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FMO rewires metabolism to promote longevity through tryptophan and one carbon metabolism in C. elegans

Hyo Sub Choi, Ajay Bhat, Marshall Howington, Megan L. Schaller, Rebecca L. Cox, Shijiao Huang, Safa Beydoun, Hillary Miller, Angela M. Tuckowski, Joy Mecano, Elizabeth S. Dean, Lindy Jensen, Daniel Beard, Charles R. Evans, Scott F. Leiser

2023Nature Communications43 citationsDOIOpen Access PDF

Abstract

Flavin containing monooxygenases (FMOs) are promiscuous enzymes known for metabolizing a wide range of exogenous compounds. In C. elegans, fmo-2 expression increases lifespan and healthspan downstream of multiple longevity-promoting pathways through an unknown mechanism. Here, we report that, beyond its classification as a xenobiotic enzyme, fmo-2 expression leads to rewiring of endogenous metabolism principally through changes in one carbon metabolism (OCM). These changes are likely relevant, as we find that genetically modifying OCM enzyme expression leads to alterations in longevity that interact with fmo-2 expression. Using computer modeling, we identify decreased methylation as the major OCM flux modified by FMO-2 that is sufficient to recapitulate its longevity benefits. We further find that tryptophan is decreased in multiple mammalian FMO overexpression models and is a validated substrate for FMO-2. Our resulting model connects a single enzyme to two previously unconnected key metabolic pathways and provides a framework for the metabolic interconnectivity of longevity-promoting pathways such as dietary restriction. FMOs are well-conserved enzymes that are also induced by lifespan-extending interventions in mice, supporting a conserved and important role in promoting health and longevity through metabolic remodeling.

Topics & Concepts

LongevityBiologyMetabolic pathwayEnzymeMetabolismMonooxygenaseFlux (metallurgy)BiochemistryCell biologyGeneticsCytochrome P450ChemistryOrganic chemistryGenetics, Aging, and Longevity in Model OrganismsCircadian rhythm and melatoninDiet and metabolism studies
FMO rewires metabolism to promote longevity through tryptophan and one carbon metabolism in C. elegans | Litcius