Project description:Bromodomains (BRDs) have emerged as compelling targets for cancer therapy. The development of selective and potent BET inhibitors and their significant activity in diverse tumor models has rapidly translated into clinical studies and has motivated drug development efforts targeting non-BET BRDs. However, the complex multidomain/subunit architecture of bromodomain protein complexes complicates predictions of consequences of their pharmacological targeting. To address this issue we developed a promiscuous bromodomain inhibitor (bromosporine, BSP) that broadly targets BRDs (including BETs) with nanomolar affinity, creating a tool for the identification of cellular processes and diseases where BRDs have a regulatory function. As a proof of principle we studied the effect of BSP in leukemic cell-lines known to be sensitive to BET inhibition and found as expected strong anti-proliferative activity. Comparison of the modulation of transcriptional profiles by BSP at short inhibitor exposure resulted in a BET inhibitor signature but no significant additional changes in transcription that could account for inhibition of other BRDs. Thus, non-selective targeting of BRDs identified BETs, but not other BRDs, as master regulators of a context dependent primary transcription response.

Project description:Bromodomains (BRDs) have emerged as compelling targets for cancer therapy. The development of selective and potent BET inhibitors and their significant activity in diverse tumor models has rapidly translated into clinical studies and has motivated drug development efforts targeting non-BET BRDs. However, the complex multidomain/subunit architecture of bromodomain protein complexes complicates predictions of consequences of their pharmacological targeting. To address this issue we developed a promiscuous bromodomain inhibitor (bromosporine, BSP) that broadly targets BRDs (including BETs) with nanomolar affinity, creating a tool for the identification of cellular processes and diseases where BRDs have a regulatory function. As a proof of principle we studied the effect of BSP in leukemic cell-lines known to be sensitive to BET inhibition and found as expected strong anti-proliferative activity. Comparison of the modulation of transcriptional profiles by BSP at short inhibitor exposure resulted in a BET inhibitor signature but no significant additional changes in transcription that could account for inhibition of other BRDs. Thus, non-selective targeting of BRDs identified BETs, but not other BRDs, as master regulators of a context dependent primary transcription response. Cells were seeded the day prior to treatment at 2x10^5 per ml. Treatments were performed so that a final concentration of 0.1 % DMSO (Cat.#D1435; Sigma) was achieved and cells were incubated with DMSO or 500 nM test compound (BSP, JQ1, LP99, GSK2801, iCBP112 or OF1) for 6 h prior to isolation of RNA. Total RNA was isolated using a standard TRIzol (Invitrogen) protocol and prepared using RNeasy columns (Cat.#74106 plus; Qiagen). RNA was quantified using a Nanodrop spectrophotometer (model ND1000; Thermo Fisher) and integrity assessed on a BioAnalyzer (2100; Agilent Laboratories, USA). All samples had a RNA Integrity Number (RIN) ≥ 9. Biological triplicates were performed for each condition tested.

Project description:Bromodomains (BRDs) have emerged as compelling targets for cancer therapy. The development of selective and potent BET inhibitors and their significant activity in diverse tumor models has rapidly translated into clinical studies and has motivated drug development efforts targeting non-BET BRDs. However, the complex multidomain/subunit architecture of bromodomain protein complexes complicates predictions of consequences of their pharmacological targeting. To address this issue we developed a promiscuous bromodomain inhibitor (bromosporine, BSP) that broadly targets BRDs (including BETs) with nanomolar affinity, creating a tool for the identification of cellular processes and diseases where BRDs have a regulatory function. As a proof of principle we studied the effect of BSP in leukemic cell-lines known to be sensitive to BET inhibition and found as expected strong anti-proliferative activity. Comparison of the modulation of transcriptional profiles by BSP at short inhibitor exposure resulted in a BET inhibitor signature but no significant additional changes in transcription that could account for inhibition of other BRDs. Thus, non-selective targeting of BRDs identified BETs, but not other BRDs, as master regulators of a context dependent primary transcription response. Cells were seeded the day prior to treatment at 2x10^5 per ml. Treatments were performed so that a final concentration of 0.1 % DMSO (Cat.#D1435; Sigma) was achieved and cells were incubated with DMSO or 500 nM test compound (BSP or JQ1) for 6 h prior to isolation of RNA. Total RNA was isolated using a standard TRIzol (Invitrogen) protocol and prepared using RNeasy columns (Cat.#74106 plus; Qiagen). RNA was quantified using a Nanodrop spectrophotometer (model ND1000; Thermo Fisher) and integrity assessed on a BioAnalyzer (2100; Agilent Laboratories, USA). All samples had a RNA Integrity Number (RIN) â?¥ 9. Biological triplicates were performed for each condition tested.

