Project description:To understand molecular mechanisms driving HB pathogenesis, we hypothesize that pathologic activation of Enhancer of Zeste Homolog 2 contributes to hepatoblastoma propagation. Here we demonstrate that EZH2 promotes proliferation in HB cell lines through interaction with β-catenin, the most frequently mutated gene in HB. We demonstrate that canonical and noncanonical EZH2 signaling occur in HB tumor cells, likely driven by aberrant EZH2 expression. We use comparison groups of liver cancer, hepatocytes, and dermal fibroblasts to establish the hepatoblastoma identity of our patient-derived cell lines.

Project description:Impressive studies have been well documented that Enhancer of zeste homolog 2 (EZH2) could have a role in inflammation as well as a wide range of malignancies; however, the underlying mechanisms remain largely unaddressed. Microglial activation is a key process in the production and release of numerous pro-inflammatory mediators that plays an important role in central nervous system (CNS) inflammation and neurodegeneration. Therefore, our aim was to investigate whether inhibition of EZH2 with selective small molecule inhibitors EPZ-6438 protects against neonatal microglia activation. First, we find that BV-2 microglia, LPS can rapidly increase EZH2 mRNA level and subsequently we performed gene expression profiles and networks in resting, EPZ-6438, LPS and LPS+EPZ-6438 challenged BV-2 microglia by transcriptome RNA sequencing and bioinformatic analyses. By examining RNA sequencing we identified EPZ-6438 target genes and co-regulated modules that were critical in inflammation. We also identified unexpected relationships between the inducible transcription factors (TFs), motif strength, and the transcription of key inflammatory mediators. Furthermore, we showed that EPZ-6438 controls important inflammatory genes targets by modulating interferon regulatory factor (IRF) 1, IRF8, Signal transducer and activator of transcription (STAT) 1 levels at their promoter site. Our unprecedented findings demonstrate that pharmacological interventions built upon EZH2 inhibition by EPZ-6438 could be a useful therapeutic application in neuroinflammatory diseases associated with microglia activation.

Project description:Mutations within the catalytic domain of the histone methyltransferase (HMT) EZH2 have been identified in subsets of Non-Hodgkin Lymphoma (NHL) patients. These genetic alterations are hypothesized to confer an oncogenic dependency on EZH2 enzymatic activity in these cancers. We previously reported the discovery of a potent, selective, S-adenosyl-methionine-competitive and orally bioavailable small molecule inhibitor of EZH2, EPZ-6438. EPZ-6438 selectively inhibits intracellular lysine 27 of histone H3 (H3K27) methylation in a concentration- and time-dependent manner in both EZH2 wild type and mutant lymphoma cells. Inhibition of H3K27 trimethylation (H3K27Me3) led to selective cell killing of human lymphoma cell lines bearing EZH2 catalytic domain point mutations. Treatment of xenograft-bearing mice with EPZ-6438 leads to dose-dependent tumor growth inhibition and eradication of genetically altered NHL with correlative diminution of H3K27Me3 levels in tumors and selected normal tissues. Mice dosed orally with EPZ-6438 for 28 days remained tumor free for up to 63 day after stopping compound treatment in two EZH2 mutant xenograft models. These data confirm the dependency of mutant NHL on EZH2 activity and portend the utility of EZH2-targeted drugs for the treatment of these genetically defined cancers. To identify potential biomarker and gain mechanistic insights in EPZ6438 treated lymphoma, lymphoma cell lines with or without EZH2 Y641 mutation were treated with EPZ6438 at Lowest Cytotoxic Concentration (LCC) and 10xLCC. Transcriptomes were profiled on Affemetrix U133 Plus2 chips. Differentially expressed genes and pathways upon compound treatment were anayzed. Lymphoma cell lines WSU-DLCL2, SU-DHL6, Pfeiffer, and Karpas422 were treated by EPZ6438 for 2 days, 4 days and 6 days. Treatment doses are LCC and 10xLCC of each cell lines. KARPAS_422, SUDHL6, and WSU_DLCL2 have the EZH2 Y641 mutation. PFEIFFER does not have the EZH2 Y641 mutation.

Project description:The impact of drugs inhibiting DNA methylation (5-aza-2'-deoxycytodine, DAC) and EZH2 (EPZ-6438) on the neuroblastoma transcriptome was analyzed in two neuroblastoma cell lines. Parallel analyses investigated associated changes in histone modification and DNA methylation. The neuroblastoma cell lines Be(2)-C and IMR5-75 were treated with DAC and EPZ-6438 in combination or alone. Controls were treated with solvent (DMSO). RNA was isolated and sequenced.

