Action of extracellular pH on Na+ and K+ membrane currents in the giant axon of Loligo vulgaris.

Voltage-clamp currents and resting membrane potential of squid giant axons have been studied at extracellular pH varying between 4 and 10. The membrane currents, analyzed according to the Hodgkin-Huxley equations, showed that sodium permeability, PNa(E), and potassium conductance gK(E), curves were shifted toward positive voltages by different amounts and slightly depressed as the external pH was lowered. Under the same conditions, taum(E) and taun(E) were found to be enhanced and shifted to a larger extent in the same direction. The rate constants alpham and alphan were shifted substantially toward positive voltages, but betam and betan changed hardly at all. The shift of the alpham(E) curve was analyzed in terms of a fixed surface charge model; it indicates that unspecific negative groups with an approximate pKa of 4.5 are located in the vicinity of sodium active sites with an average charge separation of 8 A. A similar figure is obtained for the potassium system from the shift of the alphan(E) curve.