[vc_row el_class=”mr-b-26″][vc_column][vc_column_text single_style=””]<\/p>\n
Table of Contents<\/b><\/p>\n [\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_single_image image=”5992″ img_size=”full”][vc_column_text single_style=””]<\/p>\n Figure 1. An overview of epigenetic mechanisms. \u2018Epigenetics\u2019<\/em><\/strong> literally means \u2018above DNA.\u2019<\/em><\/strong> A genome<\/strong> is the complete set of genetic information (DNA<\/strong>) in an organism. Epigenetic processes describe changes to the genome that can alter gene expression without changing the underlying DNA sequence. These changes are mitotically inheritable;<\/strong> and involve the interplay of (1) DNA methylation, (2) histone (H2A, H2B, H3, and H4) modification, and (3) RNA-based mechanisms<\/strong> (non-coding RNA molecules).<\/p>\n [\/vc_column_text][\/vc_column][\/vc_row][vc_row el_id=”introduction”][vc_column][vc_custom_heading text=”Introduction”][vc_column_text single_style=””]<\/p>\n The field of epigenetics has evolved rapidly over recent decades; and generated a great deal of interest, primarily focusing on how our very molecular makeup in the form of modification to the genome can be altered by factors as varied as nutrition, aging, disease, stress, alcohol, and exposure to pollutants [1].<\/p>\n Epigenetic changes have previously been implicated in the etiology of a variety of diseases, for example, in the initiation and progression of certain cancers, and inherited growth disorder syndromes. However, the exploration of epigenetics\u2019 role in fetal reprograming is still in its infancy.<\/strong><\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n This series of blogs focuses on how nutritional exposure during pregnancy may influence the infant epigenome,<\/strong> and the meaningful impact that such modifications may have on the long-term health of the child. In order to better comprehend:<\/p>\n [\/vc_column_text][\/vc_column][\/vc_row][vc_row el_id=”blog-scroll-point-1″][vc_column][vc_custom_heading text=”Epigenetic Layers and Players”][vc_column_text single_style=””]<\/p>\n Epigenetic processes describe changes to the genome that can alter gene expression without changing the underlying DNA sequence.<\/u><\/em><\/span> These changes are mitotically heritable, and involve the interplay of the following chromatin and epigenetic mechanisms (see Figure 1<\/strong>), for example:<\/p>\n [\/vc_column_text][\/vc_column][\/vc_row][vc_row el_id=”blog-scroll-point-2″][vc_column][vc_custom_heading text=”1. DNA Methylation” use_theme_fonts=”yes”][vc_column_text single_style=””]<\/p>\n DNA methylation most commonly occurs at loci where a cytosine is found next to a guanine on a DNA strand along its linear sequence, consequently termed cytosine-phosphate-guanine<\/strong><\/em> or CpG sites.<\/em><\/strong> It involves the covalent bonding of a methyl (CH3<\/sub>) group to the cytosine at the 5\u2019-carbon position to form 5-methylcytosine<\/strong> [2].<\/p>\n CpGs found in high densities are termed CpG islands<\/em><\/strong>. Approximately two-thirds of human genes contain CpG islands in their promoter regions,<\/em><\/span> although repetitive elements in the genome<\/em><\/span> can also contain many CpG sites. CpGs are generally methylated in non-promoter regions and unmethylated at promoter regions.<\/strong> Most importantly, methylation at CpG sites in promoters is usually associated with transcriptional silencing, although not consistently.<\/p>\n [\/vc_column_text][vc_single_image image=”5993″ img_size=”full”][vc_column_text single_style=””]<\/p>\n Figure 2. DNA methylation cycle.<\/strong> DNA methylation involves the transfer of a methyl group (CH3<\/sub>)<\/em><\/strong> from the universal donor S-adenosylmethionine<\/em><\/strong> (SAM<\/em><\/strong>) to the fifth carbon of a cytosine<\/strong> (C<\/strong>), by a DNA methyltransferase (DNMT<\/strong>), to produce 5-methylcytosine (5-mC<\/strong>). S-adenosylhomocysteine (SAH<\/strong>) is produced as a byproduct. DNA de-methylation occurs via passive<\/em><\/strong> or active processes<\/em><\/strong> that may co-exist in cells. Active de-methylation involves the sequential conversion of 5-methylcytosine (5-mC<\/strong>) to 5-hydroxymethylcytosine (5-hmC<\/strong>) and derivatives of 5-formylcytosine (5-fC<\/strong>) and 5-carboxylcytosine (5-caC<\/strong>), likely then modified to cytosine (C<\/strong>); and it is regulated by ten-eleven translocation<\/strong> (TET<\/strong>) family of proteins.<\/strong>[DNMT, DNA methyltransferase; TET, ten-eleven translocation proteins; TDG, thymine DNA glycosylase]<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n The process of DNA methylation universally involves the transfer of a methyl (CH3<\/sub><\/strong>) group from S-adenosyl-L-methionine (SAM<\/strong> or AdoMet<\/strong>) to cytosine, catalyzed by DNA methyltransferase enzymes (DNMTs<\/strong>), to produce 5-methylcytosine (5-mC<\/strong>) (see Figure 2<\/strong>).