Project description:Integration of synthetic CpG Free DNA induces de novo DNAme in the flanking CpG island. Cellular differentiation requires global changes to DNA methylation (DNAme), where it functions to regulate transcription factor and chromatin remodeling activity, and genome interpretation. Here, we describe a simple DNAme engineering approach in pluripotent stem cells (PSCs), extending across large stretches of CpG dense “islands (CGIs).” Integration of synthetic CpG free single-stranded DNA (ssDNA) induces a target CpG Island Methylation Response (CIMR) in multiple PSC lines, Nt2d1 embryonal carcinoma cells, and mouse PSCs, but not in highly methylated CpG Island Methylator Phenotype (CIMP) positive cancer lines. CIMR DNAme at MLH1 spans the CGI, is robustly maintained throughout cellular differentiation, suppresses target gene activity, and sensitizes derived cardiomyocytes and thymic epithelial cells to the chemotherapy cisplatin. Additional CIMR DNAme is reported on at TP53 and ONECUT1 CGIs. Collectively, this new resource enables total CpG Island DNAme engineering in pluripotency and the genesis of novel epigenetic models of development and disease

Project description:Genome-wide methylation analysis was performed by methylated DNA immunoprecipitation (MeDIP)-CpG island (CGI) microarray analysis to identify candidate CGIs specifically methylated in mouse colon tumors associated with colitis. We sucessfully identified 23 candidate CGIs methylated in tumors.

Project description:While the majority of RNA polymerase II initiation events in mammalian genomes take place within CpG island (CGI) promoters, our understanding of their regulation remains limited. Here we combine single-molecule footprinting with interaction proteomics to identify BANP as a critical CGI regulator and the long sought-after TF that binds the orphan CGCG element in mouse and human. We show that BANP drives the activity of essential metabolic genes in the mouse genome in pluripotent and terminally differentiated cells. However, BANP binding is strongly repelled by DNA methylation of its motif in vitro and in vivo, which epigenetically restricts most binding to CGIs and accounts for its absence at aberrantly methylated CGIs in cancer cells. Upon binding to an unmethylated motif, BANP opens chromatin and phases nucleosomes. Our results establish Banp as a critical activator and put forth a model whereby CGI promoter activity relies on methylation-sensitive TFs capable of chromatin opening.

Project description:De novo DNA methylation (DNAme) occurs coincident with transcription during mouse oogenesis. As many oocyte transcripts originate in Long Terminal Repeats (LTRs), which are divergent across species, we examined whether polymorphic LTR-initiated transcription units (LITs) shape the oocyte methylome. We identified thousands of syntenic regions in mouse, rat and human, including CpG islands (CGIs), that show divergent DNAme associated with polymorphic LITs. Notably, many CGI promoters methylated exclusively in mouse and/or rat are embedded within rodent-specific LITs, and show persistent maternal methylation in the blastocyst. Polymorphic LITs are also responsible for divergent methylation of CGI promoters in distantly related mouse strains, revealing that LITs also promote intra-species diversification of promoter DNAme.

Project description:CpG islands (CGIs) including those at imprinting control regions (ICRs) are protected from de novo methylation in somatic cells. However, many cancers often exhibit CGI hypermethylation, implying that the machinery is impaired in cancer cells. Here, we conducted a comprehensive analysis of CGI methylation during the somatic cell reprogramming. Although most CGIs remain hypomethylated, a small subset of CGIs, particularly at several ICRs, were often de novo methylated in reprogrammed pluripotent stem cells (PSCs). Such de novo ICR methylation was linked with the silencing of reprogramming factors, which occurs at a late stage of reprogramming. The ICR-preferred CGI hypermethylation was similarly observed in human PSCs. Mechanistically, ablation of Dnmt3a prevented PSCs from de novo ICR methylation. Notably, the ICR-preferred CGI hypermethylation was observed in pediatric cancers, while adult cancers exhibit genome-wide CGI hypermethylation. These results may have important implications in the pathogenesis of pediatric cancers and the application of PSCs.

Project description:Genome-wide DNA methylation of colorectal cancer patients with lymph node metastases showed global loss of DNA methylation in CG-poor, non-CpG island (CGI) regions. Overall CGI methylation was increased in tumour samples. Differential methylation analysis of CGIs identified 60 putative biomarkers, with >20% increase in DNA methylation in both primary tumour and metastasis samples compared to normal adjacent tissue.

