scholarly article | Q13442814 |
review article | Q7318358 |
P50 | author | Xu Yan | Q51114701 |
Nir Eynon | Q51114709 | ||
Sarah Voisin | Q55743382 | ||
David Bishop | Q43198033 | ||
P2093 | author name string | D J Bishop | |
P2860 | cites work | A six months exercise intervention influences the genome-wide DNA methylation pattern in human adipose tissue | Q21563356 |
DNA methylation patterns and epigenetic memory | Q22065780 | ||
An acute bout of high-intensity interval training increases the nuclear abundance of PGC-1α and activates mitochondrial biogenesis in human skeletal muscle | Q50336512 | ||
PGC1α promoter methylation in blood at 5-7 years predicts adiposity from 9 to 14 years (EarlyBird 50). | Q51102461 | ||
Exercise and CaMK activation both increase the binding of MEF2A to the Glut4 promoter in skeletal muscle in vivo. | Q51583817 | ||
Conserved DNA methylation in Gadd45a(-/-) mice. | Q51811765 | ||
Recall of physical activity in the distant past: the 32-year follow-up of the Prospective Population Study of Women in Göteborg, Sweden. | Q51943888 | ||
Role of physical activity in modulating breast cancer risk as defined by APC and RASSF1A promoter hypermethylation in nonmalignant breast tissue. | Q55043220 | ||
Single and combined influence of ACE and ACTN3 genotypes on muscle phenotypes in octogenarians | Q57891226 | ||
Mitochondrial regulators of fatty acid metabolism reflect metabolic dysfunction in type 2 diabetes mellitus | Q58449812 | ||
Conversion of 5-methylcytosine to 5-hydroxymethylcytosine in mammalian DNA by MLL partner TET1 | Q24316558 | ||
Physical activity and global genomic DNA methylation in a cancer-free population | Q24594829 | ||
A decade of exploring the cancer epigenome - biological and translational implications | Q24614467 | ||
DNA demethylation dynamics | Q24629227 | ||
Establishing, maintaining and modifying DNA methylation patterns in plants and animals | Q24630397 | ||
Neuronal activity-induced Gadd45b promotes epigenetic DNA demethylation and adult neurogenesis | Q24651301 | ||
Epigenetic silencing of tumour suppressor gene p15 by its antisense RNA | Q24655224 | ||
Histone deacetylase degradation and MEF2 activation promote the formation of slow-twitch myofibers | Q24673210 | ||
Diet and lifestyle factor associations with CpG island methylator phenotype and BRAF mutations in colon cancer | Q28210081 | ||
Epigenetic reprogramming in mammalian development | Q28212171 | ||
Biologic and epigenetic impact of commuting to work by car or using public transportation: a case-control study | Q28383742 | ||
A genome-wide association study of hypertension and blood pressure in African Americans | Q28475715 | ||
The microRNA miR-696 regulates PGC-1{alpha} in mouse skeletal muscle in response to physical activity | Q28504595 | ||
Exercise impacts brain-derived neurotrophic factor plasticity by engaging mechanisms of epigenetic regulation | Q28579553 | ||
Environmental epigenomics and disease susceptibility | Q29547452 | ||
Cancer epigenetics: from mechanism to therapy | Q29614799 | ||
Epigenetics in cancer | Q29617139 | ||
GADD45A does not promote DNA demethylation | Q33325901 | ||
Exercise improves cognitive responses to psychological stress through enhancement of epigenetic mechanisms and gene expression in the dentate gyrus. | Q33404079 | ||
The effect of marathon on mRNA expression of anti-apoptotic and pro-apoptotic proteins and sirtuins family in male recreational long-distance runners | Q33576265 | ||
Gemcitabine functions epigenetically by inhibiting repair mediated DNA demethylation | Q33761140 | ||
Distinct alterations in chromatin organization of the two IGF-I promoters precede growth hormone-induced activation of IGF-I gene transcription | Q33780197 | ||
Analysis of DNA methylation in a three-generation family reveals widespread genetic influence on epigenetic regulation. | Q33996649 | ||
Molecular Signals of Epigenetic States | Q34146698 | ||
The ACE gene and human performance: 12 years on. | Q34187481 | ||
