Project description:Aging is under genetic control in C. elegans but the mechanisms of lifespan regulation are not completely known. MicroRNAs (miRNAs) regulate various aspects of development and metabolism and one miRNA has been previously implicated in lifespan. Here we show that multiple miRNAs change expression in C. elegans aging, including novel miRNAs, and that mutations in several of the most up-regulated miRNAs lead to lifespan defects. Some act to promote normal lifespan and stress resistance while others inhibit these phenomena. We find that these miRNAs genetically interact with genes in the DNA damage checkpoint response pathway and in the insulin signaling pathway. Our findings reveal that miRNAs both positively and negatively influence lifespan. Since several miRNAs up-regulated during aging regulate genes in conserved pathways of aging and thereby influence lifespan in C. elegans, we propose that miRNAs may play important roles in stress response and aging of more complex organisms. 4 sample examined: Wild-type (N2) and long-lived daf-2(e1379) animals at days 0 and 10 of adulthood

Project description:Deletion of several ribosomal proteins genes (RPKOs) has been shown to extend the lifespan of Saccharomyces cerevisiae in a Gcn4-dependent manner. To characterize the underlying mechanisms, we systematically analyzed the gene expression of both short- and long-lived RPKO strains at multiple levels. We found that up-regulation of amino acid biosynthesis and global down-regulation of protein synthesis are hallmarks of long-lived strains. We provide direct evidence that gene expression changes observed in long-lived strains result from translational up-regulation of GCN4 mRNA via skipping of upstream open reading frames (uORFs), in turn due to slow/defective ribosome assembly. We further demonstrate that Gcn4 acts as a transcriptional repressor on promoters of translation-related genes, thereby globally reducing protein synthesis. Our data suggest that the Gcn4-dependent increase in lifespan can be attributed partially to its ability to dampen the translation capacity of the cell, thereby engaging a well known mechanism of longevity.

Project description:Here, we analyzed 76 ecologically diverse wild yeast isolates and discovered a wide diversity of replicative lifespan. Phylogenetic analyses pointed to genes and environmental factors that strongly interact to modulate the observed aging patterns. We then identified genetic networks causally associated with natural variation in replicative lifespan across wild yeast isolates, as well as genes, metabolites and pathways, many of which have never been associated with yeast lifespan in laboratory settings. In addition, a combined analysis of lifespan-associated metabolic and transcriptomic changes revealed unique adaptations to interconnected amino acid biosynthesis, glutamate metabolism and mitochondrial function in long-lived strains. Overall, our multi-omic and lifespan analyses across diverse isolates of the same species shows how gene-environment interactions shape cellular processes involved in phenotypic variation such as lifespan.

Project description:We developed a morphological biomarker that detects multiple discrete sub-populations (or “age states”) at any given chronological age in a population of nematodes (C. elegans). Age-matched animals in different age states have distinct transcriptome profiles, one markedly older than the other as determined by comparison with other aging study microarray datasets. Here we characterized the frequencies of three healthy adult states and the transitions between them across the lifespan. Jaccard similarity showed expression profiles were more similar within states than between states. Chronologically identical individuals showed less similarity than morphologically identical individuals isolated on different days. We used short-lived and long-lived strains to confirm the general applicability of the state classifier and to monitor state progression. This exploration revealed healthy and unhealthy states, the former being favored in long-lived strains and the latter showing delayed onset. Short-lived strains rapidly transitioned through the putative healthy state. We expected state exit factors to be up regulated later in a given state. Several small heat shock protein encoding genes demonstrated oscillation within states. Oscillatory expression of sHSPs within states and proteasome components between states, supports an extension of a proteostasis collapse model to include periodic collapses and rebuilding phases.

Project description:Protein translation (PT) declines with age in invertebrates, rodents, and humans. It has been assumed that elevated PT at young ages is beneficial to health and PT ends up dropping as a passive byproduct of aging. In Drosophila, we show that a transient elevation in PT during early-adulthood exerts long-lasting negative impacts on aging trajectories and proteostasis in later-life. Blocking the early-life PT elevation robustly improves life-/health-span and prevents age-related protein aggregation, whereas transiently inducing an early-life PT surge in long-lived fly strains abolishes their longevity/proteostasis benefits. The early-life PT elevation triggers proteostatic dysfunction, silences stress responses, and drives age related functional decline via juvenile hormone-lipid transfer protein axis and germline signaling. Our findings suggest that PT is adaptively suppressed after early-adulthood, alleviating later-life proteostatic burden, slowing down age-related functional decline, and improving lifespan. Our work provides a theoretical framework for understanding how lifetime PT dynamics shape future aging trajectories.

Project description:Our data describes the first atlas of long-lived proteins in somatic and reproductive tissues of Drosophila during adult lifespan, and reveals a preferential ubiquitylation in the aging proteome.

Project description:To understand how reduced insulin/IGF-1 signaling extends Drosophila lifespan through its downstream transcription factor dFOXO. We conducted ChIP analysis with a dFOXO antibody followed by Illumina high-throughput sequencing from chico heterozygous mutants, which are long-lived and normal sized, and from adult flies with ablated insulin producing cells (IPCs), which are also long-lived. dFOXO bound at promoters of 273 genes common among these genotypes, thus potentially enriching for shared factors in control of aging. Two replicates were sequenced from chico heterozygous mutants and IPC ablated flies.

Project description:Aging is under genetic control in C. elegans but the mechanisms of lifespan regulation are not completely known. MicroRNAs (miRNAs) regulate various aspects of development and metabolism and one miRNA has been previously implicated in lifespan. Here we show that multiple miRNAs change expression in C. elegans aging, including novel miRNAs, and that mutations in several of the most up-regulated miRNAs lead to lifespan defects. Some act to promote normal lifespan and stress resistance while others inhibit these phenomena. We find that these miRNAs genetically interact with genes in the DNA damage checkpoint response pathway and in the insulin signaling pathway. Our findings reveal that miRNAs both positively and negatively influence lifespan. Since several miRNAs up-regulated during aging regulate genes in conserved pathways of aging and thereby influence lifespan in C. elegans, we propose that miRNAs may play important roles in stress response and aging of more complex organisms.

Project description:Protein translation (PT) declines with age in invertebrates, rodents, and humans1-6. It has been assumed that elevated PT at young ages is beneficial to health and PT ends up dropping as a passive byproduct of aging. In Drosophila, we show that a transient elevation in PT during early-adulthood exerts long-lasting negative impacts on aging trajectories and proteostasis in later-life. Blocking the early-life PT elevation robustly improves life-/health-span and prevents age-related protein aggregation, whereas transiently inducing early-life PT surge in long-lived fly strains abolishes their longevity/proteostasis benefits. The early-life PT elevation triggers proteostatic dysfunction, silences stress responses, and drives age-related functional decline via juvenile hormone-lipid transfer protein axis and germline signaling. Our findings suggest that PT is adaptively suppressed after early-adulthood, alleviating later-life proteostatic burden, slowing down age-related functional decline, and improving lifespan. Our work provides a novel theoretical framework for understanding how lifetime PT dynamics shape future aging trajectories.

Project description:We quantified gene expression in three different strains of the short-lived killifish Nothobranchius furzeri during aging.