Neuroethology of melibe leonina swimming behavior

Abstract

The nudibranchW Melibe leonina swims by rhythmically flexing its body from side to side at a frequency of 1 cycle every 2-5 sec. Melibe swim spontaneously, when they are dislodged from the substrate, or when they come in contact with predatory seastars, such as Pycnopodia helianthoides. Intraccllular recordings obtained from semi-intact swimming Melibe reveal a population of -15 swim motoneurons (SMNs) in each pedal ganglion. In general, SMNs in one pedal ganglion fire out-of-phase with SMNs in the opposite pedal ganglion, resulting in rhythmic side-to-side bending movements. In isolated brains, recordings from SMNs yield similar results, indicating the existence of a swim central pattern generator (CPG). There is no evidence for synaptic interactions between SMNs and either inhibiting . or exciting SMNs has no impact on the swim pattern. The SMNs are driven by a CPG consisting of 4 interncurons; 2 in the cerebropleural ganglia and 1 in each pedal ganglion. Appropriate bursting activity in the swim interneurons is necessary for swimming to occur. Either hyperpolarization or depolarization of any of the 4 CPG interneurons disrupts the normal swim pattern. Swimming behavior, and the fictive swim motor program expressed by the isolated brain, are inhibited by light and nitric oxide donors. NADPH-diaphorase staining and nitric oxide synthase (NOS) immunocytochemistry of Melibe brains suggests the source of nitric oxide might be a pair of bilaterally symmetrical cells located in the cerebropleural ganglia.