Intracellular protons inhibit inward rectifier K+ channel of guinea-pig ventricular cell membrane.

The effect of intracellular protons (Hi+) on the inward rectifier K+ channel of the guinea-pig ventricular cell membrane was examined, using the patch-clamp technique. The inward single-channel current was recorded in "inside-out" and "outside-out" patch configurations, while the pH of the solution perfusing the intra- and extracellular side, respectively, was varied. Low intracellular pH (pHi), but not low extracellular pH, inhibited the channel. Low pHi reduced the unit amplitude, which was about 20% smaller at pHi 6.0 than that at pHi 7.4 at every voltage tested. The slope conductance decreased from 41.7 pS at pHi 7.4 to 35.1 pS at pHi 6.0. Low pHi also reduced the channel activity without apparent voltage dependence. The concentration/response curve indicated the half-maximum inhibition at pHi 6.11 and a Hill coefficient of 2.52. Lowering the pHi from 7.4 to 6.0 did not affect the distributions of the open times and the closed times below 50 ms, while the time constant of the histogram constructed from closings longer than 50 ms was approximately doubled. These results indicate that the inward rectifier K+ channel in ventricular myocytes is inhibited by H+ from the intracellular side. This might contribute to the depolarization of the resting membrane potential induced by intracellular acidosis during myocardial ischaemia.