Brain senescence drives sarcopenia-like transcriptomic remodeling in skeletal muscle

Aging is accompanied by a progressive decline in skeletal muscle mass and function, culminating in sarcopenia, a major contributor to frailty, disability, and mortality in older adults. While skeletal muscle aging has traditionally been attributed to cell-autonomous and local tissue mechanisms, increasing evidence suggests that systemic, cell non-autonomous processes play a central role in coordinating aging across organs. The brain, particularly the hypothalamus, has emerged as a key regulator of organismal aging, yet its contribution to skeletal muscle aging remains poorly defined. Here, we tested the hypothesis that senescence(definition) confined to the brain is sufficient to induce aging-like molecular remodeling in skeletal muscle via systemic mechanisms. To model brain senescence, young mice were subjected to fractionated whole-brain irradiation (WBI), a well-established approach that induces widespread cellular senescence and neuroinflammation in the brain while sparing peripheral tissues. Two months after WBI, transcriptomic profiling of quadriceps muscle was performed and compared with that of naturally aged mice. WBI-induced robust gene expression changes in skeletal muscle that closely mirrored those observed during chronological aging. Pathway-level analyses revealed marked downregulation of mitochondrial organization, respiratory chain assembly, and metabolic processes, alongside enrichment of remodeling- and stress-associated pathways. Upstream regulator analysis identified FOXO1, FOXO3, KLF15, and STAT3, which are key drivers of muscle catabolism and atrophy, as central mediators of the observed transcriptional program. Semantic similarity analysis further demonstrated a high concordance between WBI-induced and aging-associated biological processes. Collectively, these findings demonstrate that brain senescence is sufficient to drive sarcopenia-like transcriptomic remodeling in skeletal muscle, implicating central nervous system aging as an upstream regulator of peripheral muscle decline. This brain-muscle aging axis may contribute to frailty in individuals with accelerated brain aging and in cancer survivors exposed to cranial irradiation, highlighting brain senescence as a potential therapeutic target to mitigate systemic aging and skeletal muscle dysfunction.