<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n Even though methylation is the most examined chemical alteration till date, other less abundant forms of modifications, such as 5-hydroxymethlcytosine (5-hmC<\/strong>), 5-formylcytosine (5-fC<\/strong>), and 5-carboxycytosine (5-caC<\/strong>) have now been described in specific contexts. These variants are now considered to be intermediates within a \u2018DNA methylation cycle\u2019<\/em><\/strong> that involves both the addition and the removal of methylation from DNA (see Figure 2<\/strong>).<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n N6-methyladenosine (m6A) or N6-methyl-2\u2019-deoxyadenosine (m6dA) has also been described as a modification of mRNA, tRNA, and other non-coding RNAs, this is in addition to a subset of tissue-\/developmental-specific genomic DNA. The mRNA m6A modification has been widely characterized and plays a critical role in several developmental processes, while limited information on DNA m6A is currently available.<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n DNA methylation is catalyzed by DNA methyltransferase<\/em> <\/strong>(DNMTs<\/em><\/strong>). In mammals, the family of cytosine DNMTs includes DNMT1, DNMT2, DNMT3A, DNMT3B,<\/strong> and DNMT3L.<\/strong> Whereas the following three DNMTs (viz., DNMT1, DNMT3A, and DNMT3B) are canonical cytosine-5-methyltransferases that catalyze the addition of methylation marks to DNA, DNMT2 and DNMT3L do not. The corresponding writers of m6A in mammals remain largely unclear.<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n DNMT1 recognizes hemi-methylated DNA;<\/span> consequently, after DNA replication and cell division, it methylates the newly synthesized strand to maintain methylation patterns of the original template stand (maintenance methylation<\/strong>). DNMT3A and 3B appear to primarily methylate fully unmethylated CpG sites<\/span> (de novo methylation<\/em><\/strong>).<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n DNA methylation is critical for a host of biological process, including:<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n Despite the majority of DNA methylation being found at CpG dinucleotides, the presence of non-CG methylation<\/em><\/strong> within mammals has now also been described. This appears localized to CpH sites<\/em><\/strong> (where H = A, C,<\/em><\/strong> or T<\/em><\/strong>), and is highly enriched in neurons, where it is deposited during synaptogenesis.<\/em><\/strong> CH methylation is also found at lower density in a range of stem cells,<\/em><\/strong> as well as blood<\/em><\/strong> and umbilical cord<\/em><\/strong> in a tissue-specific manner, though much remains unclear as to its regulation and potential role in development and disease.<\/p>\n [\/vc_column_text][\/vc_column][\/vc_row][vc_row el_id=”blog-scroll-point-3″][vc_column][vc_custom_heading text=”2. Histone Variants and Histone Modifications” use_theme_fonts=”yes”][vc_column_text single_style=””]<\/p>\n Nucleosomes:<\/strong> DNA is tightly woven around histone proteins, forming compact complexes of DNA and protein called \u2018nucleosomes.<\/em><\/strong>\u2019 Nucleosomes, in turn, are packed together to form chromatin (see Figure 1<\/strong>). Within the nucleosomes, histone proteins are arranged in an eight-part configuration, consisting of two copies of each of histones H2A, H2B, H3, and H4.<\/span><\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n Histone variants:<\/strong> In addition to these canonical histones, there are numerous histone variants that show tissue and\/or developmental specificity of expression, independent of DNA replication. For instance, H3 has at least three variants, H3.1, H3.2, and H3.3,<\/strong> which differ by only a few amino acids. Nevertheless, they have very different expression patterns and functions. This is similarly the case for variants of other histone proteins.<\/p>\n Additionally, some histone variants show a restricted chromosomal location associated with their function, including centromere-specific H3 variant histone (such as CENP-A), located to a specific region on every chromosome and essential for chromosome segregation.<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n Histone modifications:<\/strong> Some histones contain long terminal \u2018tails<\/em><\/strong>\u2019 (particularly on the N-terminus<\/em><\/strong>) that sit \u2019outside<\/em><\/strong>\u2019 of the core nucleosomal structure and are therefore accessible to a range of modifying proteins. These tails can be covalently modified at many positions in a variety of ways by the addition of specific molecular groups, including acetyl, methyl, phospho, ubiquitin, and other molecules.<\/span> These are called \u2018post-translational histone modifications\u2019<\/em><\/strong><\/strong> or \u2018histone marks\u2019<\/em><\/strong> and collectively are known as \u2018histone code\u2019<\/em><\/strong> (see Figure 1<\/strong>).