Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-23T21:23:12.213Z Has data issue: false hasContentIssue false

The integration of epigenetics and genetics in nutrition research for CVD risk factors

Published online by Cambridge University Press:  06 December 2016

Yiyi Ma
Affiliation:
Department of Medicine, Biomedical Genetics, Boston University, Boston, MA, USA Jean Mayer USDA Human Nutrition Research Center on Aging at Tufts University, Boston, MA, USA
Jose M. Ordovas*
Affiliation:
Jean Mayer USDA Human Nutrition Research Center on Aging at Tufts University, Boston, MA, USA Department of Cardiovascular Epidemiology and Population Genetics, Centro Nacional de Investigaciones Cardiovasculares, Madrid, Spain IMDEA Alimentación, Madrid, Spain
*
*Corresponding author: J. M. Ordovás, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

There is increasing evidence documenting gene-by-environment (G × E) interactions for CVD related traits. However, the underlying mechanisms are still unclear. DNA methylation may represent one of such potential mechanisms. The objective of this review paper is to summarise the current evidence supporting the interplay among DNA methylation, genetic variants, and environmental factors, specifically (1) the association between SNP and DNA methylation; (2) the role that DNA methylation plays in G × E interactions. The current evidence supports the notion that genotype-dependent methylation may account, in part, for the mechanisms underlying observed G × E interactions in loci such as APOE, IL6 and ATP-binding cassette A1. However, these findings should be validated using intervention studies with high level of scientific evidence. The ultimate goal is to apply the knowledge and the technology generated by this research towards genetically based strategies for the development of personalised nutrition and medicine.

Type
Conference on ‘New technology in nutrition research and practice’
Copyright
Copyright © The Authors 2016 

CVD is the leading cause of total global mortality. The WHO estimates that 17·3 million people died from CVD in 2008, representing 30 % of all global deaths. In the USA alone, the overall rate of death attributed to CVD was 235·5 per 100 000 based on 2010 data( Reference Go, Mozaffarian and Roger 1 ). Moreover, CVD are projected to remain the single leading cause of death worldwide.

With the goal to prevent and cure CVD, numerous risk factors have been identified, including dyslipidaemia, inflammation, obesity, hypertension, smoking, age and diabetes( Reference Grundy, Pasternak and Greenland 2 ). Dyslipidaemia refers to high concentrations of TAG, total cholesterol and LDL cholesterol and low concentration of HDL cholesterol. According to the American Heart Association( Reference Roger, Go and Lloyd-Jones 3 ), the prevalence of adults having high TAG (>150 mg/dl), high total cholesterol (≥200 mg/dl), high LDL-cholesterol (≥130 mg/dl), and low HDL-cholesterol (≤40 mg/dl) is 33, 44·4, 31·9 and 18·9 %, respectively. Also, inflammation is part of the complex biological response to harmful stimuli, which is common to a number of chronic diseases. However, for the most part, both dyslipidaemia and inflammation are preventable or reversible by having a healthy lifestyle.

Of the factors that define a healthy lifestyle, diet is one of the most important components. Specifically, dietary fatty acids (FA) are associated with risk factors for CVD. For example, although it is still under debate, unsaturated FA tend to increase HDL-cholesterol( Reference Hunter, Zhang and Kris-Etherton 4 ), reduce TAG( Reference Lopez-Alvarenga, Ebbesson and Ebbesson 5 ), and decrease IL-6( Reference Masson and Mensink 6 ) compared with SFA. Although MUFA and PUFA differ in the magnitude of these beneficial effects( Reference Bos, de Vries and Feskens 7 ), anti-atherosclerosis effect has been demonstrated for n-3 not n-6 PUFA( Reference Hansen, Grimsgaard and Nilsen 8 Reference Lopez-Garcia, Schulze and Manson 18 ). In addition, individuals exhibit different physiological responses to dietary FA, reflecting, in part, the contributions of genetic variability( Reference Schaefer, Lamon-Fava and Ausman 19 ).

The role of genetic factors in contributing to these inter-individual differences in lipid responses to dietary FA has been widely studied. Our group has found that the association between dietary intake of total fat and plasma HDL-cholesterol was modified by a genetic variant located within the hepatic lipase gene (LIPC)( Reference Ordovas, Corella and Demissie 20 ), and that the association between dietary PUFA intake and plasma fasting TAG is modified by the genetic variants located within APOA5 gene( Reference Lai, Corella and Demissie 21 ). The effect of PUFA on HDL may differ according to different genotypes of several genes such as APOA5, APOA1IL6, NF-κ-light-chain enhancer of activated B cells, TNF-α ( Reference Ordovas, Corella and Cupples 22 Reference Fontaine-Bisson, Wolever and Chiasson 25 ). In addition, there is also a genetically based difference in TAG response to n-3 PUFA( Reference Lindi, Schwab and Louheranta 26 , Reference Tai, Corella and Demissie 27 ). As a result of wide availability of new genetic technologies such as genome-wide association studies and next generation sequencing, an enriched catalogue of common or rare SNP has been formulated. However, the variation explained by all these genetic variants only account for <20 %, indicating the existence of other sources of variability, such as epigenetic mechanisms.

Epigenetics has become a research area of intense interest and growth. The definition of epigenetics underwent a series of changes as biological knowledge expanded. In 1940, epigenetics was first defined as ‘… the interactions of genes with their environment which bring the phenotype into being…’ by developmental biologists( Reference Waddington 28 ). In the 1990s, epigenetics was described as the study of changes in gene expression, which were not a result of changes in the DNA sequence( Reference Wolffe and Matzke 29 ). Recently, inspired by genome-wide technologies, a new term epigenomics has been coined, targeting the study of all factors contributing to changes in genome-wide chromatin structure including DNA methylation, histone modification and chromatin remodelling( Reference Portela and Esteller 30 ).

DNA methylation is the best-studied epigenetic mechanism and involves the addition of a methyl group directly onto DNA residues such as cytosine and adenine( Reference Cheng 31 ) and the C5-methylcytosine modification is the most common in eukaryotes. DNA methylation can occur in different regions of the genome such as repetitive sequences, gene body, promoter-related CpG island and CpG island shore, which are located up to 2 kb upstream of the CpG island( Reference Portela and Esteller 30 ). DNA methylation patterns in different regions present different functions. For example, gene silencing is correlated with hypermethylation in promoter regions rather than in the gene body( Reference Hellman and Chess 32 ). Also, cancer and ageing are correlated with hypomethylation of repetitive elements, while this is not the case for methylation of specific genes. Considering the different functionalities of DNA methylation in different regions, studies of DNA methylation occurring in specific sites of specific genes could provide more interpretable and meaningful explanations.

Similar to all the other epigenetic mechanisms, DNA methylation may act as a biomarker of the effect of environmental factors on the genome. A wide array of factors have been identified to affect DNA methylation patterns, including ageing( Reference Fraga, Ballestar and Paz 33 , Reference Wong, Caspi and Williams 34 ), dietary FA( Reference Devlin, Singh and Wade 35 Reference Ceccarelli, Racanicchi and Martelli 37 ), malnutrition( Reference Waterland, Kellermayer and Laritsky 38 Reference Tobi, Lumey and Talens 40 ), dietary protein( Reference Sandovici, Smith and Nitert 41 , Reference Lillycrop, Phillips and Jackson 42 ), methyl-donors( Reference Hoyo, Murtha and Schildkraut 43 Reference Waterland and Jirtle 45 ), chemical pollutants( Reference Baccarelli, Wright and Bollati 46 Reference Langevin, Houseman and Christensen 48 ), sun exposure( Reference Gronniger, Weber and Heil 49 ) and smoking( Reference Breitling, Yang and Korn 50 , Reference Belinsky, Palmisano and Gilliland 51 ). The connection of ageing with DNA methylation was first observed in the candidate tumour suppressor genes, of which the methylation is increased with age, leading to gene silencing( Reference Ahuja, Li and Mohan 52 ). Later, it was reported that the ageing effect on DNA methylation is a prevalent phenomenon across the whole genome based on studies with monozygotic and dizygotic twins, which showed that the variation in DNA methylation increases significantly with age( Reference Fraga, Ballestar and Paz 33 , Reference Wong, Caspi and Williams 34 ). Also dietary FA were suggested to regulate DNA methylation patterns. The intervention of a high-fat diet was found to increase the DNA methylation of a metabolically related gene, PPARγ, coactivator 1α (PPARGC1A); however, after the intervention was withdrawn, DNA methylation of PPARGC1A returned back to its baseline level( Reference Brons, Jacobsen and Nilsson 53 ). The methylation of this gene was also affected by palmitic acid and oleic acid( Reference Barres, Osler and Yan 36 ). Arachidonic acid and DHA were shown to affect DNA methylation of FA desaturase 2 in mice liver( Reference Devlin, Singh and Wade 35 ). In addition, EPA was found to have a demethylation effect on the tumour suppressor gene( Reference Ceccarelli, Racanicchi and Martelli 37 ).

Besides the effects of environmental factors, DNA methylation has been associated with different phenotypes. For instance, DNA methylation has been proposed as one mechanism of atherosclerosis( Reference Dong, Yoon and Goldschmidt-Clermont 54 ). In ApoE knockout mice, DNA methylation changes were shown to precede any histological sign of atherosclerosis( Reference Lund, Andersson and Lauria 55 ). In addition, the same study also found associations between global DNA hypermethylation and dyslipidaemia, characterised by the atherogenic lipoproteins. An in vitro oligonucleotide-binding assay found that a CG-rich 17-nucleotide sequence binds ApoA1 ( Reference Panin, Tuzikov and Gimautdinova 56 ), suggesting a relationship between lipoproteins and DNA methylation target sites, CpG dinucleotides. Besides affecting lipid concentrations, DNA methylation is also involved in inflammation. IL-6 is an acute phase protein induced during inflammation that functions as an inducer of differentiation of inflammatory helper T cells( Reference Veldhoen, Hocking and Atkins 57 , Reference Bettelli, Carrier and Gao 58 ). DNA methylation has been identified as one mechanism of transcription regulation of IL6. For example, methylation of the promoter region in IL6 is negatively correlated with gene expression( Reference Nile, Read and Akil 59 ) in peripheral blood mononuclear cells and the DNA methyltransferase inhibitor 5-aza-2′-deoxycytidine induces IL6 transcription( Reference Dandrea, Donadelli and Costanzo 60 ) in cancer cells. This silencing of IL6 expression may be due to the binding of methyl-CpG-binding protein 2 to the hypothetical binding sites in IL6 gene, which is close to its transcription start site.

The significance of this knowledge relates to its eventual translation into public health. The traditional concept of ‘one size fits all’ is limited, and the study of epigenetics will facilitate knowledge to further the development of personalised medical care. In this case, it is necessary to generate a more complete understanding of both genetic and epigenetic mechanisms contributing to the substantial inter-individual variations of response to environmental challenges. Moreover, we will also expand our knowledge of the molecular mechanism of gene–environment interaction and provide more solid evidence to promote new dietary guidelines.

Epigenetics and DNA methylation

Overview of epigenetics

Epigenetics acts as the cross-talk between the genome and environment, encompassing three major mechanisms: DNA methylation, histone modification, and chromatin remodelling. DNA methylation involves adding a methyl group onto a DNA nucleotide such as cytosine and adenine( Reference Cheng 31 ). With respect to histone modifications, a wide array of modifications are introduced to the histone tails, including methylation, acetylation, phosphorylation, ubiquitylation, sumoylation, ADP ribosylation, deamination, proline isomerisation, crotonylation, propionylation, butyrylation, formylation, hydroxylation and O-GlcNAcylation( Reference Dawson and Kouzarides 61 ). In terms of the chromatin remodelling mechanism, ATP-dependent enzymes remodel and control chromatin structure and assembly to make it become active or inactive to the extrinsic stimulus( Reference Ho and Crabtree 62 ). These mechanisms play a critical role in development.

