SOX2 expression in the developing, adult, as well as, diseased prostate.

BACKGROUND: SOX2 is a member of SOX (SRY-related high mobility group box) family of transcription factors. METHODS: In this study, we examined the expression of SOX2 in murine and human prostatic specimens by immunohistochemistry. RESULTS: We found that SOX2 was expressed in murine prostates during budding morphogenesis and in neuroendocrine (NE) prostate cancer (PCa) murine models. Expression of SOX2 was also examined in human prostatic tissue. We found that SOX2 was expressed in 26 of the 30 BPH specimens. In these BPH samples, expression of SOX2 was limited to basal epithelial cells. In contrast, 24 of the 25 primary PCa specimens were negative for SOX2. The only positive primary PCa was the prostatic NE tumor, which also showed co-expression of synaptophysin. Additionally, the expression of SOX2 was detected in all prostatic NE tumor xenograft lines. Furthermore, we have examined the expression of SOX2 on a set of tissue microarrays consisting of metastatic PCa tissues. Expression of SOX2 was detected in at least one metastatic site in 15 of the 24 patients with metastatic castration-resistant PCa; and the expression of SOX2 was correlated with synaptophysin. CONCLUSIONS: SOX2 was expressed in developing prostates, basal cells of BPH, as well as prostatic NE tumors.

PPARγ isoforms differentially regulate metabolic networks to mediate mouse prostatic epithelial differentiation.

Recent observations indicate prostatic diseases are comorbidities of systemic metabolic dysfunction. These discoveries revealed fundamental questions regarding the nature of prostate metabolism. We previously showed that prostate-specific ablation of PPARγ in mice resulted in tumorigenesis and active autophagy. Here, we demonstrate control of overlapping and distinct aspects of prostate epithelial metabolism by ectopic expression of individual PPARγ isoforms in PPARγ knockout prostate epithelial cells. Expression and activation of either PPARγ 1 or 2 reduced de novo lipogenesis and oxidative stress and mediated a switch from glucose to fatty acid oxidation through regulation of genes including Pdk4, Fabp4, Lpl, Acot1 and Cd36. Differential effects of PPARγ isoforms included decreased basal cell differentiation, Scd1 expression and triglyceride fatty acid desaturation and increased tumorigenicity by PPARγ1. In contrast, PPARγ2 expression significantly increased basal cell differentiation, Scd1 expression and AR expression and responsiveness. Finally, in confirmation of in vitro data, a PPARγ agonist versus high-fat diet (HFD) regimen in vivo confirmed that PPARγ agonization increased prostatic differentiation markers, whereas HFD downregulated PPARγ-regulated genes and decreased prostate differentiation. These data provide a rationale for pursuing a fundamental metabolic understanding of changes to glucose and fatty acid metabolism in benign and malignant prostatic diseases associated with systemic metabolic stress.

Perspectives on tissue interactions in development and disease.

From the morphogenetic movements of the three germ layers during development to the reactive stromal microenvironment in cancer, tissue interactions are vital to maintaining healthy organ morphologic architecture and function. The stromal compartment is thought to be complicit in tumor progression and, as such, represents an opportune target for disease therapies. However, recent developments in our understanding of the diversity of the stromal compartment and the lack of appropriate models to study its relevance in human disease have limited our further understanding of the role of tissue interactions in tumor progression. The failure any model to fully recapitulate the complexities of systemic biology continue to create a higher imperative for incorporating various perspectives into a broader understanding for the ultimate goal of designing interventional therapies. Understanding this potential, this review examines the biological models used to study stromal-epithelial interactions and includes an attempt to incorporate behavioral terminology to define and mathematically model ecological relationships in stromal-epithelial interactions. In addition, the current attempt to incorporate these diverse ecological perspectives into in silico mathematical models through cross-disciplinary coordination is reviewed, which will provide a fresh perspective on defining cell group behavior and tissue ecology in disease and hopefully lead to the generation of new hypotheses to be empirically validated.

Fibroblast growth factor-2 mediates transforming growth factor-beta action in prostate cancer reactive stroma.

Transforming growth factor-beta (TGF-beta) is overexpressed at sites of wound repair and in most adenocarcinomas including prostate cancer. In stromal tissues, TGF-beta regulates cell proliferation, phenotype and matrix synthesis. To address mechanisms of TGF-beta action in cancer-associated reactive stroma, we developed prostate stromal cells null for TGF-beta receptor II (TbetaRII) or engineered to express a dominant-negative Smad3 to attenuate TGF-beta signaling. The differential reactive stroma (DRS) xenograft model was used to evaluate altered stromal TGF-beta signaling on LNCaP tumor progression. LNCaP xenograft tumors constructed with TbetaRII null or dominant-negative Smad3 stromal cells exhibited a significant reduction in mass and microvessel density relative to controls. Additionally, decreased cellular fibroblast growth factor-2 (FGF-2) immunostaining was associated with attenuated TGF-beta signaling in stroma. In vitro, TGF-beta stimulated stromal FGF-2 expression and release. However, stromal cells with attenuated TGF-beta signaling were refractory to TGF-beta-stimulated FGF-2 expression and release. Re-expression of FGF-2 in these stromal cells in DRS xenografts resulted in restored tumor mass and microvessel density. In summary, these data show that TGF-beta signaling in reactive stroma is angiogenic and tumor promoting and that this effect is mediated in part through a TbetaRII/Smad3-dependent upregulation of FGF-2 expression and release.