Aerobic exercise training resets the human skeletal muscle methylome 10 years after breast cancer treatment and survival

Cancer survivors suffer impairments in skeletal muscle in terms of reduced mass and function. Interestingly, human skeletal muscle possesses an epigenetic memory of earlier stimuli, such as exercise. Long‐term retention of epigenetic changes in skeletal muscle following cancer survival and/or exerci...

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Published in:The FASEB journal 2023-01, Vol.37 (1), p.e22720-n/a
Main Authors: Gorski, Piotr P., Raastad, Truls, Ullrich, Max, Turner, Daniel C., Hallén, Jostein, Savari, Sebastian Imre, Nilsen, Tormod S., Sharples, Adam P.
Format: Article
Language:English
Subjects:
Breast Neoplasms - genetics
Breast Neoplasms - therapy
CpG Islands - genetics
DNA Methylation
Epigenesis, Genetic
Epigenome
Exercise - physiology
Female
Humans
Immediate-Early Proteins - genetics
Muscle, Skeletal - physiology
Tumor Suppressor Proteins - genetics
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Summary:Cancer survivors suffer impairments in skeletal muscle in terms of reduced mass and function. Interestingly, human skeletal muscle possesses an epigenetic memory of earlier stimuli, such as exercise. Long‐term retention of epigenetic changes in skeletal muscle following cancer survival and/or exercise training has not yet been studied. We, therefore, investigated genome‐wide DNA methylation (methylome) in skeletal muscle following a 5‐month, 3/week aerobic‐training intervention in breast cancer survivors 10–14 years after diagnosis and treatment. These results were compared to breast cancer survivors who remained untrained and to age‐matched controls with no history of cancer, who undertook the same training intervention. Skeletal muscle biopsies were obtained from 23 females before(pre) and after(post) the 5‐month training period. InfiniumEPIC 850K DNA methylation arrays and RT‐PCR for gene expression were performed. The breast cancer survivors displayed a significant retention of increased DNA methylation (i.e., hypermethylation) at a larger number of differentially methylated positions (DMPs) compared with healthy age‐matched controls pre training. Training in cancer survivors led to an exaggerated number of DMPs with a hypermethylated signature occurring at non‐regulatory regions compared with training in healthy age‐matched controls. However, the opposite occurred in important gene regulatory regions, where training in cancer survivors elicited a considerable reduction in methylation (i.e., hypomethylation) in 99% of the DMPs located in CpG islands within promoter regions. Importantly, training was able to reverse the hypermethylation identified in cancer survivors back toward a hypomethylated signature that was observed pre training in healthy age‐matched controls at 300 (out of 881) of these island/promoter‐associated CpGs. Pathway enrichment analysis identified training in cancer survivors evoked a predominantly hypomethylated signature in pathways associated with cell cycle, DNA replication/repair, transcription, translation, mTOR signaling, and the proteosome. Differentially methylated region (DMR) analysis also identified genes: BAG1, BTG2, CHP1, KIFC1, MKL2, MTR, PEX11B, POLD2, S100A6, SNORD104, and SPG7 as hypermethylated in breast cancer survivors, with training reversing these CpG island/promoter‐associated DMRs toward a hypomethylated signature. Training also elicited a largely different epigenetic response in healthy individuals than that
ISSN:0892-6638
1530-6860
DOI:10.1096/fj.202201510RR