Project description:We report the global methylation patterns by MBDCap-seq for total 232 primary samples in endometrial cohorts, breast cancer cohorts and breast cancer cell lines. We found total 1,007 differentially methylated regions (DMRs) include CpG islands and shores in endometrial cohorts, and 2529 for Breast Cancer cohorts. We also identified 153 regions that are distinctly different from regular CpG islands at the 5'-ends of genes. Those regions, always contain a chain of 1-2 main islands and a few satellites alone on GC-poor and gene-less region. Majority of CpG atolls contain lowly transcribed or silenced genes in normal controls. This phenomenon provides a new opportunity to develop sensitive biomarkers for cancer diagnosis and prognosis

Project description:Extensive changes in DNA methylation are common in cancer and may contribute to oncogenesis through transcriptional silencing of tumor suppressor genes. Genome-scale studies have yielded important insights into these changes, but have focused on CpG islands or gene promoters. We used whole-genome bisulfite sequencing (Bisulfite-Seq) to comprehensively profile a primary human colorectal tumor and adjacent-normal colon tissue at single-basepair resolution. Regions of focal hypermethylation in the tumor were located primarily at CpG islands and were concentrated within regions of long-range (>100 kb) hypomethylation. These hypomethylated domains covered nearly half the genome and coincided with late replication and attachment to the nuclear lamina in human cell lines. The confluence of hypermethylation and hypomethylation within these domains was confirmed in 25 diverse colorectal tumors with matched adjacent tissue. We propose that widespread DNA methylation changes in cancer are linked to silencing programs orchestrated by the 3D organization of chromatin within the nucleus. dbGAP study: phs000385

Project description:Extensive changes in DNA methylation are common in cancer and may contribute to oncogenesis through transcriptional silencing of tumor suppressor genes. Genome-scale studies have yielded important insights into these changes, but have focused on CpG islands or gene promoters. We used whole-genome bisulfite sequencing (Bisulfite-Seq) to comprehensively profile a primary human colorectal tumor and adjacent-normal colon tissue at single-basepair resolution. Regions of focal hypermethylation in the tumor were located primarily at CpG islands and were concentrated within regions of long-range (>100 kb) hypomethylation. These hypomethylated domains covered nearly half the genome and coincided with late replication and attachment to the nuclear lamina in human cell lines. The confluence of hypermethylation and hypomethylation within these domains was confirmed in 25 diverse colorectal tumors with matched adjacent tissue. We propose that widespread DNA methylation changes in cancer are linked to silencing programs orchestrated by the 3D organization of chromatin within the nucleus. dbGAP study: phs000385 Primary tissue samples sequenced using 76-bp bisulfite sequencing (WGBS or Methyl-seq) using the Illumina GAII platform. Two independent libraries were constructed for each sample, and these libraries were combined into a single data file for each sample.

Project description:Cancer is characterised by DNA hypermethylation and gene silencing of CpG island-associated promoters, including tumour suppressor genes The methyl-CpG-binding domain (MBD) family of proteins bind to methylated DNA and can aid in the meditation of gene silencing by interaction with histone deacetylases and histone methyltransferases. However the mechanisms responsible for eliciting CpG island hypermethylation in cancer, and the potential role that MBD may proteins play in modulation of the methylome remain unclear. Our previous work demonstrated that MBD2 preferentially binds to the hypermethylated GSTP1 promoter CpG island in prostate cancer cells. Here, we use functional genetic approaches to investigate if MBD2 plays an active role in promoting DNA methylation. First, we show that loss of MBD2 results in inhibition of both maintenance and spread of de novo methylation of a transfected construct containing the GSTP1 promoter CpG island in prostate cancer cells and Mbd2-/- mouse fibroblasts. De novo methylation was rescued by transient expression of Mbd2 in Mbd2-/- cells. Second, we show that MBD2 depletion triggers significant hypomethylation genome-wide in prostate cancer cells with concomitant loss of MBD2 binding at promoter and enhancer regulatory regions. Finally, CpG islands and shores that become hypomethylated after MBD2 depletion in LNCaP cancer cells show significant hypermethylation in clinical prostate cancer, highlighting a potential active role of MBD2 in promoting cancer specific hypermethylation. Importantly, co-immunoprecipiation of MBD2 reveals that MBD2 associates with DNA methyltransferase (DNMT) enzymes 1 and 3A. Together our results demonstrate that MBD2 plays a critical role in “rewriting” the cancer methylome at specific regulatory regions.

