V. N. Ierusalimsky

A Single Serotonergic Modulatory Cell Can Mediate Reinforcement in the Withdrawal Network of the Terrestrial Snail

A cluster of 40 serotonergic cells in the rostral part of pedal ganglia of the terrestrial snail Helix lucorum was shown previously to participate in the modulation of withdrawal behavior and to be necessary during the acquisition of aversive withdrawal conditioning in intact snails. Local extracellular stimulation of the serotonergic cells paired with a test stimulus elicited a pairing-specific increase (the difference between paired and explicitly unpaired sessions was significant, p <.01) of synaptic responses to test stimulation in the premotor interneurons involved in withdrawal. This result suggested participation of serotonergic cells in mediating the reinforcement in the withdrawal network. Intracellular stimulation of only one identified Pd4 cell from the pedal group of serotonergic neurons paired with a test stimulus also significantly increased (the difference between paired and explicitly unpaired sessions was significant, p <.05) synaptic responses to paired nerve stimulation in same premotor interneurons involved in withdrawal. Morphological investigation of a cluster of pedal serotonergic neurons showed that only the Pd4 cell had branches in the parietal ganglia neuropile where the synapses of premotor withdrawal interneurons and of presynaptic neurons are located. The data suggest that a single serotonergic cell can mediate the reinforcement in the withdrawal network of the terrestrial snail. Patterns of responses of the Pd4 cells to tactile and chemical stimuli conform to the suggestion.

Caspase-like activity is essential for long-term synaptic plasticity in the terrestrial snail Helix.

Although caspase activity in the nervous system of mollusks has not been described before, we suggested that these cysteine proteases might be involved in the phenomena of neuroplasticity in mollusks. We directly measured caspase‐3 (DEVDase) activity in the Helix lucorum central nervous system (CNS) using a fluorometrical approach and showed that the caspase‐3‐like immunoreactivity is present in the central neurons of Helix. Western blots revealed the presence of caspase‐3‐immunoreactive proteins with a molecular mass of 29 kDa. Staurosporin application, routinely used to induce apoptosis in mammalian neurons through the activating cleavage of caspase‐3, did not result in the appearance of a smaller subunit corresponding to the active caspase in the snail. However, it did increase the enzyme activity in the snail CNS. This suggests differences in the regulation of caspase‐3 activity in mammals and snails. In the snail CNS, the caspase homolog seems to possess an active center without activating cleavage typical for mammals. In electrophysiological experiments with identified snail neurons, selective blockade of the caspase‐3 with the irreversible and cell‐permeable inhibitor of caspase‐3 N‐benzyloxycarbonyl‐Asp(OMe)‐Glu(OMe)‐Val‐Asp‐(OMe)‐fluoro‐methylketone prevented development of the long‐term stage of synaptic input sensitization, suggesting that caspase is necessary for normal synaptic plasticity in snails. The results of our study give the first direct evidence that the caspase‐3‐like activity is essential for long‐term plasticity in the invertebrate neurons. This activity is presumably involved in removing inhibitory constraints on the storage of long‐term memory.

Cannabinoid regulation in identified synapse of terrestrial snail

In the terrestrial snail a direct monosynaptic glutamatergic connection between the primary sensory neuron and a premotor interneuron involved in withdrawal behaviour can be functionally identified using electrophysiological techniques. We investigated the involvement of cannabinoids in regulation of this synaptic contact. The results demonstrate that the specific binding sites for agonists to mammalian type 1 cannabinoid receptors (CB1Rs) exist in the snails nervous system. Application of a synthetic cannabinoid agonist anandamide selectively changed the efficacy of synaptic contacts between the identified neurons. A decrease in the long‐term synaptic facilitation of the synaptic contact elicited by high‐frequency nerve tetanization in the presence of cannabinoid agonist anandamide was observed, suggesting a possible role of endocannabinoids in regulation of plasticity at this synaptic site. The selective antagonist of CB1Rs [N‐(piperidin‐1‐yl)‐5‐(4‐iodophenyl)‐1‐(2,4‐dichlorophenyl)‐4‐methyl‐1H‐pyrazole‐3‐carboxamide] AM251 bath application was changing the efficacy of the synaptic contact only when the postsynaptic neuron had been intracellularly activated before its application. This observation implies an involvement of endocannabinoids in plasticity phenomena induced by activity in the postsynaptic target. Additional support of endocannabinoid involvement in synaptic function at this site was given by experiments in which AM251 blocked the short‐term suppression of synaptic excitation evoked by low‐frequency nerve tetanization, a phenomenon qualitatively similar to cannabinoid‐dependent synaptically evoked suppression of excitation demonstrated in the mammalian nervous system. The results of the present study suggest an involvement of cannabinoids in the regulation of synaptic efficacy. Further, anandamide could be a candidate for an endogenous neuromessenger involved in plasticity processes.

