Epigenetic Modifications of the PGC-1α Promoter during Exercise Induced Expression in Mice

Lochmann, Timothy L.; Thomas, Ravindar R.; Bennett, James P.; Taylor, Shirley M.

doi:10.1371/journal.pone.0129647

Cited by 41 publications

(36 citation statements)

References 53 publications

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“…EPS altered mRNA level of Ccnd1 and Ppard , two genes respectively involved in muscle growth and metabolism and previously shown to be induced by muscle contraction (27, 28). In contrast, our EPS protocol failed to induce Ppargc1a mRNA expression although several studies including one from our group have reported that Ppargc1a expression is increased after a single bout of exercise (4, 25, 28, 29). The lack of response for Ppargc1a gene in our hands is likely due to the nature of the contraction protocol, as previous reports show Ppargc1a gene expression is induced by slow-type tetanic contraction (30).…”

Section: Discussioncontrasting

confidence: 62%

Muscle Contraction Induces Acute Hydroxymethylation of the Exercise-Responsive Gene Nr4a3

et al. 2016

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Exercise training triggers numerous positive adaptations through the regulation of genes controlling muscle structure and function. Epigenetic modifications, including DNA methylation, participate in transcriptional activation by allowing the recruitment of the transcription machinery to gene promoters. Exercise induces dynamic DNA demethylation at gene promoters; however, the contribution of the demethylation precursor hydroxymethylcytosine is unknown. Given the evanescent nature of hydroxymethylcytosine, a muscle contraction model that allows for the collection of samples that are repeatedly stimulated over time is required to determine whether contraction-induced demethylation is preceded by changes in the hydroxymethylcytosine level. Here, we established an acute skeletal muscle contraction model to mimic the effects of acute exercise on gene expression. We used this model to investigate the effect of muscle contraction on DNA demethylation and hydroxymethylation. First, we performed an acute exercise study in healthy humans to identify an exercise-responsive gene that we could study in culture. We identified the nuclear receptor subfamily 4 group A member 3 (Nr4a3) gene with the highest fold-expression increase after acute exercise. We then refined an electrical pulse stimulation (EPS) protocol that could induce expression of the Nr4a3 gene in C2C12 myotubes. Using targeted bisulfite sequencing, we found that in response to EPS, a region of the Nr4a3 promoter is rapidly demethylated at 60 min and re-methylated at 120 min. Of interest, hydroxymethylation of the differentially methylated region of Nr4a3 promoter after EPS was elevated immediately after EPS, with lowest levels reached at 60 min after EPS. In conclusion, we have established a cell culture-based protocol to mimic the acute transcriptional responses to exercise. Furthermore, we provide insight into the mechanism by which the exercise-responsive gene Nr4a3 is demethylated after muscle contraction.

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Section: Discussioncontrasting

confidence: 62%

Muscle Contraction Induces Acute Hydroxymethylation of the Exercise-Responsive Gene Nr4a3

et al. 2016

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“…More, recently 120 min of steady‐state exercise (60% Vo 2 peak) reportedly increased methylation in the promoter of fatty acid‐binding protein 3 (FABP3) after 4 h of recovery resulting in the impaired mRNA transcription (Lane et al ., ). Furthermore, suppression of DNA methylation was also associated with increased basal mRNA levels of the PGC‐1α promoter A after exercise but not the PGC‐1α promoter B where this was controlled by the methylation of lysine 4 on histone 3 (H3K4me3) (Lochmann et al ., ). With respect to chronic exercise, 6 months of supervised aerobic exercise 3 × 1 h per week (varied intensity) changed the methylation of several genes associated with metabolism (Nitert et al ., ).…”

Section: Epigenetics Underpins Programming and Gives Muscle An ‘Epi‐mmentioning

confidence: 97%

Does skeletal muscle have an ‘epi’‐memory? The role of epigenetics in nutritional programming, metabolic disease, aging and exercise

2016

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SummarySkeletal muscle mass, quality and adaptability are fundamental in promoting muscle performance, maintaining metabolic function and supporting longevity and healthspan. Skeletal muscle is programmable and can ‘remember’ early‐life metabolic stimuli affecting its function in adult life. In this review, the authors pose the question as to whether skeletal muscle has an ‘epi’‐memory? Following an initial encounter with an environmental stimulus, we discuss the underlying molecular and epigenetic mechanisms enabling skeletal muscle to adapt, should it re‐encounter the stimulus in later life. We also define skeletal muscle memory and outline the scientific literature contributing to this field. Furthermore, we review the evidence for early‐life nutrient stress and low birth weight in animals and human cohort studies, respectively, and discuss the underlying molecular mechanisms culminating in skeletal muscle dysfunction, metabolic disease and loss of skeletal muscle mass across the lifespan. We also summarize and discuss studies that isolate muscle stem cells from different environmental niches in vivo (physically active, diabetic, cachectic, aged) and how they reportedly remember this environment once isolated in vitro. Finally, we will outline the molecular and epigenetic mechanisms underlying skeletal muscle memory and review the epigenetic regulation of exercise‐induced skeletal muscle adaptation, highlighting exercise interventions as suitable models to investigate skeletal muscle memory in humans. We believe that understanding the ‘epi’‐memory of skeletal muscle will enable the next generation of targeted therapies to promote muscle growth and reduce muscle loss to enable healthy aging.

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“…Interestingly, the same exercise modality at a lower intensity (40% VO 2 max) had no effect on DNA methylation, suggesting that exercise intensity may be a critical factor in influencing DNA methylation. A recent study in mice has replicated some of these findings, showing that exercise reduced PGC1a promoter methylation, which was associated with increased basal transcription of this gene (Lochmann et al 2015). Another study has found that 120 min of cycling in healthy subjects (60% VO 2 max) increased methylation at the promoters of FABP3 and COX4L1, which was associated with decreased expression of these genes (Lane et al 2015).…”

Section: Skeletal Muscle Dna Methylation and Regulating Enzymes In Rementioning

confidence: 78%

Exercise and the Skeletal Muscle Epigenome

McGee

Walder

2017

Cold Spring Harb Perspect Med

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An acute bout of exercise is sufficient to induce changes in skeletal muscle gene expression that are ultimately responsible for the adaptive responses to exercise. Although much research has described the intracellular signaling responses to exercise that are linked to transcriptional regulation, the epigenetic mechanisms involved are only just emerging. This review will provide an overview of epigenetic mechanisms and what is known in the context of exercise. Additionally, we will explore potential interactions between metabolism during exercise and epigenetic regulation, which serves as a framework for potential areas for future research. Finally, we will consider emerging opportunities to pharmacologically manipulate epigenetic regulators and mechanisms to induce aspects of the skeletal muscle exercise adaptive response for therapeutic intervention in various disease states.

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Epigenetic Modifications of the PGC-1α Promoter during Exercise Induced Expression in Mice

Cited by 41 publications

References 53 publications

Muscle Contraction Induces Acute Hydroxymethylation of the Exercise-Responsive Gene Nr4a3

Muscle Contraction Induces Acute Hydroxymethylation of the Exercise-Responsive Gene Nr4a3

Does skeletal muscle have an ‘epi’‐memory? The role of epigenetics in nutritional programming, metabolic disease, aging and exercise

Exercise and the Skeletal Muscle Epigenome

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