Abstract

Neuropeptides play crucial roles in modulating neuronal networks, including changing intrinsic properties of neurons and synaptic efficacy. We previously reported a Caenorhabditis elegans mutant, acr-2(gf), that displays spontaneous convulsions as the result of a gain-of-function mutation in a neuronal nicotinic acetylcholine receptor subunit. The ACR-2 channel is expressed in the cholinergic motor neurons, and acr-2(gf) causes cholinergic overexcitation accompanied by reduced GABAergic inhibition in the locomotor circuit. Here we show that neuropeptides play a homeostatic role that compensates for this excitation-inhibition imbalance in the locomotor circuit. Loss of function in genes required for neuropeptide processing or release of dense core vesicles specifically modulate the convulsion frequency of acr-2(gf). The proprotein convertase EGL-3 is required in the cholinergic motor neurons to restrain convulsions. Electrophysiological recordings of neuromuscular junctions show that loss of egl-3 in acr-2(gf) causes a further reduction of GABAergic inhibition. We identify two neuropeptide encoding genes, flp-1 and flp-18, that together counteract the excitation-inhibition imbalance in acr-2(gf) mutants. We further find that acr-2(gf) causes an increased expression of flp-18 in the ventral cord cholinergic motor neurons and that overexpression of flp-18 reduces the convulsion of acr-2(gf) mutants. The effects of these peptides are in part mediated by two G-protein coupled receptors, NPR-1 and NPR-5. Our data suggest that the chronic overexcitation of the cholinergic motor neurons imposed by acr-2(gf) leads to an increased production of FMRFamide neuropeptides, which act to decrease the activity level of the locomotor circuit, thereby homeostatically modulating the excitation and inhibition imbalance.

Highlights

  • Neuropeptides are widespread and diverse modulators of neuronal circuit function, and have long been known to play regulatory roles in complex behaviors, such as learning, feeding, temperature regulation, and pain sensation [1,2]

  • We show that neuropeptides processed by EGL-3 and released from the cholinergic motor neurons inhibit the convulsions caused by acr-2(gf)

  • Egl-21(lf); egl-3(lf); acr-2(gf) triple mutants behaved to egl-3(lf); acr-2(gf). These observations suggest that egl-21 may not be required, or has a partial role, for processing the specific neuropeptides involved in acr-2(gf) convulsive behavior

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Summary

Introduction

Neuropeptides are widespread and diverse modulators of neuronal circuit function, and have long been known to play regulatory roles in complex behaviors, such as learning, feeding, temperature regulation, and pain sensation [1,2]. In recent years great strides have been made in the recognition of the diverse means by which neuropeptides regulate neuronal circuits [9,10,11,12,13,14,15,16]. Numerous studies from C. elegans have revealed important insights on the precise mechanisms underlying endogenous neuropeptide function in animal behaviors [15,17,18,19]. The release of dense core vesicles occurs in response to Ca2+ influx, and relies on several unique proteins in addition to those that are involved in fast neurotransmitter release [26]

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