Sleep has historically been viewed through a brain centric lens with little known about the contribution of the periphery. Through a targeted screen of secreted peptides from the fat body, gut, and body wall muscle in Drosophila, we identified CG11037, a trypsin-like serine endopeptidase secreted from midgut enterocytes, as a previously unrecognized regulator of sleep. Loss of CG11037 reduces daily sleep, as well as sleep following injury/infection, although recovery is enhanced suggesting reduced need for sleep during sickness. Proteomic analysis of flies with reduced CG11037 revealed altered oxidative stress response pathways including cytochrome P450 related proteins. Indeed, gut-specific knockdown of Cyp6a2 or Cyp28d1 phenocopies CG11037 sleep defects, and loss of CG11037 or P450 elevates reactive oxygen species (ROS) selectively in the gut without affecting brain ROS. Rescue of sleep by antioxidant treatment demonstrates that peripheral ROS accumulation drives the behavioral phenotype. Strikingly, despite physiological dysfunction and reduced sleep, CG11037 or Cytochrome P450 knockdown extends lifespan in a ROS dependent manner, suggesting that stress adaptation of these knockdowns allows them to live longer. Together, these findings uncover a mechanism for the unexpected association of reduced sleep and extended lifespan.
Moore, R. S., Xiong, R., Astacio, E., Williams, J. A., Brooks, T., Grant, G., Stucynski, J., Fazelinia, H., Nash, E., Spruce, L., Sehgal, A.
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