Project description:Androgens drive the onset and progression of prostate cancer (PCa) by modulating androgen receptor (AR) transcriptional activity. Although several microarray-based studies have identified androgen-regulated genes, here we identify in-parallel global androgen-dependent changes in both gene and alternative mRNA isoform expression by exon-level analyses of the LNCaP transcriptome. While genome-wide gene expression changes correlated well with previously-published studies, we additionally uncovered a subset of 226 novel androgen-regulated genes. Gene expression pathway analysis of this subset revealed gene clusters associated with, and including the tyrosine kinase LYN, as well as components of the mTOR (mammalian target of rapamycin) pathway, which is commonly dysregulated in cancer. We also identified 1279 putative androgen-regulated alternative events, of which 325 (~25%) mapped to known alternative splicing events or alternative first/last exons. We selected 30 androgen-dependent alternative events for RT-PCR validation, including mRNAs derived from genes encoding tumour suppressors and cell cycle regulators. Of seven positively-validating events (~23%), five events involved transcripts derived from known AR gene targets. In particular, we found a novel androgen-dependent mRNA isoform derived from an alternative internal promoter within the TSC2 tumour suppressor gene, which is predicted to encode a protein lacking an interaction domain required for mTOR inhibition. We confirmed that expression of the alternative TSC2 mRNA isoform was directly regulated by androgens. Furthermore, by chromatin immunoprecipitation, we observed recruitment of AR to the alternative promoter region at early timepoints following androgen stimulation, which correlated with expression of alternative transcripts. Together, our data suggest that alternative mRNA isoform expression might mediate the cellular response to androgens, and may have roles in clinical PCa. Total 8 samples were analysed. 4 control (LNCaP cells grown in RPMI-1640 media with charcoal-stripped 10% FBS devoid of steroids) and 4 treatment (LNCaP cells grown in media devoid of steroid, and subsequently treated with 10nM R1881 synthetic androgen analogue for 24 hours).

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:The catalytic subunit of the human telomerase (hTERT) is activated during tumorigenesis in many cancers including prostate cancer (PCa). Androgens mediate their effect through the androgen receptor (AR), a key factor controlling PCa growth. hTERT expression is known to be regulated by androgens, however contrarily observed to be inhibited or activated. Here, we reveal that androgens repress or activate hTERT expression in a concentration-dependent manner. Low physiological androgen levels activate while supraphysiological androgen levels (SAL) repress hTERT expression. We confirmed SAL-mediated gene repression of hTERT in native human PCa samples derived from patients treated ex vivo as well as in cancer spheroids derived from androgen-dependent and castration resistant PCa (CRPC) cells. Interestingly, based on chromatin immunoprecipitation (ChIP) data both a positive androgen response element (pARE) at -4kb distal and a negative response element (nARE) at the proximal -0.1kb promoter region were identified. Focusing on the nARE it was narrowed down to -121 to -58 bp in the core promoter region. ChIP experiments confirmed an androgen-dependent recruitment of AR and the tumor suppressors inhibitor of growth 1 and 2 (ING1 and ING2), recently identified as AR co-repressors. Mechanistically, the knockdown of either ING1 or ING2 reduced androgen-mediated repression of hTERT indicating that ING1 and ING2 mediate AR-regulated transrepression on the hTERT expression. Thus, our data suggest a dual, biphasic function of AR to control hTERT expression by transactivation and transrepression. The inhibition of hTERT by androgens by a nARE located in the proximal promoter region is mediated at least in part by the AR co-repressors ING1 and ING2.

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: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.

Project description:Growing studies support a direct role for nuclear mTOR in gene regulation and chromatin structure. Still, the scarcity of known chromatin-bound mTOR partners limits our understanding of how nuclear mTOR controls transcription. Herein, we comprehensively mapped the mTOR chromatin-bound interactome in four cellular models of prostate cancer (PCa) identifying a conserved 67-protein interaction network enriched for epigenetic and transcription factors as well as SUMOylation machinery in both androgen-dependent and -independent cells. Notably, SUMO2/3 and nuclear pore protein NUP210 are among the strongest interactors while the androgen receptor (AR) is the dominant androgen-inducible mTOR partner. Further investigation showed that NUP210 facilitates mTOR nuclear trafficking, that mTOR, AR and NuRD act as a functional transcriptional complex, and that androgens dictate mTOR-SUMO2/3 promoter-enhancer specificity. This work identifies a vast network of mTOR-associated nuclear complexes advocating novel molecular strategies to modulate mTOR-dependent gene regulation with evident implications for PCa and other diseases.

