Project description:Promising activity of BET protein inhibitors (BETis) is compromised by adaptive or innate resistance in AML. Here, modeling of BETi- persister/resistance (BETi-P/R) in human post-MPN secondary AML (sAML) cells demonstrated accessible and active chromatin in specific super-enhancers/enhancers, which was associated with increased levels of nuclear β-catenin, TCF7L2, JMJD6, and c-Myc in BETi-P/R sAML cells. Following BETi treatment, c-Myc levels were rapidly restored in BETi-P/R sAML cells. CRISPR/Cas9-mediated knockout of TCF7L2 or JMJD6 reversed BETi-P/R, whereas ectopic overexpression conferred BETi-P/R in sAML cells; confirming the mechanistic role of the β-catenin-TCF7L2- JMJD6-MYC axis in BETi-resistance. Patient-derived, post-MPN, CD34+ sAML blasts exhibiting relative resistance to BETi, as compared to sensitive sAML blasts, displayed higher mRNA and protein expressions of TCF7L2, JMJD6 and c-Myc, and following BETi washout exhibited rapid restoration of c-Myc and JMJD6. CRISPR/Cas9 knockout of TCF7L2 and JMJD6 depleted their levels, inducing loss of viability of the sAML blasts. Disruption of co-localization of nuclear β-catenin with TBL1 and TCF7L2 by the small molecule inhibitor BC2059 combined with depletion of BRD4 by BET-PROTAC reduced c-Myc levels and exerted synergistic lethality in BETi-P/R sAML cells. This combination also reduced leukemia burden and improved survival of mice engrafted with BETi-P/R sAML cells or with patient-derived AML blasts innately resistant to BETi. Therefore, multi- targeted disruption of β-catenin-TCF7L2-JMJD6-MYC axis overcomes adaptive and innate BETi-resistance, exhibiting pre-clinical efficacy against human post-MPN sAML cells.

Project description:Promising activity of BET protein inhibitors (BETis) is compromised by adaptive or innate resistance in AML. Here, modeling of BETi- persister/resistance (BETi-P/R) in human post-MPN secondary AML (sAML) cells demonstrated accessible and active chromatin in specific super-enhancers/enhancers, which was associated with increased levels of nuclear β-catenin, TCF7L2, JMJD6, and c-Myc in BETi-P/R sAML cells. Following BETi treatment, c-Myc levels were rapidly restored in BETi-P/R sAML cells. CRISPR/Cas9-mediated knockout of TCF7L2 or JMJD6 reversed BETi-P/R, whereas ectopic overexpression conferred BETi-P/R in sAML cells; confirming the mechanistic role of the β-catenin-TCF7L2- JMJD6-MYC axis in BETi-resistance. Patient-derived, post-MPN, CD34+ sAML blasts exhibiting relative resistance to BETi, as compared to sensitive sAML blasts, displayed higher mRNA and protein expressions of TCF7L2, JMJD6 and c-Myc, and following BETi washout exhibited rapid restoration of c-Myc and JMJD6. CRISPR/Cas9 knockout of TCF7L2 and JMJD6 depleted their levels, inducing loss of viability of the sAML blasts. Disruption of co-localization of nuclear β-catenin with TBL1 and TCF7L2 by the small molecule inhibitor BC2059 combined with depletion of BRD4 by BET-PROTAC reduced c-Myc levels and exerted synergistic lethality in BETi-P/R sAML cells. This combination also reduced leukemia burden and improved survival of mice engrafted with BETi-P/R sAML cells or with patient-derived AML blasts innately resistant to BETi. Therefore, multi- targeted disruption of β-catenin-TCF7L2-JMJD6-MYC axis overcomes adaptive and innate BETi-resistance, exhibiting pre-clinical efficacy against human post-MPN sAML cells.

