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Nutritional influences on epigenetics and age-related disease

Published online by Cambridge University Press:  04 November 2011

Lara K. Park
Affiliation:
Vitamins and Carcinogenesis Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging at Tufts University, Boston, MA 02111, USA Biochemical and Molecular Nutrition Program, Friedman School of Nutrition, Tufts University, Boston, MA 02111, USA
Simonetta Friso
Affiliation:
Department of Medicine, University of Verona School of Medicine, Verona, Italy
Sang-Woon Choi*
Affiliation:
Vitamins and Carcinogenesis Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging at Tufts University, Boston, MA 02111, USA Biochemical and Molecular Nutrition Program, Friedman School of Nutrition, Tufts University, Boston, MA 02111, USA
*
*Corresponding author: Dr Sang-Woon Choi, fax +1 617 556 3234, email [email protected]
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Abstract

Nutritional epigenetics has emerged as a novel mechanism underlying gene–diet interactions, further elucidating the modulatory role of nutrition in aging and age-related disease development. Epigenetics is defined as a heritable modification to the DNA that regulates chromosome architecture and modulates gene expression without changes in the underlying bp sequence, ultimately determining phenotype from genotype. DNA methylation and post-translational histone modifications are classical levels of epigenetic regulation. Epigenetic phenomena are critical from embryonic development through the aging process, with aberrations in epigenetic patterns emerging as aetiological mechanisms in many age-related diseases such as cancer, CVD and neurodegenerative disorders. Nutrients can act as the source of epigenetic modifications and can regulate the placement of these modifications. Nutrients involved in one-carbon metabolism, namely folate, vitamin B12, vitamin B6, riboflavin, methionine, choline and betaine, are involved in DNA methylation by regulating levels of the universal methyl donor S-adenosylmethionine and methyltransferase inhibitor S-adenosylhomocysteine. Other nutrients and bioactive food components such as retinoic acid, resveratrol, curcumin, sulforaphane and tea polyphenols can modulate epigenetic patterns by altering the levels of S-adenosylmethionine and S-adenosylhomocysteine or directing the enzymes that catalyse DNA methylation and histone modifications. Aging and age-related diseases are associated with profound changes in epigenetic patterns, though it is not yet known whether these changes are programmatic or stochastic in nature. Future work in this field seeks to characterise the epigenetic pattern of healthy aging to ultimately identify nutritional measures to achieve this pattern.

Type
70th Anniversary Conference on ‘Vitamins in early development and healthy aging: impact on infectious and chronic disease’
Copyright
Copyright © The Authors 2011

Abbreviations:
CpG

cytosine-guanine dinucleotides

DNMT

DNA methyltransferase

EGCG

epigallocatechin-3-gallate

HAT

histone acetyltransferase

HDAC

histone deacetylase

SAM

S-adenosylmethionine

SAH

S-adenosylhomocysteine

SIRT1

Sirtuin 1

In the advent of Genome Wide Association Studies, considerable progress has been made elucidating genetic susceptibilities to complex chronic diseases( Reference Juran and Lazaridis 1 ). Despite this progress there is still a substantial proportion of phenotypic disparity that has not been explained by genetics, thus shifting the focus to environmental influences. Nutrition is a major environmental exposure that influences all aspects of health and lifespan( Reference Rakyan, Down and Balding 2 ). Nutrients are known to alter gene expression and thereby affect phenotype( Reference Crott, Choi and Ordovas 3 ). Epigenetics is a recently highlighted molecular mechanism by which nutrients can alter gene expression( Reference Choi and Friso 4 ). Epigenetic phenomena are heritable and modifiable marks that regulate gene transcription without altering the underlying DNA sequence( Reference Choi and Friso 4 ).

DNA methylation and histone modifications are classical epigenetic phenomena that alter localised DNA compaction to regulate expression( Reference Choi and Friso 4 ). DNA methylation is a biochemical modification of cytosine in DNA with a one-carbon unit (a methyl group) and is typically associated with gene repression( Reference Choi and Friso 4 ). Post-translation modifications of histone tails by methylation, acetylation, phosphorylation, biotinylation and ubiquitination modulate the compaction of the DNA around the core histones and serve as docking sites for transcriptional regulators( Reference Choi and Friso 4 ). Histone modifications can either activate or repress gene expression depending on the type of modification and the placement along the histone tail( Reference Choi and Friso 4 ). Extensive synergy exists between levels of epigenetic marks to determine accessibility of genes to transcriptional regulators( Reference Cheng and Blumenthal 5 ).

Nutrition affects epigenetic phenomena at multiple levels( Reference Choi and Friso 4 ). First, nutrients act as a source of methyl groups or as co-enzymes for one-carbon metabolism that regulates methyl transfer( Reference Kim, Friso and Choi 6 ). B-vitamins including folate, vitamin B12, vitamin B6 and vitamin B2 are involved as co-enzymes with methionine, choline, betaine and serine as methyl donors for DNA methylation and histone methylation( Reference Jang, Mason and Choi 7 ). Second, nutrients and bioactive food components can directly affect enzymes that catalyse DNA methylation and histone modifications( Reference Choi and Friso 4 ). Third, diet is the ultimate input determining systemic metabolism which modifies cellular milieu leading to alterations in epigenetic patterns( Reference Cyr and Domann 8 ).

Although it is known that these epigenetic phenomena can be modified by nutrients, their role in physiologic and pathological processes has not been extensively studied through these mechanisms( Reference Choi and Friso 4 ). In this overview, we will focus on the influences of nutrition on epigenetics and how these influences affect the age-related diseases.

Nutrition and DNA methylation

Nutrients, one-carbon metabolism and DNA methylation

DNA methylation is the most studied epigenetic mechanism which entails the addition of a methyl group at cytosine–guanine dinucleotides (CpG)( Reference Zilberman and Henikoff 9 ). The reactions involved in DNA methylation are a part of one-carbon metabolism, which regulates the transfer of the one-carbon moiety (methyl group) into biological methylation reactions( Reference Choi and Friso 4 ). B-vitamins are coenzymes in one-carbon metabolism (Fig. 1), supporting that nutrients regulate epigenetic reactions( Reference Friso and Choi 10 ). The amino acid methionine is converted to S-adenosylmethionine (SAM), the unique methyl donor for many biological methylation reactions including DNA methylation( Reference Choi and Friso 4 ). Folate-derived methyl groups are utilised for remethylation of homocysteine to produce methionine( Reference Friso and Choi 10 ). Choline also provides methyl groups for the folate-independent homocysteine remethylation reaction; together these demonstrate how nutrients can serve as the source of epigenetic modifications( Reference Tibbetts and Appling 11 ). After transferring the methyl group, SAM is converted to S-adenosylhomocysteine (SAH), an inhibitor of methyltransferases( Reference Tibbetts and Appling 11 ). Deficiency of B-vitamins, methionine and/or choline can significantly affect DNA methylation by altering the levels of SAM and SAH( Reference Choi and Friso 4 , Reference Taban-Shomal, Kilter and Wagner 12 , Reference Kim, Hong and Lee 13 ).

Fig. 1. One-carbon metabolism. S-adenosylmethionine (SAM) is the unique methyl donor for many biological methylation reactions including DNA and histone methylation. S-adenosylhomocysteine (SAH) is an inhibitor of methyltransferases such as DNA methyltransferases (DNMT) and histone methyltransferases. In one-carbon metabolism vitamins B2, B6, B12 and folate are coenzymes, while methionine, choline, betaine and serine are methyl donors. THF, tetrahydrofolate; 5-mTHF, 5-methyltetrahydrofolate; MT, methyltransferases; HMT, histone methyltransferases; MTHFR, methylenetetrahydrofolate reductase; MS, methionine synthase; SHMT, serine hydroxymethyltransferase; GNMT, glycine N-methyltransferase; CBS, cystathionine-β-synthase; MAT, methionine adenosyltransferase; SAHH, S-adenosylhomocysteine hydrolase; BHMT, Betaine homocysteine methyltransferase; B2, vitamin B2; B6, vitamin B6; B12, vitamin B12.

