PROJECT SUMMARY Functional genomic studies have contributed enormously to our understanding of conserved genetic pathways influencing aging in evolutionarily divergent organisms. The use of high throughput machinery and the application of skilled manpower along with screening systematic gene knock-out in yeast and gene depletion (RNA interference) in worm have led to the identification of several genes that influence life span. Some of these genes have human orthologues and have been examined successfully in the context of invertebrate and mammalian aging. Although, it is now clear that at least some aspects of cellular aging are highly conserved, identification of conserved components of longevity pathways across evolutionarily divergent organisms has lagged far behind. We will address this issue by analyzing the function of conserved essential genes in regulation of longevity. Essential genes in yeast are approximately 5 times more likely to have human orthologs than non-essential genes. For example, among the 1123 yeast essential genes, 856 of them have both worm and human homologs. However, to date, despite the greater functional importance and high conservation between species, there has been no comprehensive study to characterize the role of essential genes in aging. Accordingly, the goal of this proposal is to test the hypothesis that essential genetic modifiers of aging in yeast are more likely to play a conserved role in the aging process in multicellular eukaryotes. In a complete screen of yeast and validation screen from worm strains with increased expression of one the essential genes for which there is a clear human ortholog, we made the striking observation that essential genes are much more likely than non-essential genes to play an important conserved role in lifespan regulation. We propose to use recently developed tools to screen the conserved gene dosage effect on lifespan using C. elegans (Aim 1). Next, we will identify genetic mechanisms of lifespan determination by analyzing genome-scale patterns of age-associated mRNA expression changes in long living strains and place new longevity genes into or out of known longevity pathways with genetic epistasis experiments (Aim 2). In the last aim, we will provide proof of mechanistic concept by investigating the molecular mechanisms underlying a promising, potentially conserved in humans, mode of longevity stemming from the overexpression of conserved essential genes (Aim 3). Such genes are a rich, untapped source for understanding genetic mechanisms of longevity determination. Thus, every hit represents a newly discovered longevity gene with a conserved human ortholog. Successful completion of this proposal will yield a wealth of new information about conserved mechanisms of molecular determination of aging and will identify dozens of candidate genes for testing in higher eukaryotes with important ramifications for healthy human aging.