Project description:RNA-seq was carried out on prostate tumors from mice with prostate-conditional PTEN knockout with and without prostate-conditional FOXP1-SHQ1 locus deletion (12 month old PTEN-flox/flox Pb-Cre4 mice and FOXP1-SHQ1-flox/flox PTEN-flox/flox Pb-Cre4 mice )

Project description:We used microarrays to detail the global gene expression and identified differentially expressed gene list between wild-type anterior prostates and Ptenpc-/- anterior prostates, Ptenpc-/-Smad4pc-/- and Ptenpc-/- anterior prostates, Ptenpc-/-p53pc-/- and Ptenpc-/- anterior prostates at 15 weeks of age.

Project description:We used microarrays to detail the global gene expression and identified differentially expressed gene list between wild-type anterior prostates and Ptenpc-/- anterior prostates, Ptenpc-/-Smad4pc-/- and Ptenpc-/- anterior prostates, Ptenpc-/-p53pc-/- and Ptenpc-/- anterior prostates at 15 weeks of age. Prostate-specific Pten deletion (Ptenpc-/-) results in prostate intraepithelial neoplasia (PIN) which, following a long latency, can progress to high-grade adenocarcinoma, albeit with minimally invasive and metastatic features. To understand this feeble progression phenotype, we conducted transcriptome comparison of five Ptenpc-/- PIN relative to three wild-type anterior prostate. Moreover, Ptenpc-/-Smad4pc-/- progress to metastasis, while Ptenpc-/-p53pc-/- not progress to metastasis. To understand this phenotype difference, we conducted transcriptome comparison of five Ptenpc-/-Smad4pc-/-to five Ptenpc-/- prostate tumor, and three Ptenpc-/-p53pc-/- to five Ptenpc-/- tumor.

Project description:We used microarrays to analyze the global gene expression and identified differentially expressed gene list between wild-type anterior prostates and Pb-Cre4;PtenLoxP/LoxP anterior prostates, Pb-Cre4;PtenLoxP/LoxP;LrfLoxP/LoxP anterior prostates at 12 weeks of age.

Project description:We used microarrays to analyze the global gene expression and identified differentially expressed gene list between wild-type anterior prostates and Pb-Cre4;PtenLoxP/LoxP anterior prostates, Pb-Cre4;PtenLoxP/LoxP;LrfLoxP/LoxP anterior prostates at 12 weeks of age. Prostate-specific Pten deletion (Pb-Cre4;PtenLoxP/LoxP) results in prostate intraepithelial neoplasia (PIN) which, following a long latency, can progress to high-grade adenocarcinoma, albeit with minimally invasive and metastatic features. However, inactivation of Lrf in the prostate epithelium in combination of Pten results in aggressive prostate tumors. To understand the molecular mechanisms by which loss of Lrf promotes Pten-loss-driven prostate tumorigenesis, we conducted transcriptome comparison of three wild-type anterior prostates, three Pb-Cre4;PtenLoxP/LoxP PIN, and three Pb-Cre4;PtenLoxP/LoxP;LrfLoxP/LoxP anterior prostate tumors.

Project description:Understanding new therapeutic paradigms for both castrate-sensitive and more aggressive castrate-resistant prostate cancer is essential to improve clinical outcomes. As a critically important cellular process, autophagy promotes stress tolerance by recycling intracellular components to sustain metabolism important for tumor survival. To assess the importance of autophagy in prostate cancer, we generated a new autochthonous genetically engineered mouse model (GEMM) with inducible prostate-specific deficiency in the Pten tumor suppressor and autophagy-related-7 (Atg7) genes. Atg7 deficiency produced an autophagy-deficient phenotype and delayed Pten-deficient prostate tumor progression in both castrate-naïve and castrate-resistant cancers. Atg7-deficient tumors display evidence of endoplasmic reticulum (ER) stress, suggesting that autophagy may promote prostate tumorigenesis through management of protein homeostasis. Taken together, these data support the importance of autophagy for both castrate-naïve and castrate-resistant growth in a newly developed GEMM, suggesting a new paradigm and model to study approaches to inhibit autophagy in combination with known and new therapies for advanced prostate cancer.

