Project description:SMARCA4 (BRG1) encodes for one of two mutually-exclusive ATPases present in mammalian SWI/SNF chromatin remodeling complexes, and is among the most frequently mutated genes in human lung adenocarcinoma. Despite its prevalence, the functional consequences of SMARCA4 mutation on tumor initiation, progression and chromatin regulation in lung cancer remains poorly understood. Using genetically engineered mouse models, patient-derived xenografts, and single-cell epigenomic profiling, we demonstrate that loss of Smarca4 sensitizes CCSP+ cells within the lung in a cell-type dependent fashion to malignant transformation and tumor progression, resulting in highly advanced dedifferentiated tumors and increased metastatic incidence. Consistent with these phenotypes, Smarca4-deficient primary tumors lack lung lineage transcription factor activities and instead show hyper-activation of embryonic stem cell-like programs, resembling a metastatic cell state. Mechanistically, we show that all three classes of SWI/SNF complexes are unable to bind and open chromatin at distinct regulatory regions in the absence of SMARCA4, thereby preventing lineage factors from binding to their targets and maintaining cell identity – ultimately accelerating tumor progression. Thus, the SWI/SNF complex – via Smarca4 – acts as a gatekeeper for lineage-specific cellular transformation and metastasis during lung cancer evolution.

Project description:SMARCA4 (BRG1) encodes for one of two mutually-exclusive ATPases present in mammalian SWI/SNF chromatin remodeling complexes, and is among the most frequently mutated genes in human lung adenocarcinoma. Despite its prevalence, the functional consequences of SMARCA4 mutation on tumor initiation, progression and chromatin regulation in lung cancer remains poorly understood. Using genetically engineered mouse models, patient-derived xenografts, and single-cell epigenomic profiling, we demonstrate that loss of Smarca4 sensitizes CCSP+ cells within the lung in a cell-type dependent fashion to malignant transformation and tumor progression, resulting in highly advanced dedifferentiated tumors and increased metastatic incidence. Consistent with these phenotypes, Smarca4-deficient primary tumors lack lung lineage transcription factor activities and instead show hyper-activation of embryonic stem cell-like programs, resembling a metastatic cell state. Mechanistically, we show that all three classes of SWI/SNF complexes are unable to bind and open chromatin at distinct regulatory regions in the absence of SMARCA4, thereby preventing lineage factors from binding to their targets and maintaining cell identity – ultimately accelerating tumor progression. Thus, the SWI/SNF complex – via Smarca4 – acts as a gatekeeper for lineage-specific cellular transformation and metastasis during lung cancer evolution.

Project description:SMARCA4 (BRG1) encodes for one of two mutually-exclusive ATPases present in SWI/SNF chromatin remodeling complexes, and is among the most frequently mutated genes in human lung adenocarcinoma. Despite its prevalence, the functional consequences of SMARCA4 alterations on lung cancer initiation and progression remain poorly understood. Using genetically engineered mouse models, patient-derived xenografts, and single-cell epigenomic profiling, we demonstrate that loss of Smarca4 sensitizes CCSP+ cells within the lung to malignant transformation and tumor progression, resulting in highly advanced dedifferentiated tumors and increased metastatic incidence. Consistent with these phenotypes, Smarca4-deficient tumors lack lung lineage transcription factor activities and instead show activation of embryonic stem cell-like programs, resembling a metastatic cell state. Thus, the SWI/SNF complex – via Smarca4 – acts as a gatekeeper for lineage-specific cellular transformation and metastasis during lung cancer evolution.

Project description:SMARCA4 (BRG1) encodes for one of two mutually-exclusive ATPases present in SWI/SNF chromatin remodeling complexes, and is among the most frequently mutated genes in human lung adenocarcinoma. Despite its prevalence, the functional consequences of SMARCA4 alterations on lung cancer initiation and progression remain poorly understood. Using genetically engineered mouse models, patient-derived xenografts, and single-cell epigenomic profiling, we demonstrate that loss of Smarca4 sensitizes CCSP+ cells within the lung to malignant transformation and tumor progression, resulting in highly advanced dedifferentiated tumors and increased metastatic incidence. Consistent with these phenotypes, Smarca4-deficient tumors lack lung lineage transcription factor activities and instead show activation of embryonic stem cell-like programs, resembling a metastatic cell state. Thus, the SWI/SNF complex – via Smarca4 – acts as a gatekeeper for lineage-specific cellular transformation and metastasis during lung cancer evolution.

