Sensitizing stimuli cause translocation of protein kinase C in Aplysia sensory neurons.

Abstract

The defensive tail-withdrawal reflex of Aplysia califonica, mediated by identified sensory neurons in pleural ganglia that form synapses on motor cells in pedal ganglia, can be sensitized by stimulating the animal with electric shock. The neurophysiological basis of this simple form of learning is thought to be the increased release of transmitter by the sensory neurons. Earlier work has focused on cAMP-dependent protein phosphorylation as the cause of the presynaptic facilitation underlying short-term sensitization. Using physiological concentrations of Mg2+ during fractionation, we now find that, independent from cAMP, protein kinase C is translocated in sensory neurons by sensitizing stimuli. Translocation occurred after behavioral training of the animal and after application to isolated ganglia of serotonin or phorbol esters. Taken together with the neurophysiological evidence presented in the accompanying paper that phorbol esters can produce the facilitation, these biochemical results suggest that protein kinase C plays a role in producing the presynaptic facilitation that underlies short-term sensitization and dishabituation of defensive reflexes.