Abstract
Imprinted genes are vulnerable to environmental influences during early embryonic development, thereby contributing to the onset of disease in adulthood. Monoallelic methylation at several germline imprints has been reported as DNMT1-dependent. However, which of these two epigenetic attributes, DNMT1-dependence or allelic methylation, renders imprinted genes susceptible to environmental stressors has not been determined. Herein, we developed a new approach, referred to as NORED, to identify 2468 DNMT1-dependent DNA methylation patterns in the mouse genome. We further developed an algorithm based on a genetic variation-independent approach (referred to as MethylMosaic) to detect 2487 regions with bimodal methylation patterns. Two approaches identified 207 regions, including known imprinted germline allele-specific methylation patterns (ASMs), that were both NORED and MethylMosaic regions. Examination of methylation in four independent mouse embryonic stem cell lines shows that two regions identified by both NORED and MethylMosaic (Hcn2 and Park7) did not display parent-of-origin-dependent allelic methylation. In these four F1 hybrid cell lines, genetic variation in Cast allele at Hcn2 locus introduces a transcription factor binding site for MTF-1 that may predispose Cast allelic hypomethylation in a reciprocal cross with either C57 or 129 strains. In contrast, each allele of Hcn2 ASM in J1 inbred cell line and Park7 ASM in four F1 hybrid cell lines seems to exhibit similar propensity to be either hypo- or hypermethylated, suggesting a ‘random, switchable’ ASM. Together with published results, our data on ASMs prompted us to propose a hypothesis of regional ‘autosomal chromosome inactivation (ACI)’ that may control a subset of autosomal genes. Therefore, our results open a new avenue to understand monoallelic methylation and provide a rich resource of candidate genes to examine in environmental and nutritional exposure models.
Highlights
Environmental factors impact human health [1,2,3]
On the basis of the loss of germline ASMs (gASMs)/differentially methylated region (DMR) in DNMT1 knockout (1KO) embryonic stems cells (ESCs) and failure to restore the loss in 1KO cells with exogenous expression of DNMT1 cDNA, we developed a new approach, ‘non-rescued DMR (NORED)’, identifying genomic regions dependent on DNMT1
All gASMs are lost in DNMT1-deficient ESCs, whereas specific loci exhibit resistance to methylation loss in DNMT3a/3b-deficient ESCs
Summary
Environmental factors impact human health [1,2,3]. For example, a high fat diet contributes to the pathogenesis of obesity and type 2 diabetes [4, 5], and low nutrition during early embryonic development may link to cardiovascular diseases in later life; [6]. and exposure to endocrine disrupting chemicals such as Bisphenol A increases the susceptibility to diseases including neurological disorders [7,8,9], heart diseases [10, 11]. and cancers [12,13,14,15,16,17,18,19,20,21,22]. Cancers [12,13,14,15,16,17,18,19,20,21,22] These factors contribute to the disease pathogenesis, largely via epigenetic mechanisms [2, 3, 5, 23, 24]. Altered epigenetic patterns have been involved in numerous human diseases. A notable example is that cancer cells are characterized by genome-wide hypomethylation and region-specific hypermethylation. Additional examples include abnormal hypomethylation of genes involved in autoimmune diseases such as systemic lupus erythematosus [25]. Many publications report altered expression of DNMT1, the maintenance enzyme for transmitting DNA methylation patterns in generations of somatic cells [24]. A systematic examination of DNMT-dependent methylation regions via global profiling of DNMT-deficient cells will significantly improve our understanding of such alterations in diseases
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