<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n Histone modifications involve various posttranslational chemical alterations to the amino acids of histone tails, including:<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n Each type of histone mark can be added and removed by a family of proteins. For example, acetylation marks on H3 and H4 are added and removed by histone acetyl transferases<\/em><\/strong> (HATs<\/em><\/strong>) and deacetylases (HDACs<\/em><\/strong>), respectively, while methylation groups are added and removed by specific histone methyltransferases<\/em><\/strong> and demethylases.<\/em><\/strong><\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n There are various mechanisms by which chemical modification of CpG sites and histones are thought to influence gene expression. The methyl group from 5-methylcytosine may block transcription factors either directly or through the recruitment of a methyl-binding protein. Otherwise, the DNMT enzymes acting on CpG sites may be physically linked to other enzymes, which generate methylation and deacetylation.<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n Chromatin remodeling:<\/strong> Even though chromatin remodeling is intricately regulated, a simplified summary is that:<\/p>\n [\/vc_column_text][\/vc_column][\/vc_row][vc_row el_id=”blog-scroll-point-4″][vc_column][vc_custom_heading text=”3. Non-coding RNAs” use_theme_fonts=”yes”][vc_column_text single_style=””]<\/p>\n While noncoding RNAs do not code for proteins<\/em><\/strong>, many are functional and may affect gene expression (see Figure 1<\/strong>). Of those that influence gene expression, micro RNAs<\/em><\/strong> (miRNAs<\/em><\/strong>) have been the most studied thus far. miRNAs are short pieces of RNA (~ 22 nucleotides<\/em><\/strong>) that affects the epigenome through binding to target mRNAs controlling the expression of key regulators such as DMNTs and histone deacetylases. In turn, CpG methylation and histone modifications can influence the transcription of certain miRNA classes. MicroRNAs may also affect gene expression directly by binding to messenger RNAs, repressing their translation.<\/p>\n [\/vc_column_text][\/vc_column][\/vc_row][vc_row el_id=”blog-scroll-point-5″][vc_column][vc_custom_heading text=”Time Points of Plasticity in the Epigenome”][vc_column_text single_style=””]<\/p>\n Times of increased cell turnover, such as during fetal development and infancy, may be particularly susceptible both to epigenetic errors<\/em><\/strong> and to environmental influences.<\/em><\/strong> The notion that environmental exposures during \u2018critical windows\u2019<\/em><\/strong> in development can have profound effects on long-term health and disease risk into adult hood has received strong evidential support from observational and experimental research [3-6].<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n A focus in DOHaD<\/strong> (developmental origins of health and disease) research has been to investigate when during development the conceptus is most vulnerable to such adverse influences, informing targeted interventions. Research initially focused on the fetal and infant periods of life, but this was followed by the general recognition that critical windows occur more widely across development, spanning from pre-conception to adolescence.<\/strong><\/span> This has led to the consensus terminology of the developmental origins of health and disease<\/em><\/strong> (DOHaD) [3].<\/p>\n [\/vc_column_text][vc_column_text single_style=””]<\/p>\n In this blog, we focus on DNA methylation and the in utero period,<\/em><\/strong> to include periconception,<\/strong> because this falls within the \u2018first 1,000 days window<\/u><\/span>,\u2019 and is also a period of remarkably rapid cell differentiation and complex epigenetic remodeling.<\/p>\n [\/vc_column_text][vc_single_image image=”5994″ img_size=”full”][vc_column_text single_style=””]<\/p>\n Figure 3. Epigenetic Remodeling in Embryogenesis.<\/strong> Genome-wide and imprint methylation programming during early development (based on mice). The time of the events depicted in the graph corresponds approximately to the events, such as methylation imprint erasure, re-establishment,<\/strong> and maintenance<\/strong> at the germline differentially methylated regions<\/em><\/strong> (gDMRs<\/em><\/strong>) during gametogenesis and early embryonic development. As primordial germ cells<\/em><\/strong> (PGCs<\/em><\/strong>) of the developing embryo enter the genital ridge, genome-wide demethylation<\/em><\/strong> occurs which erases the imprint marks (solid grey lines) present on the maternal and paternal chromosomes (DNA demethylation<\/u><\/em><\/span>), and de novo methylation<\/em><\/strong> follows to establish the new sex-specific imprints during gametogenesis (sex-specific remethylation<\/u><\/em><\/span>). Following fertilization, global demethylation<\/em><\/strong> occurs. The paternal pronucleus undergoes active<\/em><\/strong> demethylation which is completed before the first DNA replication while the maternal chromosome is demethylated by a DNA replication-dependent \n
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