Across animal phyla, monoamines signal through both metabotropic and ionotropic receptors. In worms as well as in humans, metabotropic monoamine receptors, which modulate neuronal activity through G-protein-mediated second messenger pathways, have received most attention. However, expression studies indicate that the vast majority of C. elegans neurons postsynaptic to aminergic neurons do not express metabotropic amine receptors. This implies that synaptic monoamine transmission may be mediated by as yet uncharacterized ionotropic receptors. Since the worm genome contains many members of the ligand-gated ion channel (LGC) superfamily, several with unknown ligands, we reasoned some of these might be activated by monoamines. We focused first on receptors related to the known ionotropic receptors MOD-1, LGC-53 and LGC-55. By heterologous expression in Xenopus oocytes we characterised agonist sensitivity and ion selectivity of four new C. elegans LGCs: GGR-3, LGC-54, LGC-52 that forms dopamine and tyramine-gated anion channels, and LGC-50 that form a serotonin-gated cation channel. Fluorescent reporters identified expression of these channels in some of the major postsynaptic targets of aminergic neurons. In particular the serotonin-gated channel LGC-50 is expressed in the interneuron RIA, which is strongly innervated by the serotonergic neuron ADF, while LGC-54 is expressed in RMH and AVE, major synaptic outputs of the dopaminergic CEP neurons. Thus, we hypothesise that these monoamine-gated LGC may mediate much, if not all, synaptic transmission from aminergic neurons in C. elegans, while metabotropic receptors may specifically function in extrasynaptic neuromodulation. We are currently testing this for LGC-50 by in vivo patch-clamp recordings from RIA, paired with optogenetic stimulation of ADF. Previous work has indicated a role for ADF and RIA in aversive pathogen learning, through which animals learn to avoid odours released by pathogenic bacteria following infection. We have found that
lgc-50 mutants show a strong defect in pathogen learning, which can be rescued by expression of LGC-50 in RIA. These results suggest that serotonin may act through LGC-50 to modify the strength of specific synapses in the olfactory navigation circuit. LGC-50 thus provides an entry point to define the molecular and neuronal changes underlying learning and memory in the worm.