Voltage-clamp analysis of a self-inhibitory synaptic potential in the buccal ganglia of Aplysia.

1. In cholinergic neurones BL4, BL5, BR4, and BR5 of Aplysia buccal ganglia, each action potential is followed, in the same cell, by a curare- and high-Mg-sensitive hyperpolarizing after-potential which is enhanced by Ca. 2. In voltage-clamped neurons, substracting currents recorded in curare from currents recorded in sea water reveals that this potential is due to curare-sensitive currents which rise to a peak, then decay exponentially with an apparently voltage-independent time constant of 43 msec. Currents are produced by a voltage-independent, Ca-enhanced, conductance change with a 0-26 mumho peak and a -64 mV reversal potential. The curare-sensitive conductance is also sensitive to high Mg. 3. Both after-potential and curare- or Mg-sensitive current follow each action potential without failures, even in threshold-raising 80 mM-Ca-144-mM-Mg solutions. 4. Both after-potential and current decrease with repetitive firing or short inter-spike interval, possibly due to receptor desensitization. 5. The Mg- and curare-sensitive conductance is also blocked by 1 mM-ACh. 6. The data are consistent with the hypothesis that the hyperpolarization following action potentials in each of these four neurones is produced by a self-inhibitory synaptic mechanism.