DNA methylation and DNA sequence

DNA methylation, CpG dinucleotides, CpG islands

In mammalian cells, most DNA methylation occurs on CpG dinucleotides( Reference Lister, Pelizzola and Dowen 63 ). Regions enriched in CpG dinucleotides are known as CpG islands. However, the definitions of CpG islands have been evolving. In 1987, Gardiner-Garden and Frommer( Reference Gardiner-Garden and Frommer 64 ) defined CpG island as ‘a stretch of DNA sequence where moving average of % G + C was >50, and the moving average of ratio of the observed to expected CpG was greater than 0·6.’ These calculations are based on a 100 bp window and sliding across the sequence at 1 bp intervals. However, in regions rich in repetitive elements, this definition results in an overestimation of its presence. Therefore, Takai and Jones set up more stringent criteria for CpG islands, including % G + C>55, ratio of observed to expected CpG greater than 0·65 and sequence length being ≥500 bp. With Takai and Jones’ criteria, a web page service algorithm CpGIS was developed( Reference Takai and Jones 65 ). Furthermore, Ponger and Mouchiroud( Reference Ponger and Mouchiroud 66 ) extended their criteria to estimate the transcription start sites associated CpG islands with the algorithm CpGProD. However, both criteria are subjective and computationally inefficient for the analysis of the genome-wide DNA sequences, so a new definition, named CpGcluster( Reference Hackenberg, Previti and Luque-Escamilla 67 ), was proposed. This algorithm is based on the distance between two consecutive CpG and uses an integer arithmetic algorithm, which makes it fast and computationally efficient compared to previous methods. However, it has low sensitivity. Recently, a new algorithm CpG_MI( Reference Su, Zhang and Lv 68 ) was developed to take into account more variability of the test such as different locations of CpG dinucleotide among different CpG islands. With the growing availability of the experimental results of DNA methylation, the prediction of DNA methylation based on machine learning approach is possible. More specifically speaking, EpiGRAPH( Reference Bock, Halachev and Buch 69 ) algorithm for prediction of DNA methylation was trained by the wet-lab experiments data, and then this algorithm could be used to predict the methylation probability of another stretch of DNA sequence.

DNA methylation and genetic variants

It has been shown that proximal sequence elements are both necessary and sufficient for regulating DNA methylation( Reference Lienert, Wirbelauer and Som 70 ). Moreover, SNP can regulate DNA methylation( Reference Wang, Ogawa and Wood 71 Reference Kerkel, Spadola and Yuan 77 ). For example, the C allele of a SNP located within the promoter region of matrix metalloproteinase 1 was shown to have significantly higher DNA methylation status than the corresponding T allele( Reference Wang, Ogawa and Wood 71 ). Also, the G allele of one SNP located within the potassium-chloride co-transporter 3 (KCC3, SLC12A6) was found to be methylated at the adjacent C nucleotide( Reference Moser, Ekawardhani and Kumsta 72 ).

Systematic analyses of the whole human genome have identified an array of such genetic variants having regulatory effects on DNA methylation patterns, indicating that genetic regulation on DNA methylation is prevalent across the whole genome. For instance, a genomic survey using methylation-sensitive SNP analysis based on a 50 and 250 K SNP genotyping platform showed that sixteen SNP-tagged loci were confirmed to have allele-specific DNA methylation events( Reference Kerkel, Spadola and Yuan 77 ). Also, in brain samples, approximately 10 % of the CpG sites included in the analysis were found to be affected by the genotypes of the SNP in cis-position, while 0·1 % of the analysed CpG sites were regulated by the genotypes of the SNP in the trans-position( Reference Zhang, Cheng and Badner 74 ). Furthermore, it was suggested by studies with sixteen human pluripotent and adult cell lines that approximately one-third (23–37 %) heterozygous SNP in the human genome may regulate DNA methylation patterns( Reference Shoemaker, Deng and Wang 73 ), and a big proportion of the observed loci with allele-specific DNA methylation events (38–88 %) is dependent on the allele status of CpG-related SNP, a type of SNP with one allele to disrupt and the other allele to create CpG dinucleotides( Reference Shoemaker, Deng and Wang 73 ). Finally, the effect of genetic variants outweighed the influence of imprinting on DNA methylation, because it was shown that the number of methylation loci affected by genetic variants were way more than those loci influenced by the sex of parent of origin( Reference Gertz, Varley and Reddy 75 ) and there is convincing evidence of the interesting interdependence between genetics and epigenetics underlying diversity in the human genome.( Reference Hellman and Chess 78 )

DNA methylation and gene function

DNA methylation has different genetic functions mostly depending on location. For example, DNA methylation within the promoter region is more likely to regulate gene transcription( Reference Portela and Esteller 30 , Reference Eden and Cedar 79 ), while DNA methylations within the gene body tend to modify the alternative promoters and splicing events( Reference Maunakea, Chepelev and Cui 80 Reference Anastasiadou, Malousi and Maglaveras 84 ).

DNA methylation within promoter regions and gene transcription

The negative correlation between DNA methylation and gene transcription is common to most genetic regions across the whole genome with rare exceptions( Reference Eden and Cedar 79 , Reference Razin and Cedar 85 ). The first experiment indicating the transcription-regulatory effects of DNA methylation was conducted by McGhee and Ginder( Reference McGhee and Ginder 86 ). Since then, a large body of evidence has accumulated supporting an inverse correlation between DNA methylation and gene transcription for most genes, including but not limited to house-keeping genes( Reference Stein, Sciaky-Gallili and Razin 87 ), genes located on the inactive X chromosome( Reference Toniolo, D'Urso and Martini 88 Reference Wolf, Dintzis and Toniolo 90 ), imprinted genes( Reference Kerkel, Spadola and Yuan 77 , Reference Orozco, Rubbi and Martin 91 ), tumour suppressor genes or oncogenes( Reference Yamada, Nishida and Tsutsumida 92 Reference Harada, Toyooka and Maitra 94 ), cellular differentiation and development-related genes( Reference Lu, Wang and Chen 95 Reference Nishino, Hattori and Tanaka 98 ), metabolic genes( Reference Devlin, Singh and Wade 35 , Reference Brons, Jacobsen and Nilsson 53 , Reference Laker, Lillard and Okutsu 99 Reference Ling, Del Guerra and Lupi 101 ) and inflammation-related genes( Reference Nile, Read and Akil 59 , Reference Tekpli, Landvik and Anmarkud 102 Reference El Gazzar, Yoza and Hu 105 ). However, in some instances, DNA methylation has been positively correlated with gene expression( Reference Bell and Felsenfeld 106 Reference Bahar Halpern, Vana and Walker 110 ). Most of such transcriptional regulation effects were related to DNA methylation within promoter regions( Reference Portela and Esteller 30 ) by direct blocking the binding of transcriptional activators or indirect recruitment of methyl-binding proteins and co-repressor complexes to facilitate the formation of heterochromatin in a cooperative way( Reference Klose and Bird 111 ).

DNA methylation within gene bodies and alternative promoter and splicing events

DNA methylation is also found on CpG sites located within gene bodies( Reference Maunakea, Nagarajan and Bilenky 82 , Reference Deaton, Webb and Kerr 112 Reference Liang, Song and Ghosh 114 ), suggesting a potential genetic function besides gene transcription. By comparing differential DNA methylation patterns on a genome-wide scale across different tissues (brain, heart, liver and testis) and different developmental stages of mice, approximately 16 % of the identified tissue differential methylation regions or developmental stage differential methylation regions were located within intragenic regions( Reference Liang, Song and Ghosh 114 ). Also, it was found that the majority of methylated CpG sites were located within gene bodies( Reference Maunakea, Nagarajan and Bilenky 82 , Reference Deaton, Webb and Kerr 112 , Reference Illingworth, Kerr and Desousa 113 , Reference Rauch, Wu and Zhong 115 ). According to analysis with human normal tissues (whole blood, monocyte, granulocyte, skeletal muscle, spleen and brain), 15·4 % of CpG islands located within the gene bodies were found to be methylated, which is higher than the proportion of methylated CpG islands within 5′ promoter region (7·8 %) and the whole gene region (10·6 %)( Reference Illingworth, Kerr and Desousa 113 ). Using human brain tissue, Maunakea et al. ( Reference Maunakea, Nagarajan and Bilenky 82 ) generated high-resolution methylome maps with dense coverage of 24·7 million of the 28 million CpG sites across the whole genome. They found that 34 % of all intragenic CpG islands were methylated, whereas only 2 % of the CpG islands located within the 5′ promoter regions were methylated, so they concluded that ‘DNA methylation may serve a broader role in intragenic compared with 5′ promoter CpG islands in the human brain’. Again, the altered DNA methylation in the immune system was shown to occur predominantly at CpG islands within gene bodies based on the analysis with both mouse cells within haematopoietic lineage( Reference Deaton, Webb and Kerr 112 ) and human B cells( Reference Rauch, Wu and Zhong 115 ).

The methylation within gene bodies may be related to alternative promoters( Reference Maunakea, Nagarajan and Bilenky 82 ) and alternative splicing events( Reference Maunakea, Chepelev and Cui 80 , Reference Gelfman and Ast 81 , Reference Shukla, Kavak and Gregory 83 , Reference Anastasiadou, Malousi and Maglaveras 84 ). Based on methylome maps of human brain tissues, differentially methylated intragenic CpG islands may act as promoters, and novel transcripts have been found to be initiated from these intragenic promoters, indicating that intragenic methylation functions to regulate cell context-specific alternative promoters in gene bodies( Reference Maunakea, Nagarajan and Bilenky 82 ). With a computational analysis of human chromosome 6, 20 and 22 based on datasets from the Human Epigenome Project and the Human Genome Project, hypermethylated CpG sites were found to be prevalent in alternatively spliced sites, and the frequency of methylation increases in loci harbouring multiple putative exonic splicing enhancers( Reference Anastasiadou, Malousi and Maglaveras 84 ). According to the analysis of data from RNA-seq experiments and methylome data with single nucleotide resolution of human cell lines, DNA methylation was found to be enriched in included alternatively spliced exons, and inhibition of DNA methylation lead to aberrant splicing of alternatively spliced exons. Further, they found that the alternative splicing may be because of the alternative definitions of exons via recruitment of methylated CpG site-binding protein 2 to the methylated CpG sites( Reference Maunakea, Chepelev and Cui 80 ). Another potential mechanism for the regulation of DNA methylation on alternative splicing events may be the fact that DNA methylation patterns affect chromatin structure( Reference Gelfman and Ast 81 ). Finally, a DNA methylation related protein, CCCTC-binding factor, was shown to promote alternative splicing events on a genome-wide scale, providing potential links between DNA methylation and alternative splicing events( Reference Shukla, Kavak and Gregory 83 ).

DNA methylation and environmental factors

DNA methylation and ageing

DNA methylation is affected by ageing partially because of its intimate relationship with development. DNA methylation patterns change during each stage of development( Reference Cedar and Bergman 116 ). Before implantation, almost all DNA methylation becomes erased except for those imprinting regions. During implantation, the entire genome gets methylated except for the CpG islands. After implantation, pluripotency genes are de novo methylated and tissue-specific genes are demethylated in the cell types for their expression.