Modifying the intake of these nutrients alters DNA methylation( Reference Niculescu and Zeisel 14 ). In animal models, folate deficiency along with aging( Reference Keyes, Mason Joel and Liu 15 ) and multiple B-vitamins deficiency( Reference Liu, Choi and Crott 16 ) induced genomic DNA hypomethylation in the colon. It is also reported that choline deficiency can change DNA methylation independently( Reference Niculescu, Craciunescu and Zeisel 17 ) or in conjunction with deficiency of other methyl donors( Reference Niculescu and Zeisel 14 ). Prolonged intake of diets deficient in sources of methyl groups such as methionine, choline, folate and vitamin B12 induce profound genomic hepatic DNA hypomethylation in a rodent model( Reference Pogribny, Ross and Wise 18 ). This model has also demonstrated that a methyl-deficient diet changes histone methylation( Reference Pogribny, Ross and Tryndyak 19 ) and microRNA production( Reference Tryndyak, Ross and Beland 20 ), which may potentiate the development of liver cancer.

Two previous human studies conducted in a metabolic unit demonstrated that marginal folate deficiency can change blood genomic DNA methylation( Reference Jacob, Gretz and Taylor 21 , Reference Rampersaud, Kauwell and Hutson 22 ). Compared to animal studies, however, evidence demonstrating significant effects of folate supplementation on DNA methylation in free living human subjects is limited. Recently, Pizzolo et al. ( Reference Pizzolo, Blom and Choi 23 ) reported that 8-week daily supplementation of 5 mg folic acid did not change DNA methylation in peripheral mononuclear cells despite increases in blood concentrations of folate and SAM and decreases in SAH. This observation suggests that changes in the levels of SAM and SAH may not always induce changes in DNA methylation. Consistently, two previous cystathionine β-synthase-deficient mouse studies demonstrated that increased levels of SAM and SAH are not always correlated with DNA methylation status in a tissue-specific manner( Reference Choumenkovitch, Selhub and Bagley 24 , Reference Caudill, Wang and Melnyk 25 ). It is important to note that different tissues have different susceptibilities to methyl deficiency and therefore this lack of response may not be consistent across all tissues( Reference Liu, Pickford and Meagher 26 ).

Other specific nutrients can modify one-carbon metabolism to alter DNA methylation( Reference Choi and Friso 4 ). Retinoic acid is known to affect glycine N-methyltransferase which catalyses the reaction from SAM to SAH( Reference Ozias and Schalinske 27 ). Genome-wide DNA methylation assays demonstrated 166 differentially methylated CpG sites between undifferentiated and retinoic acid-treated human embryonic stem cells( Reference Cheong, Lee and Park 28 ). Interestingly, a high-throughput DNA methylation array with neuroblastoma cells in vitro demonstrated that 402 gene promoters became demethylated and eighty-eight hypermethylated following retinoic acid treatment( Reference Das, Foley and Bryan 29 ). These studies indicate that nutrients can interact with the pathways regulating DNA methylation, though it remains to be determined how nutrients target specific genes for epigenetic modification or, alternatively, if these changes are stochastic in nature.

The trace element Se is an essential component of the antioxidant selenoproteins such as glutathione peroxidases( Reference Jackson-Rosario and Self 30 ). Se has been known to influence the trans-sulfuration pathway in one-carbon metabolism which converts homocysteine to cysteine and ultimately glutathione( Reference Davis and Uthus 31 ). In a rodent study, Uthus et al. ( Reference Uthus, Yokoi and Davis 32 ) found that plasma total homocysteine and cysteine were significantly decreased and glutathione significantly increased by Se deficiency. They also found significantly decreased genomic DNA methylation by Se deficiency in the colon, with concomitant trend for decreased DNA methyltransferase (DNMT) activity (P<0·06), suggesting a relationship between Se metabolism and DNMT function( Reference Uthus, Ross and Davis 33 ). Most recently, Zeng et al. ( Reference Zeng, Yan and Cheng 34 ) reported that dietary Se supplementation increases exon-specific DNA methylation of the tumour suppressor p53 in the rat liver and colon thereby suggesting the over-supplementation with Se may increase cancer risk. These observations indicate that Se alters one-carbon metabolism leading to both genomic and gene-specific changes in DNA methylation.

Research into the chemopreventive effects of vitamin D has taken the forefront due to the role of the vitamin D receptor in cell-cycle regulation and differentiation( Reference Lamprecht and Lipkin 35 ). Recent evidence demonstrates that incubation of MCF-7 breast cancer cells with vitamin D3, which models oestrogen receptor+ non-invasive breast cancer, reduces the aberrant hypermethylation and restores gene expression of retinoic acid receptor β2( Reference Stefanska, Rudnicka and Bednarek 36 ) and phosphatase and tensin homologue( Reference Stefanska, Salamé and Bednarek 37 ). Although this mechanism remains to be validated in vivo, this work indicates that vitamin D can modify gene-specific DNA methylation.

Bioactive food components and DNA methylation

Bioactive food components are compounds consumed in the diet that are not essential for life, though they may have beneficial health effects( Reference Choi and Friso 4 ). Numerous bioactive food components can alter epigenetic patterns through both direct and indirect interactions with the enzymes regulating the placement of epigenetic marks( Reference Choi and Friso 4 ). Research indicates that these interactions can be gene specific in nature, suggesting that the bioactive food compounds may target these enzymes to specific sites within the genome( Reference Davis and Ross 38 ).

Genistein is an isoflavone belonging to the flavonoids group of compounds derived from legumes that has demonstrated great potential to regulate the epigenome( Reference Meeran, Ahmed and Tollefsbol 39 , Reference Zhang and Chen 40 ). In the agouti mouse model, it is well established that maternal dietary genistein increases the level of DNA methylation at the agouti locus and produces more pseudo-agouti black coat-coloured offspring( Reference Dolinoy, Weidman and Waterland 41 ). In mouse embryonic stem cells, genistein does not affect de novo methylation occurring between day 0 and day 4, but interferes with subsequent regulatory processes leading to decreased methylation at the uncoupling protein 1 and synaptotagmin-like 1 promoters( Reference Sato, Yamakawa and Masuda 42 ). This indicates that genistein perturbed the methylation pattern of differentiated embryonic stem cells after de novo methylation in a time-dependent manner. Fang et al. ( Reference Fang, Chen and Sun 43 , Reference Fang, Chen and Yang 44 ) reported that genistein dose-dependently inhibited DNMT activity and partially reactivated genes repressed by hypermethylation such as retinoic acid receptor β, p16 and O-6-methylguanine-DNA methyltransferase in oesophageal squamous cell carcinoma cell lines. Similar effects were observed from the cancer cell lines of colon( Reference Wang and Chen 45 ), prostate( Reference Vardi, Bosviel and Rabiau 46 ) and cervix( Reference Jha, Nikbakht and Parashar 47 ). These observations indicate that genistein can modify DNA methylation tissue specifically, gene specifically and life cycle specifically.

