Project description:Treatment-induced neuroendocrine transdifferentiation (NEtD) complicates therapies for metastatic prostate cancer (PCa). We propose that NEtD requires first an intermediary reprogramming to metastable cancer stem-like cells (CSCs) and showed that AR+/PSA+ PCa cell lines were efficiently reprogrammed to and maintained as CSCs by growth in androgen-free neural/neural crest (N/NC) stem medium. Such reprogrammed CSCs overexpressed stem genes, had features of N/NC stem cells, high tumor-initiating potential, resistance to anti-androgen and an EMT phenotype. Serum-containing mediums allowed re-differentiation to N-/NC-derived cell lineages or return back to PCa-like cancer cells. Once returned, the cells had increased resistance to androgen signaling inhibition. Finally, a 62-gene signature derived from reprogrammed PCa cell lines distinguished tumors from PCa patients with adverse outcomes. Gene expression profiles were obtained for RNAs extracted from biological replicates of parental LNCaP cells or from Neuroendocrine-like LNCaP (LNCaP-NE) cells grown for 15 days in CSS-media with no androgen.

Project description:Treatment-induced neuroendocrine transdifferentiation (NEtD) complicates therapies for metastatic prostate cancer (PCa). We propose that NEtD requires first an intermediary reprogramming to metastable cancer stem-like cells (CSCs) and showed that AR+/PSA+ PCa cell lines were efficiently reprogrammed to and maintained as CSCs by growth in androgen-free neural/neural crest (N/NC) stem medium. Such reprogrammed CSCs overexpressed stem genes, had features of N/NC stem cells, high tumor-initiating potential, resistance to anti-androgen and an EMT phenotype. Serum-containing mediums allowed re-differentiation to N-/NC-derived cell lineages or return back to PCa-like cancer cells. Once returned, the cells had increased resistance to androgen signaling inhibition. Finally, a 62-gene signature derived from reprogrammed PCa cell lines distinguished tumors from PCa patients with adverse outcomes. To compare gene expression between parental PCa cells and STM-reprogrammed cells (LNCaP, VCaP, CWR-22rv1 and LAPC4), RNAs from biological triplicate samples of parental cells and corresponding STM-reprogrammed cells (>14 days in STM) were extracted.

Project description:Treatment-induced neuroendocrine transdifferentiation (NEtD) complicates therapies for metastatic prostate cancer (PCa). Based on evidence that PCa cells can transdifferentiate to other neuroectodermally-derived cell lineages in vitro, we proposed that NEtD requires first an intermediary reprogramming to metastable cancer stem-like cells (CSCs) of a neural class and we demonstrate that several different AR+/PSA+ PCa cell lines were efficiently reprogrammed to, maintained and propagated as CSCs by growth in androgen-free neural/neural crest (N/NC) stem medium. Such reprogrammed cells lost features of prostate differentiation; gained features of N/NC stem cells and tumor-initiating potential; were resistant to androgen signaling inhibition; and acquired an invasive phenotype in vitro and in vivo. When placed back into serum-containing mediums, reprogrammed cells could be re-differentiated to N-/NC-derived cell lineages or return back to an AR+ prostate-like state. Once returned, the AR+ cells were resistant to androgen signaling inhibition. Acute androgen deprivation or anti-androgen treatment in serum-containing medium led to the transient appearance of a sub-population of cells with similar characteristics. Finally, a 132 gene signature derived from reprogrammed PCa cell lines distinguished tumors from PCa patients with adverse outcomes. This model may explain neural manifestations of PCa associated with lethal disease. The metastable nature of the reprogrammed stem-like PCa cells suggests that cycles of PCa cell reprogramming followed by re-differentiation may support disease progression and therapeutic resistance. The ability of a gene signature from reprogrammed PCa cells to identify tumors from patients with metastasis or PCa-specific mortality implies that developmental reprogramming is linked to aggressive tumor behaviors.

