Abstract
The selectivity filter in potassium channels, a main component of the ion permeation pathway, configures a stack of binding sites (sites S1-S4) to which K+ and other cations may bind. Specific ion binding to such sites induces changes in the filter conformation, which play a key role in defining both selectivity and permeation. Here, using the potassium channel KcsA as a model, we contribute new evidence to reinforce this assertion. First, ion binding to KcsA blocked by tetrabutylammonium at the most cytoplasmic site in the selectivity filter (S4) suggests that such a site, when in the nonconductive filter conformation, has a higher affinity for cation binding than the most extracellular S1 site. This filter asymmetry, along with differences in intracellular and extracellular concentrations of K+versus Na+ under physiological conditions, should strengthen selection of the permeant K+ by the channel. Second, we used different K+ concentrations to shift the equilibrium between nonconductive and conductive states of the selectivity filter in which to test competitive binding of Na+ These experiments disclosed a marked decrease in the affinity of Na+ to bind the channel when the conformational equilibrium shifts toward the conductive state. This finding suggested that in addition to the selective binding of K+ and other permeant species over Na+, there is a selective exclusion of nonpermeant species from binding the channel filter, once it reaches a fully conductive conformation. We conclude that selective binding and selective exclusion of permeant and nonpermeant cations, respectively, are important determinants of ion channel selectivity.
Highlights
The selectivity filter in potassium channels, a main component of the ion permeation pathway, configures a stack of binding sites to which K؉ and other cations may bind
Similar to the conditions used in crystallography, KcsA in our experimental system has both the extra- and intracellular ends of the selectivity filter, exposed to the same media and not subjected to any electrochemical gradient
The pore could presumably be asymmetrical, and in an attempt to let pore asymmetry be manifested in our ion binding experiments, we have used tetrabutylammonium (TBAϩ),2 a well known blocker of potassium channels that binds to the intracellular end of the pore [32,33,34] in a practically irreversible manner
Summary
We previously reported ion binding assays based on monitoring the intrinsic fluorescence of KcsA [25]. Studies using tryptophan to phenylalanine mutants of KcsA assigned the cation-induced fluorescence changes to the Trp and Trp residues [26], both located at the short helix, with their indole side chains practically in contact with the polypeptide backbone of the selectivity filter [2, 6, 27]. The second set of sites (i) results from the contribution of all S1–S4 crystallographic sites; (ii) is available only to permeant cations when the filter is in the conductive conformation; and (iii) shows low affinity (millimolar KD values), favoring cation dissociation and permeation. We find a selective exclusion of nonpermeant species from binding to the channel once the selectivity filter changes its conformation to a conductive state
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