Epigallocatechin-3-gallate (EGCG), the primary polyphenol in green tea, is known to have anti-cancer effects through many different mechanisms( Reference Suganuma, Saha and Fujiki 48 ). One candidate mechanism is the inhibition of DNMT1 leading to hypomethylation and de-repression of epigenetically silenced genes( Reference Lee, Shim and Zhu 49 ). Nandakumar et al. ( Reference Nandakumar, Vaid and Katiyar 50 ) reported that EGCG reactivates silenced tumour suppressor genes p21 and p16 by reducing DNA methylation in human skin cancer cells, resulting in re-expression of mRNA and proteins of silenced tumour suppressors. Wong et al. ( Reference Wong, Nguyen and Noh 51 ) also reported that physiologically relevant concentrations of EGCG can induce the expression of forkhead box P3, a master switch that controls the development and function of regulatory T-cells and Jurkat T-cells in vitro. These cells play a critical role in the maintenance of tolerance and the control of autoimmunity. The expression of forkhead box P3 was associated with reduced DNMT expression and DNA demethylation in EGCG-treated cells, suggesting that EGCG may epigenetically modify forkhead box P3 methylation and promote regulatory T-cell induction and expansion to potentially support the immune response to cancer. The DNMT inhibitory effects of EGCG were not as potent as pharmacologic agents such as 5-aza-2′-deoxycytidine, though this is not unexpected as nutrients are not specifically designed as therapeutics. It appears that EGCG provides potentially sustained and longer-term exposure effects with lower toxicity compared with pharmacologic agents, demonstrating the potential benefits of natural substances as chemotherapeutics.

In addition to the direct inhibitory effects of DNMT1, it is also reported that consumption of polyphenols could increase the formation of SAH, which supports an additional mechanism inhibiting DNA methylation by EGCG( Reference Lee, Shim and Zhu 52 ). Animal studies also demonstrated that EGCG consumption through drinking water can moderately decrease the level of SAM in the intestine( Reference Fang, Chen and Yang 44 ). Both observations indicate that the inhibitory effects of EGCG on DNMT1 could be conveyed indirectly by modifying one-carbon metabolism.

Apigenin from parsley( Reference Fang, Chen and Yang 44 ), curcumin from turmeric( Reference Fu and Kurzrock 53 ), lycopene from tomato( Reference King-Batoon, Leszczynska and Klein 54 ) and sulforaphane from cruciferous vegetables( Reference Meeran, Patel and Tollefsbol 55 ) are also known to have an inhibitory effect on DNMT, though their effects are weaker than that of tea polyphenols and genistein. Further studies are needed to determine the optimal nutrients intakes to effectively regulate the epigenome in health.

Nutrition and histone modifications

Bioactive food components and histone modifications

Histone proteins are essential for the packaging of DNA into chromosomes within the nucleus of a cell( Reference Esteller 56 ). Post-translational modifications of histones have been highlighted due to their function to regulate gene expression, especially synergistic interactions with DNA methylation( Reference Cheng and Blumenthal 5 ). Further, dysregulated histone acetylation patterns have been associated with many diseases including cancer, cardiac hypertrophy and asthma( Reference Esteller 56 Reference North and Ellis 58 ). Among many different types of histone tail modifications, histone acetylation has been the most frequent target to evaluate the epigenetic effects of nutrients, bioactive components and aging( Reference Davis and Ross 38 , Reference Bandyopadhyay and Medrano 59 ). Histone acetylation is an epigenetic phenomenon that acetylates lysine residues at the histone tail to alter local DNA compaction, leading to site-specific changes in gene expression( Reference An 60 ). The histone acetylation status is regulated by a family histone acetyltransferases (HAT) and histone deacetylases (HDAC).

Butyrate is generated during the fermentation of dietary fibre in the large intestine( Reference Alvaro, Solà and Rosales 61 ). Early in 1977, Riggs et al. ( Reference Riggs, Whittaker and Neumann 62 ) reported that addition of sodium n-butyrate to tissue culture media increases global histone acetylation in cancer cell lines. Thereafter, sulforaphane, an isothiocyanate from broccoli, broccoli sprouts and cabbage as well as allyl compounds from garlic such as diallyl disulfide and S-allyl mercaptocysteine have been demonstrated to have HDAC inhibitory effects( Reference Meeran, Ahmed and Tollefsbol 39 ). In light of the development of chemotherapeutic HDAC inhibitors, this suggests potential functional significance of this family of bioactive food components as chemopreventive agents to regulate histone acetylation status( Reference Fang 63 ).

Curcumin, a yellow pigment present in the spice turmeric (Curcuma longa), has been linked with multiple beneficial activities with anti-inflammatory, antioxidant and anti-cancer properties( Reference Goel and Aggarwal 64 ). Curcumin is known to have inhibitory activity against HDAC and HAT, with a specifically strong inhibition of HAT in cancer models( Reference Goel and Aggarwal 64 , Reference Marcu, Jung and Lee 65 ). Kang et al. ( Reference Kang, Cha and Jeon 66 ) demonstrated that curcumin-mediated HAT inhibitory activity is associated with decreased histone 3 and 4 acetylation in both glioblastoma cancer cells and adult neural-derived stem cells. Functionally, these epigenetic changes were associated with increased apoptosis in cancer cells and promoted neuronal differentiation in stem cells, suggesting possible therapeutic potential in cancer and neurodegenerative diseases.

Aging and nutritional epigenetics

There is a body of literature demonstrating changes in epigenetic patterns over the aging process. It is currently unknown whether these changes are programmatic or stochastic, and whether they are causal or resultant of the aging process in itself( Reference Gravina and Vijg 67 ). Aging is known to affect DNA methylation in a complex fashion( Reference Choi, Friso and Dolnikowski 68 ). Total methylcytosine content is prone to decrease by aging, leading to genomic hypomethylation in most vertebrate tissues( Reference Richardson 69 , Reference Golbus, Palella and Richardson 70 ), whereas promoter regions tend to undergo paradoxical hypermethylation in many genes( Reference Thompson, Atzmon and Gheorghe 71 ). The most plausible mechanism proposes that decreased expression of the maintenance DNMT1 underlies reduced genomic hypomethylation, while increased expression of de novo DNMT mediates promoter hypermethylation( Reference Kim, Friso and Choi 72 ).

In previous studies, aging reduces genomic DNA methylation and increases promoter methylation of p16 tumour suppressor gene in the mouse colon( Reference Keyes, Mason Joel and Liu 15 ). Dietary supplementation of the methyl donor folate increased both genomic and p16 promoter DNA methylation in the aged mouse colon but not in the young, indicating that DNA methylation can be modified by diet in an age-dependent manner( Reference Keyes, Mason Joel and Liu 15 , Reference Sauer, Jang and Zimmerly 73 ).

Wallace et al. ( Reference Wallace, Grau and Levine 74 ) investigated the association of blood folate levels with promoter CpG island methylation in normal colorectal mucosa in a multicentre chemoprevention trial of aspirin or folic acid for the prevention of colonic adenoma. For each 10-year difference in age, they observed a 1·7% increase in methylation level for oestrogen receptor α and a 2·9% increase for secreted frizzled-related protein-1, both of which were statistically significant (P<0·0001). These genes are particularly relevant because secreted frizzled-related protein-1 acts as an inhibitor of the Wnt signalling, a pathway that is implicated in colorectal carcinogenesis( Reference Burgess, Faux and Layton 75 ). Oestrogen receptor α activates a transcriptional programme regulating cellular proliferation, and this activity changes with aging due to reductions in sex hormones( Reference Issa, Ottaviano and Celano 76 ). Erythrocyte folate levels were positively associated with methylation levels of both oestrogen receptor α (P<0·03) and secreted frizzled-related protein-1 (P<0·01)( Reference Wallace, Grau and Levine 74 ). These results suggest that promoter CpG methylation in normal colorectal mucosa correlates with age and erythrocyte folate levels and that erythrocyte folate could be a clinical marker of colorectal DNA methylation.

Normal aging is accompanied by a profound loss of histone proteins from the genome that hypothetically would have a profound effect on genomic structural integrity and the regulation of transcriptional programmes( Reference Das and Tyler 77 ). Previous work in yeast models demonstrates increased overall histone expression promotes lifespan, underscoring the importance of histone-mediated regulation of DNA architecture in health( Reference Feser, Truong and Das 78 ).