Project description:The impact of drugs inhibiting DNA methylation (5-aza-2'-deoxycytodine, DAC) and EZH2 (EPZ-6438) on the neuroblastoma methylome was analyzed in two neuroblastoma cell lines. Parallel analyses investigated associated changes in histone modification and RNA expression. The neuroblastoma cell lines Be(2)-C and IMR5-75 were treated with a combination of DAC and EPZ-6438. Controls were treated with solvent (DMSO). DNA was isolated, bisulphite converted and hybridised to the llumina HumanMethylation450 BeadChip

Project description:The impact of drugs inhibiting DNA methylation (5-aza-2'-deoxycytodine, DAC) and EZH2 (EPZ-6438) on H3K27me3 coverage was analyzed in two neuroblastoma cell lines. Parallel analyses investigated associated changes in RNA expression and DNA methylation. The neuroblastoma cell lines Be(2)-C and IMR5-75 were treated with a combination of DAC and EPZ-6438. Controls were treated with solvent (DMSO). H3K27me3 ChIP seq was done to investigate treatment-related changes of this mark. In addition, H3K4me3 and H3K27ac ChIP seq was done in DMSO treated samples to identify putative regulatory regions.

Project description:Mutations within the catalytic domain of the histone methyltransferase (HMT) EZH2 have been identified in subsets of Non-Hodgkin Lymphoma (NHL) patients. These genetic alterations are hypothesized to confer an oncogenic dependency on EZH2 enzymatic activity in these cancers. We previously reported the discovery of a potent, selective, S-adenosyl-methionine-competitive and orally bioavailable small molecule inhibitor of EZH2, EPZ-6438. EPZ-6438 selectively inhibits intracellular lysine 27 of histone H3 (H3K27) methylation in a concentration- and time-dependent manner in both EZH2 wild type and mutant lymphoma cells. Inhibition of H3K27 trimethylation (H3K27Me3) led to selective cell killing of human lymphoma cell lines bearing EZH2 catalytic domain point mutations. Treatment of xenograft-bearing mice with EPZ-6438 leads to dose-dependent tumor growth inhibition and eradication of genetically altered NHL with correlative diminution of H3K27Me3 levels in tumors and selected normal tissues. Mice dosed orally with EPZ-6438 for 28 days remained tumor free for up to 63 day after stopping compound treatment in two EZH2 mutant xenograft models. These data confirm the dependency of mutant NHL on EZH2 activity and portend the utility of EZH2-targeted drugs for the treatment of these genetically defined cancers. To identify potential biomarker and gain mechanistic insights in EPZ6438 treated lymphoma, lymphoma cell lines with or without EZH2 Y641 mutation were treated with EPZ6438 at Lowest Cytotoxic Concentration (LCC) and 10xLCC. Transcriptomes were profiled on Affemetrix U133 Plus2 chips. Differentially expressed genes and pathways upon compound treatment were anayzed.

Project description:Purpose: Hepatoblastoma (HB) is a malignant pediatric hepatic progenitor cell tumor with uncertain etiology. To discover genomic biomarkers associated with this malignancy, we conduct the study. Experimental Design: A panel of ten cases and two pairs of identical twins for HB were screened using high-resolution array-based comparative genomic hybridization (array CGH) technology. Genomic DNA from the peripheral blood was subject to our laboratory investigation. Results: In total of the twelve HB cases tested, we identified four high recurrent copy-number variations (CNVs) including gain on 1p13.3 (25%) and losses on 5p15.33 (33.3%), 16q12.2 (33.3%), and 19q13.42 (25%). Additionally, the twin study indicated that microdeletions of 3p12.1 and 12p13.2 correlated with hepatoblastoma occurrence. Among these candidate CNVs, 5p15.33 and 16q12.2 not only the most prevalent genomic deletion in this survey, but also encompassed hepatic expressed gene, Zinc finger, DHHC-type containing 11B (ZDHHC11B) and Zinc finger, DHHC-type containing 11 (ZDHHC11) map to 5p15.33; carboxylesterase 4-like (CES4) map to 16q12.2. Furthermore, the microdeletion of 5p15.33 was associated with high mortality rate (3/3; P = 0.018) in patients with native liver. Currently, the only surviving patient with 5p15.33 microdeletion is who has receipt liver transplantation. Conclusions: These results suggested that losses on 3p12.1, 5p15.33, 12p13.2 and 16q12.2 may be pathogenic for HB. In addition, HB patient who affected by 5p15.33 microdeletion seems to carry high risk of mortality unless undergo liver transplantation. Thus, 5p15.33 microdeletion was suggested as potential prognostic biomarker for poor survival in hepatoblastoma.

Project description:Here we report the discovery of highly potent and selective EZH2 small molecule inhibitors, their validation by a cellular thermal shift assay, their application across a large lymphoma cell panel and their efficacy in GCBDLBCL xenograft models. RNA-seq of KARPAS-422 cell line RNA, in duplicate, treated with DMSO as control, and EZH2 inhibitors CPI360, EPZ-6438 and GSK126. Eight samples in total.

Project description:To gain insight into the pathobiology of hepatoblastoma (HB), RNA sequence analysis and protein-protein interaction analysis of previously established and sequenced HB samples were conducted. Ubiquitination was identified as a key pathway dysregulated in HB and UBE2C, encoding an E2 ubiquitin ligase often overexpressed in cancer cells, was markedly upregulated in 5 of the 6 HB cell lines. The silencing of UBE2C in HUH6 HB cell model resulted in decreased cell viability and migration. RNA sequencing analysis showed alterations in cell cycle regulation after UBE2C knockdown.