Statistical Mechanical Equilibrium Theory of Selective Ion Channels

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Statistical Mechanical Equilibrium Theory of Selective Ion Channels

Benoît Roux

Groupe de Recherche en Transport Membranaire, Départements de physique et de chimie, Université de Montréal, C.P. 6128, Montréal H3C 3J7, Canada

A rigorous statistical mechanical formulation of the equilibrium properties of selective ion channels is developed, incorporatingthe influence of the membrane potential, multiple occupancy, andsaturation effects. The theory provides a framework for discussingfamiliar quantities and concepts in the context of detailed microscopicmodels. Statistical mechanical expressions for the free energyprofile along the channel axis, the cross-sectional area of thepore, and probability of occupancy are given and discussed. Inparticular, the influence of the membrane voltage, the significanceof the electric distance, and traditional assumptions concerningthe linearity of the membrane electric field along the channelaxis are examined. Important findings are: 1) the equilibriumprobabilities of occupancy of multiply occupied channels havethe familiar algebraic form of saturation properties which isobtained from kinetic models with discrete states of denumerableion occupancy (although this does not prove the existence of specificbinding sites; 2) the total free energy profile of an ion alongthe channel axis can be separated into an intrinsic ion-pore freeenergy potential of mean force, independent of the transmembranepotential, and other contributions that arise from the interfacialpolarization; 3) the transmembrane potential calculated numericallyfor a detailed atomic configuration of the gramicidin A channelembedded in a bilayer membrane with explicit lipid molecules isshown to be closely linear over a distance of 25 Å along the channelaxis. Therefore, the present analysis provides some support forthe constant membrane potential field approximation, a conceptthat has played a central role in the interpretation of flux databased on traditional models of ion permeation. It is hoped thatthis formulation will provide a sound physical basis for developingnonequilibrium theories of ion transport in selective biologicalchannels.

Biophys J, July 1999, p. 139-153, Vol. 77, No. 1
© 1999 by the Biophysical Society 0006-3495/99/07/139/15 $2.00

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