Sirtuins, a group of conserved NAD+-dependent deacetylases, promote longevity in many organisms( Reference Haigis and Sinclair 79 ). Sirtuin 1 (SIRT1) is known to deacetylate histones and non-histone proteins, thereby regulating metabolism, stress resistance, cellular survival, cellular senescence/aging, inflammation-immune function, endothelial functions and circadian rhythms( Reference Haigis and Sinclair 79 ). Yeast silent information regulator 2, related to the mammalian homologue SIRT1, establishes and maintains chromatin silencing by removing acetylation at histone H4 at lysine 16 (H4K16)( Reference Vaquero, Sternglanz and Reinberg 80 ). Dang et al. ( Reference Dang, Steffen and Perry 81 ) reported an age-associated decrease in silent information regulator 2 protein accompanied by an increase in acetylation at H4K16, resulting in compromised transcriptional silencing.

Naturally occurring dietary polyphenols, such as resveratrol, curcumin, quercetin and catechins, have been shown to activate SIRT1 in a variety of models( Reference Chung, Yao and Caito 82 ). Since the activation of SIRT1 by polyphenols is beneficial in various cellular functions in response to environmental and pro-inflammatory stimuli, the regulation of SIRT1 activity by dietary polyphenols is a promising strategy against chronic inflammation, which plays an aetiological role in many age-related diseases.

Li et al. ( Reference Li, Liu and Xie 83 ) found that histone H3 acetylation at lysine 9 and 14 sites, H3K9 and H3K14, respectively, which can be modulated by extrinsic signals, plays a key role in regulating mesenchymal stem cell aging and differentiation. Human mesenchymal cells in early and late passages were examined for their expression of osteogenic genes and genes involved in self-renewal and proliferation to determine their in vitro spontaneous differentiation towards the osteoblast lineage v. multi-potent potential, respectively. Altered expression of these genes were closely associated with epigenetic dysregulation of H3K9 and H3K14 acetylation but not with methylation of CpG islands in the promoter regions of most of these genes, suggesting that histone acetylation may be more sensitive to cellular senescence than DNA promoter methylation.

Nutritional influences on age-related diseases through epigenetics

Epigenetic patterns are heavily influenced by the environment; due to dietary requirements for sustenance, it follows that nutrition represents a substantial daily environmental input( Reference Kennedy 84 ). Nutrition influences our physiology over the course of the entire lifecycle, with particular phases representing times that are more sensitive to nutritional inputs( Reference Stipp 85 ). Most recent studies indicate that the effects of nutrition in early life alters programmes leading to differential disease susceptibilities later in life which may be conveyed through epigenetic mechanisms( Reference Zeisel 86 ). Furthermore, the majority of age-related chronic diseases in the developed world are multi-factorial with substantial lifestyle components, indicating a significant role for nutritional epigenetics in their development( Reference Feinberg 87 ).

Sie et al. ( Reference Sie, Medline and van Weel 88 ) investigated the effect of maternal and post-weaning folic acid supplementation on colorectal cancer risk in the offspring. The data suggested for the first time that maternal folic acid supplementation at North American post-fortification levels recommended to women at reproductive age protects against the development of colorectal cancer in the offspring. This protective effect may be mediated in part by increased global DNA methylation, decreased epithelial proliferation and reduced DNA damage in the colorectum. However, the same group reported that high intrauterine and post-weaning dietary exposure to folic acid may increase the risk of mammary tumours in the offspring, mediated in part by altered DNA methylation and DNMT activity( Reference Ly, Lee and Chen 89 ). These results indicate that different tissues have variable responses to folic acid supplementation, again emphasising the tissue specificity of epigenetic regulation.

The disruption of the HAT and HDAC balance can also be a major mechanism underlying changing epigenetic patterns with functional disease output, including cancer and neurodegeneration( Reference Saha and Pahan 90 ). In a rodent study, aged mice display specific deregulation of histone H4 at lysine 12 (H4K12) acetylation during learning and fail to initiate a hippocampal gene expression programme associated with memory consolidation. Restoration of deregulated histone acetylation reinstates the expression of learning-induced genes and recovers cognitive functions, purporting the importance of epigenetic histone regulation in neurological function( Reference Peleg, Sananbenesi and Zovoilis 91 ). Interestingly, Govindarajan et al. ( Reference Govindarajan, Agis-Balboa and Walter 92 ) reported that butyrate, which is known to have an HDAC inhibitory effect, improves memory function in an Alzheimer's disease mouse model when administered at an advanced stage of disease.

As aberrant histone deacetylation has been demonstrated to silence critical genes in carcinogenesis, HDAC inhibitors have great potential as new anti-cancer drugs due to their ability to modulate transcription( Reference Tanji, Ozawa and Kikugawa 93 ). HDAC inhibitors such as trichostatin-A induce apoptosis and suppress cancer cell growth by affecting the acetylation status of tumour suppressor genes in cancer cell lines, though their specificity to gene targets is not well understood( Reference Fortson, Kayarthodi and Fujimura 94 , Reference Xiong, Du and Zhang 95 ). Sulforaphane and curcumin have similar effects on cancer cells by modifying histone acetylation( Reference Goel and Aggarwal 64 , Reference Clarke, Hsu and Yu 96 ). Sulforaphane inhibits HDAC activity in vivo and suppresses tumorigenesis in APCmin mice( Reference Myzak, Dashwood and Orner 97 ). In vitro, sulforaphane exerts differential effects on cell proliferation, HDAC activity and downstream targets in both normal and cancer cells( Reference Clarke, Hsu and Yu 96 ). Accompanied by reduced HDAC4 expression and activity, curcumin induces apoptosis and cell cycle arrest in medulloblastoma cells in vitro and reduced tumour growth in in vivo medulloblastoma xenografts( Reference Lee, Krauthauser and Maduskuie 98 ). These observations indicate that both sulforaphane and curcumin or any other bioactive components that have histone modification effects have the potential to be developed as cancer chemotherapeutic agents. Similar to trichostatin-A, it is important to determine the gene specificity of this nutrient-induced HDAC repression. Furthermore, studies need to determine whether the amounts of these nutrients can be consumed in the whole diet at physiological quantities or if supraphysiological supplements are required. The timing of nutrient exposure needs to be determined as well; are these nutrients effective at reducing carcinogenesis prior to cancer development, during early carcinogenesis or in late-stage disease?

Nutrition, systemic metabolism and epigenetics

In contrast to single-nutrient–single-gene interactions, systemic metabolism also plays a role in determining diet–gene interactions( Reference Cyr and Domann 8 ). In light of the increasing prevalence of obesity and subsequent development of type II diabetes mellitus, a large proportion of the population is being exposed to chronic hyperglycaemia and impaired lipid homoeostasis leading to a substantially different cellular milieu( Reference Ren, Pulakat and Whaley-Connell 99 ). Epigenetic mechanisms are currently being investigated within the scope of the metabolic profiles characteristic of obesity and its associated sequellae( Reference Cooper and El-Osta 100 ). Exposure of macrophages to high glucose to model hyperglycaemia caused recruitment of lysine-specific demethylase 1H3 and a reduction in H3K9 methylation at the NF-κB-p65 gene promoter leading to an increased expression of this transcription factor( Reference Cooper and El-Osta 100 ). Similar results were observed in both endothelial cells and vascular smooth muscle cells( Reference Fernandez, Siebel and El-Osta 101 ). These epigenetic marks were sustained following return to normoglycaemic conditions, lending support to the notion of metabolic memory that has been observed in clinical studies describing persistent vascular injury following previous poor metabolic control( 102 ). Furthermore, human vascular smooth muscle cells treated with high-glucose conditions demonstrated activating histone 3 at lysine 4 (H3K4) dimethylation marks and increased gene expression at the NF-κB targets, monocyte chemotactic protein-1 and IL-6, indicating epigenetic mechanisms underlying the hyperglycaemia-induced vascular inflammation( Reference Teperino, Schoonjans and Auwerx 103 ).

