Project description:Advanced prostate cancer (PrCa) remains a leading cause of cancer-related death among men because nearly all patients progress on standard therapy that targets androgen receptor (AR) signaling. An important mechanism driving therapeutic resistance is lineage plasticity, the ability of PrCa cells to reprogram into AR independent lineage variants like neuroendocrine (NE) PrCa. The histone methyltransferase EZH2 has been implicated in PrCa lineage plasticity and EZH2 inhibitors are being evaluated clinically for the treatment of PrCa. Here we test how Ezh2 impacts the evolution of PrCa lineage plasticity using genetically engineered mice and human patient data. Ezh2 deficiency in mice diversifies the evolution of PrCa lineage variants, including a newly discovered variant with high expression of neurofilament genes. Analogous PrCa lineage variants are detectable in human specimens where they similarly correlate with EZH2 expression. Lineage variant diversification is associated with activation of transcription factor programs and AR cistrome reprogramming that is normally repressed by Ezh2. These findings advance the understanding of PrCa lineage plasticity and have implications for targeting EZH2 as a PrCa therapy.

Project description:Advanced prostate cancer (PrCa) remains a leading cause of cancer-related death among men because nearly all patients progress on standard therapy that targets androgen receptor (AR) signaling. An important mechanism driving therapeutic resistance is lineage plasticity, the ability of PrCa cells to reprogram into AR independent lineage variants like neuroendocrine (NE) PrCa. The histone methyltransferase EZH2 has been implicated in PrCa lineage plasticity and EZH2 inhibitors are being evaluated clinically for the treatment of PrCa. Here we test how Ezh2 impacts the evolution of PrCa lineage plasticity using genetically engineered mice and human patient data. Ezh2 deficiency in mice diversifies the evolution of PrCa lineage variants, including a newly discovered variant with high expression of neurofilament genes. Analogous PrCa lineage variants are detectable in human specimens where they similarly correlate with EZH2 expression. Lineage variant diversification is associated with activation of transcription factor programs and AR cistrome reprogramming that is normally repressed by Ezh2. These findings advance the understanding of PrCa lineage plasticity and have implications for targeting EZH2 as a PrCa therapy.

Project description:Advanced prostate cancer (PrCa) remains a leading cause of cancer-related death among men because nearly all patients progress on standard therapy that targets androgen receptor (AR) signaling. An important mechanism driving therapeutic resistance is lineage plasticity, the ability of PrCa cells to reprogram into AR independent lineage variants like neuroendocrine (NE) PrCa. The histone methyltransferase EZH2 has been implicated in PrCa lineage plasticity and EZH2 inhibitors are being evaluated clinically for the treatment of PrCa. Here we test how Ezh2 impacts the evolution of PrCa lineage plasticity using genetically engineered mice and human patient data. Ezh2 deficiency in mice diversifies the evolution of PrCa lineage variants, including a newly discovered variant with high expression of neurofilament genes. Analogous PrCa lineage variants are detectable in human specimens where they similarly correlate with EZH2 expression. Lineage variant diversification is associated with activation of transcription factor programs and AR cistrome reprogramming that is normally repressed by Ezh2. These findings advance the understanding of PrCa lineage plasticity and have implications for targeting EZH2 as a PrCa therapy.

Project description:Prostate cancer relapsing from antiandrogen therapies can exhibit variant histology with altered lineage marker expression, suggesting lineage plasticity facilitates therapeutic resistance. Mechanisms underlying prostate cancer lineage plasticity are unknown, and relevant experimental models are needed. We demonstrate Rb1 loss facilitates lineage plasticity and metastasis of prostate adenocarcinoma initiated by Pten mutation in the mouse. Additional loss of Trp53 causes resistance to antiandrogen therapy. Gene expression profiling indicates mouse tumors are comparable to human prostate cancer neuroendocrine variants; both mouse and human tumors exhibit increased expression of epigenetic reprogramming factors like Ezh2 and Sox2. Clinically relevant Ezh2 inhibitors restore androgen receptor expression and sensitivity to antiandrogen therapy. These findings uncover genetic mutations enabling prostate cancer progression, identify mouse models for studying prostate cancer lineage plasticity, and suggest an epigenetic approach for extending clinical responses to antiandrogen therapy.

