Project description:Epigenetic dysregulation is widespread in cancer. However, the specific epigenetic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenetic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenetic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are the most impactful tumor suppressive epigenetic regulators in lung cancer. Histone modifications generated by HBO1 complex are frequently reduced in human lung adenocarcinomas. HBO1 and MLL1 complexes regulate chromatin accessibility at shared genomic regions, lineage fidelity and expression of canonical tumor suppressor genes. The HBO1 and MLL1 complexes are epistatic during lung tumorigenesis, and their functional correlation is conserved in human cancer cell lines. Together, these results provide a phenotypic roadmap of epigenetic regulators in lung tumorigenesis in vivo.

Project description:Epigenomic dysregulation is widespread in cancer. However, the specific epigenomic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenomic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenomic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are robust tumor suppressors in lung cancer. Histone modifications generated by HBO1 complex are frequently diminshed in human lung adenocarcinomas and is associated with worse clinical features. HBO1 and MLL1 complexes co-occupy shared genomic regions, impacting chromatin accessibility, expression of canonical tumor suppressor genes and lineage fidelity. The HBO1 complex is epistatic with the MLL1 complex and other tumor suppressor genes in lung adenocarcinoma development. Collectively, these results uncover HBO1 and MLL1 complexes as critical functional modules restraining lung adenocarcinoma development and provide a in vivo phenotypic roadmap of epigenomic regulators in lung tumorigenesis.

Project description:Epigenomic dysregulation is widespread in cancer. However, the specific epigenomic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenomic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenomic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are robust tumor suppressors in lung cancer. Histone modifications generated by HBO1 complex are frequently diminshed in human lung adenocarcinomas and is associated with worse clinical features. HBO1 and MLL1 complexes co-occupy shared genomic regions, impacting chromatin accessibility, expression of canonical tumor suppressor genes and lineage fidelity. The HBO1 complex is epistatic with the MLL1 complex and other tumor suppressor genes in lung adenocarcinoma development. Collectively, these results uncover HBO1 and MLL1 complexes as critical functional modules restraining lung adenocarcinoma development and provide a in vivo phenotypic roadmap of epigenomic regulators in lung tumorigenesis.

Project description:Epigenomic dysregulation is widespread in cancer. However, the specific epigenomic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenomic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenomic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are robust tumor suppressors in lung cancer. Histone modifications generated by HBO1 complex are frequently diminshed in human lung adenocarcinomas and is associated with worse clinical features. HBO1 and MLL1 complexes co-occupy shared genomic regions, impacting chromatin accessibility, expression of canonical tumor suppressor genes and lineage fidelity. The HBO1 complex is epistatic with the MLL1 complex and other tumor suppressor genes in lung adenocarcinoma development. Collectively, these results uncover HBO1 and MLL1 complexes as critical functional modules restraining lung adenocarcinoma development and provide a in vivo phenotypic roadmap of epigenomic regulators in lung tumorigenesis.

Project description:Epigenomic dysregulation is widespread in cancer. However, the specific epigenomic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenomic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenomic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are robust tumor suppressors in lung cancer. Histone modifications generated by HBO1 complex are frequently diminshed in human lung adenocarcinomas and is associated with worse clinical features. HBO1 and MLL1 complexes co-occupy shared genomic regions, impacting chromatin accessibility, expression of canonical tumor suppressor genes and lineage fidelity. The HBO1 complex is epistatic with the MLL1 complex and other tumor suppressor genes in lung adenocarcinoma development. Collectively, these results uncover HBO1 and MLL1 complexes as critical functional modules restraining lung adenocarcinoma development and provide a in vivo phenotypic roadmap of epigenomic regulators in lung tumorigenesis.

Project description:Epigenomic dysregulation is widespread in cancer. However, the specific epigenomic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenomic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenomic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are robust tumor suppressors in lung cancer. Histone modifications generated by HBO1 complex are frequently diminshed in human lung adenocarcinomas and is associated with worse clinical features. HBO1 and MLL1 complexes co-occupy shared genomic regions, impacting chromatin accessibility, expression of canonical tumor suppressor genes and lineage fidelity. The HBO1 complex is epistatic with the MLL1 complex and other tumor suppressor genes in lung adenocarcinoma development. Collectively, these results uncover HBO1 and MLL1 complexes as critical functional modules restraining lung adenocarcinoma development and provide a in vivo phenotypic roadmap of epigenomic regulators in lung tumorigenesis.

