Project description:Advanced prostate cancer is often associated with the emergence of more aggressive disease phenotypes, including neuroendocrine prostate cancer (NEPC), which are currently incurable. To identify drivers of aggressive prostate cancer, we conducted a Sleeping Beauty (SB) transposon mutagenesis screen based on a mouse model having conditional loss of function of Pten and Tp53 prostate (NPp53). Compared with the control mice (NPp53-SB(—)), the experimental mice (NPp53-SB(+)) develop aggressive prostate cancer phenotypes that are highly heterogeneous and highly metastasis. Most notably, a high percentage of NPp53-SB(+) prostate tumors have features of NEPC, which are conserved with human prostate cancer. To identify and prioritize drivers of NEPC in these NPp53-SB(+) tumors, we used a novel integrative approach that combines (i) genomic analyses of common insert sites (CIS) for the SB transposon, (ii) VIPER analyses of control NPp53-SB(+) prostate tumors to identify master regulators (MRs) enriched in NEPC, and (iii) comparative transcriptomic analyses with data from human prostate cancer patients followed by integrative analyses using of these data using a CINDy algorithm to identify CIS-associated genes that modulate the NEPC phenotypes. Among these the nicotinamide adenosine dinucleotide (NAD)-dependent deacetylase, sirtuin 1 (Sirt1). Loss- and gain-of-function studies in human prostate cancer cell lines showed that SIRT1 promotes NEPC, while its depletion or inhibition reduces NEPC. Overall, this integrative phenotypic and systems analyses have identified of candidate drivers of NEPC and may be generalizable to analyzing and interpreting data from analogous in vivo mutagenesis screens.

Project description:Although most prostate tumors are relatively indolent, advanced disease can progress to aggressive, often lethal variants, including neuroendocrine prostate cancer (NEPC). To identify drivers of aggressive prostate cancer, we used Sleeping Beauty (SB) transposon mutagenesis in a mouse model having prostate-specific loss of Pten and Tp53 (NPp53 mice). Compared with control NPp53-SB(—) mice, experimental NPp53-SB(+) mice developed more aggressive tumors with increased metastasis. Notably, NPp53-SB(+) mice exhibited NEPC phenotypes with transcriptomic features that recapitulate human NEPC. Analysis of recurrent common insertion sites (CIS) and associated genes (CIS-genes) identified genes differentially expressed between NEPC and non-NEPC tumors. Analysis of NEPC-enriched CIS genes by cross-species integration of genomic and transcriptomic data prioritized Sirtuin 1 (Sirt1) as a candidate mechanistic determinant of NEPC. Gain- and loss-of-function studies in human prostate cancer cells and mouse NEPC organoids confirmed that SIRT1 promotes NEPC, while pharmacological inhibition suppresses it. Thus, integration of cross-species analyses with an unbiased forward genetic screen uncovered novel drivers of NEPC.

Project description:Neuroendocrine prostate cancer (NEPC) is a highly aggressive form of prostate cancer characterized by the loss of androgen receptor (AR) signaling and the acquisition of neuroendocrine (NE) characteristics. However, the underlying molecular mechanism, especially related to the drivers or the determinants responsible for NE transdifferentiation, remains unclear. In this study, we compared gene expression profiling of NEPC and non-NEPC specimens and paid a particular attention to those transcriptional factors affecting neural differentiation during development. We identified that Paired box 6 (Pax6) expression was significantly elevated in NEPC and negatively regulated by AR signaling. While knock-down of Pax6 in NEPC cells inhibited NEPC phenotypes, over-expression of Pax6 in non-NEPC cells led to development of NEPC. Mechanistically, loss of AR resulted in an enhanced expression of Pax6, which reprogramed the lineage plasticity of prostate cancer cells to develop NE phenotypes through the c-Met/Stat5a signaling. By performing ATAC-seq, we found that high expression level of Pax6 elicited enhanced chromatin accessibility mainly through attenuation of H4K20me3 that usually causes chromatin silence in cancer cells. Taken together, these findings highlight PAX6 as a novel molecule to drive NEPC progression and suggest that it might serve as a potential target for the management of NEPC.

Project description:MYCN amplification and overexpression are common in neuroendocrine prostate cancer (NEPC). However, the impact of aberrant N-Myc expression in prostate tumorigenesis and the cellular origin of NEPC have not been established. We define N-Myc and activated AKT1 as oncogenic components sufficient to transform human prostate epithelial cells to prostate adenocarcinoma and NEPC including the small cell prostate carcinoma (SCPC) variant with phenotypic and molecular features of aggressive, late-stage human disease. We directly show that prostate adenocarcinoma and NEPC can both arise from a common epithelial clone. Further, N-Myc is required for tumor maintenance and destabilization of N-Myc through Aurora A kinase inhibition reduces tumor burden. Our findings establish N-Myc as a driver of NEPC and a target for therapeutic intervention. Expression profiling by high throughput sequencing of experimentally generated human tumors with mixed NEPC and prostate adenocarcinoma. Gene expression analysis of laser capture microdissected NEPC and adenocarcinoma from three independent engineered human tumors of mixed NEPC and prostate adenocarcinoma phenotype.