Project description:Prostate cancer (PrCa) manifests substantial variation in incidence rates among distinct populations. African American (AA) men are more likely to be diagnosed with and die from PrCa than European American (EA) men. Despite ongoing advancements in identifying polygenic risk variants from large genome-wide association study (GWAS) cohorts, the genetic mechanisms underlying the higher prevalence of PrCa in AA men remain unclear. A systematic approach that does not rely on extensive cohorts to identify causal regulatory variants contributing to PrCa development is still lacking. Here, by employing a sequence-based deep learning model of prostate regulatory enhancers, we identified ~2,000 essential SNPs (eSNPs) with increased alternative allele frequency in AA and which potentially affect the enhancer function leading to greater PrCa susceptibility. The identified eSNPs potentially mediate PrCa development through two complementary mechanisms: alternative alleles with increased enhancer activity are associated with immune system suppression, while those with decreased enhancer activity are linked to differentiation processes. Interestingly, the eSNPs disrupt the binding of key prostate transcription factors including FOX, AR and HOX families, collectively contributing to PrCa predisposition. Together these eSNPs can be used to assess polygenic risk score that is more effective than previous GWAS-based risk scores in distinguishing individuals with PrCa from the control.

Project description:In castration-resistant prostate cancer (CRPC), clinical response to androgen receptor (AR) antagonists is limited mainly due to AR-variants expression and restored AR signaling. The metabolite spermine is most abundant in prostate and it decreases as prostate cancer progresses, but its functions remain poorly understood. Here, we show spermine inhibits full-length androgen receptor (AR-FL) and androgen receptor splice variant 7 (AR-V7) signaling and suppresses CRPC cell proliferation by directly binding and inhibiting protein arginine methyltransferase PRMT1. Spermine reduces H4R3me2a modification at the AR locus and suppresses AR binding as well as H3K27ac modification levels at AR target genes. Spermine supplementation restrains CRPC growth in vivo. PRMT1 inhibition also suppresses AR-FL and AR-V7 signaling and reduces CRPC growth. Collectively, we demonstrate spermine as an anticancer metabolite by inhibiting PRMT1 to transcriptionally inhibit AR-FL and AR-V7 signaling in CRPC, and we indicate spermine and PRMT1 inhibition as powerful strategies overcoming limitations of current AR-based therapies in CRPC.

Project description:Enhancer of Zeste Homolog 2 (EZH2) and androgen receptor (AR) are both crucial for the development and progression of prostate tumor, including advanced castration-resistant prostate cancer (CRPC). Previously, it was reported that, in order to sustain tumorigenicity of prostate cancer, EZH2 has noncanonical functions in interaction with AR for mediating gene activation, in addition to its canonical role as a transcriptional repressor and enzymatic subunit of Polycomb Repressive Complex 2 (PRC2). However, the molecular basis underlying non-canonical activities of EZH2 in prostate cancer remains far from clear, and therapeutic strategies for targeting EZH2:AR-mediated gene-activation activities are also lacking. Here, we report that a hidden transactivation domain of EZH2 (EZH2TAD) binds both AR and AR’s variants enriched in CRPCs, notably AR splice variant 7 (AR-V7), mediating the assembly and/or recruitment of a gene-activation-related complex at genomic sites that lack PRC2 binding. Such noncanonical targets of EZH2:AR/AR-V7:(co)activators are enriched for the clinically-relevant prostate oncogenes. EZH2TAD is crucial for EZH2-mediated transactivation of oncogenes and for CRPC growth in vitro and in vivo. To completely block EZH2’s multifaceted oncogenic activities in prostate cancer, we employed MS177, a recently developed proteolysis targeting chimera (PROTAC) of EZH2. MS177 achieved on-target depletion of both EZH2’s canonical (EZH2:PRC2) and noncanonical (EZH2TAD:AR/AR-V7:coactivators) complexes in prostate tumor, eliciting much more potent antitumor effects than the existing catalytic inhibitors of EZH2. Overall, this study reports previously unappreciated requirements of EZH2TAD for mediating EZH2’s noncanonical recruitment and gene-activation functions in prostate tumor and suggests EZH2-targeting PROTACs as potentially attractive therapeutics for the treatment of aggressive prostate tumors that reply on circuits wired by EZH2 and AR.