Project description:Cancer is characterised by DNA hypermethylation and gene silencing of CpG island-associated promoters, including tumour suppressor genes The methyl-CpG-binding domain (MBD) family of proteins bind to methylated DNA and can aid in the meditation of gene silencing by interaction with histone deacetylases and histone methyltransferases. However the mechanisms responsible for eliciting CpG island hypermethylation in cancer, and the potential role that MBD may proteins play in modulation of the methylome remain unclear. Our previous work demonstrated that MBD2 preferentially binds to the hypermethylated GSTP1 promoter CpG island in prostate cancer cells. Here, we use functional genetic approaches to investigate if MBD2 plays an active role in promoting DNA methylation. First, we show that loss of MBD2 results in inhibition of both maintenance and spread of de novo methylation of a transfected construct containing the GSTP1 promoter CpG island in prostate cancer cells and Mbd2-/- mouse fibroblasts. De novo methylation was rescued by transient expression of Mbd2 in Mbd2-/- cells. Second, we show that MBD2 depletion triggers significant hypomethylation genome-wide in prostate cancer cells with concomitant loss of MBD2 binding at promoter and enhancer regulatory regions. Finally, CpG islands and shores that become hypomethylated after MBD2 depletion in LNCaP cancer cells show significant hypermethylation in clinical prostate cancer, highlighting a potential active role of MBD2 in promoting cancer specific hypermethylation. Importantly, co-immunoprecipiation of MBD2 reveals that MBD2 associates with DNA methyltransferase (DNMT) enzymes 1 and 3A. Together our results demonstrate that MBD2 plays a critical role in “rewriting” the cancer methylome at specific regulatory regions.

Project description:Cancer is characterised by DNA hypermethylation and gene silencing of CpG island-associated promoters, including tumour suppressor genes The methyl-CpG-binding domain (MBD) family of proteins bind to methylated DNA and can aid in the meditation of gene silencing by interaction with histone deacetylases and histone methyltransferases. However the mechanisms responsible for eliciting CpG island hypermethylation in cancer, and the potential role that MBD may proteins play in modulation of the methylome remain unclear. Our previous work demonstrated that MBD2 preferentially binds to the hypermethylated GSTP1 promoter CpG island in prostate cancer cells. Here, we use functional genetic approaches to investigate if MBD2 plays an active role in promoting DNA methylation. First, we show that loss of MBD2 results in inhibition of both maintenance and spread of de novo methylation of a transfected construct containing the GSTP1 promoter CpG island in prostate cancer cells and Mbd2-/- mouse fibroblasts. De novo methylation was rescued by transient expression of Mbd2 in Mbd2-/- cells. Second, we show that MBD2 depletion triggers significant hypomethylation genome-wide in prostate cancer cells with concomitant loss of MBD2 binding at promoter and enhancer regulatory regions. Finally, CpG islands and shores that become hypomethylated after MBD2 depletion in LNCaP cancer cells show significant hypermethylation in clinical prostate cancer, highlighting a potential active role of MBD2 in promoting cancer specific hypermethylation. Importantly, co-immunoprecipiation of MBD2 reveals that MBD2 associates with DNA methyltransferase (DNMT) enzymes 1 and 3A. Together our results demonstrate that MBD2 plays a critical role in “rewriting” the cancer methylome at specific regulatory regions. LNCaP prostate cancer cell line clones with reduced MBD2 expression were establised by using shRNA to MBD2 and scrambled control clones were established with scrambled control shRNA. To interrogate expression changes induced by MBD2 knock-down we profiled three stably transfected scrambled control clones and three MBD2 knockdown clones on Affymetrix HuGene 1.0ST expression arrays. Differential expression analysis was carried out to identified genes up-/down-regulated by MBD2 knockdown.

