Abstract
We have previously identified large megabase-sized hypomethylated zones in the genome of the breast cancer cell line MCF-7 using the TspRI-ExoIII technique. In this report, we used a more convenient high throughput method for mapping the hypomethylated zones in a number of human tumor genomes simultaneously. The method was validated by the bisulfite sequencing of 39 randomly chosen sites in a demethylated domain and by bisulfite genome-wide sequencing of the MCF-7 genome. This showed that the genomes of the various tumor cell lines, as well as some primary tumors, exhibit common hypomethylated domains. Interestingly, these hypomethylated domains are correlated with low CpG density distribution genome-wide, together with the histone H3K27Me3 landscape. Furthermore, they are inversely correlated with the H3K9Ac landscape and gene expression as measured in MCF-7 cells. Treatment with drugs resulted in en-bloc changes to the methylation domains. A close examination of the methylation domains found differences between non-invasive and invasive tumors with respect to tumorigenesis related genes. Taken together these results suggest that the human genome is organized in epigenomic domains that contain various different types of genes and imply that there are cis- and trans-regulators that control these domain-wide epigenetic changes and hence gene expression in the human genome. The hypomethylated domains are located in gene deserts that contain mainly tissue-specific genes and therefore we hypothesize that tumor cells keep these regions demethylated and silenced in order to save energy and resources and allow higher levels of cell proliferation and better survival (a thrifty tumor genome hypothesis).
Highlights
DNA methylation and histone modifications constitute the major epigenetic mechanisms involved in regulating mammalian gene expression [1,2,3]
The results show that genomes from several different tumor types all exhibit similar methylome patterns, albeit with subtle variations. This methylome domain pattern was found to be correlated with various histone modification landscapes, with CpG density distribution, gene density and gene expression
In our previous study we developed the TspRI-ExoIII method that allows the rapid mapping of methylated regions in the human genome [1]. Using this method we discovered the presence of large megabase-sized hypomethylated domains in a breast tumor genome
Summary
DNA methylation and histone modifications constitute the major epigenetic mechanisms involved in regulating mammalian gene expression [1,2,3]. To provide a high throughput method for mapping overall methylation pattern in a genome, we previously developed a biochemical method to remove sequences that contain unmethylated HpaII sites [1] Using this method we have shown that there are megabase-sized hypomethylated domains in breast tumor cell lines. The results show that genomes from several different tumor types all exhibit similar methylome patterns, albeit with subtle variations This methylome domain pattern was found to be correlated with various histone modification landscapes, with CpG density distribution, gene density and gene expression. We suggest that this implies that tumor cells keep these regions demethylated and silenced in order to save energy and resources. This would allow higher levels of cell proliferation and better survival of the tumor cells and supports a thrifty tumor genome hypothesis
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