Project description:Cancers have long been recognized to be not only genetically but also epigenetically distinct from their tissues of origin. Although genetic alterations underlying oncogene upregulation have been well studied, to what extent epigenetic mechanisms, such as DNA methylation, can also induce oncogene expression remains unknown. Here, through pan-cancer analysis of 4,182 genome-wide profiles, including whole-genome bisulfite sequencing (WGBS) data from 30 normal tissues and 35 solid tumors, we discovered a strong correlation between gene-body hypermethylation of DNA methylation canyons (broad under-methylated regions) and overexpression of ~43% homeobox genes, many of which are also oncogenes. To gain insights into the cause-and-effect relationship, we used a newly developed dCas9-SunTag-DNMT3A system to methylate genomic sites of interest. The locus-specific hypermethylation of gene-body canyon, but not promoter, of homeobox oncogene DLX1 and POU3F3, can direct increase its gene expression. Together, our pan-cancer analysis followed by functional validation reveals DNA hypermethylation as a novel epigenetic mechanism for homeobox oncogene upregulation.

Project description:Cancer cells usually depend on the aberrant function of one or few driver genes to initiate and promote their malignancy, an attribute known as oncogene addiction. However, cancer cells might become dependent on the normal cellular functions of certain genes that are not oncogenes but ensure cell survival (non-oncogene addiction). The downregulation or silencing of DNA repair genes and the consequent genetic and epigenetic instability is key to promote malignancy, but the activation of the DNA-damage response (DDR) has been shown to become a type of non-oncogene addiction that critically supports tumour survival. In the present study, a systematic evaluation of DNA repair addiction at the pan-cancer level was performed using data derived from The Cancer Dependency Map and The Cancer Genome Atlas (TCGA). From 241 DDR genes, 59 were identified as commonly essential in cancer cell lines. However, large differences were observed in terms of dependency scores in 423 cell lines and transcriptomic alterations across 18 cancer types. Among these 59 commonly essential genes, 14 genes were exclusively associated with better overall patient survival and 19 with worse overall survival. Notably, a specific molecular signature among the latter, characterized by DDR genes like UBE2T, RFC4, POLQ, BRIP1, and H2AFX showing the weakest dependency scores, but significant upregulation was strongly associated with worse survival. The present study supports the existence and importance of non-oncogenic addiction to DNA repair in cancer and may facilitate the identification of prognostic biomarkers and therapeutic opportunities.

Project description:Homeobox A11 (HOXA11) is one of the hypermethylated genes in breast cancer and its function in breast tumorigenesis remains elusive. In this study, we analyzed the methylation status of HOXA11 in 264 paired breast cancer and normal tissue as well as in matched serum samples by MethyLight assay. Further, the function of HOXA11 in breast tumorigenesis was analyzed by cell proliferation and migration assays. We found that HOXA11 was hypermethylated in cancer tissues (45.08%), especially in invasive ductal carcinomas (P<0.001), patients with a family history of cancer (P=0.033), cases with metastatic lymph nodes (P=0.004) and P53 positive group (P=0.017). Kaplan-Meier survival analysis and Cox regression analysis revealed that HOXA11 hypermethylation is an independent predictor of poor outcomes. The over expression of HOXA11 suppressed cell growth in MDA-MB-231, MCF7, SKBR3 and BT474 cells. In conclusion, the hypermethylation of HOXA11 is an independent prognostic biomarker in breast cancer. Additionally, HOXA11 can be a potential tumor suppressor.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Aberrant DNA hypermethylation of promoter CpG islands in the context of a hypomethylated genome is a hallmark of cancer. Thus far there is no human experimental model available to mechanistically investigate this phenomenon. Here we show that upon reprogramming of human embryonic stem cells to the naïve state, the acquisition of a globally hypomethylated genome is accompanied by hypermethylation of a subset of bivalent promoter CpG islands, resulting in a DNA methylome comparable to the human inner cell mass. We show that de novo methylation is carried out by DNMT3A and coordinated by the transcription factor network. We further show that the subset of bivalent sites that become hypermethyated are functionally distinct, with an enrichment in developmental genes, and demonstrate that this is mirrored in DNA hypermethylation patterns across cancer types, suggesting that common mechanisms may be responsible. We propose a wider utility of this experimental system to understand pre-malignant cancer-associated processes.

