Project description:Second-generation hormonal therapy inhibits castration-resistant prostate cancer (CRPC), but the tumor eventually recurs as neuroendocrine prostate cancer (NEPC) and turns lethal. With limited treatment options for advanced CRPC exhibiting an NEPC phenotype, we aimed to elucidate the mechanisms of adeno-to-neuroendocrine lineage transition to guide the development of effective therapeutic strategies. By integrating single-cell RNA sequencing data from fresh human CRPC cases, we identified three distinct neuroendocrine subtypes in CRPC: a REST-dependent subtype (NE I), an N-Myc-dependent subtype (NE II), and a combined N-Myc/REST subtype (NE I+II) among 5,797 neuroendocrine-like epithelial cells. These subtypes were validated through multiplex immunofluorescence staining. Single-cell trajectory analysis uncovered N-Myc and REST as key transcription factors driving these distinct neuroendocrine lineages, and multi-omics time course analysis of publicly available transcriptomic data further recapitulated the N-Myc and REST lineage progression. Notably, we observed PSMA loss in the N-Myc lineage and identified STMN1 as a biomarker for PSMA-negative NEPC. We further validated the prognostic value of STMN1 in the TCGA dataset and in 60 in-house CRPC tissues. Our analyses provide valuable insights into the adeno-to-neuroendocrine lineage transition in prostate cancer, offering a powerful tool for early detection of lethal NEPC phenotypes and guiding 177Lu-PSMA-617 therapy for advanced CRPC.

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:Following extensive treatment with androgen receptor (AR) pathway inhibitors, a significant number of metastatic prostate cancer develop treatment resistance, and approximately 20% of these castration-resistant prostate cancers (CRPC) transdifferentiate, at least partially, into neuroendocrine (NE) prostate cancer (NEPC).In human cancer, FOXA2 is highly expressed in most of NEPC and a small portion of CRPC patients, has been suggested as a marker of NEPC and elevated in other NE lineage cancers including SCLC. In addition, preclinical studies demonstrated that Foxa2 is required for NEPC tumor growth and metastasis in TRAMP mouse model and associated with NEPC transformation in Pten, Trp53, and Rb1 triple knockout mouse model. However, whether FOXA2 is an essential driver of NEPC, and the underlying mechanism in shaping epigenetic landscape of NEPC is largely unknown.

Project description:Following extensive treatment with androgen receptor (AR) pathway inhibitors, a significant number of metastatic prostate cancer develop treatment resistance, and approximately 20% of these castration-resistant prostate cancers (CRPC) transdifferentiate, at least partially, into neuroendocrine (NE) prostate cancer (NEPC).In human cancer, FOXA2 is highly expressed in most of NEPC and a small portion of CRPC patients, has been suggested as a marker of NEPC and elevated in other NE lineage cancers including SCLC. In addition, preclinical studies demonstrated that Foxa2 is required for NEPC tumor growth and metastasis in TRAMP mouse model and associated with NEPC transformation in Pten, Trp53, and Rb1 triple knockout mouse model. However, whether FOXA2 is an essential driver of NEPC, and the underlying mechanism in shaping epigenetic landscape of NEPC is largely unknown.

Project description:The transdifferentiation from adenocarcinoma following androgen deprivation therapy (ADT) is thought to be the primary process leading to the development of neuroendocrine prostate cancer (NEPC). However, it remains unclear how lineage factors interact with ADT to endow the lineage transition. Through an integrated analysis of NEPC-based CRISPR-Cas9 screening and scRNA-seq tracking of tumor transitions, we unveil that antiandrogen-induced ZMYND8-dependent epigenetic programming orchestrates the transdifferentiation of NEPC. We demonstrate that the ablation of Zmynd8 restricts NEPC development in Pten/Trp53/Rb1 knockout mouse models. Conversely, ASCL1-induced upregulation of ZMYND8 shapes the neuroendocrine (NE) lineage to confer resistance to AR-targeted therapy. Mechanistically, FOXM1, a key regulator in castration-resistant prostate cancer (CRPC), stabilizes ZMYND8 binding to chromatin regions harboring H3K4me1-K14ac modification and FOXM1 targeting. Antiandrogen treatment frees the SWI/SNF chromatin remodeling complex from AR, enabling its interaction with ZMYND8/FOXM1 to upregulate key NE lineage regulators (e.g., FOXA2, SOX2, and POU3F2), thus inducing transdifferentiation. Having identified ZMYND8's link to adverse disease outcomes in CRPC patients, we develop a small molecule, ZMYND8i-34, designed to selectively inhibit its histone recognition. In pre-clinical models, ZMYND8i-34 treatment effectively blocks NE transdifferentiation and curtails CRPC development. Together, our results highlight the importance of antiandrogen treatment endowing ZMYND8-dependent epigenetic reprogramming to orchestrate lineage fate and suggest that targeting ZMYND8 may hold the potential to restrict NEPC development and overcome treatment resistance.