Project description:Mammalian SWI/SNF complexes are considered as key epigenetic regulators and they are recurrently mutated in many types of cancer. Most of the studies of these chromatin remodeling complexes are focused on their role in regulating protein-coding genes. However, here we show that the SWI/SNF complex is able to control the expression of microRNAs. We used a SMARCA4-deficient model of lung adenocarcinoma where we could track changes of the miRNome upon SMARCA4 restoration. We found that exogenous SMARCA4 was successfully incorporated into endogenous SWI/SNF complexes and that these SMARCA4-SWI/SNF complexes induced significant changes in the expression of cancer-related microRNAs. The most significantly dysregulated miRNA was miR-222, whose expression was promoted by SMARCA4-SWI/SNF complexes but not by SMARCA2-SWI/SNF complexes via their direct binding to a miR-222 enhancer region. Importantly, miR-222 expression decreased cell viability and impaired cell clonogenicity, phenocopying the tumor-suppressor role of the SMARCA4-SWI/SNF complex in lung cancer. Finally, we showed that the miR-222 enhancer does not interact with any cancer-related protein-coding genes, supporting that its tumor suppressor effect may be exerted via miR-222. Overall, this study highlights the relevant role of the SWI/SNF complex in regulating the expression of the non-coding genome.

Project description:Advanced prostate cancer initially responds to hormonal treatment, but ultimately becomes resistant and requires more potent therapies. One mechanism of resistance seen in 10% of these patients is through lineage plasticity, which manifests in a partial or complete small cell or neuroendocrine prostate cancer (NEPC) phenotype. Here, we investigate the role of the mammalian SWI/SNF chromatin remodeling complex in NEPC. Using large patient datasets, patient-derived organoids and cancer cell lines, we identify SWI/SNF subunits that are deregulated in NEPC, demonstrate that SMARCA4 (BRG1) overexpression is associated with aggressive disease and that SMARCA4 depletion impairs prostate cancer cell growth. We also show that SWI/SNF complexes interact with different lineage-specific factors in prostate adenocarcinoma and in NEPC cells, and that induction of lineage plasticity through depletion of REST is accompanied by changes in SWI/SNF genome occupancy. These data suggest a specific role for mSWI/SNF complexes in therapy-related lineage plasticity, which may be relevant for other solid tumors.

Project description:Here we performed transcriptional profiling of the prostate cancer cell lines LNCaP and 22Rv1 comparing non-targeting siRNA treatment versus siRNAs targeting SWI/SNF complex proteins (SMARCA2, SMARCA4, and SMARCB1). Goal was to determine the effect of SWI/SNF knockdown on gene expression in prostate cancer. Two-condition experiment: non-targeting siRNA versus SWI/SNF-siRNA treated cells. Three SWI/SNF proteins were targeted: SMARCA2, SMARCA4, and SMARB1. Biological replicates: 1 control replicate, 2 treatment replicates per SWI/SNF protein. Technical replicates: 1 replicate per SWI/SNF protein. Cell lines: 22Rv1 and LNCaP.

Project description:Lung cancer is a devastating disease that remains the top cause of cancer mortality. While targeted therapies against EGFR and EML4-ALK fusion and recent advances in immunotherapy have shown substantial clinical benefit for some patients, the vast majority of patients with lung cancer still lack effective therapies underscoring the dire need for more context-specific therapeutics. Cancer genomic studies have identified frequent genetic alterations in chromatin and epigenetic regulators including inactivating mutations in components of the SWI/SNF chromatin remodeling complex. In lung adenocarcinoma, about 20% of tumors have inactivating mutations in components of the SWI/SNF chromatin remodeling complex including SMARCA4 and ARID1A. With the aim of understanding the mechanism of tumor development driven by mutations in this complex, we developed a genetically engineered mouse (GEM) model of lung adenocarcinoma by selectively ablating Smarca4 in the lung epithelium. We demonstrate that Smarca4 acts as a bona fide tumor suppressor and cooperates with p53 loss and Kras activation. Cross species integrative gene expression analyses revealed signature of enhanced oxidative phosphorylation (OXPHOS) in SMARCA4 mutant murine as well as human lung adenocarcinomas. We further show that SMARCA4 mutant cells have increased oxygen consumption and increased respiratory capacity primarily driven by increased expression of the mitochondrial master regulator, PGC1-α. Importantly, we show that SMARCA4 and other SWI/SNF mutant lung cancer cell lines and xenograft tumors have exquisite sensitivity to inhibition of OXPHOS by a novel small molecule, IACS-010759, that is under clinical development. Mechanistically, we show that SMARCA4 deficient cells have a blunted transcriptional response to energy stress creating a therapeutically attractive collateral vulnerability. These findings provide the mechanistic basis for further development of OXPHOS inhibitors as therapeutics against SWI/SNF mutant tumors.

