Basolateral pH-Sensitive K⁺ Channels Mediate Membrane Potential of Proximal Tubule Cells in Bullfrog Kidney

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The present study investigated basolateral K⁺ channels and their pH-sensitivity in isolated bullfrog proximal tubule cells by using the patch-clamp technique, and compared channel activity with the basolateral membrane potential (E_M) and intracellular pH (pH_i) monitored by using double-barreled H⁺-selective microelectrodes in perfused bullfrog proximal tubules. In the patch-clamp experiments, K⁺ channels with inward slope conductance of about 50 pS were observed in the basolateral membrane of isolated proximal tubule cells in cell-attached patches. Raising pH of the bath with HCO₃^--free HEPES Ringer solutions from 7.7 (control) to 8.2 in the presence of an H⁺ ionophore, FCCP (2 μM), enhanced channel activity to 126.4% of controls; lowering bath pH to 7.2 and to 6.7 reduced channel activity to 26.4 and to 1.7% of controls. Microelectrode experiments in bullfrog proximal tubules perfused with HCO₃^--free HEPES Ringer solutions showed that E_M and pH_i in control conditions of peritubular pH 7.7 without FCCP were −52.6mV and 7.45. Raising peritubular pH to 8.2 in the presence of FCCP (2μM) increased E_M and pH_i to −61.8mV and 7.73; lowering it to 7.2 and to 6.7 decreased E_M and pH_i to −28.6 mV and 7.25 and to −10.6 mV and 6.95. These results suggest that changes in E_M in response to cellular alkalinization or acidification made by HCO₃^--free HEPES solutions are produced primarily by changes in activity of the pH-sensitive K⁺ channels.