Project description:Due to the urgent need of new targeting strategies in PCa, AR interacting proteins should be considered. In this study we aimed to test the effect of a long-term knockdown of NCOA1, an AR coactivator, in PCa progression and metastatogenesis and whether NCOA1 could be used as a possible therapeutic target. To test the consequences of NCOA1 knockdown on proliferation, we performed by 3H thymidine incorporation assays revealing a strong reduction in castration resistant MDA PCa 2b and androgen-dependent LNCaP cells, without affecting AR negative PC3 cells. Furthermore, Boyden chamber assays revealed a strong decrease in migration and invasion upon NCOA1 knockdown. Using a cDNA microarray, we identified protein kinase D1 (PRKD1) as one prominent upregulated gene in MDA PCa 2b, which was not seen in PC3 cells. Knockdown of PRKD1 clearly reverted the reduced migratory potential. Moreover, we found phospholipase A2, group7 (PLA2G7) and eukaryotic translation initiation factor 5A2 (EIF5A2), which might be involved in migration of PC3 cells. Further, we can clearly demonstrate that PRKD1 is negatively regulated by the AR/NCOA1 complex. In addition, immunhistochemical staining revealed a strong increase in NCOA1 expression in matched and unmatched patients’ samples, respectively between normal prostate and primary tumor. Regarding the PRKD1 staining, no final conclusion can be drawn in terms of a tumor suppressor function. Thus, our findings directly associate NCOA1/AR complex with PRKD1 regulation and further suggest NCOA1 as a potential therapeutic target also due to the effect on PC3 cell migration. Cell lines with a stable knockdown of NCOA1 were generated by lentiviral-based transduction of shRNA vectors. For each of the two cell lines MDA and PC3, gene expression profiles were generated for KO and CTRL samples with 3 biological replicates for each. Differential expression analysis was performed by comparing the gene expression estimates between KO and CTRL samples for each cell line.

Project description:Background: Breast (BCa) and prostate (PCa) cancers are hormone receptor (HR)-driven cancers. Estrogen receptor alpha (ERa) is overexpressed in 70% of diagnosed BCa patients and androgen receptor (AR) is overexpressed in 80-90% of diagnosed PCa patients. Thus, BCa and PCa patients are given therapy that reduces hormone levels or directly blocks HR activity; but most patients eventually develop treatment resistance. 15-30% of BCa patients and ≥ 30% of PCa patients that acquire treatment resistance develop tumors enriched in cancer cells with low or no HR accumulation. Furthermore, 15-20% of BCa patients and 10-20% of PCa patients are intrinsically HR-negative (HR-), and thus, have intrinsic resistance to therapy. We have previously reported that interleukin-1 (IL-1) inflammatory cytokine downregulates ERa and AR mRNA in HR-positive (HR+) BCa and PCa cell lines. Additionally, we had identified pro-survival proteins and processes upregulated by IL-1 in HR+ BCa and PCa cells, that are basally high in HR- BCa and PCa cells. Therefore, we hypothesize that IL-1 confers a conserved gene expression pattern in HR+ BCa and PCa cells that mimics conserved basal gene expression patterns in HR- BCa and PCa cells, to promote HR-independent survival and tumorigenicity. Methods: To identify changes in global gene expression we performed RNA sequencing (RNA-seq) for HR+ BCa and PCa cell lines exposed to IL-1 and for untreated HR- BCa and PCa cell lines. We confirmed expression patterns of select genes by RT-qPCR and used siRNA and/or drug inhibition to silence select genes in BCa and PCa cell lines. We also compared our gene expression data with publicly available data sets from hormone receptor-independent sublines. Finally, we performed Ingenuity Pathway Analysis (IPA) to identify signaling pathways encode by our RNA-seq data set. Results: We identified 350 genes in common between BCa and PCa cells that are induced or repressed by IL-1 in HR+ cells that are, respectively, basally high or low in HR- cells. Among these genes, we identified Sequestome-1 (SQSTM1/p62) and SRY (Sex-Determining Region Y)-Box 9 (SOX9) to be essential for survival of HR- BCa and PCa cell lines. Analysis of publicly available data indicates that p62 and SOX9 expression are elevated in hormone receptor-independent BCa and PCa sublines generated in vitro, suggesting that p62 and SOX9 have a role in acquired treatment resistance. We also assessed HR- cell line viability in response verteporfin, an FDA approved therapy for macular degeneration known to target p62, and we found that verteporfin is cytotoxic for HR- cells lines. Conclusions: Taken together, our 350 gene set can be used to identify novel therapeutic targets and/or biomarkers conserved among acquired (e.g. due to inflammation) or intrinsic hormone receptor-independent BCa and PCa.

