Abstract
Transcriptome analysis has become increasingly utilized in aging research. However, the identification of the key molecular changes underlying aging processes and longevity-promoting regimens from transcriptome data remains challenging. Here, we present Transcriptomic CLassification via Adaptive learning of Signature States (T-CLASS), an online tool that identifies, from transcriptome data, gene sets of several hundred genes that provide an optimal representation of longevity and aging paradigms. We systematically evaluated the effectiveness of T-CLASS with diverse datasets, including longevity-promoting regimens in Caenorhabditis elegans, cellular senescence by different means in both cultured mouse primary cells and cultured human cells, and human sarcopenia. We found that T-CLASS exhibited robust and high classification performance across datasets compared to preexisting machine/deep learning-based gene selection tools. By focusing our further analysis on longevity-promoting regimens in C. elegans, we showed that T-CLASS successfully classified transcriptomic changes caused by ten lifespan-extending small molecules, among which we experimentally validated the effect of rifampicin and atracurium as a proof of principle. Overall, T-CLASS is an effective and practical tool for uncovering and classifying physiological changes caused by genetic and pharmacological interventions that affect aging.