Project description:Enhancer of Zeste Homolog 2 (EZH2) and androgen receptor (AR) are both crucial for the development and progression of prostate tumor, including advanced castration-resistant prostate cancer (CRPC). Previously, it was reported that, in order to sustain tumorigenicity of prostate cancer, EZH2 has noncanonical functions in interaction with AR for mediating gene activation, in addition to its canonical role as a transcriptional repressor and enzymatic subunit of Polycomb Repressive Complex 2 (PRC2). However, the molecular basis underlying non-canonical activities of EZH2 in prostate cancer remains far from clear, and therapeutic strategies for targeting EZH2:AR-mediated gene-activation activities are also lacking. Here, we report that a hidden transactivation domain of EZH2 (EZH2TAD) binds both AR and AR’s variants enriched in CRPCs, notably AR splice variant 7 (AR-V7), mediating the assembly and/or recruitment of a gene-activation-related complex at genomic sites that lack PRC2 binding. Such noncanonical targets of EZH2:AR/AR-V7:(co)activators are enriched for the clinically-relevant prostate oncogenes. EZH2TAD is crucial for EZH2-mediated transactivation of oncogenes and for CRPC growth in vitro and in vivo. To completely block EZH2’s multifaceted oncogenic activities in prostate cancer, we employed MS177, a recently developed proteolysis targeting chimera (PROTAC) of EZH2. MS177 achieved on-target depletion of both EZH2’s canonical (EZH2:PRC2) and noncanonical (EZH2TAD:AR/AR-V7:coactivators) complexes in prostate tumor, eliciting much more potent antitumor effects than the existing catalytic inhibitors of EZH2. Overall, this study reports previously unappreciated requirements of EZH2TAD for mediating EZH2’s noncanonical recruitment and gene-activation functions in prostate tumor and suggests EZH2-targeting PROTACs as potentially attractive therapeutics for the treatment of aggressive prostate tumors that reply on circuits wired by EZH2 and AR.

Project description:The goal of this experiment was to compare the gene expression programs mediated by androgen/AR vs. constitutively active, truncated AR variants in castration-resistant CWR-R1 prostate cancer cells. Because constitutive activity of truncated AR variants can mask androgen/AR target genes, the androgen/AR transcriptional program was assessed by silencing the trucnated AR 1/2/3/CE3 variant with siRNA targeting AR exon CE3 and treating cells with vehicle (ethanol) or 1nM DHT. Similarly, because full-length AR activity can mask truncated AR variant target genes, the AR variant transcriptional program was assessed under castrate conditions by selectively silencing full-length AR with siRNA targeting AR exon 7, and comparing this profile with CWR-R1 cells transfected wtih siRNA targeting AR exon 1, which silences all AR expression (full-length and truncated AR variants).

Project description:The goal of this experiment was to compare the gene expression programs mediated by androgen/AR vs. constitutively active, truncated AR variants in castration-resistant CWR-R1 prostate cancer cells. Because constitutive activity of truncated AR variants can mask androgen/AR target genes, the androgen/AR transcriptional program was assessed by silencing the trucnated AR 1/2/3/CE3 variant with siRNA targeting AR exon CE3 and treating cells with vehicle (ethanol) or 1nM DHT. Similarly, because full-length AR activity can mask truncated AR variant target genes, the AR variant transcriptional program was assessed under castrate conditions by selectively silencing full-length AR with siRNA targeting AR exon 7, and comparing this profile with CWR-R1 cells transfected wtih siRNA targeting AR exon 1, which silences all AR expression (full-length and truncated AR variants). CWR-R1 cells were maintained under castrate conditions in long term culture in order to enrich for the population of cells harboring a 48kb intragenic deletion in AR intron 1. These late-passage CWR-R1 cells were electroporated with siRNAs targeting AR exon 1, AR exon 7, or AR exon CE3. Electroporated cells were seeded in RPMI 1640 medium containing antibiotics and 5% charcoal-stripped, steroid-depleted medium and allowed to recover for 48h. After this 48h recovery, electroporated cells were switched to serum-free RPMI 1640 with 1nM DHT or 0.1% ethanol (vehicle control) for an additional 24h prior to extraction of total RNA. Three independent biological replicates were performed.