Endurance training promotes chromatin closure and timely repression of the post-exercise immediate early stress response

Endurance training promotes chromatin closure and timely repression of the post-exercise immediate early stress response

Objectives: Endurance training is known to elicit numerous changes in skeletal muscle to enhance performance and function. Many of these adaptations are controlled by the modulation of transcriptional programs in myonuclei. While previous studies have explored alterations in DNA methylation and hist...

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Bibliographic Details
Main Authors: Laura M. de Smalen, Volkan Adak, Aurel B. Leuchtmann, Konstantin Schneider-Heieck, Stefan A. Steurer, Christoph Handschin
Format: Article
Language:English
Published: Elsevier 2025-09-01
Series:Molecular Metabolism
Subjects:
Exercise
Endurance training
Skeletal muscle plasticity
Chromatin accessibility
Immediate early genes
Online Access:http://www.sciencedirect.com/science/article/pii/S2212877825001139
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Summary:Objectives: Endurance training is known to elicit numerous changes in skeletal muscle to enhance performance and function. Many of these adaptations are controlled by the modulation of transcriptional programs in myonuclei. While previous studies have explored alterations in DNA methylation and histone modifications in response to exercise, the specific changes in chromatin restructuring and accessibility, a prerequisite for transcription, are still poorly understood. Methods: A multi-omics analysis was performed: ATAC-sequencing was used to map chromatin accessibility in myonuclei isolated from endurance-trained and untrained mice at multiple time points (0 h, 6 h, and 72 h) post-exercise. Gene expression was assessed via RNA-sequencing, and motif activity analysis identified regulatory factors involved in exercise-induced chromatin remodeling and transcriptomic response. Results: Endurance training amplified rapid chromatin closing immediately after exercise, with trained muscle exhibiting a more pronounced loss of chromatin accessibility at 0 h and 6 h post-exercise compared to untrained muscle. These chromatin accessibility changes persisted longer in trained muscle, with significant retention until 72 h post-exercise. Immediate early transcription factors, such as Fos and Jun, showed a training state-dependent shift in activation dynamics. Similarly, specific modulation of genes involved in metabolism, insulin response and angiogenesis was observed. Conclusions: Endurance training triggers rapid and persistent chromatin remodeling in muscle, contributing to the transcriptional response to exercise. Our findings suggest that training induces long-lasting epigenetic changes, potentially underpinning muscle memory and improved physiological resilience. These new insights into the molecular mechanisms of muscle adaptation help to understand the training response, and might become relevant in disease prevention.
ISSN:2212-8778

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