Synaptic facilitation at connections of Hermissenda type B photoreceptors

The enhancement of excitability in type B photoreceptors is an important neural mechanism underlying classically conditioned suppression of phototaxis in the marine mollusk Hermissenda crassicornis. However, the possibility that type B photoreceptors also exhibit synaptic plasticity has not previously been explored. We now report that connections of type B photoreceptors onto type A photoreceptors exhibit synaptic facilitation, and that this facilitation involves the same first messenger (5-HT) and second messenger (protein kinase C) previously implicated in the learning- produced excitability changes. In brief, we found that application of 5- HT dramatically facilitates synaptic potentials evoked by type B cells in type A cell cells, and that this facilitation is blocked by preincubation with staurosporine, a protein kinase inhibitor. Furthermore, activation of protein kinase C also induces synaptic facilitation, whereas activation of the cAMP-dependent protein kinase has no effect. Changes in synaptic strength produced by these manipulations are paralleled by changes in type B cell input resistance (a simple index of cellular excitability), whereas type A cell input resistance is unaffected. These findings indicate a previously unrecognized form of neuronal plasticity in Hermissenda that may contribute importantly to the learned changes in behavior, and thereby highlight general principles of learning-related neuronal plasticity shared by different preparations and species.

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