Project description:Androgen receptor (AR) is a master transcription factor that drives prostate cancer (PCa) development and progression. Alterations in the expression or activity of AR coregulators significantly impact the disease's outcome. To identify all the essential components of the AR coregulator complex, we utilized a proteomic approach called rapid immunoprecipitation of endogenous proteins (RIME) to systematically identify all coregulator proteins of the AR interactome in PCa cells.

Project description:Prostate cancer (PCa) is the most frequently diagnosed cancer in Canadian men and is the third cause of cancer mortality. PCa initiation and growth is driven by the androgen receptor (AR). AR is activated by androgens such as testosterone and controls prostatic cell proliferation and survival. We sought to characterize global AR signalling networks. We performed BioID proximity labeling proteomics in androgen-dependent LAPC4 cells to delineate AR protein interaction networks. We report the identification of 32 AR associated proteins in non-stimulated cells. Strikingly, the AR signalling network increased to 183 and 201 proteins, upon 24h or 72h androgenic stimulation, respectively. Among this group, we identified 215 proteins that were not previously reported as AR interactors. Interestingly, these AR associated proteins were previously reported to be involved in DNA metabolism, RNA processing and RNA polymerase II transcription. Moreover, we identified 44 transcription factors, such as the Krüppel-like factor 4 (KLF4), which was specifically revealed in androgen-stimulated cells. We determined that KLF4 acts as a repressor of AR target genes transcription in PCa cells. Taken together, our data report the largest high-confidence proximity networks for AR in PCa cells.

Project description:Androgen receptor (AR) signaling remains the key therapeutic target in the management of hormone-naïve advanced prostate cancer (PCa) and castration-resistant PCa (CRPC). Recently, landmark molecular features have been reported for CRPC, including the expression of constitutively active AR variants that lack the ligand-binding domain. Besides their role in CRPC, AR variants lead to the expression of genes involved in tumor progression. However, little is known about the specificity of their mode of action compared with that of wild-type AR (AR-WT). We performed AR transcriptome analyses in an androgen-dependent PCa cell line as well as cross-analyses with publicly available RNA-seq dataset and established that transcriptional repression capacity that was marked for AR-WT was pathologically lost by AR variants. Functional enrichment analyses allowed us to associate AR-WT repressive function to a panel of genes involved in cell adhesion and epithelial-to-mesenchymal transition. So, we postulate that a less documented AR-WT normal function in prostate epithelial cells could be the repression of a panel of genes linked to cell plasticity, and that this repressive function could be pathologically abrogated by AR variants in PCA.

Project description:Androgen receptor (AR) signaling remains the key therapeutic target in the management of hormone-naïve advanced prostate cancer (PCa) and castration-resistant PCa (CRPC). Recently, landmark molecular features have been reported for CRPC, including the expression of constitutively active AR variants that lack the ligand-binding domain. Besides their role in CRPC, AR variants lead to the expression of genes involved in tumor progression. However, little is known about the specificity of their mode of action compared with that of wild-type AR (AR-WT). We performed AR transcriptome analyses in an androgen-dependent PCa cell line as well as cross-analyses with publicly available RNA-seq dataset and established that transcriptional repression capacity that was marked for AR-WT was pathologically lost by AR variants. Functional enrichment analyses allowed us to associate AR-WT repressive function to a panel of genes involved in cell adhesion and epithelial-to-mesenchymal transition. So, we postulate that a less documented AR-WT normal function in prostate epithelial cells could be the repression of a panel of genes linked to cell plasticity, and that this repressive function could be pathologically abrogated by AR variants in PCA.

