.
During embryonic development DNA methylation patterns are largely erased and then re-established between generations in mammals. Almost all of the methylations from the parents are erased, first during
gametogenesis, and again in early
embryogenesis, with demethylation and
remethylation occurring each time. Demethylation in early embryogenesis occurs in the preimplantation period in two stages – initially in the
zygote, then during the first few embryonic replication cycles of
morula and
blastula. A wave of methylation then takes place during the implantation stage of the embryo, with CpG islands protected from methylation. This results in global repression and allows
housekeeping genes to be expressed in all cells. In the post-implantation stage, methylation patterns are stage- and tissue-specific, with changes that would define each individual cell type lasting stably over a long period. Studies on rat limb buds during
embryogenesis have further illustrated the dynamic nature of DNA methylation in development. In this context, variations in global DNA methylation were observed across different developmental stages and culture conditions, highlighting the intricate regulation of methylation during organogenesis and its potential implications for regenerative medicine strategies. Whereas DNA methylation is not necessary
per se for transcriptional silencing, it is thought nonetheless to represent a "locked" state that definitely inactivates transcription. In particular, DNA methylation appears critical for the maintenance of mono-allelic silencing in the context of
genomic imprinting and
X chromosome inactivation. In these cases, expressed and silent alleles differ by their methylation status, and loss of DNA methylation results in loss of imprinting and re-expression of Xist in somatic cells. During embryonic development, few genes change their methylation status, at the important exception of a number of genes specifically expressed in the germline. DNA methylation appears absolutely required in
differentiated cells, as knockout of any of the three competent DNA methyltransferase results in embryonic or post-partum lethality. By contrast, DNA methylation is dispensable in undifferentiated cell types, such as the inner cell mass of the blastocyst, primordial germ cells or embryonic stem cells. Since DNA methylation appears to directly regulate only a limited number of genes, how precisely DNA methylation absence causes the death of differentiated cells remain an open question. Due to the phenomenon of
genomic imprinting, maternal and paternal genomes are differentially marked and must be properly
reprogrammed every time they pass through the germline. Therefore, during
gametogenesis, primordial germ cells must have their original biparental DNA methylation patterns erased and re-established based on the sex of the transmitting parent. After fertilization, the paternal and maternal genomes are once again demethylated and remethylated (except for differentially methylated regions associated with imprinted genes). This reprogramming is likely required for totipotency of the newly formed embryo and erasure of acquired epigenetic changes.
In cancer is when methyl groups do not bond to CpG islands, causing an
oncogene to be expressed when it otherwise should not be. In the diagram, cell 1 is cancer-free as it is not experiencing hypomethylation. Then, we see an example of hypomethylation where methyl groups do not bond, causing the expression of an oncogene and thus inducing cancer development. Methylation can also silence a tumor suppressor gene. In the diagram, we see that cell 3 is cancer-free, as there is no
hypermethylation, meaning methyl groups are not actively bound and silencing a tumor suppressor gene. In cell 4, it is cancerous due to hypermethylation, causing the tumor suppressor gene to not be expressed. In multiple disease processes, such as
cancer, gene promoter
CpG islands acquire abnormal hypermethylation, which results in
transcriptional silencing that can be inherited by daughter cells following cell division. Alterations of DNA methylation have been recognized as an important component of cancer development. Hypomethylation, in general, arises earlier and is linked to chromosomal instability and loss of imprinting, whereas hypermethylation is associated with promoters and can arise secondary to gene (oncogene suppressor) silencing, but might be a target for
epigenetic therapy. In developmental contexts, dynamic changes in DNA methylation patterns also have significant implications. For instance, in rat limb buds, shifts in methylation status were associated with different stages of
chondrogenesis, suggesting a potential link between DNA methylation and the progression of certain developmental processes. Typically, there is hypermethylation of
tumor suppressor genes and hypomethylation of
oncogenes. Generally, in progression to cancer, hundreds of genes are
silenced or activated. Although silencing of some genes in cancers occurs by mutation, a large proportion of carcinogenic gene silencing is a result of altered DNA methylation (see
DNA methylation in cancer). DNA methylation causing silencing in cancer typically occurs at multiple
CpG sites in the
CpG islands that are present in the
promoters of protein coding genes. Altered expressions of
microRNAs also silence or activate multiple genes in progression to cancer (see
microRNAs in cancer). Altered microRNA expression occurs through
hyper/hypo-methylation of
CpG sites in
CpG islands in promoters controlling transcription of the
microRNAs. Silencing of DNA repair genes through methylation of CpG islands in their promoters appears to be especially important in progression to cancer (see
methylation of DNA repair genes in cancer).