Project description:Bromodomains (BRDs) are evolutionary conserved epigenetic protein interaction modules which recognize (“read”) acetyl-lysine, however their role(s) in regulating cellular states and their potential as targets for the development of targeted treatment strategies is poorly understood. Here we present a set of 25 chemical probes, selective tool small molecule inhibitors, covering 29 human bromodomain targets. We comprehensively evaluate the selectivity of this probe-set using BROMOscan® and demonstrate the utility of the set in studies of muscle cell differentiation and triple negative breast cancer (TNBC). We identified cross talk between histone acetylation and the glycolytic pathway resulting in a vulnerability of TNBC cell lines to inhibition of BRPF2/3 BRDs under conditions of glucose deprivation or GLUT1 inhibition. This chemical probe set will serve as a resource for future applications in the discovery of new physiological roles of bromodomain proteins in normal and disease states and as a toolset for bromodomain target validation.

Project description:Studies investigating the causes of autism spectrum disorder (ASD) point to genetic as well as epigenetic mechanisms of the disease. Identification of epigenetic processes that contribute to ASD development and progression is of major importance and may lead to the development of novel therapeutic strategies. Here we identify the bromodomain and extra-terminal domain containing transcriptional regulators (BETs) as epigenetic drivers of an ASD-like disorder in mice. We found that the pharmacological suppression of the BET proteins by a novel, highly selective and brain-permeable inhibitor, I-BET858, leads to selective suppression of neuronal gene expression followed by the development of an autism-like syndrome in mice. Many of the I-BET858 affected genes have been linked to ASD in humans thus suggesting the key role of the BET-controlled gene network in ASD. Our studies also suggest that environmental factors controlling BET proteins or their target genes may contribute to the epigenetic mechanism of ASD. There are 24 total samples. There are two timepoints, 2 and 12 hours. Triplicates were performed for each treatment. Control samples were prepared by treating with DMSO for each of the timepoints.

Project description:Heart failure is driven by the interplay between master regulatory transcription factors and dynamic alterations in chromatin structure. Coordinate activation of developmental, inflammatory, fibrotic and growth regulators underlies the hallmark phenotypes of pathologic cardiac hypertrophy and contractile failure. While transactivation in this context is known to be associated with recruitment of histone acetyl-transferase enzymes and local chromatin hyperacetylation, the role of epigenetic reader proteins in cardiac biology is unknown. We therefore undertook a first study of acetyl-lysine reader proteins, or bromodomains, in heart failure. Using a chemical genetic approach, we establish a central role for BET-family bromodomain proteins in gene control during the evolution of heart failure. BET inhibition suppresses cardiomyocyte hypertrophy in a cell-autonomous manner, confirmed by RNA interference in vitro. Following both pressure overload and neurohormonal stimulation, BET inhibition potently attenuates pathologic cardiac remodeling in vivo. Integrative transcriptional and epigenomic analyses reveal that BET proteins function mechanistically as pause-release factors critical to activation of canonical master regulators and effectors that are central to heart failure pathogenesis. Specifically, BET bromodomain inhibition in mice abrogates pathology-associated pause release and transcriptional elongation, thereby preventing activation of cardiac transcriptional pathways relevant to the gene expression profile of failing human hearts. This study implicates epigenetic readers in cardiac biology and identifies BET co-activator proteins as therapeutic targets in heart failure. ChIP-Seq of mouse heart tissues from mice induced with heart failure and treated with JQ1 BET bromodomain inhibitor

Project description:Heart failure (HF) is driven via interplay between master regulatory transcription factors and dynamic alterations in chromatin structure. While pathologic gene transactivation in this context is known to be associated with recruitment of histone acetyl-transferases and local chromatin hyperacetylation, the role of epigenetic reader proteins in cardiac biology is unknown. We therefore undertook a first study of acetyl-lysine reader proteins, or bromodomains, in HF. Using a chemical genetic approach, we establish a central role for BET-family bromodomain proteins in gene control during HF pathogenesis. BET inhibition potently suppresses cardiomyocyte hypertrophy in vitro and pathologic cardiac remodeling in vivo. Integrative transcriptional and epigenomic analyses reveal that BET proteins function mechanistically as pause-release factors critical to activation of canonical master regulators and effectors that are central to HF pathogenesis and relevant to the pathobiology of failing human hearts. This study implicates epigenetic readers in cardiac biology and identifies BET co-activator proteins as therapeutic targets in HF. Gene expression analysis of neonatal rat ventricular mycotes (NRVM) subjected to phenylephrine (PE) treatment followed by treatment with vehicle (DMSO) or the BET bromodomain inhibitor JQ1

