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The resting conductance of cultured beta-cells from murine pancreases was investigated using the whole-cell, cell-attached and isolated patch modes of the patch-clamp technique. Whole-cell experiments revealed a high input resistance of the cells (greater than 20 G omega per cell or greater than 100 k omega X cm2), if the medium dialysing the cell interior contained 3 mM ATP. The absence of ATP evoked a large additional K+ conductance. In cell-attached patches single K+-channels were observed in the absence of glucose. Addition of glucose (20 mM) to the bath suppressed the channel activity and initiated action potentials. Similar single-channel currents were recorded from isolated patches. In this case the channels were reversibly blocked by adding ATP (3 mM) to the solution at the intracellular side of the membrane. The conductances (51 pS and 56 pS for [K+]0 = 145 mM, T = 21 degrees C) and kinetics (at -70 mV: tau open = 2.2 ms and 1.8 ms, tau closed = 0.38 ms and 0.33 ms) of the glucose- and ATP-dependent channels were found to be very similar. It is concluded that both channels are identical. The result suggests that glucose could depolarize the beta-cell by increasing the cytoplasmic concentration of ATP.


Journal article


Pflugers Arch

Publication Date





305 - 309


Adenosine Triphosphate, Animals, Body Fluids, Electric Conductivity, Glucose, Intracellular Fluid, Ion Channels, Islets of Langerhans, Mice, Mice, Inbred Strains, Potassium