The establishment and maintenance of DNA methylation patterns in mouse somatic cells

Allele-specific non-CpG methylation of the Nf1 gene during early mouse development

Recent reports of cytosine methylation occurring at CpA and CpT dinucleotides in murine ES cells as well as in Drosophila have renewed interest in methylation at sites other than CpGs. Our examination of the murine neurofibromatosis type 1 gene by sodium bisulfite genomic sequencing has revealed non-CpG methylation primarily in the oocyte and the maternally derived allele of the 2-cell embryo, with markedly lower levels found in sperm. Non-CpG methylation was not found in later stages of embryo development or in adult tissue. Our results suggest that maternal-specific de novo non-CpG methylation has occurred sometime between ovulation and formation of the 2-cell embryo, while during the same period the paternally derived allele has undergone site-specific active demethylation. Our data demonstrate both stage and parent-of-origin specific changes in methylation patterns within the neurofibromatosis type 1 coding region-involving cytosines located at both CpG and non-CpG dinucleotides.

De novo methylation of an embryonic globin gene during normal development is strand specific and spreads from the proximal transcribed region

The recently discovered de novo methyltransferases DNMT3a and DNMT3b have been shown to be critical to embryonic development. However, at a single gene level, little is known about how the methylation pattern is established during development. The avian embryonic rho-globin gene promoter is completely unmethylated in 4-day-old chicken embryonic erythroid cells, where it is expressed at a high level, and completely methylated in adult erythroid cells, where it is silent. The methylation pattern of the rho-globin gene promoter, proximal transcribed region, and distal transcribed region on both DNA strands was examined during development in chicken erythroid cells. It was found that de novo methylation targets the CpG-dense proximal transcribed region on the coding (top) strand initially, followed by spreading into the 3' region and into the promoter region. Methylation of the template (bottom) strand lags behind that of the coding strand, and complete methylation of both strands occurs only after the gene has been silenced. The results of the study indicate that establishment of the de novo methylation pattern involves strand-specificity and methylation spreading.

Methylation and colorectal cancer

Statistics rate colorectal adenocarcinoma as the most common cause of cancer death on exclusion of smoking-related neoplasia. However, the reported accumulation of genetic lesions over the adenoma to adenocarcinoma sequence cannot wholly account for the neoplastic phenotype. Recently, heritable, epigenetic changes in DNA methylation, in association with a repressive chromatin structure, have been identified as critical determinants of tumour progression. Indeed, the transcriptional silencing of both established and novel tumour suppressor genes has been attributed to the aberrant cytosine methylation of promoter-region CpG islands. This review aims to set these epigenetic changes within the context of the colorectal adenoma to adenocarcinoma sequence. The role of cytosine methylation in physiological and pathological gene silencing is discussed and the events behind aberrant cytosine methylation in ageing and cancer are appraised. Emphasis is placed on the interrelationships between epigenetic and genetic lesions and the manner in which they cooperate to define a CpG island methylator phenotype at an early stage in tumourigenesis. Finally, the applications of epigenetics to molecular pathology and patient diagnosis and treatment are reviewed.

The role of DNA methylation in mammalian epigenetics

Genes constitute only a small proportion of the total mammalian genome, and the precise control of their expression in the presence of an overwhelming background of noncoding DNA presents a substantial problem for their regulation. Noncoding DNA, containing introns, repetitive elements, and potentially active transposable elements, requires effective mechanisms for its long-term silencing. Mammals appear to have taken advantage of the possibilities afforded by cytosine methylation to provide a heritable mechanism for altering DNA-protein interactions to assist in such silencing. Genes can be transcribed from methylation-free promoters even though adjacent transcribed and nontranscribed regions are extensively methylated. Gene promoters can be used and regulated while keeping noncoding DNA, including transposable elements, suppressed. Methylation is also used for long-term epigenetic silencing of X-linked and imprinted genes and can either increase or decrease the level of transcription, depending on whether the methylation inactivates a positive or negative regulatory element.