Project description:Cancer is characterised by DNA hypermethylation and gene silencing of CpG island-associated promoters, including tumour suppressor genes The methyl-CpG-binding domain (MBD) family of proteins bind to methylated DNA and can aid in the meditation of gene silencing by interaction with histone deacetylases and histone methyltransferases. However the mechanisms responsible for eliciting CpG island hypermethylation in cancer, and the potential role that MBD may proteins play in modulation of the methylome remain unclear. Our previous work demonstrated that MBD2 preferentially binds to the hypermethylated GSTP1 promoter CpG island in prostate cancer cells. Here, we use functional genetic approaches to investigate if MBD2 plays an active role in promoting DNA methylation. First, we show that loss of MBD2 results in inhibition of both maintenance and spread of de novo methylation of a transfected construct containing the GSTP1 promoter CpG island in prostate cancer cells and Mbd2-/- mouse fibroblasts. De novo methylation was rescued by transient expression of Mbd2 in Mbd2-/- cells. Second, we show that MBD2 depletion triggers significant hypomethylation genome-wide in prostate cancer cells with concomitant loss of MBD2 binding at promoter and enhancer regulatory regions. Finally, CpG islands and shores that become hypomethylated after MBD2 depletion in LNCaP cancer cells show significant hypermethylation in clinical prostate cancer, highlighting a potential active role of MBD2 in promoting cancer specific hypermethylation. Importantly, co-immunoprecipiation of MBD2 reveals that MBD2 associates with DNA methyltransferase (DNMT) enzymes 1 and 3A. Together our results demonstrate that MBD2 plays a critical role in â??rewritingâ?? the cancer methylome at specific regulatory regions. LNCaP prostate cancer cell line clones with reduced MBD2 expression were establised by using shRNA to MBD2 and scrambled control clones were established with scrambled control shRNA. To interrogate methylation changes induced by MBD2 knock-down we profiled three stably transfected scrambled control clones and three MBD2 knockdown clones on Illumina HumanMethylation450K arrays. Differential methylation analysis was carried out to identified CpG sites hypo-/hyper-methylated as a result of MBD2 knockdown.

Project description:BACKGROUND & AIM: Sessile serrated adenoma/polyps (SSA/Ps) are the likely culprit of ~20% colon cancers but they are molecularly poorly understood. We investigated their epigenetic phenotype using high-throughput analysis of DNA methylation and gene expression. METHODS: 17 SSA/Ps and, as a comparative group, 15 conventional adenomas (all with matched samples of normal mucosa) were prospectively collected during colonoscopy. DNA from the 64 tissues was analyzed, via bisulfite next generation sequencing, for methylation at ~2.7 million CpG sites located prevalently in gene regulatory regions spanning 80.5Mb (~2.5% of the genome). The transcriptome of these samples was also investigated using RNA sequencing. An independent series of 61 archival lesions was used for targeted verification of DNA methylation. RESULTS: Both SSA/Ps and conventional adenomas showed a profound remodelling of their methylome. Cytosine hypermethylation was more pervasive in SSA/Ps than adenomas, in terms of number of hypermethylated regions (22,147 vs 15,965, respectively) and genes (4938 vs 3443, respectively). In addition, the extent of hypermethylation in a given region was higher in SSA/Ps than adenomas. This methylation pattern of SSA/Ps was reminiscent of the CpG island methylator phenotype (CIMP) of their descendant cancers. We have called this phenotype proto-CIMP since most of the hypermethylation occurred in CpG islands and shores. SSA/Ps were also protected from a wave of demethylation that instead occurred in adenomas outside of CpG islands/shores (4288 vs 18,417 hypomethylated regions in SSAPs vs adenomas). Verification studies of six hypermethylated regions demonstrated the high potential of DNA methylation markers for predicting the diagnosis of SSA/Ps and/or adenomas. Proto-CIMP of SSA/Ps was surprisingly associated with a higher number of up- (618) than downregulated (349) genes, while adenomas showed the opposite trend (516 up- vs 712 downregulated genes). CONCLUSIONS: The epigenetic landscape of SSA/Ps differs substantially from that of conventional adenomas. This huge amount of epigenetic variation represents a rich source of promising diagnostic tools, such as novel DNA markers or histologic stainings, for the tailored management of the two most frequent colon cancer precursors.