Hypercholesterolaemia and circulating oxidised LDL are also systemic metabolic characteristics that potentiate the development of age- and obesity-related chronic diseases( Reference Tonstad and Després 104 ). Consistent with the notion that chronic inflammation plays an aetiological role in atherogenesis, incubation of human umbilical-cord vein endothelial cells with oxidized LDL also led to altered epigenetic marks at inflammation-related genes( Reference N'Guessan, Riediger and Vardarova 105 ). Cells exposed to oxidized LDL demonstrated recruitment of cAMP-response-element-binding protein-binding protein/p300 and reduced HDAC1 and HDAC2 binding leading to increased activating histone marks at the IL-8 and monocyte chemoattractant protein-1 promoters. In utero exposure to hypercholesterolemia from ApoE −/− mothers led to differential global histone methylation patterns in offspring vascular smooth muscle cells and endothelial cells( Reference Alkemade, van Vliet and Henneman 106 ). These effects were further potentiated when offspring were fed a high-fat diet inducing hypercholesterolemia. Studies in primate models have demonstrated that maternal high-fat diet leads to altered hepatic histone modifications and epigenetic enzyme expression, with gene-specific changes localised to genes involved in circadian rhythms, lipid metabolism and heat shock responses( Reference Aagaard-Tillery, Grove and Bishop 107 ). Taken together, these studies demonstrate that both trans-generational and post-natal exposure to the metabolic characteristics of high-fat diet and hypercholesterolaemia lead to differential epigenetic patterns in various tissues which may potentiate chronic disease development later in life.

Conclusion and future perspectives

The field of nutritional epigenetics is further elucidating the nature of gene–diet interaction, thus providing support for the role of nutrition and lifestyle in determining phenotype from genotype( Reference Friso and Choi 10 ). Aging is associated with substantial changes in epigenetic patterns and recent work is implicating epigenetic mechanisms in the aetiology of many age-related diseases( Reference Feinberg 108 ). In some cases, evidence suggests that nutrients may slow down the age-related epigenetic changes and delay disease onset, though it is too soon to draw broad conclusions( Reference Zeisel 86 ). Future work seeks to characterise the epigenetic pattern of healthy aging and to identify nutritional measures to achieve this pattern.

Nutritional epigenetics is a field in its infancy; there is much research to be done that has great potential to yield findings with significant public health implications. Questions that remain to be answered include determining the tissue specificity of nutrient exposures, particularly as many studies have been performed in vitro with single-cell types. Specific timing of nutritional exposures and their concomitant efficacy of epigenetic regulations needs to be examined. Accumulating evidence supports the notion that maternal nutrition is critical in epigenetic programming of offspring( Reference Heerwagen, Miller and Barbour 109 ), but other time periods of the lifecycle need to be investigated. This is particularly critical with respect to nutritional epigenetic interventions for diseases; should exposure be prior to disease development, implicating the importance of lifetime dietary patterns, or can there be effective therapeutic effects following disease diagnosis? Last, the question remains as to whether nutrition and aging modulate epigenetic patterns in a programmatic fashion or if the effects are more stochastic in nature. Genome Wide Association Studies technology that identified original gene–diet interactions is now being applied to nutritional epigenetics, embarking into the arena of Epigenome-Wide Association Studies which will support these endeavours( Reference Rakyan, Down and Balding 2 ).

There is significant impetus to continue research within the field of nutritional epigenetics as the findings may support significant public health applications. While DNA sequences cannot be changed and aging cannot be avoided, individuals have the ability to change their diet. Nutrition has the potential to modulate the interactions between genes, aging and disease susceptibility through epigenetic mechanisms. Future work promises fruitful results underlying the role of nutrition guiding healthful aging phenotypes from genotype.

Acknowledgements

This material is based on work supported by the U.S. Department of Agriculture, under agreement no. 58-1950-7-707. 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. The authors declare no conflicts of interest. This project was supported in part by the National Institute of Health Grant R01 AG025834 (to S.W.C.). L.K.P., S.F. and S.W.C. participated in the conception, design and drafting of the manuscript.