Project description:Heart failure (HF) is driven via interplay between master regulatory transcription factors and dynamic alterations in chromatin structure. While pathologic gene transactivation in this context is known to be associated with recruitment of histone acetyl-transferases and local chromatin hyperacetylation, the role of epigenetic reader proteins in cardiac biology is unknown. We therefore undertook a first study of acetyl-lysine reader proteins, or bromodomains, in HF. Using a chemical genetic approach, we establish a central role for BET-family bromodomain proteins in gene control during HF pathogenesis. BET inhibition potently suppresses cardiomyocyte hypertrophy in vitro and pathologic cardiac remodeling in vivo. Integrative transcriptional and epigenomic analyses reveal that BET proteins function mechanistically as pause-release factors critical to activation of canonical master regulators and effectors that are central to HF pathogenesis and relevant to the pathobiology of failing human hearts. This study implicates epigenetic readers in cardiac biology and identifies BET co-activator proteins as therapeutic targets in HF. Gene expression analysis of mouse hearts subjected to either trans aortic constriction (TAC) or sham surgeries followed by treamtent with dmso vehicle or the BET bromodomain inhibitor JQ1

Project description:The evolutionarily conserved BET bromodomain family contain a distinctive tandem bromodomain structure that enables their chromatin binding to facilitate transcription. Whilst first-in-class drugsthat equally inhibit both bromodomains have shown pre-clinicaland clinical efficacy in a range of malignant and inflammatory pathologies, the functional contribution of the first (BD1) and second (BD2) bromodomains to these pathologies remains largely unknown. Here we haveexploited detailedstructuralinsights and our extensivemedicinal chemistry capabilities to develop novel compounds that are exquisitely selectivefor either BD1 or BD2 of the BET proteins. Using thesewell characterised domain-specific inhibitors we show that BD1 is required by all BET proteins to associate with chromatin and maintain established malignant transcriptional programs.Therefore, targeting BD1 alone phenocopies the therapeutic effects of current non-selective BET inhibitorsin models of cancer. Whilst steady state gene expression primarily requires BD1,we find that the rapid increase of gene expression effectedby a wide range of inflammatory stimuli requiresboth BD1 and BD2. Moreover, although BRD4 is the principal member required for the maintenance of established gene expression, efficient gene induction also requires BRD2 and BRD3. Selective inhibition of BD2 is effective in perturbing the recruitment of all the BET proteins for stimulated gene expression and consequently small molecule inhibitors of BD2 amelioratethe immunoinflammatory end organ damage seen in models of inflammatory arthritis, psoriasis and hepatitis. Together,these data provide novel biological and functional insights into this family of key transcriptional regulators. Importantly, they also help refine the future therapeutic approach when targeting the BET proteinsin distinct pathologies such as cancer and immuno-inflammation.

Project description:The evolutionarily conserved BET bromodomain family contain a distinctive tandem bromodomain structure that enables their chromatin binding to facilitate transcription. Whilst first-in-class drugsthat equally inhibit both bromodomains have shown pre-clinicaland clinical efficacy in a range of malignant and inflammatory pathologies, the functional contribution of the first (BD1) and second (BD2) bromodomains to these pathologies remains largely unknown. Here we haveexploited detailedstructuralinsights and our extensivemedicinal chemistry capabilities to develop novel compounds that are exquisitely selectivefor either BD1 or BD2 of the BET proteins. Using thesewell characterised domain-specific inhibitors we show that BD1 is required by all BET proteins to associate with chromatin and maintain established malignant transcriptional programs.Therefore, targeting BD1 alone phenocopies the therapeutic effects of current non-selective BET inhibitorsin models of cancer. Whilst steady state gene expression primarily requires BD1,we find that the rapid increase of gene expression effectedby a wide range of inflammatory stimuli requiresboth BD1 and BD2. Moreover, although BRD4 is the principal member required for the maintenance of established gene expression, efficient gene induction also requires BRD2 and BRD3. Selective inhibition of BD2 is effective in perturbing the recruitment of all the BET proteins for stimulated gene expression and consequently small molecule inhibitors of BD2 amelioratethe immunoinflammatory end organ damage seen in models of inflammatory arthritis, psoriasis and hepatitis. Together,these data provide novel biological and functional insights into this family of key transcriptional regulators. Importantly, they also help refine the future therapeutic approach when targeting the BET proteinsin distinct pathologies such as cancer and immuno-inflammation.