Low-conductance K channels in apical membrane of rat cortical collecting tubule

G. Frindt and L. G. Palmer Department of Physiology, Cornell University Medical College, New York, New York 10021. Low-conductance, K-selective channels were identified in the apical membrane of the rat cortical collecting tubule (CCT) by use of the patch-clamp technique. Isolated, split tubules were bathed in K gluconate medium to depolarize the cell while keeping the intracellular K concentration high. With the patch-clamp pipette containing predominantly either Na+ or Li+ but no K, outward currents were observed through channels that had a single-channel conductance (g) of 9 pS and a probability of being open (Po) of greater than 0.9, independent of the voltage (+/- 40 mV) applied to the pipette (Vp). Similarly, only outward currents were observed when the patch was excised into high-K solution, implying a high selectivity of the channel for K+. When 1 mM BaCl2 was added to the pipette, Po decreased to 0.36 at Vp = 0; however, g was not changed but the channels flickered rapidly between open and blocked states; Po decreased as Vp was made positive, and increased as Vp was made negative. With the pipette filled with KCl + 1 mM Ba, the channels conducted K+ in both directions. The inward currents (at positive Vp were larger than the outward currents (at negative Vp) and g near Vp = 0 increased to 25 pS. When the pipette was filled with RbCl + 1 mM Ba the inward and outward currents were similar in magnitude, suggesting that the channels can conduct Rb, although not as well as K. With the tubules bathed in NaCl Ringer solution and the pipette containing KCl, inward currents were observed that could be attributed to the same pathway for K.