Project description:Prostate carcinogenesis is associated with changes in androgen signaling from driving cellular differentiation to promoting oncogenic behaviors. RUNX2 binds the androgen receptor (AR), and ectopic expression of RUNX2 is linked to prostate cancer (PCa) progression. We therefore investigated genome-wide the influence of RUNX2 on androgen-induced gene expression and AR DNA binding in PCa cells. The predominant function of RUNX2 is to inhibit the androgen response, attributable in part to dissociation of AR from target genes such as the tumor suppressor NKX3-1. At a minority of AR target genes, however, AR activity persists in the presence of RUNX2. Some of these genes are co-operatively stimulated by androgen and RUNX2 signaling and are characterized by the presence of putative enhancers co-occupied by AR and RUNX2. Genes synergistically stimulated by AR and RUNX2 include the invasion-promoting transcription factor SNAI2. Indeed, co-activation of AR and RUNX2, but neither alone, stimulated PCa cell invasiveness, which was abolished by SNAI2 silencing. Accordingly, PCa biopsies most strongly stained for SNAI2 exhibit high nuclear expression of both RUNX2 and AR. The RUNX2-mediated locus-dependent modulation of AR activity in PCa opens a research avenue that may guide the development of novel diagnostic and therapeutic approaches to patient management. total RNA from C4-2B/Rx2dox cells was extracted in biological triplicates from four different conditions. Ethanol vehicle control, dox to induce RUNX2 expression, DHT to activate androgen receptor and DHT+dox combined.

Project description:The androgen receptor (AR) plays a key role in progression to incurable androgen-ablation resistant prostate cancer (PCA). We have identified three novel AR splice variants lacking the ligand binding domain (designated as AR3, AR4 and AR5) in hormone insensitive PCA cells. AR3, one of the major splice variants expressed in human prostate tissues, is constitutively active and its transcriptional activity is not regulated by androgens or antiandrogens. Immunohistochemistry analysis on tissue microarrays containing 429 human prostate tissue samples shows that AR3 is significantly upregulated during PCA progression and AR3 expression level is correlated with the risk of tumor recurrence after radical prostatectomy. Overexpression of AR3 confers ablation-independent growth of PCA cells while specific knock-down of AR3 expression (without altering AR level) in hormone resistant PCA cells attenuates their growth under androgen-depleted conditions in both cell culture and xenograft models, suggesting an indispensable role of AR3 in ablation-independent growth of PCA cells. Furthermore, AR3 may play a distinct yet essential role in ablation-independent growth through regulating a unique set of genes including AKT1, which are not regulated by the prototype AR. Our data suggest that aberrant expression of AR splice variants may be a novel mechanism underlying ablation-independence during PCA progression and AR3 may serve as a prognostic marker to predict patient outcome in response to hormonal therapy. Given that these novel AR splice variants are not inhibited by currently available anti-androgen drugs, development of new drugs targeting these AR isoforms may potentially be effective for treatment of ablation-resistant PCA. Total RNA was extracted from CWR-R1 and 22Rv1 cells treated with shAR3-1, shARa and the scrambled shRNA control, respectively. Each of CWR-R1 and 22Rv1 cells treated with shAR3-1 was compared with the scrambled shRNA control. The same experiments were performed for the cells treated with shARa.

Project description:Prostate carcinogenesis is associated with changes in androgen signaling from driving cellular differentiation to promoting oncogenic behaviors. RUNX2 binds the androgen receptor (AR), and ectopic expression of RUNX2 is linked to prostate cancer (PCa) progression. We therefore investigated genome-wide the influence of RUNX2 on androgen-induced gene expression and AR DNA binding in PCa cells. The predominant function of RUNX2 is to inhibit the androgen response, attributable in part to dissociation of AR from target genes such as the tumor suppressor NKX3-1. At a minority of AR target genes, however, AR activity persists in the presence of RUNX2. Some of these genes are co-operatively stimulated by androgen and RUNX2 signaling and are characterized by the presence of putative enhancers co-occupied by AR and RUNX2. Genes synergistically stimulated by AR and RUNX2 include the invasion-promoting transcription factor SNAI2. Indeed, co-activation of AR and RUNX2, but neither alone, stimulated PCa cell invasiveness, which was abolished by SNAI2 silencing. Accordingly, PCa biopsies most strongly stained for SNAI2 exhibit high nuclear expression of both RUNX2 and AR. The RUNX2-mediated locus-dependent modulation of AR activity in PCa opens a research avenue that may guide the development of novel diagnostic and therapeutic approaches to patient management.