The ability of ventral inhibitory motor neurons of the nematode Ascaris to generate slow depolarizing potentials was investigated using intracellular recording and current injection. In quiescent cells, regenerative depolarizations with peak amplitudes of approximately 20 mV and durations of several 100 ms were evoked in response to brief depolarizing current pulses. Repetitive slow potentials were produced in response to sustained depolarizing currents in a threshold-dependent manner. Repetitive slow potentials also occurred spontaneously, exhibiting cycle periods of about 700 ms. The ability of inhibitory motor neurons to generate slow potentials was blocked by addition of Co++, Cd++, or other Ca-channel blockers to the saline but not by TTX or substitution of Na+ with Tris. The amplitude and duration of slow potentials were increased in the presence of Ba++, Sr++, and TEA. Spontaneous slow potentials exhibited characteristics expected of intrinsically generated oscillations, including frequency modulation by injection of prolonged offset currents, phase resetting by brief current pulses, and suppression by strong hyperpolarization. Slow potentials appear to be generated in the ventral nerve cord processes and/or cell body of the motor neuron, and they produce rhythmic inhibitory postsynaptic potentials in ventral muscle cells. Slow potentials may therefore contribute to locomotory or other motor behaviors of the animal.