Abstract
The identification and validation of drugs that promote health during aging (“geroprotectors”) are key to the retardation or prevention of chronic age‐related diseases. Here, we found that most of the established pro‐longevity compounds shown to extend lifespan in model organisms also alter extracellular matrix gene expression (i.e., matrisome) in human cell lines. To harness this observation, we used age‐stratified human transcriptomes to define the age‐related matreotype, which represents the matrisome gene expression pattern associated with age. Using a “youthful” matreotype, we screened in silico for geroprotective drug candidates. To validate drug candidates, we developed a novel tool using prolonged collagen expression as a non‐invasive and in‐vivo surrogate marker for Caenorhabditis elegans longevity. With this reporter, we were able to eliminate false‐positive drug candidates and determine the appropriate dose for extending the lifespan of C. elegans. We improved drug uptake for one of our predicted compounds, genistein, and reconciled previous contradictory reports of its effects on longevity. We identified and validated new compounds, tretinoin, chondroitin sulfate, and hyaluronic acid, for their ability to restore age‐related decline of collagen homeostasis and increase lifespan. Thus, our innovative drug screening approach—employing extracellular matrix homeostasis—facilitates the discovery of pharmacological interventions promoting healthy aging.
Highlights
The demographic shift in the human population reflects an aging society—over 20% of Europeans are predicted to be 65 or over by the year 2025 (Riera & Dillin, 2015)
We identified and validated new compounds, tretinoin, chondroitin sulfate, and hyaluronic acid, for their ability to restore age-related decline of collagen homeostasis and increase lifespan
We demonstrated that a concise list of 1027 matrisome or 99 matreotype genes facilitates the identification of lifespan-enhancing drugs
Summary
The demographic shift in the human population reflects an aging society—over 20% of Europeans are predicted to be 65 or over by the year 2025 (Riera & Dillin, 2015). Heparan/chondroitin biosynthesis and TGFβ pathway are frequently enriched in C. elegans longevity drug screens (Liu et al, 2016) These functionally implicated genes are all members of the matrisome. Organismal phenotypes, physiological states, and cellular identity are characterized by distinct sets of expressed ECM proteins. Since these unique ECM compositions are an expression profile on a temporary, sometimes local basis and do not involve the entire matrisome, we coined the term matreotype (Ewald, 2019). We define a youthful human matreotype using data from the Genotype-Tissue Expression (GTEx) project (Consortium, 2013) We query this young matreotype signature with the drug resource Connectivity Map (CMap) (Lamb et al, 2006) data to identify longevity-promoting compounds. Our results implicate previously known longevity drugs as well as novel drugs, providing a proof-of-concept for our approach
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