In atherosclerosis Epigenetic modifications such as DNA methylation have been implicated in cardiovascular disease, including
atherosclerosis. In animal models of atherosclerosis, vascular tissue, as well as blood cells such as mononuclear blood cells, exhibit global hypomethylation with gene-specific areas of hypermethylation. DNA methylation polymorphisms may be used as an early biomarker of atherosclerosis since they are present before lesions are observed, which may provide an early tool for detection and risk prevention. Two of the cell types targeted for DNA methylation
polymorphisms are monocytes and lymphocytes, which experience an overall hypomethylation. One proposed mechanism behind this global hypomethylation is elevated
homocysteine levels causing
hyperhomocysteinemia, a known risk factor for cardiovascular disease. High plasma levels of homocysteine inhibit DNA methyltransferases, which causes hypomethylation. Hypomethylation of DNA affects genes that alter smooth muscle cell proliferation, cause endothelial cell dysfunction, and increase inflammatory mediators, all of which are critical in forming atherosclerotic lesions. High levels of homocysteine also result in hypermethylation of CpG islands in the promoter region of the
estrogen receptor alpha (ERα) gene, causing its down regulation. ERα protects against atherosclerosis due to its action as a growth suppressor, causing the smooth muscle cells to remain in a quiescent state. Hypermethylation of the ERα promoter thus allows intimal smooth muscle cells to proliferate excessively and contribute to the development of the atherosclerotic lesion. Another gene that experiences a change in methylation status in atherosclerosis is the
monocarboxylate transporter (MCT3), which produces a protein responsible for the transport of lactate and other ketone bodies out of a number of cell types, including vascular smooth muscle cells. In atherosclerosis patients, there is an increase in methylation of the CpG islands in exon 2, which decreases MCT3 protein expression. The downregulation of MCT3 impairs lactate transport and significantly increases smooth muscle cell proliferation, which further contributes to the atherosclerotic lesion. An ex vivo experiment using the demethylating agent
Decitabine (5-aza-2 -deoxycytidine) was shown to induce MCT3 expression in a dose dependent manner, as all hypermethylated sites in the exon 2 CpG island became demethylated after treatment. This may serve as a novel therapeutic agent to treat atherosclerosis, although no human studies have been conducted thus far.
In heart failure In addition to
atherosclerosis described above, specific epigenetic changes have been identified in the failing human heart. This may vary by disease etiology. For example, in ischemic heart failure DNA methylation changes have been linked to changes in gene expression that may direct gene expression associated with the changes in heart metabolism known to occur. Additional forms of heart failure (e.g. diabetic cardiomyopathy) and co-morbidities (e.g. obesity) must be explored to see how common these mechanisms are. Most strikingly, in failing human heart these changes in DNA methylation are associated with racial and socioeconomic status which further impact how gene expression is altered, and may influence how the individual's heart failure should be treated.
In aging In humans and other mammals, DNA methylation levels can be used to accurately estimate the age of tissues and cell types, forming an accurate
epigenetic clock. A
longitudinal study of
twin children showed that, between the ages of 5 and 10, there was divergence of methylation patterns due to environmental rather than genetic influences. There is a global loss of DNA methylation during aging. Hypomethylated CpGs observed in the centenarian DNAs compared with the neonates covered all genomic compartments (promoters,
intergenic,
intronic and
exonic regions). and
FHL2 In exercise High intensity exercise has been shown to result in reduced DNA methylation in skeletal muscle.
Promoter methylation of
PGC-1α and
PDK4 were immediately reduced after high intensity exercise, whereas
PPAR-δ methylation was not reduced until three hours after exercise. One study showed a possible increase in global genomic DNA methylation of
white blood cells with more physical activity in non-Hispanics.
In B-cell differentiation A study that investigated the methylome of
B cells along their differentiation cycle, using whole-genome
bisulfite sequencing (WGBS), showed that there is a hypomethylation from the earliest stages to the most differentiated stages. The largest methylation difference is between the stages of germinal center B cells and memory B cells. Furthermore, this study showed that there is a similarity between B cell tumors and long-lived B cells in their DNA methylation signatures. Contextual
fear conditioning (a form of associative learning) in animals, such as mice and rats, is rapid and is extremely robust in creating memories. In mice and in rats contextual fear conditioning, within 1–24 hours, it is associated with altered methylations of several thousand DNA cytosines in genes of
hippocampus neurons. Twenty four hours after contextual fear conditioning, 9.2% of the genes in rat
hippocampus neurons are differentially methylated. That review also indicated the mechanisms by which the new patterns of methylation gave rise to new patterns of
messenger RNA expression. These new
messenger RNAs were then transported by
messenger RNP particles (neuronal granules) to synapses of the neurons, where they could be translated into proteins. Active changes in neuronal DNA methylation and demethylation appear to act as controllers of
synaptic scaling and
glutamate receptor trafficking in
learning and
memory formation. ==DNA methyltransferases (in mammals)==