References

1. Juran, BD & Lazaridis, KN (2011) Genomics in the post-GWAS era. Semin Liver Dis 31, 215222.CrossRefGoogle ScholarPubMed
2. Rakyan, VK, Down, TA, Balding, DJ et al. (2011) Epigenome-wide association studies for common human diseases. Nat Rev Genet 12, 529541.CrossRefGoogle ScholarPubMed
3. Crott, JW, Choi, SW, Ordovas, JM et al. (2004) Effects of dietary folate and aging on gene expression in the colonic mucosa of rats: implications for carcinogenesis. Carcinogenesis 25, 6976.CrossRefGoogle ScholarPubMed
4. Choi, SW & Friso, S (2010) Epigenetics: a new bridge between nutrition and health. Adv Nutr 1, 8–16.CrossRefGoogle ScholarPubMed
5. Cheng, X & Blumenthal, RM (2010) Coordinated chromatin control: structural and functional linkage of DNA and histone methylation. Biochemistry 49, 29993008.CrossRefGoogle ScholarPubMed
6. Kim, KC, Friso, S & Choi, SW (2009) DNA methylation, an epigenetic mechanism connecting folate to healthy embryonic development and aging. J Nutr Biochem 20, 917926.CrossRefGoogle ScholarPubMed
7. Jang, H, Mason, JB & Choi, SW (2005) Genetic and epigenetic interactions between folate and aging in carcinogenesis. J Nutr 135, Suppl. 12, 2967S2971S.CrossRefGoogle ScholarPubMed
8. Cyr, AR & Domann, FE (2011) The redox basis of epigenetic modifications: from mechanisms to functional consequences. Antioxid Redox Signal 15, 551589.CrossRefGoogle ScholarPubMed
9. Zilberman, D & Henikoff, S (2007) Genome-wide analysis of DNA methylation patterns. Development 134, 39593965.CrossRefGoogle ScholarPubMed
10. Friso, S & Choi, SW (2002) Gene-nutrient interactions and DNA methylation. J Nutr 132, 8 Suppl., 2382S2387S.CrossRefGoogle ScholarPubMed
11. Tibbetts, AS & Appling, DR (2010) Compartmentalization of mammalian folate-mediated one-carbon metabolism. Annu Rev Nutr 30, 5781.CrossRefGoogle ScholarPubMed
12. Taban-Shomal, O, Kilter, H, Wagner, A et al. (2009) The cardiac effects of prolonged vitamin B12 and folate deficiency in rats. Cardiovasc Toxicol 9, 95–102.CrossRefGoogle ScholarPubMed
13. Kim, J-M, Hong, K, Lee, JH et al. (2009) Effect of folate deficiency on placental DNA methylation in hyperhomocysteinemic rats. J Nutr Biochem 20, 172176.CrossRefGoogle ScholarPubMed
14. Niculescu, MD & Zeisel, SH (2002) Diet, methyl donors and DNA Methylation: interactions between dietary folate, methionine and choline. J Nutr 132, 2333S2335S.CrossRefGoogle ScholarPubMed
15. Keyes, MK, Mason Joel, B, Liu, Zhenhua et al. (2007) Older age and dietary folate are determinants of genomic and p16-specific DNA methylation in mouse colon. J Nutr 137, 17131717.CrossRefGoogle ScholarPubMed
16. Liu, Z, Choi, SW, Crott, JW et al. (2007) Mild depletion of dietary folate combined with other B vitamins alters multiple components of the Wnt pathway in mouse colon. J Nutr 137, 27012708.CrossRefGoogle ScholarPubMed
17. Niculescu, MD, Craciunescu, CN & Zeisel, SH (2006) Dietary choline deficiency alters global and gene-specific DNA methylation in the developing hippocampus of mouse fetal brains. FASEB J 20, 4349.CrossRefGoogle ScholarPubMed
18. Pogribny, IP, Ross, SA, Wise, C et al. (2006) Irreversible global DNA hypomethylation as a key step in hepatocarcinogenesis induced by dietary methyl deficiency. Mutat Res 593, 8087.CrossRefGoogle ScholarPubMed
19. Pogribny, IP, Ross, SA, Tryndyak, VP et al. (2006) Histone H3 lysine 9 and H4 lysine 20 trimethylation and the expression of Suv4-20h2 and Suv-39h1 histone methyltransferases in hepatocarcinogenesis induced by methyl deficiency in rats. Carcinogenesis 27, 11801186.CrossRefGoogle ScholarPubMed
20. Tryndyak, VP, Ross, SA, Beland, FA et al. (2009) Down-regulation of the microRNAs miR-34a, miR-127, and miR-200b in rat liver during hepatocarcinogenesis induced by a methyl-deficient diet. Mol Carcinog 48, 479487.CrossRefGoogle ScholarPubMed
21. Jacob, RA, Gretz, DM, Taylor, PC et al. (1998) Moderate folate depletion increases plasma homocysteine and decreases lymphocyte DNA methylation in postmenopausal women. J Nutr 128, 12041212.CrossRefGoogle ScholarPubMed
22. Rampersaud, GC, Kauwell, GP, Hutson, AD et al. (2000) Genomic DNA methylation decreases in response to moderate folate depletion in elderly women. Am J Clin Nutr 72, 998–1003.CrossRefGoogle ScholarPubMed
23. Pizzolo, F, Blom, HJ, Choi, SW et al. (2011) Folic acid effects on S-adenosylmethionine, S-adenosylhomocysteine, and DNA methylation in patients with intermediate hyperhomocysteinemia. J Amer Coll Nutr 30, 1118.CrossRefGoogle ScholarPubMed
24. Choumenkovitch, SF, Selhub, J, Bagley, PJ et al. (2002) In the cystathionine beta-synthase knockout mouse, elevations in total plasma homocysteine increase tissue S-adenosylhomocysteine, but responses of S-adenosylmethionine and DNA methylation are tissue specific. J Nutr 132, 21572160.CrossRefGoogle ScholarPubMed
25. Caudill, MA, Wang, JC, Melnyk, S et al. (2001) Intracellular S-adenosylhomocysteine concentrations predict global DNA hypomethylation in tissues of methyl-deficient cystathionine beta-synthase heterozygous mice. J Nutr 131, 28112818.CrossRefGoogle ScholarPubMed
26. Liu, J, Pickford, R, Meagher, AP et al. (2011) Quantitative analysis of tissue folate using ultra high-performance liquid chromatography tandem mass spectrometry. Anal Biochem 411, 210217.CrossRefGoogle ScholarPubMed
27. Ozias, MK & Schalinske, KL (2003) All-trans-retinoic acid rapidly induces glycine N-methyltransferase in a dose-dependent manner and reduces circulating methionine and homocysteine levels in rats. J Nutr 133, 40904094.CrossRefGoogle Scholar
28. Cheong, HS, Lee, HC, Park, BL et al. (2010) Epigenetic modification of retinoic acid-treated human embryonic stem cells. BMB Rep 43, 830835.CrossRefGoogle ScholarPubMed
29. Das, S, Foley, N, Bryan, K et al. (2010) MicroRNA mediates DNA demethylation events triggered by retinoic acid during neuroblastoma cell differentiation. Cancer Res 70, 78747881.CrossRefGoogle ScholarPubMed
30. Jackson-Rosario, SE & Self, WT (2010) Targeting selenium metabolism and selenoproteins: Novel avenues for drug discovery. Metallomics 2, 112116.CrossRefGoogle ScholarPubMed
31. Davis, CD & Uthus, EO (2003) Dietary folate and selenium affect dimethylhydrazine-induced aberrant crypt formation, global DNA methylation and one-carbon metabolism in rats. J Nutr 133, 29072914.CrossRefGoogle ScholarPubMed
32. Uthus, EO, Yokoi, K & Davis, CD (2002) Selenium deficiency in fisher-344 rats decreases plasma and tissue homocysteine concentrations and alters plasma homocysteine and cysteine redox status. J Nutr 132, 11221128.CrossRefGoogle ScholarPubMed
33. Uthus, EO, Ross, SA & Davis, CD (2006) Differential effects of dietary selenium (se) and folate on methyl metabolism in liver and colon of rats. Biol Trace Elem Res 109, 201214.CrossRefGoogle ScholarPubMed
34. Zeng, H, Yan, L, Cheng, W-H et al. (2011) Dietary selenomethionine increases exon-specific DNA methylation of the p53 gene in rat liver and colon mucosa. J Nutr 141, 14641468.CrossRefGoogle ScholarPubMed
35. Lamprecht, SA & Lipkin, M (2003) Chemoprevention of colon cancer by calcium, vitamin D and folate: molecular mechanisms. Nat Rev Cancer 3, 601614.CrossRefGoogle ScholarPubMed
36. Stefanska, B, Rudnicka, K, Bednarek, A et al. (2010) Hypomethylation and induction of retinoic acid receptor beta 2 by concurrent action of adenosine analogues and natural compounds in breast cancer cells. Eur J Pharmacol 638, 4753.CrossRefGoogle ScholarPubMed