Project description:Genome-wide methylation analysis was performed by methylated DNA immunoprecipitation (MeDIP)-CpG island (CGI) microarray analysis to identify candidate CGIs specifically methylated in mouse colon tumors associated with colitis. We sucessfully identified 23 candidate CGIs methylated in tumors. Two samples were analyzed by MeDIP-CGI microarray. One is a pool of two AOM/DSS-induced colon tumors in BALB/c mice and another is a pool of two normal colonic epithelial cell samples obtained from untreated BALB/c mice by the crypt isolation technique. The pool of normal colonic epithelial cell samples was used as reference. Dye-swaps were not perfromed. The methylation statuses of CGIs identified by microarray were confirmed by another method, methylation-specific PCR.

Project description:X chromosome inactivation (XCI) is a dosage compensation mechanism in female cells to regulate X-linked gene expression. We report here that subcultures from established lines of female hESCs displayed variations (0-100%) in the expression of XCI markers such as XIST RNA coating and enrichment of histone H3 lysine 27 trimethylation (H3K27me3) on inactive X chromosome. Surprisingly, regardless of the presence or absence of XCI markers in different cultures, all female hESCs we examined (H7, H9, and HSF6 cells) exhibit a mono-allelic expression pattern for a majority of X-linked genes. Our results suggest that these established female hESCs have completed XCI during the process of derivation and/or propagation, and the XCI pattern of lines we investigated is already non-random. However, XIST gene expression in subsets of female hESCs is unstable and subject to epigenetic silencing through DNA methylation. Concomitant with the loss of XCI markers including XIST expression and H3K27me3, approximately 12% of X-linked CpG islands become hypomethylated and a subset of previously silenced X-linked alleles are reactivated, resulting a significant elevation of gene expression dosage. Because changes in dosage compensation of X-linked genes could impair somatic cell function, we propose that XCI status should be routinely checked in subcultures of female hESCs, with cultures displaying XCI markers better suited for use in regenerative medicine. Keywords: Genotyping, gene expression and DNA methylation We used Affymetrix Genotyping array for looking for X-linked SNPs with HSF6, H7 and H9 genomic DNA, Agilent Gene expression array for comparing gene expression patten changes between HSF6 hESCs with X-inactiation and HSF6 hESCs without X-inactivation (3 repeats). Finally, mDIP-Chip method was used to detect X-linked CpG island methylation changes differences between hESCs with X-inactivation and hESCs without X-inactivation using Agilent CpG island array (3 repeats, and one of them has dye swap)

Project description:CpG island methylation

Project description:Abnormal epigenetic gene regulation may play a pivotal role in atherogenesis. In particular, global DNA hypomethylation potentially leading to proatherogenic gene expression, occurs in atherosclerotic lesions in humans and animal models. In order to identify genomic sequences targeted for DNA hypomethylation in atherosclerosis, we analysed the methylation status of CpG islands (CGIs) in 45 human arteries with advanced atherosclerotic lesions and 16 normal counterparts by a microarray approach. Methylation data for 10,367 CGIs revealed that a subset (1.5%) of such sequences was hypermethylated in normal arteries, in accordance with data previously obtained in peripheral blood cells. Ninety-four per cent of this CGI subset was demethylated in atherosclerotic tissue, while only 17 of normally hypomethylated CGIs was hypermethylated in diseased tissue. A functional classification of genes physically associated with differentially methylated CGIs revealed a bias towards transcription factors (42%). The latter include HOX members, NOTCH1 and FOXP1, which are known to regulate angiogenesis, dedifferentiation, cell migration and macrophage function. The methylation status of selected CGIs was validated in further 10 subjects for either group. Expression patterns of these factors were compatible with the observed differential methylation. Our data suggest that one of the molecular changes associated with aberrant DNA methylation in advanced atherosclerosis is the regulation of critical transcription factor genes for the induction of a proatherogenic cellular phenotype. Two-condition experiment, i.e. normal vs. atherosclerotic arteries. 16 and 45 normal and atherosclerotic samples, respectively, were pooled and used to interrogate CpG island arrays in triplicate, for a total of six arrays. Each array was co-hybridized with untreated DNA (reference) and hypermethylated DNA obtained by biochemical filtration.