Project description:Promising activity of BET protein inhibitors (BETis) is compromised by adaptive or innate resistance in AML. Here, modeling of BETi- persister/resistance (BETi-P/R) in human post-MPN secondary AML (sAML) cells demonstrated accessible and active chromatin in specific super-enhancers/enhancers, which was associated with increased levels of nuclear β-catenin, TCF7L2, JMJD6, and c-Myc in BETi-P/R sAML cells. Following BETi treatment, c-Myc levels were rapidly restored in BETi-P/R sAML cells. CRISPR/Cas9-mediated knockout of TCF7L2 or JMJD6 reversed BETi-P/R, whereas ectopic overexpression conferred BETi-P/R in sAML cells; confirming the mechanistic role of the β-catenin-TCF7L2- JMJD6-MYC axis in BETi-resistance. Patient-derived, post-MPN, CD34+ sAML blasts exhibiting relative resistance to BETi, as compared to sensitive sAML blasts, displayed higher mRNA and protein expressions of TCF7L2, JMJD6 and c-Myc, and following BETi washout exhibited rapid restoration of c-Myc and JMJD6. CRISPR/Cas9 knockout of TCF7L2 and JMJD6 depleted their levels, inducing loss of viability of the sAML blasts. Disruption of co-localization of nuclear β-catenin with TBL1 and TCF7L2 by the small molecule inhibitor BC2059 combined with depletion of BRD4 by BET-PROTAC reduced c-Myc levels and exerted synergistic lethality in BETi-P/R sAML cells. This combination also reduced leukemia burden and improved survival of mice engrafted with BETi-P/R sAML cells or with patient-derived AML blasts innately resistant to BETi. Therefore, multi- targeted disruption of β-catenin-TCF7L2-JMJD6-MYC axis overcomes adaptive and innate BETi-resistance, exhibiting pre-clinical efficacy against human post-MPN sAML cells.

Project description:MYC is a driver oncogene in many cancers. Inhibition of MYC promises high therapeutic potential, but specific MYC inhibitors remain unavailable for clinical use. Previous studies suggest that MYC amplified Medulloblastoma cells are vulnerable to HDAC inhibition. Using co-immunoprecipitation, mass spectrometry and ChIP-sequencing we show that HDAC2 is a cofactor of MYC in MYC amplified primary medulloblastoma and cell lines. The MYC-HDAC2 complex is bound to genes defining the MYC-dependent transcriptional profile. Class I HDAC inhibition leads to stabilization and reduced DNA binding of MYC protein inducing a down-regulation of MYC activated genes (MAGs) and up-regulation of MYC repressed genes (MRGs). MAGs and MRGs are characterized by opposing biological functions and distinct E-box distribution. We conclude that MYC and HDAC2 (class I) are localized in a complex in MYC amplified medulloblastoma and drive a MYC-specific transcriptional program, which is reversed by the class I HDAC inhibitor entinostat. Thus, the development of HDAC inhibitors for treatment of MYC amplified medulloblastoma should include HDAC2 in its profile in order to directly target MYC´s trans-activating and trans-repressing function.

Project description:MYC is a driver oncogene in many cancers. Inhibition of MYC promises high therapeutic potential, but specific MYC inhibitors remain unavailable for clinical use. Previous studies suggest that MYC amplified Medulloblastoma cells are vulnerable to HDAC inhibition. Using co-immunoprecipitation, mass spectrometry and ChIP-sequencing we show that HDAC2 is a cofactor of MYC in MYC amplified primary medulloblastoma and cell lines. The MYC-HDAC2 complex is bound to genes defining the MYC-dependent transcriptional profile. Class I HDAC inhibition leads to stabilization and reduced DNA binding of MYC protein inducing a down-regulation of MYC activated genes (MAGs) and up-regulation of MYC repressed genes (MRGs). MAGs and MRGs are characterized by opposing biological functions and distinct E-box distribution. We conclude that MYC and HDAC2 (class I) are localized in a complex in MYC amplified medulloblastoma and drive a MYC-specific transcriptional program, which is reversed by the class I HDAC inhibitor entinostat. Thus, the development of HDAC inhibitors for treatment of MYC amplified medulloblastoma should include HDAC2 in its profile in order to directly target MYC´s trans-activating and trans-repressing function.

Project description:MYC is a driver oncogene in many cancers. Inhibition of MYC promises high therapeutic potential, but specific MYC inhibitors remain unavailable for clinical use. Previous studies suggest that MYC amplified Medulloblastoma cells are vulnerable to HDAC inhibition. Using co-immunoprecipitation, mass spectrometry and ChIP-sequencing we show that HDAC2 is a cofactor of MYC in MYC amplified primary medulloblastoma and cell lines. The MYC-HDAC2 complex is bound to genes defining the MYC-dependent transcriptional profile. Class I HDAC inhibition leads to stabilization and reduced DNA binding of MYC protein inducing a down-regulation of MYC activated genes (MAGs) and up-regulation of MYC repressed genes (MRGs). MAGs and MRGs are characterized by opposing biological functions and distinct E-box distribution. We conclude that MYC and HDAC2 (class I) are localized in a complex in MYC amplified medulloblastoma and drive a MYC-specific transcriptional program, which is reversed by the class I HDAC inhibitor entinostat. Thus, the development of HDAC inhibitors for treatment of MYC amplified medulloblastoma should include HDAC2 in its profile in order to directly target MYC´s trans-activating and trans-repressing function.