37. Stefanska, B, Salamé, P, Bednarek, A et al. (2011) Comparative effects of retinoic acid, vitamin D and resveratrol alone and in combination with adenosine analogues on methylation and expression of phosphatase and tensin homologue tumour suppressor gene in breast cancer cells. Br J Nutr 1, 110.Google Scholar
38. Davis, CD & Ross, SA (2007) Dietary components impact histone modifications and cancer risk. Nutr Rev 65, 8894.CrossRefGoogle ScholarPubMed
39. Meeran, SM, Ahmed, A & Tollefsbol, TO (2010) Epigenetic targets of bioactive dietary components for cancer prevention and therapy. Clin Epigenetics 1, 101116.CrossRefGoogle ScholarPubMed
40. Zhang, Y & Chen, H (2011) Genistein, an epigenome modifier during cancer prevention. Epigenetics 6, 888891.CrossRefGoogle ScholarPubMed
41. Dolinoy, DC, Weidman, JR, Waterland, RA et al. (2006) Maternal genistein alters coat color and protects Avy mouse offspring from obesity by modifying the fetal epigenome. Environ Health Perspect 114, 567572.CrossRefGoogle ScholarPubMed
42. Sato, N, Yamakawa, N, Masuda, M et al. (2011) Genome-wide DNA methylation analysis reveals phytoestrogen modification of promoter methylation patterns during embryonic stem cell differentiation. PLoS One 6, e19278.CrossRefGoogle ScholarPubMed
43. Fang, MZ, Chen, D, Sun, Y et al. (2005) Reversal of hypermethylation and reactivation of p16INK4a, RARbeta, and MGMT genes by genistein and other isoflavones from soy. Clin Cancer Res 11, 70337041.CrossRefGoogle ScholarPubMed
44. Fang, M, Chen, D & Yang, CS (2007) Dietary polyphenols may affect DNA methylation. J Nutr 137, 223S228S.CrossRefGoogle ScholarPubMed
45. Wang, Z & Chen, H (2010) Genistein increases gene expression by demethylation of WNT5a promoter in colon cancer cell line SW1116. Anticancer Res 30, 45374545.Google ScholarPubMed
46. Vardi, A, Bosviel, R, Rabiau, N et al. (2010) Soy phytoestrogens modify DNA methylation of GSTP1, RASSF1A, EPH2 and BRCA1 promoter in prostate cancer cells. In Vivo 24, 393400.Google ScholarPubMed
47. Jha, AK, Nikbakht, M, Parashar, G et al. (2010) Reversal of hypermethylation and reactivation of the RARbeta2 gene by natural compounds in cervical cancer cell lines. Folia Biol (Praha) 56, 195200.Google ScholarPubMed
48. Suganuma, M, Saha, A & Fujiki, H (2011) New cancer treatment strategy using combination of green tea catechins and anticancer drugs. Cancer Sci 102, 317323.CrossRefGoogle ScholarPubMed
49. Lee, WJ, Shim, J-Y & Zhu, BT (2005) Mechanisms for the inhibition of DNA methyltransferases by tea catechins and bioflavonoids. Mol Pharmacol 68, 10181030.CrossRefGoogle ScholarPubMed
50. Nandakumar, V, Vaid, M & Katiyar, SK (2011) (−)-Epigallocatechin-3-gallate reactivates silenced tumor suppressor genes, Cip1/p21 and p16INK4a, by reducing DNA methylation and increasing histones acetylation in human skin cancer cells. Carcinogenesis 32, 537544.CrossRefGoogle ScholarPubMed
51. Wong, CP, Nguyen, LP, Noh, SK et al. (2011) Induction of regulatory T cells by green tea polyphenol EGCG. Immunol Lett 139, 7–13.CrossRefGoogle ScholarPubMed
52. Lee, WJ, Shim, JY & Zhu, BT (2005) Mechanisms for the inhibition of DNA methyltransferases by tea catechins and bioflavonoids. Mol Pharmacol 68, 10181030.CrossRefGoogle ScholarPubMed
53. Fu, S & Kurzrock, R (2010) Development of curcumin as an epigenetic agent. Cancer 116, 46704676.CrossRefGoogle ScholarPubMed
54. King-Batoon, A, Leszczynska, JM & Klein, CB (2008) Modulation of gene methylation by genistein or lycopene in breast cancer cells. Environ Mol Mutagen 49, 3645.CrossRefGoogle ScholarPubMed
55. Meeran, SM, Patel, SN & Tollefsbol, TO (2010) Sulforaphane causes epigenetic repression of hTERT expression in human breast cancer cell lines. PLoS ONE 5, e11457.CrossRefGoogle ScholarPubMed
56. Esteller, M (2007) Cancer epigenomics: DNA methylomes and histone-modification maps. Nat Rev Genet 8, 286298.CrossRefGoogle ScholarPubMed
57. Kee, HJ & Kook, H (2011) Roles and targets of class I and IIa histone deacetylases in cardiac hypertrophy. J Biomed Biotechnol 2011, 928326.CrossRefGoogle Scholar
58. North, ML & Ellis, AK (2011) The role of epigenetics in the developmental origins of allergic disease. Ann Allergy Asthma Immunol 106, 355361.CrossRefGoogle ScholarPubMed
59. Bandyopadhyay, D & Medrano, EE (2003) The emerging role of epigenetics in cellular and organismal aging. Exp Gerontol 38, 12991307.CrossRefGoogle ScholarPubMed
60. An, W (2007) Histone acetylation and methylation. In Chromatin and Disease 41(III), 355374.CrossRefGoogle ScholarPubMed
61. Alvaro, A, Solà, R, Rosales, R et al. (2008) Gene expression analysis of a human enterocyte cell line reveals downregulation of cholesterol biosynthesis in response to short-chain fatty acids. IUBMB Life 60, 757764.CrossRefGoogle ScholarPubMed
62. Riggs, MG, Whittaker, RG, Neumann, JR et al. (1997). n-Butyrate causes histone modification in HeLa and friend erythroleukaemia cells. Nature 268, 462464.CrossRefGoogle Scholar
63. Fang, JY (2005) Histone deacetylase inhibitors, anticancerous mechanism and therapy for gastrointestinal cancers. J Gastroenterol Hepatol 20, 988994.CrossRefGoogle ScholarPubMed
64. Goel, A & Aggarwal, BB (2010) Curcumin, the golden spice from Indian saffron, is a chemosensitizer and radiosensitizer for tumors and chemoprotector and radioprotector for normal organs. Nutr Cancer 62, 919930.CrossRefGoogle ScholarPubMed
65. Marcu, MG, Jung, YJ, Lee, S et al. (2006) Curcumin is an inhibitor of p300 histone acetylatransferase. Med Chem 2, 169174.Google ScholarPubMed
66. Kang, S-K, Cha, S-H & Jeon, H-G (2006) Curcumin-induced histone hypoacetylation enhances caspase-3-dependent glioma cell death and neurogenesis of neural progenitor cells. Stem Cells Dev 15, 165174.CrossRefGoogle ScholarPubMed
67. Gravina, S & Vijg, J (2010) Epigenetic factors in aging and longevity. Pflügers Archiv 459, 247258.CrossRefGoogle ScholarPubMed
68. Choi, SW, Friso, S, Dolnikowski, GG et al. (2003) Biochemical and molecular aberrations in the rat colon due to folate depletion are age-specific. J Nutr 133, 12061212.CrossRefGoogle ScholarPubMed
69. Richardson, BI (2003) Impact of aging on DNA methylation. Ageing Res Rev 2, 245261.CrossRefGoogle ScholarPubMed
70. Golbus, J, Palella, TD & Richardson, BC (1990) Quantitative changes in T cell DNA methylation occur during differentiation and ageing. Eur J Immunol 20, 18691872.CrossRefGoogle Scholar
71. Thompson, RF, Atzmon, G, Gheorghe, C et al. (2010) Tissue-specific dysregulation of DNA methylation in aging. Aging Cell 9, 506518.CrossRefGoogle ScholarPubMed
72. Kim, KC, Friso, S & Choi, SW (2009) DNA methylation, an epigenetic mechanism connecting folate to healthy embryonic development and aging. J Nutr Biochem 20, 917926.CrossRefGoogle ScholarPubMed
73. Sauer, J, Jang, H, Zimmerly, EM et al. (2010) Ageing, chronic alcohol consumption and folate are determinants of genomic DNA methylation, p16 promoter methylation and the expression of p16 in the mouse colon. Br J Nutr 1, 2430.CrossRefGoogle Scholar
74. Wallace, K, Grau, MV, Levine, AJ et al. (2010) Association between folate levels and CpG island hypermethylation in normal colorectal mucosa. Cancer Prev Res 3, 15521564.CrossRefGoogle ScholarPubMed
75. Burgess, AW, Faux, MC, Layton, M, et al. (2011) Wnt signaling and colon tumorigenesis – a view from the periphery. Exp Cell Res (Epublication ahead of print version).CrossRefGoogle ScholarPubMed
