Developmental Reactive Oxygen Species Target Histone Methylation to Individualize Stress resistance and Lifespan

A central aspect of aging research concerns the question as to when individuality in lifespan arises and what mechanism(s) promote and potentially manifest individual differences in longevity. We have now discovered that a transient increase in reactive oxygen species (ROS), which occurs naturally during early development in a subpopulation of synchronized , sets processes into motion that increase stress resistance, improve redox homeostasis and ultimately prolong lifespan in those animals. We find that these effects are linked to the global ROS-mediated decrease in developmental histone H3K4me3 levels. Studies in HeLa cells confirmed that global H3K4me3 levels are ROS-sensitive, and that depletion of H3K4me3 levels increases stress resistance in mammalian cell cultures. studies identified the Set1-MML histone methyltransferase as the redox sensitive unit of the H3K4-trimethylating COMPASS complex. Our findings imply a novel link between early-life events, ROS-sensitive epigenetic marks, stress resistance and lifespan.