The activity of the murine DNA methyltransferase Dnmt1 is controlled by interaction of the catalytic domain with the N-terminal part of the enzyme leading to an allosteric activation of the enzyme after binding to methylated DNA

The mammalian DNA methyltransferase Dnmt1 is responsible for the maintenance of the pattern of DNA methylation in vivo. It is a large multidomain enzyme comprising 1620 amino acid residues. We have purified and characterized individual domains of Dnmt1 (NLS-containing domain, NlsD, amino acid residues: 1-343; replication foci-directing domain, 350-609; Zn-binding domain (ZnD), 613-748; polybromo domain, 746-1110; and the catalytic domain (CatD), 1124-1620). CatD, ZnD and NlsD bind to DNA, demonstrating the existence of three independent DNA-binding sites in Dnmt1. CatD shows a preference for binding to hemimethylated CpG-sites; ZnD prefers methylated CpGs; and NlsD specifically binds to CpG-sites, but does not discriminate between unmethylated and methylated DNA. These results are not compatible with the suggestion that the target recognition domain of Dnmt1 resides in the N terminus of the enzyme. We show by protein-protein interaction assays that ZnD and CatD interact with each other. The isolated catalytic domain does not methylate DNA, neither alone nor in combination with other domains. Full-length Dnmt1 was purified from baculovirus-infected insect cells. Under the experimental conditions, Dnmt1 has a strong (50-fold) preference for hemimethylated DNA. Dnmt1 is stimulated to methylate unmodified CpG sites by the addition of fully methylated DNA. This effect is dependent on Zn, suggesting that binding of methylated DNA to ZnD triggers the allosteric activation of the catalytic center of Dnmt1. The allosteric activation model can explain kinetic data obtained by others. It suggests that Dnmt1 might be responsible for spreading of methylation, a process that is observed during aging and carcenogenesis but may be important for de novo methylation of DNA.

Differential inheritance modes of DNA methylation between euchromatic and heterochromatic DNA sequences in ageing fetal bovine fibroblasts

To elucidate overall changes in DNA methylation occurring by inappropriate epigenetic control during ageing, we compared fetal bovine fibroblasts and their aged neomycin-resistant versions using bisulfite-PCR technology. Reduction in DNA methylation was observed in euchromatic repeats (18S-rRNA/art2) and promoter regions of single-copy genes (the cytokeratin/beta-lactoglobulin/interleukin-13 genes). Contrastingly, a stable maintenance of DNA methylation was revealed in various heterochromatic sequences (satellite I/II/alphoid and Bov-B). The differential inheritance mode of DNA methylation was confirmed through the analysis of individual neomycin-resistant clones. These global, multi-locus analyses provide evidence on the tendency of differential epigenetic modification between genomic DNA regions during ageing.

Methylation profiling in acute myeloid leukemia

Aberrant methylation of multiple CpG islands has been described in acute myeloid leukemia (AML), but it is not known whether these are independent events or whether they reflect specific methylation defects in a subset of cases. To study this issue, the methylation status of 14 promoter-associated CpG islands was analyzed in 36 cases of AML previously characterized for estrogen-receptor methylation (ERM). Cases with methylation density of 10% or greater were considered positive. Seventeen cases (47%) were ERM(+) while 19 cases were ERM(-). Hypermethylation of any of the following, p15, p16, CACNA1G, MINT1, MINT2, MDR1, THBS1, and PTC1 (2 promoters), was relatively infrequent (6% to 31% of patients). For each of these CpG islands, the methylation density was positively correlated with ERM density (rank order correlation coefficients, 0.32-0.59; 2-tailed P < or = .058 for each gene). Hypermethylation of MYOD1, PITX2, GPR37, and SDC4 was frequently found in AML (47% to 64% of patients). For each of these genes as well, methylation density was positively correlated with ERM density (correlation coefficients 0.43 to 0.69, P < or = .0087 for each gene). MLH1 was unmethylated in all cases. Hypermethylation of p15, MDR1, and SDC4 correlated with reduced levels of expression. There was an inverse correlation between age and the number of genes methylated (P = .0030). It was concluded that CpG-island methylation in AML results from methylation defects in subsets of cases. These results have potential implications for the classification and prognosis of AML and for the identification of patients who may benefit from treatment with methylation inhibitors.

