Abstract
Rat neocortical neurons in cell culture were studied with the patch-clamp technique in order to determine the properties of a large-conductance K + channel in excised inside-out patches. In the presence of a physiological ionic gradient for K + across the patch membrane ([K +] i = 120 mM; [K +] o = 3 mM), outward channel activity was detected when the patches were brought to membrane potential values less negative than −30 mV. Depolarization of the membrane increased the magnitude of the current. The I– V relationship displayed rectification at negative membrane potentials. When the I– V curve was differentiated the slope conductance calculated at 0 mV membrane potential was 120 pS. The single-channel permeability was 5.2 × 10 −13 cm/s and the current flow through the open K + channel could be modeled using the constant-field electrodiffusion theory. K + channel opening was not observed following removal of Ca 2+ from the intracellular surface of the membrane. Our experiments indicate that, as in other cell types, rat neocortical neurons in culture exhibit a large-conductance K + channel which is activated by Ca 2+ acting on the cytoplasmic surface.
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