Project description:BACKGROUND & AIM: Sessile serrated adenoma/polyps (SSA/Ps) are the likely culprit of ~20% colon cancers but they are molecularly poorly understood. We investigated their epigenetic phenotype using high-throughput analysis of DNA methylation and gene expression. METHODS: 17 SSA/Ps and, as a comparative group, 15 conventional adenomas (all with matched samples of normal mucosa) were prospectively collected during colonoscopy. DNA from the 64 tissues was analyzed, via bisulfite next generation sequencing, for methylation at ~2.7 million CpG sites located prevalently in gene regulatory regions spanning 80.5Mb (~2.5% of the genome). The transcriptome of these samples was also investigated using RNA sequencing. An independent series of 61 archival lesions was used for targeted verification of DNA methylation. RESULTS: Both SSA/Ps and conventional adenomas showed a profound remodelling of their methylome. Cytosine hypermethylation was more pervasive in SSA/Ps than adenomas, in terms of number of hypermethylated regions (22,147 vs 15,965, respectively) and genes (4938 vs 3443, respectively). In addition, the extent of hypermethylation in a given region was higher in SSA/Ps than adenomas. This methylation pattern of SSA/Ps was reminiscent of the CpG island methylator phenotype (CIMP) of their descendant cancers. We have called this phenotype proto-CIMP since most of the hypermethylation occurred in CpG islands and shores. SSA/Ps were also protected from a wave of demethylation that instead occurred in adenomas outside of CpG islands/shores (4288 vs 18,417 hypomethylated regions in SSAPs vs adenomas). Verification studies of six hypermethylated regions demonstrated the high potential of DNA methylation markers for predicting the diagnosis of SSA/Ps and/or adenomas. Proto-CIMP of SSA/Ps was surprisingly associated with a higher number of up- (618) than downregulated (349) genes, while adenomas showed the opposite trend (516 up- vs 712 downregulated genes). CONCLUSIONS: The epigenetic landscape of SSA/Ps differs substantially from that of conventional adenomas. This huge amount of epigenetic variation represents a rich source of promising diagnostic tools, such as novel DNA markers or histologic stainings, for the tailored management of the two most frequent colon cancer precursors.

Project description:BACKGROUND & AIM: Sessile serrated adenoma/polyps (SSA/Ps) are the likely culprit of ~20% colon cancers but they are molecularly poorly understood. We investigated their epigenetic phenotype using high-throughput analysis of DNA methylation and gene expression. METHODS: 17 SSA/Ps and, as a comparative group, 15 conventional adenomas (all with matched samples of normal mucosa) were prospectively collected during colonoscopy. DNA from the 64 tissues was analyzed, via bisulfite next generation sequencing, for methylation at ~2.7 million CpG sites located prevalently in gene regulatory regions spanning 80.5Mb (~2.5% of the genome). The transcriptome of these samples was also investigated using RNA sequencing. An independent series of 61 archival lesions was used for targeted verification of DNA methylation. RESULTS: Both SSA/Ps and conventional adenomas showed a profound remodelling of their methylome. Cytosine hypermethylation was more pervasive in SSA/Ps than adenomas, in terms of number of hypermethylated regions (22,147 vs 15,965, respectively) and genes (4938 vs 3443, respectively). In addition, the extent of hypermethylation in a given region was higher in SSA/Ps than adenomas. This methylation pattern of SSA/Ps was reminiscent of the CpG island methylator phenotype (CIMP) of their descendant cancers. We have called this phenotype proto-CIMP since most of the hypermethylation occurred in CpG islands and shores. SSA/Ps were also protected from a wave of demethylation that instead occurred in adenomas outside of CpG islands/shores (4288 vs 18,417 hypomethylated regions in SSAPs vs adenomas). Verification studies of six hypermethylated regions demonstrated the high potential of DNA methylation markers for predicting the diagnosis of SSA/Ps and/or adenomas. Proto-CIMP of SSA/Ps was surprisingly associated with a higher number of up- (618) than downregulated (349) genes, while adenomas showed the opposite trend (516 up- vs 712 downregulated genes). CONCLUSIONS: The epigenetic landscape of SSA/Ps differs substantially from that of conventional adenomas. This huge amount of epigenetic variation represents a rich source of promising diagnostic tools, such as novel DNA markers or histologic stainings, for the tailored management of the two most frequent colon cancer precursors.