Mutations and genetic variability affect gene expression and lifespan, but the impact of variations in gene expression within individuals on their aging-related mortality is poorly understood. We performed a longitudinal study in the short-lived killifish, Nothobranchius furzeri, and correlated quantitative variations in gene expression during early adult life with lifespan. Shorter- and longer-lived individuals differ in their gene expression before the onset of aging-related mortality; differences in gene expression are more pronounced early in life. We identified mitochondrial respiratory chain complex I as a hub in a module of genes whose expression is negatively correlated with lifespan. Accordingly, partial pharmacological inhibition of complex I by the small molecule rotenone reversed aging-related regulation of gene expression and extended lifespan in N. furzeri by 15%. These results support the use of N. furzeri as a vertebrate model for identifying the protein targets, pharmacological modulators, and individual-to-individual variability associated with aging.
Keywords: GAGE; Nothobranchius furzeri; RNA transport; RNA-seq; aging; history trait; hormesis; hourglass; life ribosome; lifespan regulation; longevity; longitudinal study; mitohormesis; rejuvenation; weighted gene coexpression network analysis (WGCNA); zebrafish.
Copyright © 2016 The Authors. Published by Elsevier Inc. All rights reserved.