Project description:Epigenomic dysregulation is widespread in cancer. However, the specific epigenomic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenomic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenomic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are robust tumor suppressors in lung cancer. Histone modifications generated by HBO1 complex are frequently diminshed in human lung adenocarcinomas and is associated with worse clinical features. HBO1 and MLL1 complexes co-occupy shared genomic regions, impacting chromatin accessibility, expression of canonical tumor suppressor genes and lineage fidelity. The HBO1 complex is epistatic with the MLL1 complex and other tumor suppressor genes in lung adenocarcinoma development. Collectively, these results uncover HBO1 and MLL1 complexes as critical functional modules restraining lung adenocarcinoma development and provide a in vivo phenotypic roadmap of epigenomic regulators in lung tumorigenesis.

Project description:Epigenomic dysregulation is widespread in cancer. However, the specific epigenomic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenomic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenomic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are robust tumor suppressors in lung cancer. Histone modifications generated by HBO1 complex are frequently reduced in human lung adenocarcinomas and is associated with worse clinical features. HBO1 and MLL1 complexes co-occupy shared genomic regions, impacting chromatin accessibility, expression of canonical tumor suppressor genes and lineage fidelity. The HBO1 complex is epistatic with the MLL1 complex and other tumor suppressor genes in lung adenocarcinoma development. Together, these results uncover the HBO1 and MLL1 complexes as critical functional modules in restraining lung adenocarcinoma development and provide a in vivo phenotypic roadmap of epigenomic regulators in lung tumorigenesis.

Project description:Epigenomic dysregulation is widespread in cancer. However, the specific epigenomic regulators and the processes they control to drive cancer phenotypes are poorly understood. We employed a novel, scalable and high-throughput in vivo method to perform iterative functional screens of >250 epigenomic regulators within autochthonous oncogenic KRAS-driven lung tumors. We identified many previously unappreciated epigenomic tumor-suppressor and tumor-dependency genes. We show that a specific HBO1 complex and MLL1 complex are robust tumor suppressors in lung cancer. Histone modifications generated by HBO1 complex are frequently reduced in human lung adenocarcinomas and is associated with worse clinical features. HBO1 and MLL1 complexes co-occupy shared genomic regions, impacting chromatin accessibility, expression of canonical tumor suppressor genes and lineage fidelity. The HBO1 complex is epistatic with the MLL1 complex and other tumor suppressor genes in lung adenocarcinoma development. Together, these results uncover the HBO1 and MLL1 complexes as critical functional modules in restraining lung adenocarcinoma development and provide a in vivo phenotypic roadmap of epigenomic regulators in lung tumorigenesis.

Project description:Aberrations in chromatin dynamics play a fundamental role in tumorigenesis, yet relatively little is known of the molecular mechanisms linking histone lysine methylation to neoplastic disease. ING4 (Inhibitor of Growth 4) is a native subunit of an HBO1 histone acetyltransferase (HAT) complex and a tumor suppressor protein. Here we show a critical role for the specific read-out of histone H3 trimethylated at lysine 4 (H3K4me3) by the ING4 PHD finger in mediating ING4 gene expression and tumor suppressor functions. The interaction between ING4 and H3K4me3 augments the acetylation activity of HBO1 on H3 tails, and drives H3 acetylation at ING4 target promoters to effect a DNA damage-dependent gene expression program. Further, ING4 facilitates apoptosis in response to genotoxic stress and inhibits anchorage-independent cell growth, and these functions are dependent on ING4 interactions with H3K4me3. Together, our results demonstrate a mechanism for brokering crosstalk between H3K4 methylation and histone H3 acetylation, and reveal a new molecular link between chromatin modulation and tumor suppressor mechanisms. ING4 ChIP-chip +/- Doxorubicin treatment in HT1080 cells on Nimblegen whole genome promoter array 4 samples: HT1080 cell lines stably expressing Flag-ING4 or Flag-ING4-D213A, +/- doxorubicin