Project description:Androgens are central to prostate cancer (PCa) development and targeting this pathway is currently the main therapeutic axis in the clinic, but the mechanism by which androgen signaling contributes to the oncometabolic state of PCa cells remains to be fully elucidated. The intersection of gene expression, binding-events and motif finding analyses following androgen exposure identified a metabolic gene signature associated with the action of estrogen-related receptors (ERRs). Unexpectedly, we show that ERRγ acts as a negative regulator of mitochondrial respiration in the context of PCa, and that AR-dependent direct repression of ERRγ promotes the reactivation of a functional TCA cycle. This metabolic state, which parallels the loss of ERRγ expression, was observed in both androgen-dependent and castration-resistant PCa and was associated with cell proliferation. Interrogation of several clinical studies revealed a strong inverse relationship between ERRγ expression and the severity of the disease. Our study uncovers a novel mechanism by which AR-dependent repression of ERRγ contributes to the reprogramming of PCa cell metabolism to favor mitochondrial activity and cell proliferation. We used microarrays to investigate the transcriptional regulation of metabolic genes by 72h treatment with R1881, a synthetic androgens, with or without repression of the estrogen-related receptor gamma, in LNCaP prostate cancer cells.

Project description:Our previous studies of proteomic-coupled-network analysis of AR protein interaction complexes (Paliouras et al., Integrative Biology, 2011) identified a number of proteins involved in RNA metabolism, specifically alternative RNA splicing. We selected two interacting RNA splicing proteins, SAM68 and DDX5 to examine RNA splicing events in prostate cancer (PCa). This analysis suggests a much more robust effect on RNA splicing with AR dictating either an exon-inclusion or -exclusion pathway. To establish the true physiological roles of AR in alternative RNA splicing, we opted to further examine the changes in global splicing profiles of LNCaP PCa cells, stimulated with and without androgens in conjunction with overexpression studies of SAM68 and DDX5.

Project description:Whether the nuclear fraction of mTOR plays a role in prostate cancer (PCa) and can participate in direct transcriptional crosstalk with the androgen receptor (AR) is as yet unknown. The intersection of gene expression, DNA binding-events, and metabolic studies uncovered the existence of a nuclear mTOR-AR transcriptional axis dictating the metabolic rewiring and nutrient usage of PCa cells. In human clinical specimens, nuclear localization of mTOR was significantly associated with metastasis and castration-resistant PCa (CRPC), correlating with a sustained metabolic gene program governed by mTOR in that context. This study thus uncovers an unexpected function of mTOR and underscores a paradigm shift from AR to mTOR as being the master transcriptional regulator of cell metabolism during PCa progression. We used microarrays to investigate the role of nuclear mTOR in prostate cancer cell transcriptional regulation by androgens in LNCaP cells.

Project description:The development and progression of castrate resistant prostate cancer (CRPC), a lethal disease, is thought to be driven by multiple events. A hallmark of CRPC is the ability to evade the cytotoxic effects of anti-androgen therapy. Importantly, persistent androgen receptor (AR) signalling is thought to play a principal role in maintaining CRPC. The precise molecular alterations driving this condition, however, are not clearly understood. Our previous studies identified specific metabolic alterations associated with localized prostate cancer (PCa) and CRPC, implicating metabolic re-programming in disease progression. Building on these findings, using a novel network-based integromics approach, here we show distinct alterations in the Hexosamine Biosynthetic Pathway (HBP) to be critical for sustaining the castrate resistant state. We found expression of the HBP enzyme glucosamine-phosphate N-acetyltransferase 1 (GNPNAT1) was regulated by androgens and elevated in androgen dependent (AD) PCa while relatively diminished in CRPC possessing either full length AR (AR-FL) or the spliced V7 variant (AR-V7). Genetic loss of function experiments for GNPNAT1 in CRPC-like cells led to increased proliferation and aggressiveness, both, in vitro and in vivo. This was mediated by specific cell cycle genes regulated by the PI3K-AKT pathway activating either AR in cells with AR-FL or SP1-ChREBP (carbohydrate response element binding protein) in cells containing AR-V7. Strikingly, addition of HBP metabolite UDP-N-acetylglucosamine (UDP) to CRPC-like cells reduced the expression of cell cycle genes and attenuated tumor cell proliferation, both in vitro and in vivo. Furthermore, addition of UDP sensitized CRPC-like cells, inclusive of those possessing AR-V7, to enzalutamide, demonstrating the therapeutic value of targeting altered metabolic pathways in lethal PCa. We anticipate that our findings will motivate the development of novel metabolic therapeutic strategies that complement existing treatments for men with lethal prostate cancer We used microarray analysis to determine key molecular alterations associated with inhibition of HBP pathway in CRPC by knocking down GNPNAT1 transcript level using lentiviral particle bearing shRNA in 22Rv1 and LNCaP-ABL cells GNPNAT1 expression was knockdown in two independent prostate cancer cells, 22Rv1 and LNCaP-ABL