Acute exercise remodels promoter methylation in human skeletal muscle. | Q34260142 | ||
Physical exercise as an epigenetic modulator: Eustress, the "positive stress" as an effector of gene expression | Q34273078 | ||
Physical activity, biomarkers, and disease outcomes in cancer survivors: a systematic review | Q34273635 | ||
No effect of weight loss on LINE-1 methylation levels in peripheral blood leukocytes from postmenopausal overweight women | Q34280050 | ||
Cancer genetics and epigenetics: two sides of the same coin? | Q34287662 | ||
Physical activity and differential methylation of breast cancer genes assayed from saliva: a preliminary investigation | Q34305262 | ||
Epigenetics in sports. | Q34323245 | ||
Exercise: putting action into our epigenome | Q34380487 | ||
The ACTN3 R577X polymorphism across three groups of elite male European athletes | Q34391348 | ||
Regulation of human glutamate dehydrogenases: implications for glutamate, ammonia and energy metabolism in brain. | Q34464768 | ||
Role of alpha-actinin-3 in contractile properties of human single muscle fibers: a case series study in paraplegics | Q34474344 | ||
Age-related changes in the global DNA methylation profile of leukocytes are linked to nutrition but are not associated with the MTHFR C677T genotype or to functional capacities | Q34534159 | ||
DNA methyltransferase 1, cytosine methylation, and cytosine hydroxymethylation in mammalian mitochondria | Q34621407 | ||
DNMT1 maintains progenitor function in self-renewing somatic tissue | Q34632106 | ||
Methods of DNA methylation analysis | Q34654713 | ||
Physical exercise and mitochondrial function in human skeletal muscle | Q34768402 | ||
DNA methylation in cancer: too much, but also too little | Q34770545 | ||
Methylation of the calcium channel-related gene, CACNA2D3, is frequent and a poor prognostic factor in gastric cancer | Q34790336 | ||
Polymorphisms in DNA repair genes, recreational physical activity and breast cancer risk | Q34818604 | ||
Two common genetic variants near nuclear-encoded OXPHOS genes are associated with insulin secretion in vivo | Q34831919 | ||
DNA methylation status is inversely correlated with green tea intake and physical activity in gastric cancer patients | Q34930032 | ||
Randomized clinical trials and observational studies: guidelines for assessing respective strengths and limitations | Q34982587 | ||
Mismatch repair genes hMLH1 and hMSH2 and colorectal cancer: a HuGE review | Q34990750 | ||
Genomic predictors of the maximal O₂ uptake response to standardized exercise training programs | Q34994565 | ||
Environmental epigenetics | Q35097642 | ||
Interpretation of observational studies | Q35582653 | ||
Significant differences in global genomic DNA methylation by gender and race/ethnicity in peripheral blood | Q35592197 | ||
A transcriptional map of the impact of endurance exercise training on skeletal muscle phenotype | Q35658108 | ||
Transcriptional regulation of pyruvate dehydrogenase kinase 4 in skeletal muscle during and after exercise | Q35855916 | ||
Msx-1 and Msx-2 in mammary gland development | Q35858263 | ||
Epigenetic changes in response to tai chi practice: a pilot investigation of DNA methylation marks | Q36031457 | ||
On the presence and role of human gene-body DNA methylation. | Q36050706 | ||
The impact of metabolism on DNA methylation | Q36088929 | ||
White blood cell global methylation and IL-6 promoter methylation in association with diet and lifestyle risk factors in a cancer-free population | Q36100989 | ||
Impact of an exercise intervention on DNA methylation in skeletal muscle from first-degree relatives of patients with type 2 diabetes | Q36410632 | ||
Non-genomic transgenerational inheritance of disease risk | Q36709421 | ||
Constructing genomic maps of positive selection in humans: where do we go from here? | Q36825567 | ||
Epigenetic regulation of muscle phenotype and adaptation: a potential role in COPD muscle dysfunction | Q36850787 | ||