Project description:Lung cancer is a devastating disease that remains the top cause of cancer mortality. While targeted therapies against EGFR and EML4-ALK fusion and recent advances in immunotherapy have shown substantial clinical benefit for some patients, the vast majority of patients with lung cancer still lack effective therapies underscoring the dire need for more context-specific therapeutics. Cancer genomic studies have identified frequent genetic alterations in chromatin and epigenetic regulators including inactivating mutations in components of the SWI/SNF chromatin remodeling complex. In lung adenocarcinoma, about 20% of tumors have inactivating mutations in components of the SWI/SNF chromatin remodeling complex including SMARCA4 and ARID1A. With the aim of understanding the mechanism of tumor development driven by mutations in this complex, we developed a genetically engineered mouse (GEM) model of lung adenocarcinoma by selectively ablating Smarca4 in the lung epithelium. We demonstrate that Smarca4 acts as a bona fide tumor suppressor and cooperates with p53 loss and Kras activation. Cross species integrative gene expression analyses revealed signature of enhanced oxidative phosphorylation (OXPHOS) in SMARCA4 mutant murine as well as human lung adenocarcinomas. We further show that SMARCA4 mutant cells have increased oxygen consumption and increased respiratory capacity primarily driven by increased expression of the mitochondrial master regulator, PGC1-α. Importantly, we show that SMARCA4 and other SWI/SNF mutant lung cancer cell lines and xenograft tumors have exquisite sensitivity to inhibition of OXPHOS by a novel small molecule, IACS-010759, that is under clinical development. Mechanistically, we show that SMARCA4 deficient cells have a blunted transcriptional response to energy stress creating a therapeutically attractive collateral vulnerability. These findings provide the mechanistic basis for further development of OXPHOS inhibitors as therapeutics against SWI/SNF mutant tumors.

Project description:Lineage-specific differentiation programs are activated by epigenetic changes in chromatin structure. Melanin-producing melanocytes maintain a gene expression program ensuring appropriate enzymatic conversion of metabolites into the pigment, melanin, and its transfer to surrounding cells. During neuroectodermal development, SMARCA4, the catalytic subunit of SWItch/Sucrose Non-Fermentable (SWI/SNF) chromatin remodeling complexes, is essential for lineage specification. SMARCA4 is also required for development of multipotent neural crest precursors into melanoblasts, which differentiate into pigment-producing melanocytes. In addition to the catalytic domain, SMARCA4 and several SWI/SNF subunits contain bromodomains which are amenable to pharmacological inhibition. We investigated the effects of pharmacological inhibitors of SWI/SNF bromodomains on melanocyte differentiation. Strikingly, treatment of murine melanoblasts and human neonatal epidermal melanocytes with selected bromodomain inhibitors abrogated melanin synthesis and visible pigmentation. Using functional genomics, iBRD9, a small molecule selective for the bromodomain of BRD9, repressed pigmentation-specific gene expression. Depletion of BRD9 confirmed a requirement for expression of pigmentation genes in the differentiation program from melanoblasts into pigmented melanocytes and in melanoma cells. Chromatin immunoprecipitation assays showed that iBRD9 disrupts the occupancy of bromodomain containing 9 (BRD9) and the catalytic subunit SMARCA4. These data indicate that BRD9 promotes melanocyte differentiation and pigmentation whereas pharmacological inhibition of BRD9 is repressive.