The correlations between ageing and DNA methylation were also suggested by in vitro studies. For example, compared to immortal cell lines, normal diploid fibroblasts were found to have a dramatic decrease in their 5-methylcytosine contents during their growth in culture( Reference Wilson and Jones 117 ). Furthermore, the observation that the decrease rate in mouse primary diploid fibroblasts was faster than in hamsters and human subjects and the fact that mouse has the shortest lifespan suggested that the rate of loss of 5-methylcytosine is positively correlated with growth potential. Also, the treatment of human diploid fibroblasts with DNA methylation inhibitors, azacytidine and azadeoxycytidine, were shown to inhibit the initial cellular growth( Reference Holliday 118 ).

Recently, epidemiological analyses have indicated the potential relationships between ageing and DNA methylation patterns. A cross-sectional study with monozygotic twins( Reference Fraga, Ballestar and Paz 33 ) found that younger twins have significantly lower levels of 5-methylated cytosines than older twins, and that the variance of DNA methylation of the older twins was significantly greater than that of the younger twins. The observed differences in DNA methylation were consistent with the findings with gene expression by showing that the 50-year-old twins had dramatically different expression profiles while the 3-year-old twins had almost identical ones. The observed discordance of DNA methylation with age was consistent across different tissues within the analysis, including lymphocytes, epithelial mouth cells, intra-abdominal fat and skeletal muscle biopsies. Later, another study with thirty-four male monozygotic twins with age ranging from 21 to 55 years identified eighty-eight sites located within or near eighty genes of which DNA methylation patterns were significantly correlated with age( Reference Bocklandt, Lin and Sehl 119 ). Three genes from that list of eighty genes were further validated and replicated with the analysis of their correlations with age in a population-based sample of thirty-one males and twenty-nine females with age ranging from 18 to 70 years, which are Edar-associated death domain, target of myb1 (chicken)-like 1 and neuronal pentraxin II. Interestingly, all of these three genes have been reported to be associated with a wide array of age-related phenotypes, such as wound healing( Reference Langton, Herrick and Headon 120 ), Parkinson disease( Reference Moran, Hickey and Michael 121 ), cancer( Reference Park, Ryu and Lee 122 , Reference Qi, Li and Zhao 123 ), and loss of teeth, hair and sweat glands( Reference Yan, Zhang and Brady 124 ). Also, a longitudinal study found that DNA methylation differs by age because methylation patterns of candidate genetic loci, such as the dopamine receptor 4 gene, the serotonin transporter gene, and the X-linked monoamine oxidase A gene, were shown to change during the period when these children grew from age 5 to 10 years( Reference Wong, Caspi and Williams 34 ).

Finally, changes in DNA methylation patterns have been reported to be associated with a series of age-related diseases. The evidence suggests that global hypomethylation and gene-specific promoter hypermethylation were associated with different types of cancer. It was found that the number of a subpopulation of cells in human colonic mucosa increase with age, and the promoter of oestrogen receptor gene in this subpopulation of cells becomes hypermethylated. This age-related hypermethylation of oestrogen receptor was found in all cells in colorectal tumours examined( Reference Issa, Ottaviano and Celano 125 ). Also, age-dependent methylation of oestrogen receptor alpha was associated with prostate cancer( Reference Li, Shiina and Deguchi 126 ). The hypermethylation of several tumour suppressor genes have been suggested as biomarkers of lung cancer( Reference Belinsky 127 ). Alzheimer's disease was correlated with DNA methylation of CpG sites located near or within the genetic loci reported to harbour genetic susceptible risk variants for Alzheimer's disease( Reference De Jager, Srivastava and Lunnon 128 ). Compared with the normal retinas, those of patients with age-related macular degeneration were found to have hypermethylation and gene repression of glutathione S-transferase isoform mu1 and glutathione S-transferase isoform mu5( Reference Hunter, Spechler and Cwanger 129 ).

DNA methylation and fatty acids

FA affect expressions of a wide array of genes by acting as ligands for transcription factors, such as PPAR, the liver X receptors (LXR), retinoid X receptor, hepatocyte NF 4, sterol regulatory element-binding proteins (SREBP), NF-κ-light-chain enhancer of activated B cells, cyclooxygenase and lipoxygenase( Reference Calder 130 ). PPAR and LXR are members of the nuclear hormone receptor superfamily of transcription factors, which bind to specific motifs within the promoters of genes as heterodimers with the retinoid X receptor( Reference Kidani and Bensinger 131 ). There are three isoforms of PPAR, including PPARα, PPARβ and PPARγ. In general, PPAR bind with both saturated and unsaturated FA with a relatively more potent binding with n-6 and n-3 PUFA and their derivatives to regulate expressions of genes that control lipid and glucose homeostasis and inflammation. Regarding LXR, there are two family members, LXRα and LXRβ. As a sensor of cholesterol in the nucleus, LXR can be activated by increased intracellular cholesterol concentrations. Also, the binding of long-chain FA to LXR( Reference Janowski, Grogan and Jones 132 ) was shown to regulate expression of genes involved in sterol and FA metabolism( Reference Geyeregger, Zeyda and Stulnig 133 ), lipogenesis( Reference Peet, Turley and Ma 134 Reference Yoshikawa, Shimano and Yahagi 137 ), carbohydrate metabolism( Reference Laffitte, Chao and Li 138 , Reference Cao, Liang and Broderick 139 ). Hepatocyte NF 4α is an orphan member of the steroid hormone receptor superfamily and functions by binding with the activated (CoA) form of FA to regulate expression of genes participating in the lipid, lipoprotein( Reference Naiki, Nagaki and Shidoji 140 , Reference Krapivner, Iglesias and Silveira 141 ) and glucose metabolism( Reference Boj, Parrizas and Maestro 142 , Reference Odom, Zizlsperger and Gordon 143 ). SREBP have three isoforms, which are SREBP-1a, SREBP-1c and SREBP-2, and all of them are transcription factors playing a critical role in controlling synthesis of FA, TAG and cholesterol( Reference Goldstein, DeBose-Boyd and Brown 144 ). PUFA were found to lower the mature form of the protein levels of SREBP by raising cellular cholesterol levels or by reducing SREBP mRNA stability and SREBP transcription or by promoting degradation of SREBP protein( Reference Thewke, Panini and Sinensky 145 Reference Yahagi, Shimano and Hasty 148 ). Cyclooxygenase and lipoxygenase function to convert n-6 and n-3 PUFA into pro- and anti-inflammatory signalling molecules to regulate activity of transcription factors of inflammation such as NF-κ-light-chain enhancer of activated B cells( Reference Patterson and Georgel 149 ).

The effect of FA on DNA methylation was also suggested by a study with mice heterozygous for disruption of cystathionine beta-synthase (Cbs +/−)( Reference Devlin, Singh and Wade 35 ), which could be induced to have hyperhomocysteinaemia (HHcy), providing an indirect evidence because of the potential modifications on DNA methylation by homocysteine through its participation in the C1 metabolism. In that study, a dosage of HHcy (normal, mild and moderate) was developed by treating the mice (Cbs +/+) with control diet (normal), the mice (Cbs +/+) with diet to induce HHcy (mild) and the mice (Cbs +/−) with diet to induce HHcy (moderate). The potential relationship between homocysteine and DNA methylation was supported by the significantly inverse correlation between total homocysteine levels and liver methylation capacity, measured by the ratio of S-adenosylmethionine to S-adenosylhomocysteine. Correspondingly, mice with moderate HHcy had higher methylation of candidate CpG sites within the promoter region of FA desaturase 2 in liver, leading to lower gene expression of  FA desaturase 2 and lower protein activity of δ(6)-desaturase (encoded by FA desaturase 2) in liver, compared with mice with mild and normal HHcy. Also, mice with moderate HHcy have lowest level of arachidonic acid and DHA in total liver than those mice with mild and normal HHcy.

Direct evidence for the link between FA and DNA methylation were conducted with in vitro and in vivo studies. Incubation of human skeletal muscle cells with 48 h treatment with free FA, such as palmitate and oleate, can increase DNA methylation levels of the promoter region of PPARγ coactivator-1α in primary human skeletal cells, leading to suppression of its gene expression( Reference Barres, Osler and Yan 36 ). Also, in vitro treatment of U937 leukemia cells with EPA was found to decrease methylation of the promoter regions of a myeloid lineage-specific transcription factor CCAAT/enhancer-binding protein, a tumour suppressor gene, resulting in an increased gene expression( Reference Ceccarelli, Racanicchi and Martelli 37 ). One in vivo study with rats found that feeding a diet high in n-3 PUFA, mainly with EPA and DHA could significantly decrease global DNA methylation levels( Reference Kulkarni, Dangat and Kale 150 ).

A randomised control trial with high-fat overfeeding in young adults with low or normal birth-weight supported a relationship between FA and DNA methylation. Having high-fat overfeeding (+50 % energy) for 5 d increased DNA methylation in the promoter region of PPARGC1A, measured in the skeletal muscle cells extracted from healthy young men with low birth-weight( Reference Brons, Jacobsen and Nilsson 53 ). The observed induction of DNA methylation in PPARGC1A was found to be reversible because DNA methylation returned to its baseline level after the high-fat diets were withdrawn. Although DNA methylation of PPARGC1A was not found to have significant correlation with its gene expression, high-fat challenge in the subjects with low birth-weight were shown to induce peripheral insulin resistance and decrease gene expression of PPARGC1A.

DNA methylation and other environmental factors

Besides ageing and dietary FA, DNA methylation patterns are modifiable by several other environmental factors, including global nutrition status, air pollution, weather and smoking. In mice, supplementation of methyl donors during gestation was shown to have a dose–response relationship with the methylation of viable yellow agouti (Avy ) locus and browness of coat colour in the offspring( Reference Waterland and Jirtle 45 ). Energy restriction in utero decreased the overall methylation and changes in the methylation patterns of imprinted loci in mice( Reference Chen, Ganguly and Rubbi 151 ). Similarly in human subjects, those subjects having experienced famine prenatally because of their in utero exposure to the Dutch Hunger Winter were shown to have less DNA methylation of the imprinted gene, insulin-like growth factor 2( Reference Heijmans, Tobi and Stein 39 , Reference Tobi, Lumey and Talens 40 ). Moreover, increased concentrations of ozone and components of fine particle mass were associated with hypomethylation of tissue factor (F3), intercellular adhesion molecule 1 and toll-like receptor 2 and hypermethylation of interferon-γ and IL6 ( Reference Bind, Lepeule and Zanobetti 152 ) and with decreases in global DNA methylation in whole blood( Reference De Prins, Koppen and Jacobs 153 ). A genome-wide analysis followed by an independent replication study showed that smokers have decreased level of DNA methylation of a single CpG site located within the coagulation factor II (thrombin) receptor-like 3 (F2RL3)( Reference Breitling, Yang and Korn 50 ). Also, methylation of tumour suppressor genes, cyclin-dependent kinase inhibitor 2A (p16) and death-associated protein kinase might lead to lung cancer( Reference Belinsky, Palmisano and Gilliland 51 ). Sun exposure was associated with the phenotypic changes related with skin ageing by their modifications of DNA methylation across the genome( Reference Gronniger, Weber and Heil 49 ). Finally, individuals with in utero exposure to rainy season in rural Gambia were shown to increase methylation of genetic regions contributing to the dramatic and systemic inter-individual variations in epigenetic regulation( Reference Waterland, Kellermayer and Laritsky 38 ).