The influence of metabolic syndrome, physical activity and genotype on catechol-O-methyl transferase promoter-region methylation in schizophrenia | Q36874705 | ||
Recreational and household physical activity at different time points and DNA global methylation. | Q36941312 | ||
DNA demethylation in zebrafish involves the coupling of a deaminase, a glycosylase, and gadd45. | Q37068711 | ||
Functional DNA methylation differences between tissues, cell types, and across individuals discovered using the M&M algorithm | Q37138680 | ||
Epigenetics in hyperhomocysteinemic states. A special focus on uremia. | Q37401983 | ||
Epigenetic control of skeletal muscle fibre type | Q37719605 | ||
A gene for speed: the emerging role of alpha-actinin-3 in muscle metabolism | Q37779180 | ||
Genes and elite athletes: a roadmap for future research | Q37871720 | ||
Impact of physical activity and doping on epigenetic gene regulation | Q37889236 | ||
Active DNA demethylation by Gadd45 and DNA repair | Q37984958 | ||
PGC-1α: a master gene that is hard to master | Q38017137 | ||
Genes for elite power and sprint performance: ACTN3 leads the way. | Q38107422 | ||
Can we optimise the exercise training prescription to maximise improvements in mitochondria function and content? | Q38152885 | ||
Dynamic epigenetic responses to muscle contraction. | Q38196166 | ||
CaMK activation during exercise is required for histone hyperacetylation and MEF2A binding at the MEF2 site on the Glut4 gene | Q38289059 | ||
High responders to resistance exercise training demonstrate differential regulation of skeletal muscle microRNA expression. | Q38504538 | ||
Neuronal activity modifies the DNA methylation landscape in the adult brain | Q38594616 | ||
Genetic polymorphisms of the enzymes involved in DNA methylation and synthesis in elite athletes. | Q39524601 | ||
Transient cyclical methylation of promoter DNA. | Q40005345 | ||
Cyclical DNA methylation of a transcriptionally active promoter | Q40005351 | ||
Pyruvate dehydrogenase kinase-4 deficiency lowers blood glucose and improves glucose tolerance in diet-induced obese mice. | Q41328950 | ||
Insulin resistance induced by physical inactivity is associated with multiple transcriptional changes in skeletal muscle in young men. | Q42925764 | ||
Muscle specific microRNAs are regulated by endurance exercise in human skeletal muscle | Q42931955 | ||
Exercise-induced histone modifications in human skeletal muscle | Q43250085 | ||
Epigenetic modification of liver mitochondrial DNA is associated with histological severity of nonalcoholic fatty liver disease | Q43761846 | ||
The role of DNA methylation in setting up chromatin structure during development | Q44436568 | ||
Association of the MTHFR 1298A>C (rs1801131) polymorphism with speed and strength sports in Russian and Polish athletes | Q44579446 | ||
ACTN3 R577X polymorphism and Israeli top-level athletes. | Q45959474 | ||
Familial aggregation of exercise heart rate and blood pressure in response to 20 weeks of endurance training: the HERITAGE family study | Q46747594 | ||
The relationship of testosterone and AR CAG repeat genotype with knee extensor muscle function of young and older men. | Q47932253 | ||
P433 | issue | 1 | |
P921 | main subject | DNA methylation | Q874745 |
P304 | page(s) | 39-59 | |
P577 | publication date | 2014-11-19 | |
P1433 | published in | Acta Physiologica | Q2662816 |
P1476 | title | Exercise training and DNA methylation in humans | |
P478 | volume | 213 |
Q52851862 | 15.5 days to decision on your manuscript! |
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Q98292340 | Age-dependent stress response DNA demethylation and gene upregulation accompany nuclear and skeletal muscle remodeling following acute resistance-type exercise in rats |
Q89750464 | An epigenetic clock for human skeletal muscle |
Q99616864 | Association of ABCG1 gene methylation and its dynamic change status with incident type 2 diabetes mellitus: the Rural Chinese Cohort Study |
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