobic. The presence of AMTis calculated to reduce the proton conductance by 99.8% dueto a significant dehydration penalty of the excess proton inthe vicinity of the channel-bound AMT.

Key Words: AMT inhibition, Ion permeation, M2 channel, Proton conductance, Proton selectivity, Proton transport

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