DNA methylation and CVD risk factors

DNA methylation and inflammation

Accumulating evidence supports that DNA methylation patterns are associated with inflammatory markers, such as IL6 ( Reference Nile, Read and Akil 59 , Reference Tekpli, Landvik and Anmarkud 102 , Reference Peluso, Bollati and Munnia 154 Reference Stefani, Viana and Dupim 156 ), IL1β ( Reference Tekpli, Landvik and Anmarkud 102 ), and IL8 ( Reference Tekpli, Landvik and Anmarkud 102 ) and high-sensitivity C-reactive protein( Reference Kim, Bhattacharjee and Khalyfa 157 ), vascular cell adhesion molecule-1( Reference Baccarelli, Tarantini and Wright 158 ). A case–control study found that patients with rheumatoid arthritis have lower DNA methylation levels of a CpG site, which was located at −1099 bp to the transcription start site of IL6, measured in peripheral blood mononuclear cells. In the macrophages from healthy control subjects, lower methylation of the previously identified CpG site was in line with the higher IL6 expression stimulated by lipopolysaccharide. Experiments with electrophoretic mobility shift assay provided potential mechanistic explanation for these associations by identifying the methylation-dependent affinity of protein–DNA interactions( Reference Nile, Read and Akil 59 ). In vitro treatment of 5-aza-2′-deoxycytidine activated IL6 expression in human pancreatic adenocarcinoma cell lines, indicating an important role of DNA methylation at the IL6 genetic locus( Reference Dandrea, Donadelli and Costanzo 60 ). Also, chromatin immune-precipitation assays with the same cell lines identified a potential response element to the binding of methyl-CpG-binding protein 2, located from −666 to −426 bp to the transcription start sites, providing potentially a mechanistic explanation for the DNA methylation of IL6 ( Reference Dandrea, Donadelli and Costanzo 60 ). A cross-sectional study with blood leucocyte found that workers living in an industrial area had the lowest, whereas rural and urban residents had the highest and intermediate methylation levels of the second intron of IL6 ( Reference Peluso, Bollati and Munnia 154 ). Another cross-sectional study with leucocytes found that a prudent diet, characterised by a high intake of vegetables and fruit, was associated with DNA methylation levels of the promoter region of IL6 ( Reference Zhang, Santella and Wolff 155 ). According to the analysis of DNA methylation patterns of IL6 in periodontal tissues, patients with periodontitis were found to have lower methylation and higher gene expression( Reference Stefani, Viana and Dupim 156 ). An in vitro study with cultured human lung cells showed that the DNA methylation levels of promoter regions of a panel of inflammation related genes (IL6, IL1β and IL8) were higher in cancer cells than normal ones, and the higher methylations went along with the lower gene expressions( Reference Tekpli, Landvik and Anmarkud 102 ). A study with patients with paediatric obstructive sleep apnoea found that DNA methylation of forkhead box P3 had a significantly positive correlation with serum levels of high-sensitivity C-reactive protein( Reference Kim, Bhattacharjee and Khalyfa 157 ). A cross-sectional study with blood samples from 742 community-dwelling elderly individuals found that hypomethylation of repetitive element LINE-1 was associated with increased levels of serum vascular cell adhesion molecule-11( Reference Baccarelli, Tarantini and Wright 158 ). Finally, a study with samples of leucocytes from 966 African American identified that DNA methylations of 257 CpG sites within 240 genes contribute to serum levels of C-reactive protein ( Reference Sun, Lazarus and Smith 159 ).

DNA methylation and dyslipidaemia

DNA methylation patterns have been related to dyslipidaemia( Reference Lund, Andersson and Lauria 55 , Reference Panin, Tuzikov and Gimautdinova 56 , Reference Irvin, Zhi and Joehanes 160 , Reference Guay, Brisson and Munger 161 ). After stimulation with lipoproteins, the global levels of 5-methylated cytosines within the differentiated human monocyte-macrophage cell line THP-1 were significantly increased( Reference Lund, Andersson and Lauria 55 ). According to a genome-wide DNA methylation analysis with samples of CD4+ cells from 991 individuals of the Genetics of Lipid-lowering Drugs and Diet Network (GOLDN) study, four CpG sites located within the intron 1 of carnitine palmitoyltransferase 1A were found to be associated with fasting levels of VLDL-cholesterol and TAG. DNA methylation of the CpG site with top findings was further found to be associated with carnitine palmitoyltransferase 1A expression. The observed association between DNA methylation, gene expression and fasting TAG was replicated in the Framingham Heart Study( Reference Irvin, Zhi and Joehanes 160 ). Also, a higher methylation pattern of the promoter region of ATP-binding cassette A1 (ABCA1) in samples of whole blood was found to be associated with a lower circulating HDL-cholesterol and HDL2-phospholipid levels in ninety-seven patients with familial hypercholesterolaemia( Reference Guay, Brisson and Munger 161 ). Similarly in patients with familial hypercholesterolaemia, leucocyte DNA methylations of lipoprotein lipase had positive correlations with HDL-cholesterol and HDL particle size, whereas DNA methylation of cholesteryl ester transfer protein had a negative association with LDL-cholesterol in all the participants and negative associations with HDL-cholesterol, HDL-TAG levels, and HDL particle size( Reference Guay, Brisson and Lamarche 162 ). Further, the methylations of lipoprotein lipase in visceral adipose tissue extracted from thirty men with severe obesity were found to have negative correlations with HDL-cholesterol and gene expression of lipoprotein lipase( Reference Guay, Brisson and Lamarche 162 ). The potential mechanism for the effects of lipoproteins on DNA methylation is unknown. The modifications of chromatin structure may account as one potential mechanism, because it was found that ApoA1 can physically bind to a CG-rich oligonucleotide in vitro, leading to the remodelling of chromatin structure( Reference Panin, Tuzikov and Gimautdinova 56 ).

Genetics and epigenetics integrate

The integration of genetics and epigenetics require large datasets with deep and comprehensive phenotyping. The proposed research in this subject has been facilitated by our access to such rich resources, specifically the GOLDN study and the Cohorts for Heart and Aging Research in Genomic Epidemiology (CHARGE) consortium.

The GOLDN study was designed to identify genetic determinants of lipid response to two interventions (a high-fat meal challenge and fenofibrate treatment for 3 weeks)( Reference Lai, Arnett and Corella 163 ). The study ascertained and recruited families from the Family Heart Study at two centres (Minneapolis, MN and Salt Lake City, UT), who self-reported to be white. Only families with at least two siblings were recruited for a total of 1327 individuals. Volunteers were required to withhold lipid-lowering agents (pharmaceuticals or nutraceuticals) for at least 4 weeks before the initial visit to be eligible. A total of 1053 individuals met all eligibility requirements.

For methylation studies, DNA was extracted from CD4+ T cells harvested from buffy coats with the use of antibody-linked Invitrogen Dynabeads. CD4+ T cells were selected for three reasons. First, DNA methylation patterns are often tissue specific. For instance, studies of whole blood samples reflect methylation variations within each blood cell type that may act to confound epigenomic association results( Reference Adalsteinsson, Gudnason and Aspelund 164 ). Second, many key genes involved in lipid metabolism are expressed in lymphocytes and other immune cells (e.g. PPAR)( Reference Bouwens, Afman and Muller 165 ). In one study, peripheral blood mononuclear cells gene expression profiles were demonstrated to reflect nutrition-related metabolic changes. Responsive genes were enriched for FA-metabolising enzymes, including carnitine palmitoyltransferase 1, ACAA2 and SCL25A20( Reference Bouwens, Afman and Muller 166 ). Therefore, this cell type should reflect underlying epigenetic variation influencing blood lipids while minimising potential confounding. Third, blood collection is the most viable tissue collection method among healthy individuals. We used the Illumina Infinium Human Methylation450 Beadchip (Illumina Inc, San Diego, CA) to interrogate approximately 470 000 autosomal CpG sites across the genome.

The CHARGE Consortium was formed to facilitate genome-wide association studies meta-analyses and replication opportunities among multiple large population-based cohort studies, which collect data in a standardised fashion and represent the preferred method for estimating disease incidence. The initial design of CHARGE included five prospective cohort studies from the USA and Europe: the Age, Gene/Environment Susceptibility-Reykjavik study, the Atherosclerosis Risk in Communities study, the Cardiovascular Health study, the Framingham Heart study and the Rotterdam study. With genome-wide data on a total of about 38 000 individuals, these cohort studies have a large number of health-related phenotypes measured in similar ways. For each harmonised trait, within-cohort genome-wide association study analyses are combined by meta-analysis. A prospective meta-analysis of data from all five cohorts, with a properly selected level of genome-wide statistical significance, is a powerful approach to finding genuine phenotypic associations with novel genetic loci.( Reference Psaty, O'Donnell and Gudnason 167 ) Since its creation, CHARGE has incorporated many other cohorts, increasing significantly its sample size and the ability to identify new and relevant associations and interactions.

Genetic variants and methylation levels revisited

Using data from the GOLDN study, we revisited the topic of the local correlation between genetic variants and DNA methylation levels (cis-meQTL) and conducted a cis-meQTL analysis. We found that over 80 % of genetic variants at CpG sites (meSNP) are meQTL loci (P < 10−9) and meSNP account for over two-thirds of the strongest meQTL signals (P < 10−200). Beyond direct effects on the methylation of the meSNP site, the CpG-disrupting allele of meSNP were associated with lowered methylation of CpG sites located within 45 bp. The effect of meSNP extends as far as 10 kb and can contribute to the observed meQTL signals in the surrounding region, likely through correlated methylation patterns and linkage disequilibrium. Therefore, GOLDN supports previous findings showing that meSNP are behind a large portion of observed meQTL signals and play a crucial role in the biological process linking genetic variation to epigenetic changes.( Reference Zhi, Aslibekyan and Irvin 168 )

APOE gene variants, methylation and ageing

Common APOE gene variants are associated with age-related diseases; however, the underlying mechanisms have not been entirely elucidated and DNA methylation may be a significant contributor. To test this possibility, we conducted an integrated analysis with both population (GOLDN study) and in vitro studies (Encyclopedia of DNA elements (ENCODE) consortium) to systematically explore the relationships among age, plasma lipids, DNA methylation patterns, sequence variants and gene expression of APOE ( Reference Ma, Smith and Lai 169 ). We found that APOE methylation was correlated with gene expression, associated with age, plasma total cholesterol and sequence variants, including both promoter variant rs405509 and well-known APOE ε variants. Furthermore, the association between APOE methylation patterns within the promoter region and age were dependent on promoter variant rs405509. These associations suggest that APOE methylation may explain its ageing effects.( Reference Ma, Smith and Lai 169 )

IL6 gene variants, methylation and dietary n-3

n-3 PUFA reduce IL6 gene expression, but their effects on transcription regulatory mechanisms are not totally elucidated. As in previous instances, we systematically explore the relationships among n-3 PUFA, DNA methylation, sequence variants, gene expression and protein concentration of IL6 by conducting an integrated analysis of data from population (GOLDN study) and in vitro studies (ENCODE consortium)( Reference Ma, Smith and Lai 170 ). As a result, methylation of IL6 promoter CpG site (cg01770232) was positively associated with IL-6 plasma concentration, IL6 gene expression and more dosage of the A allele of rs2961298, but negatively associated with circulating total n-3 PUFA. Furthermore, there was significant interaction between rs2961298 and circulating total n-3 PUFA for cg01770232 methylation. Therefore, in GOLDN, the association between n-3 PUFA and IL6 promoter methylation was not only negative but also dependent on sequence variants.( Reference Ma, Smith and Lai 170 )

