Project description:Epigenetic alterations have been increasingly implicated in oncogenesis. Analysis of Drosophila mutants suggests that Polycomb and SWI/SNF complexes can serve antagonistic developmental roles. However, the relevance of this relationship to human disease is unclear. Here we have investigated functional relationships between these epigenetic regulators in oncogenic transformation. Mechanistically, we show that loss of the SNF5 tumor suppressor leads to elevated expression of the Polycomb gene EZH2 and that Polycomb targets are broadly H3K27-trimethylated and repressed in SNF5-deficient fibroblasts and cancers. Further, we show antagonism between SNF5 and EZH2 in the regulation of stem cell-associated programs and that Snf5 loss activates those programs. Finally, using conditional mouse models, we show that inactivation of Ezh2 blocks tumor formation driven by Snf5 loss.

Project description:Epigenetic alterations have been increasingly implicated in oncogenesis. Analysis of Drosophila mutants suggests that Polycomb and SWI/SNF complexes can serve antagonistic developmental roles. However, the relevance of this relationship to human disease is unclear. Here we have investigated functional relationships between these epigenetic regulators in oncogenic transformation. Mechanistically, we show that loss of the SNF5 tumor suppressor leads to elevated expression of the Polycomb gene EZH2 and that Polycomb targets are broadly H3K27-trimethylated and repressed in SNF5-deficient fibroblasts and cancers. Further, we show antagonism between SNF5 and EZH2 in the regulation of stem cell-associated programs and that Snf5 loss activates those programs. Finally, using conditional mouse models, we show that inactivation of Ezh2 blocks tumor formation driven by Snf5 loss.

Project description:Epigenetic antagonism between Snf5 and Ezh2 during oncogenic transformation and elevated levels of H3K27me3 in Snf5-deficient cells

Project description:Effect of liver-specific inactivation of SNF5 on liver transcriptome. Comparison of control and mutant livers.

Project description:Epigenetic antagonism between Snf5 and Ezh2 during oncogenic transformation

Project description:Disruption of antagonism between SWI/SNF chromatin remodelers and Polycomb repressor complexes drives the formation of numerous cancer types. Recently, an inhibitor of Polycomb protein EZH2 was approved for treatment of sarcomas mutant in SWI/SNF subunit SMARCB1, but resistance occurs. Here we sought to identify additional contributors to SWI/SNF-Polycomb antagonism and potential resistance mechanisms. We performed CRISPR screens and found that NSD1 loss caused resistance to EZH2 inhibition. NSD1 loss reduced H3K36me2 and impaired transcriptional activation of targets inhibited by EZH2 or activated by SMARCB1. Further, inhibiting the H3K36me2 demethylase KDM2A restored EZH2 inhibition in cells lacking NSD1. Our results expand the mechanistic understanding of SWI/SNF and Polycomb interplay and identify NSD1 as key for coordinating this transcriptional control.

Project description:Disruption of antagonism between SWI/SNF chromatin remodelers and Polycomb repressor complexes drives the formation of numerous cancer types. Recently, an inhibitor of Polycomb protein EZH2 was approved for treatment of sarcomas mutant in SWI/SNF subunit SMARCB1, but resistance occurs. Here we sought to identify additional contributors to SWI/SNF-Polycomb antagonism and potential resistance mechanisms. We performed CRISPR screens and found that NSD1 loss caused resistance to EZH2 inhibition. NSD1 loss reduced H3K36me2 and impaired transcriptional activation of targets inhibited by EZH2 or activated by SMARCB1. Further, inhibiting the H3K36me2 demethylase KDM2A restored EZH2 inhibition in cells lacking NSD1. Our results expand the mechanistic understanding of SWI/SNF and Polycomb interplay and identify NSD1 as key for coordinating this transcriptional control.

Project description:Analysis of global gene expression by SNF5 level change in human pluripotent and differentiated cells. The core subunit of BAF complex SNF5 is at the nexus of the link between chromatin remodeling and tumor suppression. We demonstrated a role for the remodeler SNF5 as a key executor in regulating pluripotency gene networks during differentiation by using loss and gain of function experiments followed by gene-expression arrays. Total RNA obtained from pluripotent state, differentiated state, absense of SNF5 and overexpression of SNF5

Project description:Aberrant forms of the SWI/SNF chromatin remodeling complex are associated with human disease. Loss of the Snf5 subunit of SWI/SNF is a driver mutation in pediatric rhabdoid cancers and forms aberrant sub-complexes that are not well characterized. We determined the effects of loss of Snf5 on the composition, nucleosome binding, recruitment and remodeling activities of yeast SWI/SNF. The Snf5 subunit interacts with the ATPase domain of Snf2 and forms a submodule consisting of Snf5, Swp82 and Taf14 as shown by mapping SWI/SNF subunit interactions by crosslinking-mass spectrometry and subunit deletion followed by immunoaffinity chromatography. Snf5 promoted binding of the Snf2 ATPase domain to nucleosomal DNA, enhanced its catalytic activity and facilitated nucleosome remodeling. Snf5 was required for acidic transcription factors to recruit SWI/SNF to chromatin. RNA-seq analysis suggested that both the recruitment and catalytic functions mediated by Snf5 are required for SWI/SNF regulation of gene expression.

Project description:Congenital heart disease is among the most frequent major birth defects. Epigenetic marks are crucial for organogenesis, but their role in heart development is poorly understood. Polycomb Repressive Complex 2 (PRC2) trimethylates histone H3 at lysine 27, establishing H3K27me3 repressive epigenetic marks that promote tissue-specific differentiation by silencing ectopic gene programs. We studied the function of the catalytic subunit of PRC2, EZH2, in murine heart development. Early EZH2 inactivation by Nkx2-5Cre caused lethal congenital heart malformations, but slightly later EZH2 inactivation by cTNT-Cre did not. To study how the cardiomyocytes gene expression program is properly established in the early heart development, we combined the technologies of RNA sequencing and chromatin immunoprecipitation sequencing to identify the functional target genes directly repressed by EZH2. Intriguingly, these were enriched for transcriptional regulators of non-cardiac expression programs, such as transcription factors that regulate neuronal (Pax6) and cardiac progenitor genes (Isl1 and Six1). EZH2 was also required to maintain spatiotemporal regulation of cardiac gene expression, as Hcn4, Mlc2a, and Bmp10 were inappropriately upregulated in ventricular RNA. Furthermore, EZH2 was required for normal cardiomyocyte proliferation, establishing H3K27me3 epigenetic marks at cell cycle inhibitors Ink4a/b and repressing their expression. Our study reveals a previously undescribed role of EZH2 in regulating heart formation and shows that perturbation of the epigenetic landscape early cardiogenesis has sustained disruptive effects at later developmental stages. 8 E12.5 heart apex were used for RNA preparation each group.