Project description:Aberrant DNA hypermethylation of promoter CpG islands in the context of a hypomethylated genome is a hallmark of cancer. Thus far there is no human experimental model available to mechanistically investigate this phenomenon. Here we show that upon reprogramming of human embryonic stem cells to the naïve state, the acquisition of a globally hypomethylated genome is accompanied by hypermethylation of a subset of bivalent promoter CpG islands, resulting in a DNA methylome comparable to the human inner cell mass. We show that de novo methylation is carried out by DNMT3A and coordinated by the transcription factor network. We further show that the subset of bivalent sites that become hypermethyated are functionally distinct, with an enrichment in developmental genes, and demonstrate that this is mirrored in DNA hypermethylation patterns across cancer types, suggesting that common mechanisms may be responsible. We propose a wider utility of this experimental system to understand pre-malignant cancer-associated processes.

Project description:Aberrant DNA hypermethylation of promoter CpG islands in the context of a hypomethylated genome is a hallmark of cancer. Thus far there is no human experimental model available to mechanistically investigate this phenomenon. Here we show that upon reprogramming of human embryonic stem cells to the naïve state, the acquisition of a globally hypomethylated genome is accompanied by hypermethylation of a subset of bivalent promoter CpG islands, resulting in a DNA methylome comparable to the human inner cell mass. We show that de novo methylation is carried out by DNMT3A and coordinated by the transcription factor network. We further show that the subset of bivalent sites that become hypermethyated are functionally distinct, with an enrichment in developmental genes, and demonstrate that this is mirrored in DNA hypermethylation patterns across cancer types, suggesting that common mechanisms may be responsible. We propose a wider utility of this experimental system to understand pre-malignant cancer-associated processes.

Project description:Aberrant DNA hypermethylation of promoter CpG islands in the context of a hypomethylated genome is a hallmark of cancer. Thus far there is no human experimental model available to mechanistically investigate this phenomenon. Here we show that upon reprogramming of human embryonic stem cells to the naïve state, the acquisition of a globally hypomethylated genome is accompanied by hypermethylation of a subset of bivalent promoter CpG islands, resulting in a DNA methylome comparable to the human inner cell mass. We show that de novo methylation is carried out by DNMT3A and coordinated by the transcription factor network. We further show that the subset of bivalent sites that become hypermethyated are functionally distinct, with an enrichment in developmental genes, and demonstrate that this is mirrored in DNA hypermethylation patterns across cancer types, suggesting that common mechanisms may be responsible. We propose a wider utility of this experimental system to understand pre-malignant cancer-associated processes.

Project description:Aberrant DNA hypermethylation of promoter CpG islands in the context of a hypomethylated genome is a hallmark of cancer. Thus far there is no human experimental model available to mechanistically investigate this phenomenon. Here we show that upon reprogramming of human embryonic stem cells to the naïve state, the acquisition of a globally hypomethylated genome is accompanied by hypermethylation of a subset of bivalent promoter CpG islands, resulting in a DNA methylome comparable to the human inner cell mass. We show that de novo methylation is carried out by DNMT3A and coordinated by the transcription factor network. We further show that the subset of bivalent sites that become hypermethyated are functionally distinct, with an enrichment in developmental genes, and demonstrate that this is mirrored in DNA hypermethylation patterns across cancer types, suggesting that common mechanisms may be responsible. We propose a wider utility of this experimental system to understand pre-malignant cancer-associated processes.

Project description:Transition to naïve human pluripotency mirrors pan-cancer DNA hypermethylation