Genetic variation at lipid-related genes, methylation and dietary fatty acids

Using data from CHARGE and ENCODE consortia, we conducted another integrated analysis to explore whether gene–diet interactions on blood lipids act through DNA methylation( Reference Ma, Follis and Smith 171 ). Based on predicted relations in FA, methylation, and lipids, we selected seven candidate SNP located within APOE, ABCA1, 3-hydroxy-3-methylglutaryl-CoA reductase, APOA5, proprotein convertase subtilisin/kexin-type 9 and hepatocyte NF-1 homeobox A. According to the meta-analysis of seven cohorts in the CHARGE consortium, plasma HDL-cholesterol was not only associated with genotypes of ABCA1 rs2246293, but also positively associated with circulating EPA, for which the association was further dependent on genotypes of ABCA1 rs2246293. With methylation data in GOLDN, we found that methylation level of ABCA1 promoter CpG site cg14019050 was not only associated with genotypes of rs2246293, but also negatively associated with circulating EPA, for which, again, the association was further modified by genotypes of rs2246293. We further found that the correlation between methylation level of ABCA1 cg14019050 and plasma HDL-cholesterol is negative in GOLDN. Using data from ENCODE consortium, we identified a negative correlation between methylation of cg14019050 and ABCA1 expression. In order to validate the mediation effect of cg14019050 methylation in the pathway from gene–EPA interaction to plasma HDL-cholesterol, we conducted an additional mediation analysis, which was further meta-analysed across the GOLDN study, Cardiovascular Health study and the Multi-Ethnic Study of Atherosclerosis. We did observe a mediation effect; however, the magnitude of the mediation effect did not reach statistical significance. At APOE, although we observed consistent significant interactions between promoter SNP rs405509 and circulating α-linolenic acid for both plasma TAG in CHARGE consortium and methylation level of CpG site cg04406254 in GOLDN, there is no evidence to support the mediation effect of APOE methylation. Therefore, we obtained little evidence that DNA methylation explains the gene–FA interactions on blood lipids.( Reference Ma, Follis and Smith 171 )

Conclusions

Despite the extensive evidence for gene–environment interactions and more specifically gene–diet interactions, the underlying biological mechanisms are still unclear. The current integrated studies of genetics and epigenetics provide gene-specific preliminary evidence that DNA methylation may act as one possible mechanism for such interactions, which is consistent with the established regulatory role of DNA methylation as the interface between ‘nature’ and ‘nurture’.

DNA methylation has been demonstrated to be determined by the local nucleotide sequence and almost all of the methylation (99·98 %) in differentiated mammalian cells occurs on the CpG dinucleotides( Reference Lister, Pelizzola and Dowen 63 ). Furthermore, the phenomenon of allele-specific DNA methylation, suggested by observed associations between genetic variants and DNA methylation, is widespread across the human genome. For example, according to analysis of twin pairs and their parents, >35 000 CpG sites were shown to have allele-specific DNA methylation events( Reference Schalkwyk, Meaburn and Smith 172 ).

Evidence has been accumulating in support of changes to DNA methylation in response to different types of environmental factors. Studies with monozygotic and dizygotic twins suggested the potential role of environmental factors in the regulation of DNA methylation( Reference Fraga, Ballestar and Paz 33 , Reference Wong, Caspi and Williams 34 ).

Based on the current knowledge, there is clear genetic contribution to DNA methylation as shown by significant SNP–CpG pair associations for genes, including APOE, IL6 and ABCA ( Reference Ma, Smith and Lai 169 Reference Ma, Follis and Smith 171 ). Moreover, there are significant interactions between methylation-related SNP and other environmental factors of interest, such as age and circulating FA. We found significant interactions for the promoter SNP of APOE, which interacted with age and α-linolenic acid, the promoter SNP of IL6 with EPA and DHA, and the promoter SNP of ABCA1 with EPA. These interactions were not only observed for the CVD traits, but also for the DNA methylation measurements of the corresponding genes. Furthermore, the results from the correlations between methylation and CVD traits and gene expression were in the same direction of the observed genetic associations and interactions. Our integrated analysis of both genetics and epigenetics provide preliminary evidence for the potential and partial mechanistic role of DNA methylation to explain gene–environment interactions, and such role maybe loci-specific.

With respect to clinical implications, the use of common SNP in the clinical setting for primary or secondary prevention remains controversial. APOE is one example, in that the ε4 variant was demonstrated to have a dosage effect on the incidence of and on the age of onset of the late-onset Alzheimer's disease( Reference Corder, Saunders and Strittmatter 173 ). However, debates persist over whether the genotyping test for APOE ε4 is necessary or desirable, because there are no medications or clinical strategies to counter the deleterious effect of the ε4 isoforms ( Reference Gordon and Landa 174 Reference Green, Roberts and Cupples 176 ). However, the finding that ε4 is associated with APOE methylation and expression suggest that the deleterious effects of ε4 might be mitigated by applying appropriate lifestyle-based modifiers that reduce the difference in methylation across different APOE isoforms.

There are many gaps and limitations that need to be overcome. First, the evidence in human subjects comes primarily from observational studies and a cause–effect relationship cannot be established. Second, DNA methylation studies in human subjects are based primarily on blood cells. Overall, we need intervention studies to increase the level of evidence supporting the notion that genotype-dependent epigenetic changes are an underlying molecular mechanism for gene–environment interactions with the objective of providing reliable evidence to advance the development of more personalised approaches to nutrition recommendations and medical care.

Acknowledgements

This material is based upon work supported by the U.S. Department of Agriculture, under agreement No. 58-1950-0-014. Any opinions, findings, conclusion, or recommendations expressed in this publication are those of the author(s) and do not necessarily reflect the view of the U.S. Department of Agriculture.

Financial Support

The authors were supported by the US Department of Agriculture, agreement no. 58-1950-0-014 and by the National Institutes of Health Grant P50 HL105185.

Conflict of Interest

None.

Authorship

Y. M. and J. M. O. contributed equally to the design of the review and writing of the manuscript and both reviewed and approved the final version.

