Differential regulation of steroid nuclear receptor coregulator expression between normal and neoplastic prostate epithelial cells.

BACKGROUND: Deregulated androgen receptor (AR) action is critical for prostate cancer (PCa) progression. Aberrant expression of AR-associated coregulators contributes to AR activity in PCa. The mechanisms underlying coregulator expression in PCa are under intense investigation as they may lead to alternative means of targeting AR activity in PCa cells. We have recently shown that over 30% of coregulator expression in the PCa cell line LNCaP is subject to androgen regulation. METHODS: Using multiple PCa cell lines as well as xenograft models, non-malignant prostate epithelial cell lines and androgen-responsive tissues derived from a male Wistar rat model system, we explored the effect of androgen stimulation and androgen deprivation on the expression of the core coactivators SRC1, SRC2, SRC3, CBP, and p300. RESULTS: Androgen stimulation of model systems representing PCa led to a decrease in the expression of SRC1, SRC2, SRC3, CBP, and p300, whereas androgen deprivation induced the expression of these coactivators. In contrast, expression of these coregulators remained largely unaffected following changes in the androgenic milieu in AR-positive models representing non-malignant prostate cells and tissues. CONCLUSIONS: Our data indicate differences in the regulation of coregulator expression between neoplastic and normal prostate cells. These findings emphasize the important potential of targeting the mechanisms regulating coregulator expression for therapeutic intervention in PCa.

Induction of FLIP expression by androgens protects prostate cancer cells from TRAIL-mediated apoptosis.

BACKGROUND: Prostate tumors initially regress in response to androgen-ablation therapy. However, most cancers eventually relapse with an androgen-depletion-independent (ADI) phenotype that is often more aggressive than the original androgen-dependent (AD) tumor. Importantly, most relapsed tumors still rely upon androgen receptor (AR) activity for proliferation and survival. The cellular Fas/FasL-associated death domain protein-like inhibitory protein (FLIP) inhibits activation of procaspase-8 by death receptor-mediated signaling at the cell surface. In the current study, we examined the androgenic regulation of FLIP and its contribution to protecting prostate cancer cells from death receptor-mediated apoptosis. METHODS: FLIP expression in tissues from intact and castrated rats as well as androgen-treated prostate cancer cell lines (LNCaP, C4-2, LNCaP-Rf, and DU-145) was monitored via Real-Time RT-PCR and immunoblot. Induction of apoptosis by TRAIL, the death receptor ligand, was determined via microscopic observation and cell counting of fragmented nuclei following fixation and staining with Hoechst 33285. RESULTS: FLIP mRNA and protein expression was reduced following castration in multiple rat tissues, including dorsolateral prostate and seminal vesicles. Androgenic induction of FLIP mRNA and protein was observed in isogenic AD LNCaP and ADI LNCaP-Rf cells, but not the isogenic ADI C4-2 cell line. Protection from TRAIL-induced apoptosis by androgen was completely blocked when LNCaP-Rf cells were depleted of endogenous FLIP via siRNA transfection. CONCLUSIONS: Androgenic protection from TRAIL-induced apoptosis is predominantly via enhanced transcription of FLIP in prostate cancer cells. Loss of androgen-sensitivity in ADI prostate cancer cells highlights this pathway as a potential target for future therapy of prostate cancer.

Androgen deprivation increases p300 expression in prostate cancer cells.

Standard therapy for nonorgan confined prostate cancer aims to block the production or action of androgens. Although initially successful, antiandrogen therapy eventually fails and androgen depletion independent (ADI) disease emerges. Remarkably, ADI prostate cancers still rely on a functional androgen receptor (AR). Aberrant expression of coregulatory proteins required for the formation of productive AR transcriptional complexes is critical for ADI AR activation. Previously, we have shown that the transcriptional coactivator p300 is required for ADI activation of the AR and is up-regulated in prostate cancer, in which its expression is associated with cell proliferation and predicts aggressive tumor features. The mechanism responsible for the deregulated expression of p300, however, remains elusive. Here, we show that p300 expression in prostate cancer cells is subject to androgen regulation. In several prostate cancer model systems, addition of synthetic and natural androgens led to decreased expression of p300 in a time-dependent and dose-dependent manner. Experiments using AR antagonists or small interfering RNA targeting the AR revealed that down-regulation of p300 depends entirely on the presence of a functional AR. It is noteworthy that androgens down-regulated p300 protein expression while leaving messenger levels unaltered. Conversely, both short-term and long-term androgen deprivation resulted in marked up-regulation of p300 expression. The androgen deprivation-induced increase in p300 expression was not affected by the addition of cytokines or growth factors or by cotreatment with antiandrogens. Moreover, increased p300 expression upon androgen starvation is crucial for prostate cancer cell proliferation, as loss of p300 expression severely reduces expression of cyclins governing G(1)-S and G(2)-M cell cycle transition and decreases 5-bromo-2'-deoxyuridine incorporation.