Intracellular localization of the HCS2 gene products in identified snail neurons in vivo and in vitro.

SUMMARY1. The HCS2 (Helix command specific 2) gene expressed in giant command neurons for withdrawal behavior of the terrestrial snail Helix lucorum encodes a unique hybrid precursor protein that contains a Ca-binding (EF-hand motif) protein and four small peptides (CNP1-CNP4) with similar Tyr-Pro-Arg-X aminoacid sequence at the C terminus. Previous studies suggest that under conditions of increased intracellular Ca2+ concentration the HCS2 peptide precursor may be cleaved, and small physiologically active peptides transported to the release sites. In the present paper, intracellular localization of putative peptide products of the HCS2-encoded precursor was studied immunocytochemically by means of light and electron microscopy.2. Polyclonal antibodies against the CNP3 neuropeptide and a Ca-binding domain of the precursor protein were used for gold labeling of ultrathin sections of identified isolated neurons maintained in culture for several days, and in same identified neurons freshly isolated from the central nervous system.3. In freshly isolated neurons, the gold particles were mainly localized over the cytoplasmic secretory granules, with the density of labeling for the CNP3 neuropeptide being two-fold higher than for the calcium-binding domain. In cultured neurons, both antibodies mostly labeled clusters of secretory granules in growth cones and neurites of the neuron. The density of labeling for cultured neurons was the same for both antibodies, and was two-fold higher than for the freshly isolated from the central nervous system neurons.4. The immunogold particles were practically absent in the bodies of cultured neurons.5. The data obtained conform to the suggestion that the HCS2 gene products are transported from the cell body to the regions of growth or release sites.

Morphological basis for coordination of growth and reproduction processes in the CNS of two terrestrial snails

The morphology of cells immunoreactive to an antibody against molluscan insulin-related peptide (MIP-IR) was studied in two species of terrestrial snail: Helix lucorum L. and Eobania vermiculata L. Immunocytochemical staining with this antibody to MIP revealed 100–130 cells in the postcerebrum, located in two clusters with common pathways in the dorsal body nerve and the cerebral artery nerve. About 75% of the MIP-IR cells were labeled by backfilling of the dorsal body nerve in Helix and Eobania; the corresponding figures for labeling by backfilling of the cerebral artery nerve were about 60% in Helix and 30% in Eobania. Upon intracellular staining of neurons of the dorsomedial postcerebrum, where most of the MIP-IR cells were located, it was found that they projected either in the dorsal body nerve or in the cerebral artery nerve or in both. The obtained data suggest that growth and reproduction processes (both functions were attributed to the insulin-related peptide-containing neurons) are regulated by the two, partially coinciding subsets of postcerebral MIP-IR neurons with different types of branching.

Selective blockade of gene expression in a single identified snail neuron

In the present study, the applicability of antisense morpholino oligos for loss-of-function experiments in neurobiology was investigated. The identified withdrawal interneurons of the parietal ganglia expressing helix command neuron-specific 2 (HCS2) gene were pressure injected with HCS2 antisense or control morpholino oligo solution at a final concentration 1-4 microM. No toxic or side effects for the neural functioning were noted immediately or several hours after injection. The changes in the concentration of HCS2-encoded protein in neurons after injection were monitored by two methods, Western blotting and immunostaining of the brain. The amount of the peptide immunoreactive with the HCS2 antibody started to decline in the injected cells at day 2 post-injection, decreased four- to five-fold at day 4, and stayed at this low level thereafter. Similar results obtained by both methods suggest significant selective blockade of production of the HCS2-encoded peptide. In contrast, no substantial decrease of the HCS2-encoded polypeptide was observed after injection with control oligos. Due to the high stability of the morpholino oligos in the cell, they represent a highly efficient tool for a specific long-term blockade of gene expression in molluscan neurons.

Immunocytochemical Study of the Distribution of hcs2 Gene Products in Command Neurons of the Helix lucorum Snail

The distribution of the putative protein products of gene hcs2 in giant command neurons of the parietal ganglia of the terrestrial snail Helix lucorum has been studied using light- and electron-microscopic immunocytochemistry. The product of the hcs2 gene is a hybrid protein belonging to the EF-hand family of Ca2+-binding proteins and is a precursor of several neuropeptides. Polyclonal antibodies to neuropeptides CNP3 and CNP4 and the C-terminal Ca2+-binding domain of the precursor protein have been used to determine their intracellular localization. The targets for all three types of antibodies have been found in cytoplasmic secretory granules. The label (colloidal gold) density in the secretory granules is two times higher in the case of neuropeptides CNP3 and CNP4 than in the case of the Ca2+-binding domain. Thus, a specific association between the putative products of the hcs2 gene and the cell secretory apparatus has been demonstrated. This agrees with the earlier hypothesis that hcs2 products may serve as neurotransmitters or neuromodulators.