References

1. Go, AS, Mozaffarian, D, Roger, VL et al. (2014) Executive summary: heart disease and stroke statistics – 2014 update: a report from the American Heart Association. Circulation 129, 399410.Google Scholar
2. Grundy, SM, Pasternak, R, Greenland, P et al. (1999) Assessment of cardiovascular risk by use of multiple-risk-factor assessment equations: a statement for healthcare professionals from the American Heart Association and the American College of Cardiology. Circulation 100, 14811492.Google Scholar
3. Roger, VL, Go, AS, Lloyd-Jones, DM et al. (2010) Heart disease and stroke statistics--2011 update: a report from the American Heart Association. Circulation 123, e18e209.Google Scholar
4. Hunter, JE, Zhang, J & Kris-Etherton, PM (2010) Cardiovascular disease risk of dietary stearic acid compared with trans, other saturated, and unsaturated fatty acids: a systematic review. Am J Clin Nutr 91, 4663.CrossRefGoogle ScholarPubMed
5. Lopez-Alvarenga, JC, Ebbesson, SO, Ebbesson, LO et al. (2010) Polyunsaturated fatty acids effect on serum triglycerides concentration in the presence of metabolic syndrome components. The Alaska-Siberia Project. Metabolism 59, 8692.Google Scholar
6. Masson, CJ, Mensink, RP (2011) Exchanging saturated fatty acids for (n-6) polyunsaturated fatty acids in a mixed meal may decrease postprandial lipemia and markers of inflammation and endothelial activity in overweight men. J Nutr 141, 816821.CrossRefGoogle Scholar
7. Bos, MB, de Vries, JH, Feskens, EJ et al. (2010) Effect of a high monounsaturated fatty acids diet and a Mediterranean diet on serum lipids and insulin sensitivity in adults with mild abdominal obesity. Nutr Metab Cardiovasc Dis 20, 591598.CrossRefGoogle Scholar
8. Hansen, JB, Grimsgaard, S, Nilsen, H et al. (1998) Effects of highly purified eicosapentaenoic acid and docosahexaenoic acid on fatty acid absorption, incorporation into serum phospholipids and postprandial triglyceridemia. Lipids 33, 131138.Google Scholar
9. Sudheendran, S, Chang, CC & Deckelbaum, RJ (2010) N-3 vs. saturated fatty acids: effects on the arterial wall. Prostaglandins Leukot Essent Fatty Acids 82, 205209.CrossRefGoogle ScholarPubMed
10. Li, Z, Lamon-Fava, S, Otvos, J et al. (2004) Fish consumption shifts lipoprotein subfractions to a less atherogenic pattern in humans. J Nutr 134, 17241728.Google Scholar
11. Fakhrzadeh, H, Ghaderpanahi, M, Sharifi, F et al. (2010) The effects of low dose n-3 fatty acids on serum lipid profiles and insulin resistance of the elderly: a randomized controlled clinical trial. Int J Vitam Nutr Res 80, 107116.CrossRefGoogle ScholarPubMed
12. Mori, TA, Bao, DQ, Burke, V et al. (1999) Dietary fish as a major component of a weight-loss diet: effect on serum lipids, glucose, and insulin metabolism in overweight hypertensive subjects. Am J Clin Nutr 70, 817825.Google Scholar
13. Illingworth, DR, Harris, WS & Connor, WE (1984) Inhibition of low density lipoprotein synthesis by dietary omega-3 fatty acids in humans. Arteriosclerosis 4, 270275.CrossRefGoogle ScholarPubMed
14. Kalogeropoulos, N, Panagiotakos, DB, Pitsavos, C et al. (2010) Unsaturated fatty acids are inversely associated and n-6/n-3 ratios are positively related to inflammation and coagulation markers in plasma of apparently healthy adults. Clin Chim Acta 411, 584591.Google Scholar
15. Farzaneh-Far, R, Harris, WS, Garg, S et al. (2009) Inverse association of erythrocyte n-3 fatty acid levels with inflammatory biomarkers in patients with stable coronary artery disease: The Heart and Soul Study. Atherosclerosis 205, 538543.Google Scholar
16. Perunicic-Pekovic, GB, Rasic, ZR, Pljesa, SI et al. (2007) Effect of n-3 fatty acids on nutritional status and inflammatory markers in haemodialysis patients. Nephrology (Carlton) 12, 331336.Google Scholar
17. Sundrarjun, T, Komindr, S, Archararit, N et al. (2004) Effects of n-3 fatty acids on serum interleukin-6, tumour necrosis factor-alpha and soluble tumour necrosis factor receptor p55 in active rheumatoid arthritis. J Int Med Res 32, 443454.Google Scholar
18. Lopez-Garcia, E, Schulze, MB, Manson, JE et al. (2004) Consumption of (n-3) fatty acids is related to plasma biomarkers of inflammation and endothelial activation in women. J Nutr 134, 18061811.CrossRefGoogle Scholar
19. Schaefer, EJ, Lamon-Fava, S, Ausman, LM et al. (1997) Individual variability in lipoprotein cholesterol response to National Cholesterol Education Program Step 2 diets. Am J Clin Nutr 65, 823830.Google Scholar
20. Ordovas, JM, Corella, D, Demissie, S et al. (2002) Dietary fat intake determines the effect of a common polymorphism in the hepatic lipase gene promoter on high-density lipoprotein metabolism: evidence of a strong dose effect in this gene-nutrient interaction in the Framingham Study. Circulation 106, 23152321.Google Scholar
21. Lai, CQ, Corella, D, Demissie, S et al. (2006) Dietary intake of n-6 fatty acids modulates effect of apolipoprotein A5 gene on plasma fasting triglycerides, remnant lipoprotein concentrations, and lipoprotein particle size: the Framingham Heart Study. Circulation 113, 20622070.Google Scholar
22. Ordovas, JM, Corella, D, Cupples, LA et al. (2002) Polyunsaturated fatty acids modulate the effects of the APOA1 G-A polymorphism on HDL-cholesterol concentrations in a sex-specific manner: the Framingham Study. Am J Clin Nutr 75, 3846.CrossRefGoogle Scholar
23. Zhou, Q, Zhang, B, Wang, P et al. (2010) Association of interleukin-6 gene -572 C > G polymorphism with dietary intake of n-3 fatty acids on plasma HDL-c level in Chinese male adults. Asia Pac J Clin Nutr 19, 506512.Google Scholar
24. Fontaine-Bisson, B, Wolever, TM, Connelly, PW et al. (2009) NF-kappaB -94Ins/Del ATTG polymorphism modifies the association between dietary polyunsaturated fatty acids and HDL-cholesterol in two distinct populations. Atherosclerosis 204, 465470.Google Scholar
25. Fontaine-Bisson, B, Wolever, TM, Chiasson, JL et al. (2007) Genetic polymorphisms of tumor necrosis factor-alpha modify the association between dietary polyunsaturated fatty acids and fasting HDL-cholesterol and apo A-I concentrations. Am J Clin Nutr 86, 768774.Google Scholar
26. Lindi, V, Schwab, U, Louheranta, A et al. (2003) Impact of the Pro12Ala polymorphism of the PPAR-gamma2 gene on serum triacylglycerol response to n-3 fatty acid supplementation. Mol Genet Metab 79, 5260.Google Scholar
27. Tai, ES, Corella, D, Demissie, S et al. (2005) Polyunsaturated fatty acids interact with the PPARA-L162 V polymorphism to affect plasma triglyceride and apolipoprotein C-III concentrations in the Framingham Heart Study. J Nutr 135, 397403.Google Scholar
28. Waddington, C (1940) Organisers and Genes. Cambridge: Cambridge University Press.Google Scholar
29. Wolffe, AP & Matzke, MA (1999) Epigenetics: regulation through repression. Science 286, 481486.Google Scholar
30. Portela, A & Esteller, M (2010) Epigenetic modifications and human disease. Nat Biotechnol 28, 10571068.Google Scholar
31. Cheng, X (1995) Structure and function of DNA methyltransferases. Annu Rev Biophys Biomol Struct 24, 293318.CrossRefGoogle ScholarPubMed
32. Hellman, A & Chess, A (2007) Gene body-specific methylation on the active X chromosome. Science 315, 11411143.Google Scholar
33. Fraga, MF, Ballestar, E, Paz, MF et al. (2005) Epigenetic differences arise during the lifetime of monozygotic twins. Proc Natl Acad Sci USA 102, 1060410609.Google Scholar
34. Wong, CC, Caspi, A, Williams, B et al. (2010) A longitudinal study of epigenetic variation in twins. Epigenetics 5, 516526.Google Scholar
35. Devlin, AM, Singh, R, Wade, RE et al. (2007) Hypermethylation of Fads2 and altered hepatic fatty acid and phospholipid metabolism in mice with hyperhomocysteinemia. J Biol Chem 282, 3708237090.CrossRefGoogle ScholarPubMed
36. Barres, R, Osler, ME, Yan, J et al. (2009) Non-CpG methylation of the PGC-1 alpha promoter through DNMT3B controls mitochondrial density. Cell Metab 10, 189198.Google Scholar
37. Ceccarelli, V, Racanicchi, S, Martelli, MP et al. (2011) Eicosapentaenoic acid demethylates a single CpG that mediates expression of tumor suppressor CCAAT/enhancer-binding protein delta in U937 leukemia cells. J Biol Chem 286, 2709227102.Google Scholar
38. Waterland, RA, Kellermayer, R, Laritsky, E et al. (2010) Season of conception in rural gambia affects DNA methylation at putative human metastable epialleles. PLoS Genet 6, e1001252.Google Scholar
39. Heijmans, BT, Tobi, EW, Stein, AD et al. (2008) Persistent epigenetic differences associated with prenatal exposure to famine in humans. Proc Natl Acad Sci USA 105, 1704617049.Google Scholar
40. Tobi, EW, Lumey, LH, Talens, RP et al. (2009) DNA methylation differences after exposure to prenatal famine are common and timing- and sex-specific. Hum Mol Genet 18, 40464053.Google Scholar
41. Sandovici, I, Smith, NH, Nitert, MD et al. (2011) Maternal diet and aging alter the epigenetic control of a promoter-enhancer interaction at the Hnf4a gene in rat pancreatic islets. Proc Natl Acad Sci USA 108, 54495454.Google Scholar
42. Lillycrop, KA, Phillips, ES, Jackson, AA et al. (2005) Dietary protein restriction of pregnant rats induces and folic acid supplementation prevents epigenetic modification of hepatic gene expression in the offspring. J Nutr 135, 13821386.Google Scholar
43. Hoyo, C, Murtha, AP, Schildkraut, JM et al. (2011) Methylation variation at IGF2 differentially methylated regions and maternal folic acid use before and during pregnancy. Epigenetics 6, 928936.Google Scholar
44. Steegers-Theunissen, RP, Obermann-Borst, SA, Kremer, D et al. (2009) Periconceptional maternal folic acid use of 400 microg per day is related to increased methylation of the IGF2 gene in the very young child. PLoS ONE 4, e7845.CrossRefGoogle Scholar
45. Waterland, RA & Jirtle, RL (2003) Transposable elements: targets for early nutritional effects on epigenetic gene regulation. Mol Cell Biol 23, 52935300.Google Scholar
46. Baccarelli, A, Wright, RO, Bollati, V et al. (2009) Rapid DNA methylation changes after exposure to traffic particles. Am J Resp Crit Care Med 179, 572578.Google Scholar
47. Bollati, V, Baccarelli, A, Hou, L et al. (2007) Changes in DNA methylation patterns in subjects exposed to low-dose benzene. Cancer Res 67, 876880.CrossRefGoogle ScholarPubMed
48. Langevin, SM, Houseman, EA, Christensen, BC et al. (2011) The influence of aging, environmental exposures and local sequence features on the variation of DNA methylation in blood. Epigenetics 6, 908919.Google Scholar
49. Gronniger, E, Weber, B, Heil, O et al. (2010) Aging and chronic sun exposure cause distinct epigenetic changes in human skin. PLoS Genet 6, e1000971.Google Scholar
50. Breitling, LP, Yang, R, Korn, B et al. (2011) Tobacco-smoking-related differential DNA methylation: 27 K discovery and replication. Am J Hum Genet 88, 450457.Google Scholar
51. Belinsky, SA, Palmisano, WA, Gilliland, FD et al. (2002) Aberrant promoter methylation in bronchial epithelium and sputum from current and former smokers. Cancer Res 62, 23702377.Google ScholarPubMed
52. Ahuja, N, Li, Q, Mohan, AL et al. (1998) Aging and DNA methylation in colorectal mucosa and cancer. Cancer Res 58, 54895494.Google Scholar
53. Brons, C, Jacobsen, S, Nilsson, E et al. (2010) Deoxyribonucleic acid methylation and gene expression of PPARGC1A in human muscle is influenced by high-fat overfeeding in a birth-weight-dependent manner. J Clin Endocrinol Metab 95, 30483056.Google Scholar
54. Dong, C, Yoon, W & Goldschmidt-Clermont, PJ (2002) DNA methylation and atherosclerosis. J Nutr 132(8 Suppl), 2406S2409S.Google Scholar
55. Lund, G, Andersson, L, Lauria, M et al. (2004) DNA methylation polymorphisms precede any histological sign of atherosclerosis in mice lacking apolipoprotein E. J Biol Chem 279, 2914729154.Google Scholar
