Abstract
Sensitization of the gill- and siphon-withdrawal reflex in Aplysia is considered a simple form of learning. Previous work has provided physiological and pharmacological evidence that cAMP-dependent protein phosphorylation within identified sensory neurons of the abdominal ganglion underlies the short-term form of this behavioral modification. Our main goal in this paper is to determine the subcellular distribution of cAMP and to measure the amounts and properties of the 2 types of subunits (regulatory and catalytic) that constitute the cAMP- dependent protein kinase. Do these biochemical parameters differ in sensory cells from those in other parts of nervous tissue? We found that the increased cAMP synthesized under conditions of sensitization is distributed in 3 compartments in the neuron: most of it is free in the cytoplasm; the remainder is bound either to cytoplasmic or to particulate proteins, which are believed to be regulatory subunits of the cAMP-dependent protein kinase. Binding of cAMP within the neurons is a measure of activation of the kinase. At rest, 17% of the binding sites in sensory cells were occupied. After brief electrical stimulation of the connective, which released endogenous transmitter, occupancy increased to 34%. This treatment increased the amount of cAMP bound to the various binding proteins differentially. The biochemical characteristics of cAMP binding were found to be the same in sensory neurons as in the rest of the nervous system but different from those in muscle. Thus, memory and learning are likely to be mediated by enzymes that are shared by other nerve cells. We found that sensory neurons have greater cAMP-dependent protein kinase activity than other neurons, however, and as a result may be more sensitive to small increases of cAMP.