Project description:Targeting the epigenome to modulate gene expression programs driving cancer development has emerged as an exciting avenue for therapeutic intervention. Pharmacological inhibition of the bromodomain and extraterminal (BET) family of chromatin adapter proteins has proven effective in this regard, suppressing growth of diverse cancer types mainly through downregulation of the c-MYC oncogene and its downstream transcriptional program. While initially effective, resistance to BET inhibitors (BETi) typically occurs through mechanisms that reactivate MYC expression. We have previously shown that lung adenocarcinoma (LAC) is inhibited by JQ1 through suppression of FOSL1, suggesting that the epigenetic landscape of tumor cells from different origins and differentiation states influences BETi response. Here, we assessed how these differences affect mechanisms of BETi resistance through the establishment of isogenic pairs of JQ1 sensitive and resistant LAC cell lines. We found that resistance to JQ1 in LAC occurs independent of FOSL1 while MYC levels remain unchanged between resistant cells and their JQ1 treated parental counterparts. Furthermore, while epithelial-mesenchymal transition (EMT) is observed upon resistance, TGF- induced EMT did not confer resistance in JQ1 sensitive LAC lines, suggesting this is a consequence, rather than a driver of BETi resistance in our model systems. Importantly, siRNA knockdown demonstrated that JQ1 resistant cell lines are still dependent on BRD4 expression and we found that phosphorylation of BRD4 is elevated in resistant LACs, identifying casein kinase 2 (CK2) as a candidate protein mediating this effect. Inhibition of CK2, as well as downstream transcriptional targets of phosphorylated BRD4 - including AXL and activators of the PI3K pathway - synergize with JQ1 to inhibit BETi resistant LAC. Overall, this demonstrates that the mechanism of resistance to BETi varies depending on cancer type, with LAC cells developing JQ1 resistance independent of MYC re-activation, and identifying CK2 phosphorylation of BRD4 as a potential target to overcome resistance in this cancer.

Project description:The bromodomain and extra-terminal domain inhibitors (BETi) are promising epigenetic drugs for the treatment of various cancers through suppression of oncogenic transcription factors including MYC. However, only a subset of CRC cells response to BETi, suggesting an intrinsic resistance to BETi in CRC. We investigated the effect of JQ1 on cell proliferation, apoptosis, angiogenesis and MYC expression in a panel of 11 CRC cells in vitro and in vivo. JQ1-resistant CRC cells were used for the screening for the effective combination therapies with JQ1. RNA-seq of single drug or combined drugs treatment was performed to explore the mechanism of action.

Project description:As the most life-threatening subtype of pediatric medulloblastoma (MB), MYC-amplified Group 3 (G3) MB lacks effective and selective therapeutics. We tried to indirectly target MYC (oncogenic driver and cancer-dependent molecule) production via inhibiting translational machinery. Through multiple datasets analyses on components of eIF4F (eukaryotic translation initiation factor 4F) complex, we found that EIF4A1 (major component with RNA helicase activity) has relatively higher expression level and the closest positive correlation with MYC in G3-MB among normal control and other 3 subtypes (e.g., WNT, SHH and G4). Both in vitro and in vivo experiments with MYC-amplified G3-MB cell lines showed effective growth inhibition upon EIF4A1 knockout or inhibitor treatment. Further FACS analysis found decreased cell proliferation and enhanced apoptosis on EIF4A1 inhibitor treatment. To explore the mechanisms of EIF4A1 inhibition on arresting MYC-amplified G3-MB, we performed the whole proteome analyses on corresponding MB cells treated with EIF4A1 inhibitor.

Project description:BET inhibitors (BETi) target bromodomain-containing proteins and are currently being evaluated as anti-cancer agents. We discovered that the maximal therapeutic effects of BETi in a Myc-driven B cell lymphoma model required an intact host immune system. Genome-wide analysis of the BETi induced transcriptional response identified the immune checkpoint ligand Cd274 (Pd-l1) as a Myc-independent, BETi target-gene. BETi directly repressed constitutively expressed and IFN-γ induced CD274 expression across different human and mouse tumor cell lines and primary patient samples. Mechanistically, BETi decreased Brd4 occupancy at the Cd274 locus without any change in Myc occupancy, resulting in transcriptional pausing and rapid loss of Cd274 mRNA production. Finally, targeted inhibition of the PD1/PD-L1 axis by combining anti-PD1 antibodies and the BETi JQ1 caused synergistic responses in mice bearing Myc-driven lymphomas. Our data uncovers a novel interaction between BETi and the PD-1/PD-L1 immune-checkpoint and provides novel insight into the transcriptional regulation of CD274.