56. Panin, LE, Tuzikov, FV & Gimautdinova, OI (2003) Tetrahydrocortisol-apolipoprotein A-I complex specifically interacts with eukaryotic DNA and GCC elements of genes. J Steroid Biochem Mol Biol 87, 309318.Google Scholar
57. Veldhoen, M, Hocking, RJ, Atkins, CJ et al. (2006) TGFbeta in the context of an inflammatory cytokine milieu supports de novo differentiation of IL-17-producing T cells. Immunity 24, 179189.CrossRefGoogle ScholarPubMed
58. Bettelli, E, Carrier, Y, Gao, W et al. (2006) Reciprocal developmental pathways for the generation of pathogenic effector TH17 and regulatory T cells. Nature 441, 235238.Google Scholar
59. Nile, CJ, Read, RC, Akil, M et al. (2008) Methylation status of a single CpG site in the IL6 promoter is related to IL6 messenger RNA levels and rheumatoid arthritis. Arthritis Rheum 58, 26862693.Google Scholar
60. Dandrea, M, Donadelli, M, Costanzo, C et al. (2009) MeCP2/H3meK9 are involved in IL-6 gene silencing in pancreatic adenocarcinoma cell lines. Nucleic Acids Res 37, 66816690.Google Scholar
61. Dawson, MA & Kouzarides, T (2012) Cancer epigenetics: from mechanism to therapy. Cell 150, 1227.Google Scholar
62. Ho, L & Crabtree, GR (2010) Chromatin remodelling during development. Nature 463, 474484.CrossRefGoogle ScholarPubMed
63. Lister, R, Pelizzola, M, Dowen, RH et al. (2009) Human DNA methylomes at base resolution show widespread epigenomic differences. Nature 462, 315322.Google Scholar
64. Gardiner-Garden, M & Frommer, M (1987) CpG islands in vertebrate genomes. J Mol Biol 196, 261282.CrossRefGoogle ScholarPubMed
65. Takai, D & Jones, PA (2003) The CpG island searcher: a new www resource. In Silico Biol 3, 235240.Google Scholar
66. Ponger, L & Mouchiroud, D (2002) CpGProD: identifying CpG islands associated with transcription start sites in large genomic mammalian sequences. Bioinformatics 18, 631633.CrossRefGoogle ScholarPubMed
67. Hackenberg, M, Previti, C, Luque-Escamilla, PL et al. (2006) CpGcluster: a distance-based algorithm for CpG-island detection. BMC Bioinformatics 7, 446.Google Scholar
68. Su, J, Zhang, Y, Lv, J et al. (2010) CpG_MI: a novel approach for identifying functional CpG islands in mammalian genomes. Nucleic Acids Res 38, e6.Google Scholar
69. Bock, C, Halachev, K, Buch, J et al. (2009) EpiGRAPH: user-friendly software for statistical analysis and prediction of (epi)genomic data. Genome Biol 10, R14.Google Scholar
70. Lienert, F, Wirbelauer, C, Som, I et al. (2011) Identification of genetic elements that autonomously determine DNA methylation states. Nat Genet 43, 10911097.Google Scholar
71. Wang, H, Ogawa, M, Wood, JR et al. (2008) Genetic and epigenetic mechanisms combine to control MMP1 expression and its association with preterm premature rupture of membranes. Hum Mol Genet 17, 10871096.CrossRefGoogle ScholarPubMed
72. Moser, D, Ekawardhani, S, Kumsta, R et al. (2009) Functional analysis of a potassium-chloride co-transporter 3 (SLC12A6) promoter polymorphism leading to an additional DNA methylation site. Neuropsychopharmacology 34, 458467.CrossRefGoogle Scholar
73. Shoemaker, R, Deng, J, Wang, W et al. (2010) Allele-specific methylation is prevalent and is contributed by CpG-SNPs in the human genome. Genome Res 20, 883889.CrossRefGoogle ScholarPubMed
74. Zhang, D, Cheng, L, Badner, JA et al. (2010) Genetic control of individual differences in gene-specific methylation in human brain. Am J Hum Genet 86, 411419.CrossRefGoogle ScholarPubMed
75. Gertz, J, Varley, KE, Reddy, TE et al. (2011) Analysis of DNA methylation in a three-generation family reveals widespread genetic influence on epigenetic regulation. PLoS Genet 7, e1002228.Google Scholar
76. Qu, W, Hashimoto, S, Shimada, A et al. (2012) Genome-wide genetic variations are highly correlated with proximal DNA methylation patterns. Genome Res 22, 14191425.Google Scholar
77. Kerkel, K, Spadola, A, Yuan, E et al. (2008) Genomic surveys by methylation-sensitive SNP analysis identify sequence-dependent allele-specific DNA methylation. Nat Genet 40, 904908.Google Scholar
78. Hellman, A & Chess, A (2010) Extensive sequence-influenced DNA methylation polymorphism in the human genome. Epigenetics Chromatin 3, 11.Google Scholar
79. Eden, S & Cedar, H (1994) Role of DNA methylation in the regulation of transcription. Curr Opin Genet Dev 4, 255259.Google Scholar
80. Maunakea, AK, Chepelev, I, Cui, K et al. (2013) Intragenic DNA methylation modulates alternative splicing by recruiting MeCP2 to promote exon recognition. Cell Res 23, 12561269.CrossRefGoogle ScholarPubMed
81. Gelfman, S & Ast, G (2013) When epigenetics meets alternative splicing: the roles of DNA methylation and GC architecture. Epigenomics 5, 351353.Google Scholar
82. Maunakea, AK, Nagarajan, RP, Bilenky, M et al. (2010) Conserved role of intragenic DNA methylation in regulating alternative promoters. Nature 466, 253257.Google Scholar
83. Shukla, S, Kavak, E, Gregory, M et al. (2011) CTCF-promoted RNA polymerase II pausing links DNA methylation to splicing. Nature 479, 7479.Google Scholar
84. Anastasiadou, C, Malousi, A, Maglaveras, N et al. (2011) Human epigenome data reveal increased CpG methylation in alternatively spliced sites and putative exonic splicing enhancers. DNA Cell Biol 30, 267275.Google Scholar
85. Razin, A & Cedar, H (1991) DNA methylation and gene expression. Microbiol Rev 55, 451458.Google Scholar
86. McGhee, JD & Ginder, GD (1979) Specific DNA methylation sites in the vicinity of the chicken beta-globin genes. Nature 280, 419420.Google Scholar
87. Stein, R, Sciaky-Gallili, N, Razin, A et al. (1983) Pattern of methylation of two genes coding for housekeeping functions. Proc Natl Acad Sci USA 80, 24222426.Google Scholar
88. Toniolo, D, D'Urso, M, Martini, G et al. (1984) Specific methylation pattern at the 3′ end of the human housekeeping gene for glucose 6-phosphate dehydrogenase. EMBO J 3, 19871995.CrossRefGoogle ScholarPubMed
89. Yen, PH, Patel, P, Chinault, AC et al. (1984) Differential methylation of hypoxanthine phosphoribosyltransferase genes on active and inactive human X chromosomes. Proc Natl Acad Sci USA 81, 17591763.Google Scholar
90. Wolf, SF, Dintzis, S, Toniolo, D et al. (1984) Complete concordance between glucose-6-phosphate dehydrogenase activity and hypomethylation of 3′ CpG clusters: implications for X chromosome dosage compensation. Nucleic Acids Res 12, 93339348.Google Scholar
91. Orozco, LD, Rubbi, L, Martin, LJ et al. (2014) Intergenerational genomic DNA methylation patterns in mouse hybrid strains. Genome Biol 15, R68.Google Scholar
92. Yamada, N, Nishida, Y, Tsutsumida, H et al. (2008) MUC1 expression is regulated by DNA methylation and histone H3 lysine 9 modification in cancer cells. Cancer Res 68, 27082716.CrossRefGoogle ScholarPubMed
93. Wang, J, Bhutani, M, Pathak, AK et al. (2007) Delta DNMT3B variants regulate DNA methylation in a promoter-specific manner. Cancer Res 67, 1064710652.Google Scholar
94. Harada, K, Toyooka, S, Maitra, A et al. (2002) Aberrant promoter methylation and silencing of the RASSF1A gene in pediatric tumors and cell lines. Oncogene 21, 43454349.Google Scholar
95. Lu, R, Wang, X, Chen, ZF et al. (2007) Inhibition of the extracellular signal-regulated kinase/mitogen-activated protein kinase pathway decreases DNA methylation in colon cancer cells. J Biol Chem 282, 1224912259.CrossRefGoogle ScholarPubMed
96. Wei, D & Loeken, MR (2014) Increased DNA methyltransferase 3b (Dnmt3b) -mediated CpG island methylation stimulated by oxidative stress inhibits expression of a gene required for neural tube and neural crest development in diabetic pregnancy. Diabetes 63, 512522.Google Scholar
97. Lee, ST, Xiao, Y, Muench, MO et al. (2012) A global DNA methylation and gene expression analysis of early human B-cell development reveals a demethylation signature and transcription factor network. Nucleic Acids Res 40, 1133911351.Google Scholar
98. Nishino, K, Hattori, N, Tanaka, S et al. (2004) DNA methylation-mediated control of Sry gene expression in mouse gonadal development. J Biol Chem 279, 2230622313.Google Scholar
99. Laker, RC, Lillard, TS, Okutsu, M et al. (2014) Exercise prevents maternal high-fat diet-induced hypermethylation of the Pgc-1alpha gene and age-dependent metabolic dysfunction in the offspring. Diabetes 63, 16051611.CrossRefGoogle ScholarPubMed
100. Barres, R, Yan, J, Egan, B et al. (2012) Acute exercise remodels promoter methylation in human skeletal muscle. Cell Metab 15, 405411.Google Scholar
101. Ling, C, Del Guerra, S, Lupi, R et al. (2008) Epigenetic regulation of PPARGC1A in human type 2 diabetic islets and effect on insulin secretion. Diabetologia 51, 615622.Google Scholar
102. Tekpli, X, Landvik, NE, Anmarkud, KH et al. (2013) DNA methylation at promoter regions of interleukin 1B, interleukin 6, and interleukin 8 in non-small cell lung cancer. Cancer Immunol Immunother: CII 62, 337345.CrossRefGoogle ScholarPubMed
103. Fernandez-Alvarez, A, Llorente-Izquierdo, C, Mayoral, R et al. (2012) Evaluation of epigenetic modulation of cyclooxygenase-2 as a prognostic marker for hepatocellular carcinoma. Oncogenesis 1, e23.CrossRefGoogle ScholarPubMed
104. Turcot, V, Bouchard, L, Faucher, G et al. (2011) DPP4 gene DNA methylation in the omentum is associated with its gene expression and plasma lipid profile in severe obesity. Obesity (Silver Spring) 19, 388395.Google Scholar
105. El Gazzar, M, Yoza, BK, Hu, JY et al. (2007) Epigenetic silencing of tumor necrosis factor alpha during endotoxin tolerance. J Biol Chem 282, 2685726864.Google Scholar
106. Bell, AC, Felsenfeld, G (2000) Methylation of a CTCF-dependent boundary controls imprinted expression of the Igf2 gene. Nature 405, 482485.Google Scholar
107. Morey, SR, Smiraglia, DJ, James, SR et al. (2006) DNA methylation pathway alterations in an autochthonous murine model of prostate cancer. Cancer Res 66, 1165911667.Google Scholar
108. Wu, H, Coskun, V, Tao, J et al. (2010) Dnmt3a-dependent nonpromoter DNA methylation facilitates transcription of neurogenic genes. Science 329, 444448.CrossRefGoogle ScholarPubMed
109. Dias, RP, Bogdarina, I, Cazier, JB et al. (2012) Multiple segmental uniparental disomy associated with abnormal DNA methylation of imprinted Loci in silver-russell syndrome. J Clin Endocrinol Metab 97, E2188E2193.Google Scholar
110. Bahar Halpern, K, Vana, T & Walker, MD (2014) Paradoxical role of DNA methylation in activation of FoxA2 gene expression during endoderm development. J Biol Chem 289, 2388223892.Google Scholar
111. Klose, RJ & Bird, AP (2006) Genomic DNA methylation: the mark and its mediators. Trends Biochem Sci 31, 8997.Google Scholar
112. Deaton, AM, Webb, S, Kerr, AR et al. (2011) Cell type-specific DNA methylation at intragenic CpG islands in the immune system. Genome Res 21, 10741086.Google Scholar
113. Illingworth, R, Kerr, A, Desousa, D et al. (2008) A novel CpG island set identifies tissue-specific methylation at developmental gene loci. PLoS Biol 6, e22.Google Scholar
114. Liang, P, Song, F, Ghosh, S et al. (2011) Genome-wide survey reveals dynamic widespread tissue-specific changes in DNA methylation during development. BMC Genomics 12, 231.Google Scholar
115. Rauch, TA, Wu, X, Zhong, X et al. (2009) A human B cell methylome at 100-base pair resolution. Proc Natl Acad Sci USA 106, 671678.Google Scholar
116. Cedar, H & Bergman, Y (2012) Programming of DNA methylation patterns. Annu Rev Biochem 81, 97117.Google Scholar
117. Wilson, VL & Jones, PA (1983) DNA methylation decreases in aging but not in immortal cells. Science 220, 10551057.Google Scholar
118. Holliday, R (1986) Strong effects of 5-azacytidine on the in vitro lifespan of human diploid fibroblasts. Exp Cell Res 166, 543552.Google Scholar
