RRC ID 86905
Author Chatterjee A, De J, Martin B, Chélot E, Zhong P, Rouyer F.
Title Neuropeptide dynamics coordinate layered plasticity mechanisms adapting Drosophila circadian behavior to changing environment.
Journal Sci Adv
Abstract The Drosophila brain contains distinct circadian oscillators responsible for generating the morning and evening bouts of locomotor activity in light-dark cycles. We lack a mechanistic understanding of how environmental changes reshape the resulting bimodal rest-activity pattern. Here, we uncover a seasonal switch mechanism that remodels the evening bout of activity. Under temperate summer-like conditions, levels of the pigment-dispersing factor (PDF) neuropeptide diminish, triggering a cascade. Lowered PDF receptor (PDFR) signaling disinhibits glycogen synthase kinase 3/SHAGGY to advance the evening output, and in parallel, weakens the siesta-promoting vcDN1p-SIFamide axis to expand the evening peak. Under these conditions, vcDN1p takes over the evening pacemaker role by exerting control over the dorsal lateral oscillator neurons. Our findings elucidate how environment-induced changes in PDFR signaling tip the balanced output of the clock network, aligning daily rhythms with seasonal time. Neuropeptide-driven parallel adjustment of clock circuitry and clock protein functioning likely represents a conserved strategy, enabling animals to adapt their daily behavior to seasonal changes.
Volume 11(35)
Pages eadt7168
Published 2025-8-29
DOI 10.1126/sciadv.adt7168
PMID 40880480
PMC PMC12396332
MeSH Animals Behavior, Animal Circadian Rhythm* / physiology Drosophila* / physiology Drosophila Proteins* / genetics Drosophila Proteins* / metabolism Drosophila melanogaster* / physiology Neurons / metabolism Neuropeptides* / genetics Neuropeptides* / metabolism Receptors, G-Protein-Coupled / genetics Receptors, G-Protein-Coupled / metabolism Signal Transduction
IF 13.117
Resource
Drosophila HMS01093