2 COMPONENTS OF CA-DEPENDENT POTASSIUM CURRENT IN IDENTIFIED NEURONS OF APLYSIA-CALIFORNICA

Outward tail currents measured in Aplysia neurones after termination of depolarizing voltage-clamp pulses consist of rapidly decaying voltage-dependent K currents and slow tail currents of much slower time course. The rapidly decaying voltage-dependent tail currents were blocked with aminopyridines, and measurements of the slow tail currents were made following decay of any residual rapid tail currents. The slow tail current exhibited 2 components of differing sensitivity to externally applied tetraethylammonium (TEA) ions. In some neurones of the abdominal ganglion (L-2, L-4), virtually all of the slow tail current was resistant to blockage by TEA, while in other (L-3, L-6) 80% or more of the slow tail current was blocked by low TEA concentrations (KD < 1 mM), the remaining slow tail current being resistant to TEA. This TEA-resistant slow tail current was identified as a K current because it reversed near the K equilibrium potential (EK), the reversal potential was shifted by changes in the external K concentration, and it could be blocked by injection of Cs+. It was abolished by replacement of external Ca2+ by Co2+ or Ba2+, by addition of Cd2+, or by injection of EGTA, and thus determined to be a Ca-dependent current. Intracellular injection of TEA or external application of aminopyridine or apamine had little or no effect on the TEA-resistant slow tail current. Quinidine reduced the TEA-sensitive, but not the TEA-resistant current. Both the TEA-sensitive and the TEA-resistant components of the slow tail current exhibited similar time courses of decay. Thus, neurons of Aplysia appear to contain different proportions of 2 classes of Ca-dependent K channels that differ in their sensitivity to certain channel blocking agents.