Project description:Despite the high incidence and mortality of prostate cancer, the etiology of this disease is not fully understood. In this study, we develop functional evidence for CBP and PTEN interaction in prostate cancer based on findings of their correlate expression in the human disease. Cbp(pc-/-);Pten(pc+/-) mice exhibited higher cell proliferation in the prostate and an early onset of high-grade prostatic intraepithelial neoplasia. Levels of EZH2 methyltransferase were increased along with its Thr350 phosphorylation in both mouse Cbp(-/-); Pten(+/-) and human prostate cancer cells. CBP loss and PTEN deficiency cooperated to trigger a switch from K27-acetylated histone H3 to K27-trimethylated bulk histones in a manner associated with decreased expression of the growth inhibitory EZH2 target genes DAB2IP, p27(KIP1), and p21(CIP1). Conversely, treatment with the histone deacetylase inhibitor panobinostat reversed this switch, in a manner associated with tumor suppression in Cbp(pc-/-);Pten(pc+/-) mice. Our findings show how CBP and PTEN interact to mediate tumor suppression in the prostate, establishing a central role for histone modification in the etiology of prostate cancer and providing a rationale for clinical evaluation of epigenetic-targeted therapy in patients with prostate cancer.

Project description:The role of ER? in prostate cancer is unclear, although loss of ER? is associated with aggressive disease. Given that mice deficient in ER? do not develop prostate cancer, we hypothesized that ER? loss occurs as a consequence of tumorigenesis caused by other oncogenic mechanisms and that its loss is necessary for tumorigenesis. In support of this hypothesis, we found that ER? is targeted for repression in prostate cancer caused by PTEN deletion and that loss of ER? is important for tumor formation. ER? transcription is repressed by BMI-1, which is induced by PTEN deletion and important for prostate tumorigenesis. This finding provides a mechanism for how ER? expression is regulated in prostate cancer. Repression of ER? contributes to tumorigenesis because it enables HIF-1/VEGF signaling that sustains BMI-1 expression. These data reveal a positive feedback loop that is activated in response to PTEN loss and sustains BMI-1.

Project description:Prostate cancer is a major cause of male death in the Western world, but few frequent genetic alterations that drive prostate cancer initiation and progression have been identified. ?-Catenin is essential for many developmental processes and has been implicated in tumorigenesis in many tissues, including prostate cancer. However, expression studies on human prostate cancer samples are unclear on the role this protein plays in this disease. We have used in vivo genetic studies in the embryo and adult to extend our understanding of the role of ?-Catenin in the normal and neoplastic prostate. Our gene deletion analysis revealed that prostate epithelial ?-Catenin is required for embryonic prostate growth and branching but is dispensable in the normal adult organ. During development, ?-Catenin controls the number of progenitors in the epithelial buds and regulates a discrete network of genes, including c-Myc and Nkx3.1. Deletion of ?-Catenin in a Pten deleted model of castration-resistant prostate cancer demonstrated it is dispensable for disease progression in this setting. Complementary overexpression experiments, through in vivo protein stabilization, showed that ?-Catenin promotes the formation of squamous epithelia during prostate development, even in the absence of androgens. ?-Catenin overexpression in combination with Pten loss was able to drive progression to invasive carcinoma together with squamous metaplasia. These studies demonstrate that ?-Catenin is essential for prostate development and that an inherent property of high levels of this protein in prostate epithelia is to drive squamous fate differentiation. In addition, they show that ?-Catenin overexpression can promote invasive prostate cancer in a clinically relevant model of this disease. These data provide novel information on cancer progression pathways that give rise to lethal prostate disease in humans.

Project description:Chromosomal translocations involving the ERG locus are frequent events in human prostate cancer pathogenesis; however, the biological role of aberrant ERG expression is controversial. Here we show that aberrant expression of ERG is a progression event in prostate tumorigenesis. We find that prostate cancer specimens containing the TMPRSS2-ERG rearrangement are significantly enriched for loss of the tumor suppressor PTEN. In concordance with these findings, transgenic overexpression of ERG in mouse prostate tissue promotes marked acceleration and progression of high-grade prostatic intraepithelial neoplasia (HGPIN) to prostatic adenocarcinoma in a Pten heterozygous background. In vitro overexpression of ERG promotes cell migration, a property necessary for tumorigenesis, without affecting proliferation. ADAMTS1 and CXCR4, two candidate genes strongly associated with cell migration, were upregulated in the presence of ERG overexpression. Thus, ERG has a distinct role in prostate cancer progression and cooperates with PTEN haploinsufficiency to promote progression of HGPIN to invasive adenocarcinoma.