Short TpA-rich segments of the zeta-eta region induce DNA methylation in Neurospora crassa

The mechanisms that establish DNA methylation in eukaryotes are poorly understood. In principle, methylation in a particular chromosomal region may reflect the presence of a "signal" that recruits methylation, the absence of a signal that prevents methylation, or both. Experiments were carried out to address these possibilities for the 1.6 kb zeta-eta (zeta-eta) region, a relict of repeat-induced point mutation (RIP) in the fungus Neurospora crassa. The zeta-eta region directs its own de novo methylation at a variety of chromosomal locations. We tested the methylation potential of a nested set of fragments with deletions from one end of the zeta-eta region, various internal fragments of this region, chimeras of eta and the homologous unmutated allele, theta (theta), and various synthetic variants, integrated precisely in single copy at the am locus on linkage group (LG) VR or the his-3 locus on LG IR. We found that: (1) the zeta-eta region contains at least two non-overlapping methylation signals; (2) different fragments of the region can induce different levels of methylation; (3) methylation induced by zeta-eta sequences can spread far into flanking sequences; (4) fragments as small as 171 bp can trigger methylation; (5) methylation signals behave similarly, but not identically, at different chromosomal sites; (6) mutation density, per se, does not determine whether sequences become methylated; and (7) neither A:T-richness nor high densities of TpA dinucleotides, typical attributes of methylated sequences in Neurospora, are essential features of methylation signals, but both promote de novo methylation. We conclude that de novo methylation of zeta-eta sequences does not simply reflect the absence of signals that prevent methylation; rather, the region contains multiple, positive signals that trigger methylation. These findings conflict with earlier models for the control of DNA methylation, including the simplest version of the collapsed chromatin model.

The epigenetics of colorectal cancer

Colorectal cancer has provided an excellent model for studying the genetic basis of cancer and is one of the better-understood malignancies in this regard. The orderly progression of the disease, with distinct genetic alterations at each step, is a useful framework for deciphering the molecular basis of neoplasia. Epigenetics, the study of clonal changes in gene expression without associated genetic lesions, has raised increased interest recently, in part because of the identification of DNA methylation as a potential molecular mediator of the process. Several tumor-suppressor genes are silenced in various neoplasms in association with aberrant promoter methylation, and in the absence of coding region mutations. The study of DNA methylation changes in colorectal cancer has now provided additional clues into the pathogenesis of the disease. This review presents evidence for a model whereby DNA methylation changes play two distinct roles in the molecular evolution of colorectal cancer. Initially, progressive methylation and silencing of a subset of genes takes place in normal tissues as a function of age or time-dependent events and predisposes these normal cells to neoplastic transformation. At a later stage of disease progression, DNA methylation plays an important role in a subset of tumors affected by the CpG island methylator phenotype (CIMP), a recently identified pathway that results in a form of epigenetic instability through the simultaneous silencing of multiple genes. DNA methylation changes have important interactions with genetic lesions in this cancer type. CIMP+ cancers include the majority of tumors with sporadic mismatch repair deficiency through hypermethylation of the hMLH1 promoter, and also account for the majority of tumors with Ki-ras mutations through an unknown mechanism. By contrast, CIMP- cases evolve along a more classic genetic instability pathway, with a high rate of p53 mutations and chromosomal changes. Thus, the integration of epigenetic and genetic information provides a more complete molecular understanding of colorectal cancer and may have implications for the diagnosis, prognosis, and treatment of patients affected by this disease.

Tandem B1 elements located in a mouse methylation center provide a target for de novo DNA methylation

A cis-acting methylation center that signals de novo DNA methylation is located upstream of the mouse Aprt gene. In the current study, two approaches were taken to determine if tandem B1 repetitive elements found at the 3' end of the methylation center contribute to the methylation signal. First, bisulfite genomic sequencing demonstrated that CpG sites within the B1 elements were methylated at relative levels of 43% in embryonal stem cells deficient for the maintenance DNA methyltransferase when compared with wild type embryonal stem cells. Second, the ability of the B1 elements to signal de novo methylation upon stable transfection into mouse embryonal carcinoma cells was examined. This approach demonstrated that the B1 elements were methylated de novo to a high level in the embryonal carcinoma cells and that the B1 elements acted synergistically. The results from these experiments provide strong evidence that the tandem B1 repetitive elements provide a significant fraction of the methylation center signal. By extension, they also support the hypothesis that one role for DNA methylation in mammals is to protect the genome from expression and transposition of parasitic elements.