Project description:The transdifferentiation from adenocarcinoma following androgen deprivation therapy (ADT) is thought to be the primary process leading to the development of neuroendocrine prostate cancer (NEPC). However, it remains unclear how lineage factors interact with ADT to endow the lineage transition. Through an integrated analysis of NEPC-based CRISPR-Cas9 screening and scRNA-seq tracking of tumor transitions, we unveil that antiandrogen-induced ZMYND8-dependent epigenetic programming orchestrates the transdifferentiation of NEPC. We demonstrate that the ablation of Zmynd8 restricts NEPC development in Pten/Trp53/Rb1 knockout mouse models. Conversely, ASCL1-induced upregulation of ZMYND8 shapes the neuroendocrine (NE) lineage to confer resistance to AR-targeted therapy. Mechanistically, FOXM1, a key regulator in castration-resistant prostate cancer (CRPC), stabilizes ZMYND8 binding to chromatin regions harboring H3K4me1-K14ac modification and FOXM1 targeting. Antiandrogen treatment frees the SWI/SNF chromatin remodeling complex from AR, enabling its interaction with ZMYND8/FOXM1 to upregulate key NE lineage regulators (e.g., FOXA2, SOX2, and POU3F2), thus inducing transdifferentiation. Having identified ZMYND8's link to adverse disease outcomes in CRPC patients, we develop a small molecule, ZMYND8i-34, designed to selectively inhibit its histone recognition. In pre-clinical models, ZMYND8i-34 treatment effectively blocks NE transdifferentiation and curtails CRPC development. Together, our results highlight the importance of antiandrogen treatment endowing ZMYND8-dependent epigenetic reprogramming to orchestrate lineage fate and suggest that targeting ZMYND8 may hold the potential to restrict NEPC development and overcome treatment resistance.

Project description:The transdifferentiation from adenocarcinoma following androgen deprivation therapy (ADT) is thought to be the primary process leading to the development of neuroendocrine prostate cancer (NEPC). However, it remains unclear how lineage factors interact with ADT to endow the lineage transition. Through an integrated analysis of NEPC-based CRISPR-Cas9 screening and scRNA-seq tracking of tumor transitions, we unveil that antiandrogen-induced ZMYND8-dependent epigenetic programming orchestrates the transdifferentiation of NEPC. We demonstrate that the ablation of Zmynd8 restricts NEPC development in Pten/Trp53/Rb1 knockout mouse models. Conversely, ASCL1-induced upregulation of ZMYND8 shapes the neuroendocrine (NE) lineage to confer resistance to AR-targeted therapy. Mechanistically, FOXM1, a key regulator in castration-resistant prostate cancer (CRPC), stabilizes ZMYND8 binding to chromatin regions harboring H3K4me1-K14ac modification and FOXM1 targeting. Antiandrogen treatment frees the SWI/SNF chromatin remodeling complex from AR, enabling its interaction with ZMYND8/FOXM1 to upregulate key NE lineage regulators (e.g., FOXA2, SOX2, and POU3F2), thus inducing transdifferentiation. Having identified ZMYND8's link to adverse disease outcomes in CRPC patients, we develop a small molecule, ZMYND8i-34, designed to selectively inhibit its histone recognition. In pre-clinical models, ZMYND8i-34 treatment effectively blocks NE transdifferentiation and curtails CRPC development. Together, our results highlight the importance of antiandrogen treatment endowing ZMYND8-dependent epigenetic reprogramming to orchestrate lineage fate and suggest that targeting ZMYND8 may hold the potential to restrict NEPC development and overcome treatment resistance.

Project description:The transdifferentiation from adenocarcinoma following androgen deprivation therapy (ADT) is thought to be the primary process leading to the development of neuroendocrine prostate cancer (NEPC). However, it remains unclear how lineage factors interact with ADT to endow the lineage transition. Through an integrated analysis of NEPC-based CRISPR-Cas9 screening and scRNA-seq tracking of tumor transitions, we unveil that antiandrogen-induced ZMYND8-dependent epigenetic programming orchestrates the transdifferentiation of NEPC. We demonstrate that the ablation of Zmynd8 restricts NEPC development in Pten/Trp53/Rb1 knockout mouse models. Conversely, ASCL1-induced upregulation of ZMYND8 shapes the neuroendocrine (NE) lineage to confer resistance to AR-targeted therapy. Mechanistically, FOXM1, a key regulator in castration-resistant prostate cancer (CRPC), stabilizes ZMYND8 binding to chromatin regions harboring H3K4me1-K14ac modification and FOXM1 targeting. Antiandrogen treatment frees the SWI/SNF chromatin remodeling complex from AR, enabling its interaction with ZMYND8/FOXM1 to upregulate key NE lineage regulators (e.g., FOXA2, SOX2, and POU3F2), thus inducing transdifferentiation. Having identified ZMYND8's link to adverse disease outcomes in CRPC patients, we develop a small molecule, ZMYND8i-34, designed to selectively inhibit its histone recognition. In pre-clinical models, ZMYND8i-34 treatment effectively blocks NE transdifferentiation and curtails CRPC development. Together, our results highlight the importance of antiandrogen treatment endowing ZMYND8-dependent epigenetic reprogramming to orchestrate lineage fate and suggest that targeting ZMYND8 may hold the potential to restrict NEPC development and overcome treatment resistance.

Project description:Neuroendocrine prostate cancer (NEPC) is a lethal subtype of prostate cancer (PCa) with hyperchromatic nuclei being a distinguishing histopathological feature. Here we show that, underlying this distinct nuclear structure, heterochromatin related genes are significantly enriched in NEPC. Among them, heterochromatin protein 1α (HP1α) expression is increased early in NE transdifferentiation and is consistently elevated in clinical NEPC samples. Functional studies showed that HP1α knockdown attenuates NEPC tumor growth by inhibiting proliferation and survival. Its ectopic expression significantly promotes NE transdifferentiation in adenocarcinoma cells subjected to androgen deprivation treatment. To identify mechanisms underlying the function of HP1α involved in NEPC cell proliferation and adenocarcinoma cell NE transdifferentiation, we analyzed gene expression profiles from stable NEPC cell lines with control or HP1α knockdown, and adenocarcinoma cell lines with control or HP1α overexpression, respectively.