C, A Fisher’s exact test was conducted for each CpG in (b) (** p,.01, *** p,.001). d, Profile of average DNA SR3029 methylation relative to TSS calculated in 100 bp bins. e, Hierarchical clustering was performed on MeDIP-chip enrichment profiles to identify genes with similar profiles. 1,282 genes that passed the filtering step of the clustering software are on the y-axis. The x-axis is based on average fluorescent ratios in 100 bp bins from 23 kb (left) to +1 kb (right). Red indicates increased DNA methylation and green indicates decreased DNA methylation while black indicates unchanged DNA methylation. f, Gene ontology classifications for genes with increased (red) or decreased (green) DNAme. g, Gene ontology classifications for genes with increased DNAme upstream of the TSS (cluster 1, white) or across the entire promoter (cluster 2, grey). h, Classification of promoters based on CpG content. HCP, ICP LCP, High-, Intermediate- low CpG content promoter. i, Classification of promoters based on presence of H3K27me3 H3K4me3. CpG and bivalent data used in (h) and (i) from [5] j, Boxplot of expression level change for genes enriched or depleted for DNAme in Eed2/2 cells as well as for each of the two clusters described in (e). doi:10.1371/journal.pone.0053880.ggenome in the absence of DNA methylation. Intersection of the two replicates yielded 471,011 peaks covering 474,802,970 bp. We 58-49-1 site designed qPCR primers to ten peaks common to both replicates and tested six biological replicates each of wildtype and DnmtTKO cells to validate the ChIP-seq results. All ten peaks confirmed the significantly increased H3K27me3 levels as assayed by 24272870 qPCR (Figure 2C). Since we couldn’t identify a single false positive peak by qPCR, we validated an additional five peaks that were significant in one of our two replicates. All five of these peaks were also significantly enriched by qPCR (Figure 2C). If we examine the union of the two replicates, we get 756,847 peaks covering 1,218,250,739 bp, or ,45 of the mouse genome with increased H3K27me3 in the absence of DNA methylation. Finally, we tested eleven sets of primers that covered regions that didn’t have a peak in either biological replicate. Interestingly, six of the eleven sets of primers showed significantly increased levels of H3K27me3 in DnmtTKO cells. This suggests our ChIP-seq results may in fact be underestimating the portion of the genome with increased H3K27me3 in the absence of DNA methylation. We suspect peak calling programs have difficulty calling peaks when there are such high levels of enrichment across the genome. We confirmed the increase of H3K27me3 in DnmtTKO by western blot and saw a nearly 3-fold increase in H3K27me3 in DnmtTKO cells relative to wildtype cells (Figure 2D). This effect was also present in v6.5 cells treated with the DNA methyltransferase inhibitor 5-azacytidine. The pharmacological and genetic manipulations that impair DNAme both support the conclusion that DNAme has a potent negative influence on H3K27me3 in ES cells, regardless of their origin. The 471,011 peaks present in both replicates show increased H3K27me3 at 50,659 annotated regions within transcripts from 20,254 gene promoters (23 to +1 kb from the TSS), or about 55 of all known genes. The 756,847 peaks that represent the union of the two replicates intersect with 76,596 annotated transcripts from 30,037 gene promoters, or 82 of known genes. In contrast, only 861 gene showed increased DNA methylation in EED-defici.C, A Fisher’s exact test was conducted for each CpG in (b) (** p,.01, *** p,.001). d, Profile of average DNA methylation relative to TSS calculated in 100 bp bins. e, Hierarchical clustering was performed on MeDIP-chip enrichment profiles to identify genes with similar profiles. 1,282 genes that passed the filtering step of the clustering software are on the y-axis. The x-axis is based on average fluorescent ratios in 100 bp bins from 23 kb (left) to +1 kb (right). Red indicates increased DNA methylation and green indicates decreased DNA methylation while black indicates unchanged DNA methylation. f, Gene ontology classifications for genes with increased (red) or decreased (green) DNAme. g, Gene ontology classifications for genes with increased DNAme upstream of the TSS (cluster 1, white) or across the entire promoter (cluster 2, grey). h, Classification of promoters based on CpG content. HCP, ICP LCP, High-, Intermediate- low CpG content promoter. i, Classification of promoters based on presence of H3K27me3 H3K4me3. CpG and bivalent data used in (h) and (i) from [5] j, Boxplot of expression level change for genes enriched or depleted for DNAme in Eed2/2 cells as well as for each of the two clusters described in (e). doi:10.1371/journal.pone.0053880.ggenome in the absence of DNA methylation. Intersection of the two replicates yielded 471,011 peaks covering 474,802,970 bp. We designed qPCR primers to ten peaks common to both replicates and tested six biological replicates each of wildtype and DnmtTKO cells to validate the ChIP-seq results. All ten peaks confirmed the significantly increased H3K27me3 levels as assayed by 24272870 qPCR (Figure 2C). Since we couldn’t identify a single false positive peak by qPCR, we validated an additional five peaks that were significant in one of our two replicates. All five of these peaks were also significantly enriched by qPCR (Figure 2C). If we examine the union of the two replicates, we get 756,847 peaks covering 1,218,250,739 bp, or ,45 of the mouse genome with increased H3K27me3 in the absence of DNA methylation. Finally, we tested eleven sets of primers that covered regions that didn’t have a peak in either biological replicate. Interestingly, six of the eleven sets of primers showed significantly increased levels of H3K27me3 in DnmtTKO cells. This suggests our ChIP-seq results may in fact be underestimating the portion of the genome with increased H3K27me3 in the absence of DNA methylation. We suspect peak calling programs have difficulty calling peaks when there are such high levels of enrichment across the genome. We confirmed the increase of H3K27me3 in DnmtTKO by western blot and saw a nearly 3-fold increase in H3K27me3 in DnmtTKO cells relative to wildtype cells (Figure 2D). This effect was also present in v6.5 cells treated with the DNA methyltransferase inhibitor 5-azacytidine. The pharmacological and genetic manipulations that impair DNAme both support the conclusion that DNAme has a potent negative influence on H3K27me3 in ES cells, regardless of their origin. The 471,011 peaks present in both replicates show increased H3K27me3 at 50,659 annotated regions within transcripts from 20,254 gene promoters (23 to +1 kb from the TSS), or about 55 of all known genes. The 756,847 peaks that represent the union of the two replicates intersect with 76,596 annotated transcripts from 30,037 gene promoters, or 82 of known genes. In contrast, only 861 gene showed increased DNA methylation in EED-defici.
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