Abstract
Aging clocks dissociate biological from chronological age. The estimation of biological age is important for identifying gerontogenes and assessing environmental, nutritional, or therapeutic impacts on the aging process. Recently, methylation markers were shown to allow estimation of biological age based on age‐dependent somatic epigenetic alterations. However, DNA methylation is absent in some species such as Caenorhabditis elegans and it remains unclear whether and how the epigenetic clocks affect gene expression. Aging clocks based on transcriptomes have suffered from considerable variation in the data and relatively low accuracy. Here, we devised an approach that uses temporal scaling and binarization of C. elegans transcriptomes to define a gene set that predicts biological age with an accuracy that is close to the theoretical limit. Our model accurately predicts the longevity effects of diverse strains, treatments, and conditions. The involved genes support a role of specific transcription factors as well as innate immunity and neuronal signaling in the regulation of the aging process. We show that this binarized transcriptomic aging (BiT age) clock can also be applied to human age prediction with high accuracy. The BiT age clock could therefore find wide application in genetic, nutritional, environmental, and therapeutic interventions in the aging process.
Highlights
Aging is the driving factor for several diseases, the declining organ function and overall progressive loss of physiological integrity[1]
There have been descriptions of a transcriptional drift during C. elegans aging[97,99], which might be due to aregulation of single transcription factors[100] and the suppression of this transcriptional drift might slow down the aging process[50]
Age prediction could be improved by rescaling the chronological age by the median lifespan[97]
Summary
Aging is the driving factor for several diseases, the declining organ function and overall progressive loss of physiological integrity[1]. Aging biomarkers that predict the biological age of an organism are important for identifying genetic and environmental factors that influence the aging process and for accelerating studies examining potential rejuvenating treatments. Initial studies have shown evidence that methods predicting the biological age are sensitive enough to detect the effect of geroprotective therapies[2,3,4,5].
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