Properties of single potassium channels modulated by glucose in rat pancreatic beta‐cells.

Abstract

The patch clamp method has been used to examine the effect of glucose on single K+ channel currents recorded from cell-attached patches on dissociated rat pancreatic .beta.-cells. Patch pipettes contained a 140 mM-K+ solution. In glucose-free solution three types of K+ channels were observed. Two of these, having conductances of around 50 pS (G-channel) and 20 pS when the external K+ concentration, [K+]o, was 140 mM, were active at the resting potential of the cell. The G-channel was observed in more patches and showed higher activity; it therefore appears to contribute the major fraction of the resting K+ permeability of the .beta.-cell. At membrane potentials positive to about +20 mV a third type of K+ channel, having a mean conductance of 20 pS, was activated. The open probability of this channel was strongly voltage dependent and increased with depolarization. The reversal potential of the G-channel current was shifted 59 mV by a 10-fold change in external K+ (Na+ substitution) indicating the channel is highly K+ selective. The single-channel conductance varied with [K+]o as predicted from the Goldman-Hodgkin-Katz equation; at physiological [K+]o (5 mM-K+) an inward conductance of around 10 pS is predicted. The amplitude of the single-channel current showed a tendency to saturate with increasing [K+]o. Single G-channel currents show burst kinetics indicating at least two closed states. The open and closed (gap) times within the bursts were distributed exponentially with time constants of 2.5 ms (.tau.o) and 0.5 ms (.tau.c1) respectively at the resting potential of the cell. There was little change in .tau.c1 over the voltage range-40 to 60 mV (pipette potential) but .tau.o increased slightly with membrane depolarization. The addition of glucose to the bath solution produced a reversible, dose-dependent decrease in G-channel activity. This decrease results principally from a reduction in the frequency and duration of the bursts of openings with increasing glucose. In addition, the mean open time decreases. The short gaps during the bursts were little affected by glucose. At glucose concentrations of 10mM and above the decrease in G-channel activity is accompanied by an increase in the input resistance of the cell and by the initiation of action potentials. It is concluded that glucose metabolism results in a reduction of G-channel open probability and thereby produces depolarization of the .beta.-cell.