RRC ID 88023
Author Shao J, Liewald JF, Steuer Costa W, Ruse C, Gruber J, Djamshedzad MS, Gebhardt W, Gottschalk A.
Title Loss of neuropeptidergic regulation of cholinergic transmission induces homeostatic compensation in muscle cells to preserve synaptic strength.
Journal PLoS Biol
Abstract Chemical synaptic transmission at the neuromuscular junction (NMJ) is regulated by electrical activity of the motor circuit, but may also be affected by neuromodulation. Here, we assessed the role of neuropeptide signaling in the plasticity of NMJ function in Caenorhabditis elegans. We show that the CAPS (Ca2+-dependent activator protein for secretion) ortholog UNC-31, which regulates exocytosis of dense core vesicles, affects both pre- and post-synaptic functional properties, as well as NMJ-mediated locomotion. Despite reduced evoked acetylcholine (ACh) transmission, the loss of unc-31 results in a more vigorous response to presynaptic stimulation, i.e., enhanced muscle contraction and Ca2+ transients. Based on expression profiles, we identified neuropeptides involved in both cholinergic (FLP-6, FLP-15, NLP-9, NLP-15, NLP-21, and NLP-38) and GABAergic motor neurons (FLP-15, NLP-15), that mediate normal transmission at the NMJ. In the absence of these peptides, neurons fail to upregulate their ACh output in response to increased cAMP signaling; for flp-15; nlp-15 double mutants, we observed overall increased postsynaptic currents, indicating that these neuropeptides may be inhibitory. We also identified proprotein convertases encoded by aex-5/kpc-3 and egl-3/kpc-2 that act synergistically to generate these neuropeptides. We propose that postsynaptic homeostatic scaling, mediated by increased muscle activation, likely through excitability, might compensate for the reduced cholinergic transmission in mutants affected for neuropeptide signaling, thus maintaining net synaptic strength. We show that in the absence of UNC-31 muscle excitability is modulated by upregulating the expression of the muscular L-type voltage-gated Ca2+ channel EGL-19. Our results unveil a role for neuropeptidergic regulation in synaptic plasticity, linking changes in presynaptic transmission to compensatory changes in muscle excitability.
Volume 23(5)
Pages e3003171
Published 2025-5-1
DOI 10.1371/journal.pbio.3003171
PII PBIOLOGY-D-24-02719
PMID 40338987
PMC PMC12088594
MeSH Acetylcholine / metabolism Animals Caenorhabditis elegans / metabolism Caenorhabditis elegans / physiology Caenorhabditis elegans Proteins / genetics Caenorhabditis elegans Proteins / metabolism Homeostasis Locomotion Motor Neurons / metabolism Motor Neurons / physiology Muscle Cells* / metabolism Muscle Cells* / physiology Neuromuscular Junction / metabolism Neuromuscular Junction / physiology Neuropeptides* / genetics Neuropeptides* / metabolism Signal Transduction Synaptic Transmission* / physiology
Resource
C.elegans tm2569 tm3572