Circadian Dysregulation in Aging Alters Senescence and Inflammatory Pathways in a Sex- and Time-of-Day-Dependent Manner.

Mar 23, 2026bioRxiv : the preprint server for biology

Aging disrupts daily body rhythms, changing cell aging and inflammation differently by sex and time of day

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Abstract

Aging disrupts circadian-regulated gene expression, particularly in pathways related to RNA splicing, ribosome biogenesis, and TOR signaling.

Circadian rhythm disruption is associated with aging and contributes to cellular senescence, a major factor in aging-related diseases.
Gene expression analysis in 6- and 24-month-old mice revealed that senescence-associated genes oscillate dynamically, influenced by sex and time of day.
Differential expression analysis indicated immune activation and metabolic changes that vary based on sex and temporal factors.
Increased transcriptional noise in aging was observed, particularly affecting circadian-regulated pathways.
Single-nucleus RNA sequencing identified two distinct cell populations with disrupted normal-expression relationships, one being senescent-like and the other profibrotic.
Key age-related circadian changes in fibroblasts mirrored those found in renal tissues, suggesting shared mechanisms across cell types.

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The circadian rhythm orchestrates gene expression and critical physiological processes but becomes disrupted with aging, contributing to disease. How this disruption interacts with cellular senescence-a key driver of aging pathology-remains poorly defined. We studied renal gene expression at four timepoints over 24hrs in 6- and 24-month-old genetically diverse UM-HET3 mice of both sexes and performed complementary analyses in synchronized fibroblasts sampled at seven timepoints. Aging dysregulated core clock relationships, including loss of the canonical anti-phase expression betweenand. Senescence-associated genes were not static but exhibited pronounced oscillations, with senescence phenotypes varying by sex and time of day. Differential expression analysis revealed immune activation, metabolic rewiring, and epigenetic changes that were sex- and time-dependent. Variance analysis uncovered increased transcriptional noise in aging, particularly in circadian-regulated pathways such as RNA splicing, ribosome biogenesis, and TOR signaling. Single-nucleus RNA-Seq identified two cell populations lacking the normal-expression relationship: one senescent-like and another profibrotic, revealing distinct cell states linked to circadian dysregulation. Fibroblasts recapitulated key age-related circadian changes seen in the kidneys, including phase shifts in mTOR and oxidative phosphorylation. Together, this work demonstrates that senescence phenotypes are dynamic, sex-specific, and time-of-day dependent, and introduces a new framework for detecting senescent cells based on circadian gene relationships. These findings underscore the need to integrate temporal context into aging research and therapeutic strategies. Bmal1Per2Bmal1Cdkn1a