Project description:Increased treatment of metastatic castration resistant prostate cancer (mCRPC) with second-generation anti-androgen therapies (ADT) has coincided with a greater incidence of lethal, aggressive variant prostate cancer (AVPC) tumors that have lost androgen receptor (AR) signaling. AVPC tumors may also express neuroendocrine markers, termed neuroendocrine prostate cancer (NEPC). Recent evidence suggests kinase signaling may be an important driver of NEPC. To identify targetable kinases in NEPC, we performed global phosphoproteomics comparing AR-negative to AR-positive prostate cancer cell lines and identified multiple altered signaling pathways, including enrichment of RET kinase activity in the AR-negative cell lines. Clinical NEPC and NEPC patient derived xenografts displayed upregulated RET transcript and RET pathway activity. Pharmacologically inhibiting RET kinase in NEPC models dramatically reduced tumor growth and cell viability in mouse and human NEPC models. Our results suggest that targeting RET in NEPC tumors with high RET expression may be a novel treatment option.

Project description:Increased treatment of metastatic castration resistant prostate cancer (mCRPC) with second-generation anti-androgen therapies (ADT) has coincided with a greater incidence of lethal, aggressive variant prostate cancer (AVPC) tumors that have lost androgen receptor (AR) signaling. AVPC tumors may also express neuroendocrine markers, termed neuroendocrine prostate cancer (NEPC). Recent evidence suggests kinase signaling may be an important driver of NEPC. To identify targetable kinases in NEPC, we performed global phosphoproteomics comparing AR-negative to AR-positive prostate cancer cell lines and identified multiple altered signaling pathways, including enrichment of RET kinase activity in the AR-negative cell lines. Clinical NEPC and NEPC patient derived xenografts displayed upregulated RET transcript and RET pathway activity. Pharmacologically inhibiting RET kinase in NEPC models dramatically reduced tumor growth and cell viability in mouse and human NEPC models. Our results suggest that targeting RET in NEPC tumors with high RET expression may be a novel treatment option.

Project description:Introduction: Neuroendocrine prostate cancer (NEPC) is an aggressive subtype of prostate cancer, exhibiting rapid progression and is unresponsive to hormone therapy. Reliable prognostic assays and more effective treatments are critically required. However, the research of NEPC has been hampered by a lack of clinically relevant in vivo models. Recently, we successfully developed a first-in-field patient tissue-derived xenograft model of complete neuroendocrine transdifferentiation from prostate adenocarcinoma. By comparing gene expression profiles of the parental adenocarcinoma line (LTL331) and the NEPC subline (LTL331R), we identified DEK, a gene not previously reported in prostate cancer, as a potential biomarker and target for NEPC. Methods: DEK protein expression in patient tissue-derived xenograft models and clinical samples was assessed by immunohistochemistry. The function of DEK was determined by siRNA-induced reduction of DEK expression in PC-3 cells, a cell line with NEPC characteristics, followed by functional assays and gene expression profiling analysis. Results: Elevated DEK protein expression was observed in all clinical NEPC cases, which is distinct from their benign counterparts (0%), hormonal naïve prostate cancer (2.45%) and castration resistant prostate cancer (29.55%). Increased DEK expression is an independent clinical risk factor and is associated with shorter disease free survival in hormonal naïve prostate cancer patients. Reduction of DEK expression in PC-3 cells led to a marked reduction in cell proliferation, cell migration and invasion. Conclusions: The results suggest that DEK may play an important role in the progression of prostate cancer, especially NEPC and provide a potential biomarker to aid risk stratification of prostate cancer and a novel therapeutic target for treating NEPC. The function of DEK was determined by siRNA-induced reduction of DEK expression in PC-3 cells, a cell line with NEPC characteristics, followed by functional assays and gene expression profiling analysis.

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:Neuroendocrine prostate cancer (NEPC) is a lethal subtype of prostate cancer that can develop from prostate cancer following aggressive hormonal therapy. Unfortunately, there are few treatment options available and new therapeutic targets and more effective treatments are urgently needed to improve management of the disease. There is now little doubt that the majority of NEPC is derived from prostatic adenocarcinoma cells via “NE transdifferentiation” that is driven at least in part by AR-axis interference and lineage plasticity. We have developed a first-in-field patient-derived xenograft model of a prostatic adenocarcinoma (LTL331) that undergoes a complete transdifferentiation to NEPC (LTL331R) upon host castration. Using this unique, high-fidelity, patient-derived prostate cancer xenograft models and powerful genomic and transcriptomic analyses, we have obtained evidence that therapy induced development of NEPC may result from epigenetic alterations which drives lineage plasticity of dormancy-capable cancer cells and functional evaluation of key regulators. These findings may lead to more suitable targets and better therapeutic strategies for prevention and treatment of NEPC.

Project description:Neuroendocrine prostate cancer (NEPC) is a lethal subtype of prostate cancer that can develop from prostate cancer following aggressive hormonal therapy. Unfortunately, there are few treatment options available and new therapeutic targets and more effective treatments are urgently needed to improve management of the disease. There is now little doubt that the majority of NEPC is derived from prostatic adenocarcinoma cells via “NE transdifferentiation” that is driven at least in part by AR-axis interference and lineage plasticity. We have developed a first-in-field patient-derived xenograft model of a prostatic adenocarcinoma (LTL331) that undergoes a complete transdifferentiation to NEPC (LTL331R) upon host castration. Using this unique, high-fidelity, patient-derived prostate cancer xenograft models and powerful genomic and transcriptomic analyses, we have obtained evidence that therapy induced development of NEPC may result from epigenetic alterations which drives lineage plasticity of dormancy-capable cancer cells and functional evaluation of key regulators. These findings may lead to more suitable targets and better therapeutic strategies for prevention and treatment of NEPC.