TY - JOUR
T1 - Sex differences in muscle protein expression and DNA methylation in response to exercise training
AU - Landen, Shanie
AU - Jacques, Macsue
AU - Hiam, Danielle
AU - Alvarez-Romero, Javier
AU - Schittenhelm, Ralf B.
AU - Shah, Anup D.
AU - Huang, Cheng
AU - Steele, Joel R.
AU - Harvey, Nicholas R.
AU - Haupt, Larisa M.
AU - Griffiths, Lyn R.
AU - Ashton, Kevin J.
AU - Lamon, Séverine
AU - Voisin, Sarah
A2 - Eynon, Nir
N1 - Funding Information:
This work was supported by Nir Eynon’s National Health & Medical Research (NHMRC) Investigator Grant (APP1194159), and Sarah Voisin’s NHMRC Early Career Research Fellowship (APP11577321). The Gene SMART study was supported by the Australian Research Council (ARC) Discovery Projects (DP190103081, and DP200101830). This research was supported by Commonwealth Collaborative Research Network funding to Bond University CRN-AESS. Dr Nicholas Harvey was supported by a PhD stipend also provided by Bond University CRN-AESS. This research was also supported by infrastructure purchased with Australian Government EIF Super Science Funds as part of the Therapeutic Innovation Australia—Queensland Node project (LRG).
Publisher Copyright:
© 2023, Society for Women's Health Research and BioMed Central Ltd.
PY - 2023/12
Y1 - 2023/12
N2 - Background: Exercise training elicits changes in muscle physiology, epigenomics, transcriptomics, and proteomics, with males and females exhibiting differing physiological responses to exercise training. However, the molecular mechanisms contributing to the differing adaptations between the sexes are poorly understood. Methods: We performed a meta-analysis for sex differences in skeletal muscle DNA methylation following an endurance training intervention (Gene SMART cohort and E-MTAB-11282 cohort). We investigated for sex differences in the skeletal muscle proteome following an endurance training intervention (Gene SMART cohort). Lastly, we investigated whether the methylome and proteome are associated with baseline cardiorespiratory fitness (maximal oxygen consumption; VO2max) in a sex-specific manner. Results: Here, we investigated for the first time, DNA methylome and proteome sex differences in response to exercise training in human skeletal muscle (n = 78; 50 males, 28 females). We identified 92 DNA methylation sites (CpGs) associated with exercise training; however, no CpGs changed in a sex-dependent manner. In contrast, we identified 189 proteins that are differentially expressed between the sexes following training, with 82 proteins differentially expressed between the sexes at baseline. Proteins showing the most robust sex-specific response to exercise include SIRT3, MRPL41, and MBP. Irrespective of sex, cardiorespiratory fitness was associated with robust methylome changes (19,257 CpGs) and no proteomic changes. We did not observe sex differences in the association between cardiorespiratory fitness and the DNA methylome. Integrative multi-omic analysis identified sex-specific mitochondrial metabolism pathways associated with exercise responses. Lastly, exercise training and cardiorespiratory fitness shifted the DNA methylomes to be more similar between the sexes. Conclusions: We identified sex differences in protein expression changes, but not DNA methylation changes, following an endurance exercise training intervention; whereas we identified no sex differences in the DNA methylome or proteome response to lifelong training. Given the delicate interaction between sex and training as well as the limitations of the current study, more studies are required to elucidate whether there is a sex-specific training effect on the DNA methylome. We found that genes involved in mitochondrial metabolism pathways are differentially modulated between the sexes following endurance exercise training. These results shed light on sex differences in molecular adaptations to exercise training in skeletal muscle.
AB - Background: Exercise training elicits changes in muscle physiology, epigenomics, transcriptomics, and proteomics, with males and females exhibiting differing physiological responses to exercise training. However, the molecular mechanisms contributing to the differing adaptations between the sexes are poorly understood. Methods: We performed a meta-analysis for sex differences in skeletal muscle DNA methylation following an endurance training intervention (Gene SMART cohort and E-MTAB-11282 cohort). We investigated for sex differences in the skeletal muscle proteome following an endurance training intervention (Gene SMART cohort). Lastly, we investigated whether the methylome and proteome are associated with baseline cardiorespiratory fitness (maximal oxygen consumption; VO2max) in a sex-specific manner. Results: Here, we investigated for the first time, DNA methylome and proteome sex differences in response to exercise training in human skeletal muscle (n = 78; 50 males, 28 females). We identified 92 DNA methylation sites (CpGs) associated with exercise training; however, no CpGs changed in a sex-dependent manner. In contrast, we identified 189 proteins that are differentially expressed between the sexes following training, with 82 proteins differentially expressed between the sexes at baseline. Proteins showing the most robust sex-specific response to exercise include SIRT3, MRPL41, and MBP. Irrespective of sex, cardiorespiratory fitness was associated with robust methylome changes (19,257 CpGs) and no proteomic changes. We did not observe sex differences in the association between cardiorespiratory fitness and the DNA methylome. Integrative multi-omic analysis identified sex-specific mitochondrial metabolism pathways associated with exercise responses. Lastly, exercise training and cardiorespiratory fitness shifted the DNA methylomes to be more similar between the sexes. Conclusions: We identified sex differences in protein expression changes, but not DNA methylation changes, following an endurance exercise training intervention; whereas we identified no sex differences in the DNA methylome or proteome response to lifelong training. Given the delicate interaction between sex and training as well as the limitations of the current study, more studies are required to elucidate whether there is a sex-specific training effect on the DNA methylome. We found that genes involved in mitochondrial metabolism pathways are differentially modulated between the sexes following endurance exercise training. These results shed light on sex differences in molecular adaptations to exercise training in skeletal muscle.
KW - DNA methylation
KW - Epigenetics
KW - Exercise
KW - Proteome
KW - Sex differences
KW - Skeletal muscle
UR - http://www.scopus.com/inward/record.url?scp=85169763439&partnerID=8YFLogxK
U2 - 10.1186/s13293-023-00539-2
DO - 10.1186/s13293-023-00539-2
M3 - Article
C2 - 37670389
AN - SCOPUS:85169763439
SN - 2042-6410
VL - 14
JO - Biology of Sex Differences
JF - Biology of Sex Differences
IS - 1
M1 - 56
ER -