Quantification of K+ secretion through apical low-conductance  K channels in the CCD

doi:10.1152/ajprenal.00471.2004

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Quantification of K⁺ secretion through apical low-conductance K channels in the CCD

Daniel A. Gray¹, Gustavo Frindt¹, and Lawrence G. Palmer¹^*

¹ Department of Physiology and Biophysics, Weill Medical College of Cornell University, New York, NY, USA

^* To whom correspondence should be addressed. E-mail: lgpalm{at}med.cornell.edu.

Outward and inward currents through single small-conductanceK⁺ (SK) channels were measured in cell-attached patches of theapical membrane of principal cells of the rat CCD. Currentsshowed mild inward rectification with high [K⁺] in the pipette(K⁺_p) which decreased as K⁺_p was lowered. Inward conductanceshad a hyperbolic dependence on K⁺_p with half-maximal conductanceat ~20 mM. Outward conductances, measured near the reversalpotential, also increased with K_p⁺ from 15 pS (K⁺_p = 0) to50 pS (K⁺_p = 134 mM). SK channel density was measured as thenumber of conducting channels per patch in cell-attached patches.As reported previously, channel density increased when animalswere on a high-K diet for 7 days. Addition of 8-cpt-cAMP tothe bath at least 5 minutes prior to making a seal increasedSK channel density to an even greater extent, although thisincrease was not additive with the effect of a high-K diet.In contrast, increases in Na channel activity, assessed as thewhole-cell amiloride-sensitive current, due to K-loading and8-cpt-cAMP treatment were additive. Single-channel conductancesand channel densities were used as inputs to a simple mathematicalmodel of the CCD to predict rates of transepithelial Na⁺ andK⁺ transport as a function of apical Na⁺ permeability and K⁺ conductance,basolateral pump rates and K⁺ conductance, and the paracellularconductance. With measured values for these parameters, themodel predicted transport rates which were in good agreementwith values measured in isolated perfused tubules. The numberand properties of SK channels account for K⁺ transport by theCCD under all physiological conditions tested.

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