76. 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.CrossRefGoogle ScholarPubMed
77. Das, C & Tyler, JK (2011) Histone exchange and histone modifications during transcription and aging. Biochim Biophys Acta (Epublication ahead of print version).Google Scholar
78. Feser, J, Truong, D, Das, C et al. (2010) Elevated histone expression promotes life span extension. Mol Cell 39, 724735.CrossRefGoogle ScholarPubMed
79. Haigis, MC & Sinclair, DA (2010) Mammalian sirtuins: biological insights and disease relevance. Annu Rev Pathol 5, 253295.CrossRefGoogle ScholarPubMed
80. Vaquero, A, Sternglanz, R & Reinberg, D (2007) NAD+-dependent deacetylation of H4 lysine 16 by class III HDACs. Oncogene 26, 55055520.CrossRefGoogle ScholarPubMed
81. Dang, W, Steffen, KK, Perry, R et al. (2009) Histone H4 lysine 16 acetylation regulates cellular lifespan. Nature 459, 802807.CrossRefGoogle ScholarPubMed
82. Chung, S, Yao, H, Caito, S et al. Regulation of SIRT1 in cellular functions: Role of polyphenols. Arch Biochem Biophys 501, 7990.CrossRefGoogle Scholar
83. Li, Z, Liu, C, Xie, Z et al. (2011) Epigenetic dysregulation in mesenchymal stem cell aging and spontaneous differentiation. PLoS ONE 6, e20526.CrossRefGoogle ScholarPubMed
84. Kennedy, ET (2006) Evidence for nutritional benefits in prolonging wellness. Am J Clin Nutr 83, 410S414S.CrossRefGoogle ScholarPubMed
85. Stipp, D (2011) Linking nutrition, maturation and aging: from thrifty genes to the spendthrift phenotype. Aging 3, 8593.CrossRefGoogle Scholar
86. Zeisel, SH (2009) Epigenetic mechanisms for nutrition determinants of later health outcomes. Am J Clin Nutr 89, 1488S1493S.CrossRefGoogle ScholarPubMed
87. Feinberg, AP (2008) Epigenetics at the epicenter of modern medicine. JAMA 299, 13451350.CrossRefGoogle ScholarPubMed
88. Sie, KK, Medline, A, van Weel, J et al. (2011) Effect of maternal and postweaning folic acid supplementation on colorectal cancer risk in the offspring. Gut (Epublication before print version).CrossRefGoogle ScholarPubMed
89. Ly, A, Lee, H, Chen, J et al. (2011) Effect of maternal and postweaning folic acid supplementation on mammary tumor risk in the offspring. Cancer Res 71, 988997.CrossRefGoogle ScholarPubMed
90. Saha, RN & Pahan, K (2006) HATs and HDACs in neurodegeneration: a tale of disconcerted acetylation homeostasis. Cell Death Differ 13, 539550.CrossRefGoogle ScholarPubMed
91. Peleg, S, Sananbenesi, F, Zovoilis, A et al. (2010) Altered histone acetylation is associated with age-dependent memory impairment in mice. Science 328, 753756.CrossRefGoogle ScholarPubMed
92. Govindarajan, N, Agis-Balboa, RC, Walter, J et al. (2011) Sodium butyrate improves memory function in an Alzheimer's disease mouse model when administered at an advanced stage of disease progression. J Alzheimer's Dis 26, 187197.CrossRefGoogle Scholar
93. Tanji, N, Ozawa, A, Kikugawa, T, et al. (2011) Potential of histone deacetylase inhibitors for bladder cancer treatment. Exp Rev Anticancer Ther 11, 959965.CrossRefGoogle ScholarPubMed
94. Fortson, WS, Kayarthodi, S, Fujimura, Y et al. Histone deacetylase inhibitors, valproic acid and trichostatin-A induce apoptosis and affect acetylation status of p53 in ERG-positive prostate cancer cells. Int J Oncol 39, 111119.Google Scholar
95. Xiong, H, Du, W, Zhang, YJ et al. (2011) Trichostatin A, a histone deacetylase inhibitor, suppresses JAK2/STAT3 signaling via inducing the promoter-associated histone acetylation of SOCS1 and SOCS3 in human colorectal cancer cells. Mol Carcinog (Epublication before print version).Google ScholarPubMed
96. Clarke, JD, Hsu, A, Yu, Z et al. (2011) Differential effects of sulforaphane on histone deacetylases, cell cycle arrest and apoptosis in normal prostate cells versus hyperplastic and cancerous prostate cells. Mol Nutr Food Res 55, 999–1009.CrossRefGoogle ScholarPubMed
97. Myzak, MC, Dashwood, WM, Orner, GA et al. (2006) Sulforaphane inhibits histone deacetylase in vivo and suppresses tumorigenesis in Apcmin mice. FASEB J 20, 506508.CrossRefGoogle Scholar
98. Lee, SJ, Krauthauser, C, Maduskuie, V et al. (2011) Curcumin-induced HDAC inhibition and attenuation of medulloblastoma growth in vitro and in vivo . BMC Cancer 11, 144157.CrossRefGoogle ScholarPubMed
99. Ren, J, Pulakat, L, Whaley-Connell, A et al. (2010) Mitochondrial biogenesis in the metabolic syndrome and cardiovascular disease. J Mol Med 88, 993–1001.CrossRefGoogle ScholarPubMed
100. Cooper, ME & El-Osta, A (2010) Epigenetics: mechanisms and implications for diabetic complications. Circ Res 107, 14031413.CrossRefGoogle ScholarPubMed
101. Fernandez, AZ, Siebel, AI & El-Osta, A (2010) Atherogenic factors and their epigenetic relationships. Int J Vasc Med 2010, 437809.Google ScholarPubMed
102. Writing Team for the Diabetes Control and Complications Trial/Epidemiology of Diabetes Interventions and Complications Research Group (2003) Sustained effect of intensive treatment of Type 1 diabetes mellitus on development and progression of diabetic nephropathy. JAMA 290, 21592167.CrossRefGoogle Scholar
103. Teperino, R, Schoonjans, K & Auwerx, J (2010) Histone methyl transferases and demethylases; can they link metabolism and transcription? Cell Metab 12, 321327.CrossRefGoogle ScholarPubMed
104. Tonstad, S & Després, J-P (2011) Treatment of lipid disorders in obesity. Exp Rev Cardiovasc 9, 10691080.CrossRefGoogle ScholarPubMed
105. N'Guessan, PD, Riediger, F, Vardarova, K et al. (2009) Statins control oxidized LDL-mediated histone modifications and gene expression in cultured human endothelial cells. Arterioscler Thromb Vasc Biol 29, 380386.CrossRefGoogle Scholar
106. Alkemade, FE, van Vliet, P, Henneman, P et al. (2010) Prenatal exposure to apoE deficiency and postnatal hypercholesterolemia are associated with altered cell-specific lysine methyltransferase and histone methylation patterns in the vasculature. Am J Pathol 176, 542548.CrossRefGoogle ScholarPubMed
107. Aagaard-Tillery, KM, Grove, K, Bishop, J et al. (2008) Developmental origins of disease and determinants of chromatin structure: maternal diet modifies the primate fetal epigenome. J Mol Endocrinol 41, 91–102.CrossRefGoogle ScholarPubMed
108. Feinberg, AP (2007) Phenotypic plasticity and the epigenetics of human disease. Nature 447, 433440.CrossRefGoogle ScholarPubMed
109. Heerwagen, MJR, Miller, MR, Barbour, LA et al. (2010) Maternal obesity and fetal metabolic programming: a fertile epigenetic soil. Am J Physiol Regul Integr Comp Physiol 299, R711R722.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. One-carbon metabolism. S-adenosylmethionine (SAM) is the unique methyl donor for many biological methylation reactions including DNA and histone methylation. S-adenosylhomocysteine (SAH) is an inhibitor of methyltransferases such as DNA methyltransferases (DNMT) and histone methyltransferases. In one-carbon metabolism vitamins B2, B6, B12 and folate are coenzymes, while methionine, choline, betaine and serine are methyl donors. THF, tetrahydrofolate; 5-mTHF, 5-methyltetrahydrofolate; MT, methyltransferases; HMT, histone methyltransferases; MTHFR, methylenetetrahydrofolate reductase; MS, methionine synthase; SHMT, serine hydroxymethyltransferase; GNMT, glycine N-methyltransferase; CBS, cystathionine-β-synthase; MAT, methionine adenosyltransferase; SAHH, S-adenosylhomocysteine hydrolase; BHMT, Betaine homocysteine methyltransferase; B2, vitamin B2; B6, vitamin B6; B12, vitamin B12.