Ion movement through gramicidin A channels. Studies on the diffusion-controlled association step.

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Ion movement through gramicidin A channels. Studies on the diffusion-controlled association step.

O S Andersen

ABSTRACT

The permeability characteristics of gramicidin A channels aregenerally considered to reflect accurately the intrinsic propertiesof the channels themselves; i.e., the aqueous convergence regionsare assumed to be negligible barriers for ion movement throughthe channels. The validity of this assumption has been examinedby an analysis of gramicidin A single-channel current-voltagecharacteristics up to very high potentials (500 mV). At lowpermeant ion concentrations the currents approach a voltage-independentlimiting value, whose magnitude is proportional to the permeantion concentration. The magnitude of this current is decreasedby experimental maneuvers that decrease the aqueous diffusioncoefficient of the ions. It is concluded that the magnitudeof this limiting current is determined by the diffusive ionmovement through the aqueous convergence regions up to the channelentrance. It is further shown that the small-signal (ohmic)permeability properties also reflect the existence of the aqueousdiffusion limitation. These results have considerable consequencesfor the construction of kinetic models for ion movement throughgramicidin A channels. It is shown that the simple two-site-three-barriermodel commonly used to interpret gramicidin A permeability datamay lead to erroneous conclusions, as biionic potentials willbe concentration dependent even when the channel is occupiedby at most one ion. The aqueous diffusion limitation must beconsidered explicitly in the analysis of gramicidin A permeabilitycharacteristics. Some implications for understanding the propertiesof ion-conducting channels in biological membranes will be considered.

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