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Epigenetic mechanisms

Histone modifications typically occur as post-translational modifications at the N-terminal of histones. These modifications include acetylation, methylation, phosphorylation, biotinylation and ubiquitination and are essential during development [26–28]. Histone modifications are catalyzed by enzymes such as histone methyltransferases (HMTs), histone demethylases (HDMs) histone acetyltransferases (HATs), and histone deacetylases (HDACs). HMTs act to add methyl groups to lysine and/or arginine residues in histones, while HDMs remove the methyl moieties. In turn, HATs catalyze the addition of acetyl groups to the lysine residues of histones, whereas HDACs are responsible for the removal of these groups [29,30]. Lysine methylation can cause either activation or repression of transcription, while arginine methylation typically activates transcription. Likewise, histone hyperacetylation results in the activation of normally repressed genes while hypoacetylation results in gene silencing. This is apparent in carcinogenesis where aberrant activity of HATs and HDACs are thought to trigger carcinogenic processes [31].

RNAi is the process by which dsRNA inhibits the accumulation of homologous transcripts from like genes [32]. RNAi or ncRNAs, in the form of antisense transcripts, can lead to transcriptional silencing by the formation of heterochromatin. The involvement of RNA in different silencing mechanisms has been described in detail in several organisms [33]. For example, in the yeast Schizosaccharomyces pombe, the deletion of different components of the RNAi machinery results in the loss of H3K9 methylation, as well as impairment of centromere function [33,34]. Similarly, DNA methylation and H3K9 methylation have been demonstrated in Arabidopsis thaliana and in α-thalassaemia [35,36]. RNAi has also been demonstrated to be involved in silencing genes associated with HIV-1, along with several types of cancers [37–41]. In addition, noncoding miRNAs can control the expression of DNMTs and other enzymes associated with epigenetic modifications, which affect mRNA translation and stability [42–44]. Exciting developments have indicated that RNAi-directed silencing of heterochromatic regions might trigger direct histone modifications and DNA methylation to specific loci, causing gene silencing [35,36,45,46].

Epigenetic modifications are of particular interest in the field of cancer research since their impact on the epigenome is involved in cell proliferation, differentiation and survival [27,47,48]. Furthermore, epigenetic modifications are often involved in transcriptional regulation and have been implicated both in tumor development and progression [40,49,50]. Epigenetic modifications causing transcriptional deregulation may result in the inappropriate expression or activation of transcription factors associated with oncogenes and/or the failure to express genes responsible for tumor suppression [51]. In fact, cancer cells have genome-wide aberrations in a number of epigenetic markers, including global hypomethylation, global downregulation of miRNAs, promoter-specific hypermethylation, histone deacetylation and upregulation of epigenetic machinery [52]. In addition, the impact of epigenomic processes in cancer is apparent by the finding that at least half of all tumor suppressor genes are inactivated through epigenetic mechanisms in tumorigenesis [16,53–55]. Bioactive dietary components consumed by ingesting natural products including fruits and vegetables can act as sources of vitamins and minerals. While this is an invaluable role, these agents have high potential for application to oncogenesis owing to in part to their anticarcinogenic properties [9,56]. A growing body of evidence suggests that dietary agents as well as non-nutrient components of fruits and vegetables can affect epigenetic processes and are involved in processes, including the reactivation of tumor suppressor genes, the initiation of apoptosis, the repression of cancer-related genes and the activation of cell survival proteins in different cancers [57–60]. Dietary phytochemicals such as tea polyphenols, genistein, sulforaphane (SFN), resveratrol, curcumin and others have been demonstrated to be effective agents against cancer and to act through epigenetic mechanisms that affect the epigenome [56,61].