119. Bocklandt, S, Lin, W, Sehl, ME et al. (2011) Epigenetic predictor of age. PLoS ONE 6, e14821.Google Scholar
120. Langton, AK, Herrick, SE & Headon, DJ (2008) An extended epidermal response heals cutaneous wounds in the absence of a hair follicle stem cell contribution. J Investig Dermatol 128, 13111318.Google Scholar
121. Moran, LB, Hickey, L, Michael, GJ et al. (2008) Neuronal pentraxin II is highly upregulated in Parkinson's disease and a novel component of Lewy bodies. Acta Neuropathol 115, 471478.Google Scholar
122. Park, JK, Ryu, JK, Lee, KH et al. (2007) Quantitative analysis of NPTX2 hypermethylation is a promising molecular diagnostic marker for pancreatic cancer. Pancreas 35, e9e15.Google Scholar
123. Qi, Y, Li, X, Zhao, L et al. (2010) Decreased Srcasm expression in esophageal squamous cell carcinoma in a Chinese population. Anticancer Res 30, 35353539.Google Scholar
124. Yan, M, Zhang, Z, Brady, JR et al. (2002) Identification of a novel death domain-containing adaptor molecule for ectodysplasin – a receptor that is mutated in crinkled mice. Curr Biol 12, 409413.Google Scholar
125. Issa, JP, Ottaviano, YL, Celano, P et al. (1994) Methylation of the oestrogen receptor CpG island links ageing and neoplasia in human colon. Nat Genet 7, 536540.Google Scholar
126. Li, LC, Shiina, H, Deguchi, M et al. (2004) Age-dependent methylation of ESR1 gene in prostate cancer. Biochem Biophys Res Commun 321, 455461.Google Scholar
127. Belinsky, SA (2004) Gene-promoter hypermethylation as a biomarker in lung cancer. Nat Rev Cancer 4, 707717.Google Scholar
128. De Jager, PL, Srivastava, G, Lunnon, K et al. (2014) Alzheimer's disease: early alterations in brain DNA methylation at ANK1, BIN1, RHBDF2 and other loci. Nat Neurosci 17, 11561163.Google Scholar
129. Hunter, A, Spechler, PA, Cwanger, A et al. (2012) DNA methylation is associated with altered gene expression in AMD. Invest Ophthalmol Vis Sci 53, 20892105.Google Scholar
130. Calder, PC (2015) Functional roles of fatty acids and their effects on human health. JPEN J Parenter Enteral Nutr 39(1 Suppl), 18S32S.Google Scholar
131. Kidani, Y & Bensinger, SJ (2012) Liver X receptor and peroxisome proliferator-activated receptor as integrators of lipid homeostasis and immunity. Immunol Rev 249, 7283.Google Scholar
132. Janowski, BA, Grogan, MJ, Jones, SA et al. (1999) Structural requirements of ligands for the oxysterol liver X receptors LXRalpha and LXRbeta. Proc Natl Acad Sci USA 96, 266271.Google Scholar
133. Geyeregger, R, Zeyda, M & Stulnig, TM (2006) Liver X receptors in cardiovascular and metabolic disease. Cell Mol Life Sci 63, 524539.Google Scholar
134. Peet, DJ, Turley, SD, Ma, W et al. (1998) Cholesterol and bile acid metabolism are impaired in mice lacking the nuclear oxysterol receptor LXR alpha. Cell 93, 693704.Google Scholar
135. Hannah, VC, Ou, J, Luong, A et al. (2001) Unsaturated fatty acids down-regulate SREBP isoforms 1a and 1c by two mechanisms in HEK-293 cells. J Biol Chem 276, 43654372.Google Scholar
136. Yoshikawa, T, Shimano, H, Amemiya-Kudo, M et al. (2001) Identification of liver X receptor-retinoid X receptor as an activator of the sterol regulatory element-binding protein 1c gene promoter. Mol Cell Biol 21, 29913000.Google Scholar
137. Yoshikawa, T, Shimano, H, Yahagi, N et al. (2002) Polyunsaturated fatty acids suppress sterol regulatory element-binding protein 1c promoter activity by inhibition of liver X receptor (LXR) binding to LXR response elements. J Biol Chem 277, 17051711.Google Scholar
138. Laffitte, BA, Chao, LC, Li, J et al. (2003) Activation of liver X receptor improves glucose tolerance through coordinate regulation of glucose metabolism in liver and adipose tissue. Proc Natl Acad Sci USA 100, 54195424.CrossRefGoogle ScholarPubMed
139. Cao, G, Liang, Y, Broderick, CL et al. (2003) Antidiabetic action of a liver x receptor agonist mediated by inhibition of hepatic gluconeogenesis. J Biol Chem 278, 11311136.CrossRefGoogle ScholarPubMed
140. Naiki, T, Nagaki, M, Shidoji, Y et al. (2002) Analysis of gene expression profile induced by hepatocyte nuclear factor 4alpha in hepatoma cells using an oligonucleotide microarray. J Biol Chem 277, 1401114019.Google Scholar
141. Krapivner, S, Iglesias, MJ, Silveira, A et al. (2010) DGAT1 participates in the effect of HNF4A on hepatic secretion of triglyceride-rich lipoproteins. Arterioscler Thromb Vasc Biol 30, 962967.Google Scholar
142. Boj, SF, Parrizas, M, Maestro, MA et al. (2001) A transcription factor regulatory circuit in differentiated pancreatic cells. Proc Natl Acad Sci USA 98, 14481144816.Google Scholar
143. Odom, DT, Zizlsperger, N, Gordon, DB et al. (2004) Control of pancreas and liver gene expression by HNF transcription factors. Science 303, 13781381.Google Scholar
144. Goldstein, JL, DeBose-Boyd, RA & Brown, MS (2006) Protein sensors for membrane sterols. Cell 124, 3546.CrossRefGoogle ScholarPubMed
145. Thewke, DP, Panini, SR & Sinensky, M (1998) Oleate potentiates oxysterol inhibition of transcription from sterol regulatory element-1-regulated promoters and maturation of sterol regulatory element-binding proteins. J Biol Chem 273, 2140221407.CrossRefGoogle ScholarPubMed
146. Worgall, TS, Sturley, SL, Seo, T et al. (1998) Polyunsaturated fatty acids decrease expression of promoters with sterol regulatory elements by decreasing levels of mature sterol regulatory element-binding protein. J Biol Chem 273, 2553725540.Google Scholar
147. Tabor, DE, Kim, JB, Spiegelman, BM et al. (1999) Identification of conserved cis-elements and transcription factors required for sterol-regulated transcription of stearoyl-CoA desaturase 1 and 2. J Biol Chem 274, 2060320610.CrossRefGoogle ScholarPubMed
148. Yahagi, N, Shimano, H, Hasty, AH et al. (1999) A crucial role of sterol regulatory element-binding protein-1 in the regulation of lipogenic gene expression by polyunsaturated fatty acids. J Biol Chem 274, 3584035844.Google Scholar
149. Patterson, WL III & Georgel, PT (2014) Breaking the cycle: the role of omega-3 polyunsaturated fatty acids in inflammation-driven cancers. Biochem Cell Biol 92, 18.Google Scholar
150. Kulkarni, A, Dangat, K, Kale, A et al. (2011) Effects of altered maternal folic acid, vitamin B12 and docosahexaenoic acid on placental global DNA methylation patterns in Wistar rats. PLoS ONE 6, e17706.Google Scholar
151. Chen, PY, Ganguly, A, Rubbi, L et al. (2013) Intrauterine calorie restriction affects placental DNA methylation and gene expression. Physiol Genomics 45, 565576.Google Scholar
152. Bind, MA, Lepeule, J, Zanobetti, A et al. (2014) Air pollution and gene-specific methylation in the Normative Aging Study: association, effect modification, and mediation analysis. Epigenetics 9, 448458.Google Scholar
153. De Prins, S, Koppen, G, Jacobs, G et al. (2013) Influence of ambient air pollution on global DNA methylation in healthy adults: a seasonal follow-up. Environ Int 59, 418424.Google Scholar
154. Peluso, M, Bollati, V, Munnia, A et al. (2012) DNA methylation differences in exposed workers and nearby residents of the Ma Ta Phut industrial estate, Rayong, Thailand. Int J Epidemiol 41, 17531760; discussion 61–3.Google Scholar
155. Zhang, FF, Santella, RM, Wolff, M et al. (2012) White blood cell global methylation and IL-6 promoter methylation in association with diet and lifestyle risk factors in a cancer-free population. Epigenetics 7, 606614.Google Scholar
156. Stefani, FA, Viana, MB, Dupim, AC et al. (2013) Expression, polymorphism and methylation pattern of interleukin-6 in periodontal tissues. Immunobiology 218, 10121017.Google Scholar
157. Kim, J, Bhattacharjee, R, Khalyfa, A et al. (2012) DNA methylation in inflammatory genes among children with obstructive sleep apnea. Am J Resp Crit Care Med 185, 330338.Google Scholar
158. Baccarelli, A, Tarantini, L, Wright, RO et al. (2010) Repetitive element DNA methylation and circulating endothelial and inflammation markers in the VA normative aging study. Epigenetics 5, 222228.Google Scholar
159. Sun, YV, Lazarus, A, Smith, JA et al. (2013) Gene-specific DNA methylation association with serum levels of C-reactive protein in African Americans. PLoS ONE 8, e73480.Google Scholar
160. Irvin, MR, Zhi, D, Joehanes, R et al. (2014) Epigenome-wide association study of fasting blood lipids in the genetics of lipid lowering drugs and diet network study. Circulation 130, 565572.Google Scholar
161. Guay, SP, Brisson, D, Munger, J et al. (2012) ABCA1 gene promoter DNA methylation is associated with HDL particle profile and coronary artery disease in familial hypercholesterolemia. Epigenetics 7, 464472.Google Scholar
162. Guay, SP, Brisson, D, Lamarche, B et al. (2013) DNA methylation variations at CETP and LPL gene promoter loci: new molecular biomarkers associated with blood lipid profile variability. Atherosclerosis 228, 413420.Google Scholar
163. Lai, CQ, Arnett, DK, Corella, D et al. (2007) Fenofibrate effect on triglyceride and postprandial response of apolipoprotein A5 variants: the GOLDN study. Arterioscler Thromb Vasc Biol 27, 14171425.CrossRefGoogle ScholarPubMed
164. Adalsteinsson, BT, Gudnason, H, Aspelund, T et al. (2012) Heterogeneity in white blood cells has potential to confound DNA methylation measurements. PLoS ONE 7, e46705.Google Scholar
165. Bouwens, M, Afman, LA & Muller, M (2008) Activation of peroxisome proliferator-activated receptor alpha in human peripheral blood mononuclear cells reveals an individual gene expression profile response. BMC Genomics 9, 262.Google Scholar
166. Bouwens, M, Afman, LA & Muller, M (2007) Fasting induces changes in peripheral blood mononuclear cell gene expression profiles related to increases in fatty acid beta-oxidation: functional role of peroxisome proliferator activated receptor alpha in human peripheral blood mononuclear cells. Am J Clin Nutr 86, 15151523.Google Scholar
167. Psaty, BM, O'Donnell, CJ, Gudnason, V et al. (2009) Cohorts for Heart and Aging Research in Genomic Epidemiology (CHARGE) Consortium: design of prospective meta-analyses of genome-wide association studies from 5 cohorts. Circ Cardiovasc Genet 2, 7380.Google Scholar
168. Zhi, D, Aslibekyan, S, Irvin, MR et al. (2013) SNPs located at CpG sites modulate genome-epigenome interaction. Epigenetics 8, 802806.Google Scholar
169. Ma, Y, Smith, CE, Lai, CQ et al. (2015) Genetic variants modify the effect of age on APOE methylation in the Genetics of Lipid Lowering Drugs and Diet Network study. Aging Cell 14, 4959.Google Scholar
170. Ma, Y, Smith, CE, Lai, CQ et al. (2016) The effects of omega-3 polyunsaturated fatty acids and genetic variants on methylation levels of the interleukin-6 gene promoter. Mol Nutr Food Res 60, 410419.Google Scholar
171. Ma, Y, Follis, JL, Smith, CE et al. (2016) Interaction of methylation-related genetic variants with circulating fatty acids on plasma lipids: a meta-analysis of 7 studies and methylation analysis of 3 studies in the Cohorts for Heart and Aging Research in Genomic Epidemiology consortium. Am J Clin Nutr 103, 567578.Google Scholar
172. Schalkwyk, LC, Meaburn, EL, Smith, R et al. (2010) Allelic skewing of DNA methylation is widespread across the genome. Am J Hum Genet 86, 196212.Google Scholar
173. Corder, EH, Saunders, AM, Strittmatter, WJ et al. (1993) Gene dose of apolipoprotein E type 4 allele and the risk of Alzheimer's disease in late onset families. Science 261, 921923.Google Scholar
174. Gordon, SC & Landa, D (2010) Disclosure of the genetic risk of Alzheimer's disease. N Engl J Med 362, 181182.Google Scholar
175. Kane, RA & Kane, RL (2009) Effect of genetic testing for risk of Alzheimer's disease. N Engl J Med 361, 298299.CrossRefGoogle ScholarPubMed
176. Green, RC, Roberts, JS, Cupples, LA et al. (2009) Disclosure of APOE genotype for risk of Alzheimer's disease. N Engl J Med 361, 245254.Google Scholar