DNA methylation in the promoter region of the p16 (CDKN2/MTS-1/INK4A) gene in human breast tumours

The p16 (CDKN2/MTS-1/INK4A) gene is one of several tumour-suppressor genes that have been shown to be inactivated by DNA methylation in various human cancers including breast tumours. We have used bisulphite genomic sequencing to examine the detailed sequence specificity of DNA methylation in the CpG island promoter/exon 1 region in the p16 gene in DNA from a series of human breast cancer specimens and normal human breast tissue (from reductive mammaplasty). The p16 region examined was unmethylated in the four normal human breast specimens and in four out of nine breast tumours. In the other five independent breast tumour specimens, a uniform pattern of DNA methylation was observed. Of the nine major sites of DNA methylation in the amplified region from these tumour DNAs, four were in non-CG sequences. This unusual concentration of non-CG methylation sites was not a general phenomenon present throughout the genome of these tumour cells because the methylated CpG island regions of interspersed L1 repeats had a pattern of (almost exclusively) CG methylation similar to that found in normal breast tissue DNA and in DNA from tumours with unmethylated p16 genes. These data suggest that DNA methylation of the p16 gene in some breast tumours could be the result of an active process that generates a discrete methylation pattern and, hence, could ultimately be amenable to therapeutic manipulation.     

Infection with human immunodeficiency virus type 1 upregulates DNA methyltransferase, resulting in de novo methylation of the gamma interferon (IFN-gamma) promoter and subsequent downregulation of IFN-gamma production

The immune response to pathogens is regulated by a delicate balance of cytokines. The dysregulation of cytokine gene expression, including interleukin-12, tumor necrosis factor alpha, and gamma interferon (IFN-gamma), following human retrovirus infection is well documented. One process by which such gene expression may be modulated is altered DNA methylation. In subsets of T-helper cells, the expression of IFN-gamma, a cytokine important to the immune response to viral infection, is regulated in part by DNA methylation such that mRNA expression inversely correlates with the methylation status of the promoter. Of the many possible genes whose methylation status could be affected by viral infection, we examined the IFN-gamma gene as a candidate. We show here that acute infection of cells with human immunodeficiency virus type 1 (HIV-1) results in (i) increased DNA methyltransferase expression and activity, (ii) an overall increase in methylation of DNA in infected cells, and (iii) the de novo methylation of a CpG dinucleotide in the IFN-gamma gene promoter, resulting in the subsequent downregulation of expression of this cytokine. The introduction of an antisense methyltransferase construct into lymphoid cells resulted in markedly decreased methyltransferase expression, hypomethylation throughout the IFN-gamma gene, and increased IFN-gamma production, demonstrating a direct link between methyltransferase and IFN-gamma gene expression. The ability of increased DNA methyltransferase activity to downregulate the expression of genes like the IFN-gamma gene may be one of the mechanisms for dysfunction of T cells in HIV-1-infected individuals.     

Chromatin conformation of the H19 epigenetic mark

Genomic imprinting in mammals is an epigenetic process that results in differential expression of the two parental alleles. The tightly linked murine H19 and Igf2 genes are reciprocally imprinted: H19 is expressed from the maternal chromosome while Igf2 is expressed from the paternal chromosome. A single regulatory region in the 5' flank of the H19 gene has been implicated in silencing both genes. On the paternal chromosome, this region is heavily methylated at CpG residues, leading to repression of the H19 gene. The mechanism by which the same region in an unmethylated state on the maternal chromosome silences Igf2 is less well understood. We have probed the chromatin structure of the region by assessing its sensitivity to nuclease digestion. Two regions of nuclease hypersensitivity that are specific to the maternal chromosome were identified. These coincide with the region that is most heavily methylated on the paternal chromosome. As is the case with paternal methylation, hypersensitivity is present in all tissues surveyed, irrespective of H19 expression. We suggest that the chromatin structure of the maternal 5' flank of the H19 gene may represent an epigenetic mark involved in the silencing of Igf2.     

Concurrent replication and methylation at mammalian origins of replication

Observations made with Escherichia coli have suggested that a lag between replication and methylation regulates initiation of replication. To address the question of whether a similar mechanism operates in mammalian cells, we have determined the temporal relationship between initiation of replication and methylation in mammalian cells both at a comprehensive level and at specific sites. First, newly synthesized DNA containing origins of replication was isolated from primate-transformed and primary cell lines (HeLa cells, primary human fibroblasts, African green monkey kidney fibroblasts [CV-1], and primary African green monkey kidney cells) by the nascent-strand extrusion method followed by sucrose gradient sedimentation. By a modified nearest-neighbor analysis, the levels of cytosine methylation residing in all four possible dinucleotide sequences of both nascent and genomic DNAs were determined. The levels of cytosine methylation observed in the nascent and genomic DNAs were equivalent, suggesting that DNA replication and methylation are concomitant events. Okazaki fragments were also demonstrated to be methylated, suggesting that the rapid kinetics of methylation is a feature of both the leading and the lagging strands of nascent DNA. However, in contrast to previous observations, neither nascent nor genomic DNA contained detectable levels of methylated cytosines at dinucleotide contexts other than CpG (i.e., CpA, CpC, and CpT are not methylated). The nearest-neighbor analysis also shows that cancer cell lines are hypermethylated in both nascent and genomic DNAs relative to the primary cell lines. The extent of methylation in nascent and genomic DNAs at specific sites was determined as well by bisulfite mapping of CpG sites at the lamin B2, c-myc, and beta-globin origins of replication. The methylation patterns of genomic and nascent clones are the same, confirming the hypothesis that methylation occurs concurrently with replication. Interestingly, the c-myc origin was found to be unmethylated in all clones tested. These results show that, like genes, different origins of replication exhibit different patterns of methylation. In summary, our results demonstrate tight coordination of DNA methylation and replication, which is consistent with recent observations showing that DNA methyltransferase is associated with proliferating cell nuclear antigen in the replication fork.