Abstract
Dopamine (10 to 50 microM) modulates in two different ways the duration of the Ca2+-dependent action potential recorded in the cell body of identified neurons of the snail Helix aspersa. In some neurons (cells E13 and F1) dopamine increases the amplitude of their Ca2+-dependent spike plateau by decreasing the S-current (Klein, M., J.S. Camardo, and E. R. Kandel (1982) Proc. Natl. Acad. Sci. U.S.A. 79: 5713–5717), a K+ current controlled by cyclic AMP. In another neuron (cell D2), dopamine decreases the Ca2+-dependent plateau of the somatic action potential by evoking a decrease in Ca2+-current resulting from a decrease in Ca2+ conductance. Both modulatory effects could be observed in the same single neuron in which dopamine induces decreases of both the Ca2+ conductance and cyclic AMP-dependent K+ conductance. Nevertheless, in these cells (such as cell F5) dopamine only evokes a decrease of the amplitude of the Ca2+ spike plateau. Since the modulation of the duration of the Ca2+ action potential recorded in the neuronal soma has been shown to constitute a good model of events taking place at synaptic endings, it is suggested that these modulatory mechanisms evoked by dopamine may be involved in processes of presynaptic facilitation and inhibition.