Relationship between developmental synaptic modulation and conditioning-induced synaptic change in Lymnaea

From likes to dislikes: conditioned taste aversion in the great pond snail (Lymnaea stagnalis)

The neural circuitry comprising the central pattern generator (CPG) that drives feeding behavior in the great pond snail (Lymnaea stagnalis (L., 1758)) has been worked out. Because the feeding behavior undergoes associative learning and long-term memory (LTM) formation, it provides an excellent opportunity to study the causal neuronal mechanisms of these two processes. In this review, we explore some of the possible causal neuronal mechanisms of associative learning of conditioned taste aversion (CTA) and its subsequent consolidation processes into LTM in L. stagnalis. In the CTA training procedure, a sucrose solution, which evokes a feeding response, is used as the conditioned stimulus (CS) and a potassium chloride solution, which causes a withdrawal response, is used as the unconditioned stimulus (US). The pairing of the CS–US alters both the feeding response of the snail and the function of a pair of higher order interneurons in the cerebral ganglia. Following the acquisition of CTA, the polysynaptic inhibitory synaptic input from the higher order interneurons onto the feeding CPG neurons is enhanced, resulting in suppression of the feeding response. These changes in synaptic efficacy are thought to constitute a “memory trace” for CTA in L. stagnalis.

Repetitive noxious stimulus altered the shadow-induced withdrawal behavior in Lymnaea

Stress alters adaptive behaviors including vigilance behaviors. In Lymnaea one of these vigilance behavior is a heightened withdrawal response to a shadow. The shadow withdrawal response (SWR) is mediated by dermal photoreceptors located primarily on the foot, mantle cavity, and skin around the pneumostome area. Here we asked whether we could obtain a neural correlate of the heightened SWR and other essential behaviors following traumatic stress. We measured the electrophysiological properties of 'Right Pedal Dorsal 11 (RPeD11)', the interneuron that plays a major role in mediating the whole-body withdrawal response. In traumatized snails 24 hours after the trauma they responded not only to a shadow stimulus with an augmented withdrawal response, but suppressed in locomotive, feeding and respiratory behavior. Their behavioral change lasted at least one week. Accompanying the behavioral change in these 'traumatized' preparations there are a number of significant changes in the neuronal properties of RPeD11 compared to naïve preparations. For example, RPeD11 is significantly more depolarized (∼10 mV) has significantly larger input resistance, and the duration of the response elicited by the shadow persists longer. All these changes result in an increased RPeD11 response and seem to raise their defensive alert level.