Project description:Due to the urgent need of new targeting strategies in PCa, AR interacting proteins should be considered. In this study we aimed to test the effect of a long-term knockdown of NCOA1, an AR coactivator, in PCa progression and metastatogenesis and whether NCOA1 could be used as a possible therapeutic target. To test the consequences of NCOA1 knockdown on proliferation, we performed by 3H thymidine incorporation assays revealing a strong reduction in castration resistant MDA PCa 2b and androgen-dependent LNCaP cells, without affecting AR negative PC3 cells. Furthermore, Boyden chamber assays revealed a strong decrease in migration and invasion upon NCOA1 knockdown. Using a cDNA microarray, we identified protein kinase D1 (PRKD1) as one prominent upregulated gene in MDA PCa 2b, which was not seen in PC3 cells. Knockdown of PRKD1 clearly reverted the reduced migratory potential. Moreover, we found phospholipase A2, group7 (PLA2G7) and eukaryotic translation initiation factor 5A2 (EIF5A2), which might be involved in migration of PC3 cells. Further, we can clearly demonstrate that PRKD1 is negatively regulated by the AR/NCOA1 complex. In addition, immunhistochemical staining revealed a strong increase in NCOA1 expression in matched and unmatched patients’ samples, respectively between normal prostate and primary tumor. Regarding the PRKD1 staining, no final conclusion can be drawn in terms of a tumor suppressor function. Thus, our findings directly associate NCOA1/AR complex with PRKD1 regulation and further suggest NCOA1 as a potential therapeutic target also due to the effect on PC3 cell migration.

Project description:Identification of an IL-1-induced gene expression pattern in AR+ PCa cells that mimics the molecular phenotype of AR- PCa cells

Project description:AR+ PCa cell lines show conserved activation of canonical IL-1 intracellular signaling cascades, including repression of androgen receptor mRNA levels, in response to acute IL-1 treatment and show conserved loss of sensitivity to prolonged (chronic) IL-1 intracelluar signaling, including the restoration of the androgen receptor. Thus, chronic IL-1 exposure selects for cells that have a growth advantage against cytotoxic/static inflammation, including restoration of constitutive AR expression.

Project description:IL-1-conferred gene expression pattern in ERa+ BCa and AR+ PCa cells is intrinsic to ERa- BCa and AR- PCa cells and promotes cell survival

Project description:SPOP, an E3 ubiquitin ligase, acts as a prostate-specific tumor suppressor with several key substrates mediating oncogenic function. However, the mechanisms underlying SPOP regulation are largely unknown. Here, we have identified G3BP1 as an interactor of SPOP and functions as a competitive inhibitor of Cul3SPOP, suggesting a distinctive mode of Cul3SPOP inactivation in prostate cancer (PCa). Transcriptomic analysis and functional studies reveal a G3BP1-SPOP ubiquitin signaling axis that promotes PCa progression through activating AR signaling. Moreover, AR directly upregulates G3BP1 transcription to further amplify G3BP1-SPOP signaling in a feed-forward manner. Our study supports a fundamental role of G3BP1 in disabling the tumor suppressive Cul3SPOP, thus defining a PCa cohort independent of SPOP mutation. Therefore, there are significantly more PCa that are defective for SPOP ubiquitin ligase than previously appreciated, and these G3BP1high PCa are more susceptible to AR-targeted therapy.

Project description:(1) Transcription profiling of MDA-PCa-2b cells comparing ARlnc1 knockdown treated cells with control cells. Two methods were used to knockdown ARlnc1: siRNA or ASO. (2) Transcription profiling of MDA-PCa-2b cells comparing dihydrotestosterone (DHT) stimulated cells with vehicle treated cells. The goal is to determine AR-regulated gene expression signature in MDA-PCa-2b cells.

Project description:Purpose: Androgen receptor (AR) is a crucial modulator of prostate cancer (PCa) cells behaviour, and AR expression has been found in several stromal cells, including macrophages, however its role in these cells in largely unknown. In this study, we described the molecular mechanims and the functional implications of AR activation and blockade in macrophages in relation to PCa progression. Results: Analysis showed the transcriptomic landscape of PCa-associated macrophages Conclusions: Our study represents the first detailed analysis of AR molecular function in Pca-associated macrophages

Project description:Prostate cancer (PCa) development and progression are associated with chronic inflammation. The cytokine interleukin (IL)-6 can influence progression, differentiation, survival, and angiogenesis of PCa. To identify novel pathways that are triggered by IL-6, we performed a gene expression profiling of two PCa cell lines, LNCaP and MDA PCa 2b, under treatment with 5 ng/ml IL-6. Interferon regulatory factor (IRF)9 was identified as one of the most prevalent IL-6 regulated genes in both cell lines. IRF9 is a mediator of type I interferon signaling and acts together with signal transduction and activator of transcription (STAT)1 and 2 to activate transcription of interferon responsive genes. The IL-6 regulation of IRF9 was confirmed at mRNA and protein levels by quantitative real-time PCR and Western blot, respectively, in both cell lines and could be blocked by the anti-IL-6 antibody Siltuximab. Three PCa cell lines with an autocrine IL-6 loop, PC3, DU145, and LNCaP-IL-6+, showed a high expression of IRF9. A tissue microarray with 36 malignant and adjacent 36 benign areas from prostate cancer specimens showed that IRF9 protein expression is moderately elevated in malignant areas and positively correlates with the tissue expression of IL-6. Downregulation and overexpression of IRF9 provided evidence for an interferon-independent role of IRF9 on cellular proliferation of different PCa cell lines. Furthermore, expression of IRF9 was essential to mediate the antiproliferative effects of IFN-M-NM-12. We concluded that IL-6 is an inducer of IRF9 expression in prostate cancer and a sensitizer for the antiproliferative effects of IFNM-NM-12. LNCaP and MDA PCa 2b cells were seeded in 12 wells each. The cells were starved for 24 h and half were treated with 5 ng/ml IL-6 for 18 h. Two biological replicates were performed, each in three replicates, resulting in 12 samples per cell line.