Project description:Recurrent point mutations in SPOP define a distinct molecular subclass of prostate cancer. Here, we describe the first mouse model showing that mutant SPOP drives prostate tumorigenesis in vivo. Conditional expression of mutant SPOP in the prostate dramatically altered phenotypes in the setting of Pten loss, with early neoplastic lesions (high-grade prostatic intraepithelial neoplasia) with striking nuclear atypia, and invasive poorly differentiated carcinoma. In mouse prostate organoids, mutant SPOP drove increased proliferation and a transcriptional signature consistent with human prostate cancer. Using these models and human prostate cancer samples, we show that SPOP mutation activates both PI3K/mTOR and androgen receptor (AR) signaling, effectively uncoupling the normal negative feedback between these two pathways. Associated RNA-seq data deposited in GEO: GSE94839.

Project description:Although an increased level of the prostate-specific antigen can be an indication for prostate cancer, other reasons often lead to a high rate of false positive results. Therefore, an additional serological screening of autoantibodies in patients’ sera could improve the detection of prostate cancer. We performed protein macroarray screening with sera from 49 prostate cancer patients, 70 patients with benign prostatic hyperplasia and 28 healthy controls and compared the autoimmune response in those groups. We were able to distinguish prostate cancer patients from normal controls with an accuracy of 83.2%, patients with benign prostatic hyperplasia from normal controls with an accuracy of 86.0% and prostate cancer patients from patients with benign prostatic hyperplasia with an accuracy of 70.3%. Combining seroreactivity pattern with a PSA level of higher than 4.0 ng/ml this classification could be improved to an accuracy of 84.1%. For selected proteins we were able to confirm the differential expression by using Lluminex on 84 samples. We provide a minimally invasive serological method to reduce false positive results in detection of prostate cancer and according to PSA screening to distinguish men with prostate cancer from men with benign prostatic hyperplasia.

Project description:15-Lipoxygenase 2 (15-LOX2), a human-specific lipid-peroxidizing enzyme, is mainly expressed in luminal compartment of the normal prostate and often decreased or lost in prostate cancer (PCa). Previous studies from our lab implicate 15-LOX2 as a functional tumor suppressor. To better understand the biological role of 15-LOX2 in vivo, we established prostate-specific 15-LOX2 transgenic mice using the ARR2PB promoter. Unexpectedly, 15-LOX2 expression resulted in age-dependent prostatic hyperplasia. Interestingly, transgenic expression of 15-LOX2sv-b, a splice variant that lacks the arachidonic acid metabolizing activity, also induced hyperplasia and enlargement of the prostate. Prostatic hyperplasia induced by both 15-LOX2 and 15-LOX2sv-b was associated with an increase in proliferative (i..e., Ki67+) and luminal cells but 15-LOX2-induced hyperplasia was also accompanied by a prominent increase in basal cells. Microarray analysis revealed distinct gene expression profiles that could help explain the prostate phenotypes. Strikingly, 15-LOX2 (but not 15-LOX2sv-b) transgenic prostate showed up-regulation of several well-known stem/progenitor cell molecules including Sca-1, Trop2, p63 and Psca. Prostatic hyperplasia caused by both 15-LOX2 and 15-LOX2sv-b did not progress to PCa over >5 years of observations. Mechanistically, hyperplastic prostate lobes (especially those of the 15-LOX2 mice) showed a dramatic increase in senescent cells revealed by increased SA-ßgal, HP1, and p27Kip1 staining. Collectively, our results suggest that 15-LOX2 expression in mouse prostate leads to hyperplasia that activates the senescence checkpoint, which may in turn function as a barrier to tumor development. RNA was isolated from combined prostatic lobes of 6 mice (to reduce inter-animal variation) from ~2.5 month old (young; y) 15-LOX2 (line fl26), 15-LOX2sv-b (line svb9), wild type (wt) and ~15 month old (old; o) wt mice and hybridized onto Agilent's whole mouse genome oligoarrays arrays (G4122A) in fl26y(vs)wty, svb9y(vs)wty and wto(vs)wty combinations. The hybridizations were carried out in duplicates using an independent set of samples (biological replicates).

Project description:15-Lipoxygenase 2 (15-LOX2), a human-specific lipid-peroxidizing enzyme, is mainly expressed in luminal compartment of the normal prostate and often decreased or lost in prostate cancer (PCa). Previous studies from our lab implicate 15-LOX2 as a functional tumor suppressor. To better understand the biological role of 15-LOX2 in vivo, we established prostate-specific 15-LOX2 transgenic mice using the ARR2PB promoter. Unexpectedly, 15-LOX2 expression resulted in age-dependent prostatic hyperplasia. Interestingly, transgenic expression of 15-LOX2sv-b, a splice variant that lacks the arachidonic acid metabolizing activity, also induced hyperplasia and enlargement of the prostate. Prostatic hyperplasia induced by both 15-LOX2 and 15-LOX2sv-b was associated with an increase in proliferative (i..e., Ki67+) and luminal cells but 15-LOX2-induced hyperplasia was also accompanied by a prominent increase in basal cells. Microarray analysis revealed distinct gene expression profiles that could help explain the prostate phenotypes. Strikingly, 15-LOX2 (but not 15-LOX2sv-b) transgenic prostate showed up-regulation of several well-known stem/progenitor cell molecules including Sca-1, Trop2, p63 and Psca. Prostatic hyperplasia caused by both 15-LOX2 and 15-LOX2sv-b did not progress to PCa over >5 years of observations. Mechanistically, hyperplastic prostate lobes (especially those of the 15-LOX2 mice) showed a dramatic increase in senescent cells revealed by increased SA-ßgal, HP1, and p27Kip1 staining. Collectively, our results suggest that 15-LOX2 expression in mouse prostate leads to hyperplasia that activates the senescence checkpoint, which may in turn function as a barrier to tumor development.

Project description:DNA modification profiling of circulating DNA (cirDNA) from plasma samples from prostate cancer patients (T2-3N0Mx), benign prostatic hyperplasia and control individuals Epigenetic differences are a common feature of many diseases, including cancer, and disease-associated changes have even been detected in bodily fluids. DNA modification studies in circulating DNA (cirDNA) may lead to the development of specific non-invasive biomarkers. Three-conditions experiment: Prostate cancer (n=19), bening prostatic hyperplasia (n=20), controls without any know prostatic disease (n=20). cirDNA was isolated and the modified fraction of the genome was enriched using DNA-modification-sensitive digestion and adaptor-mediated PCR. Enriched fraction was labelled with Cy3. DNA samples extracted from white blood cells (WBC) of 20 individuals unrelated to this project were pooled and used as reference (Cy5-labelled).

Project description:Trascription profiling analysis was performed on HCT-116 cell lines transiently silenced with TRAP1 compared with scrumble

Project description:DNA modification profiling of circulating DNA (cirDNA) from plasma samples from prostate cancer patients (T2-3N0Mx), benign prostatic hyperplasia and control individuals Epigenetic differences are a common feature of many diseases, including cancer, and disease-associated changes have even been detected in bodily fluids. DNA modification studies in circulating DNA (cirDNA) may lead to the development of specific non-invasive biomarkers.

Project description:To study the differential expression of genes in prostate cancer tissue and benign prostatic hyperplasia

Project description:Transcription profiling by array of MCF7 cell lines silenced with TRAP1 small interfering RNA compared with scramble

Project description:TRAP1 is a HSP90 molecular chaperone involved in cancer cell adaptation to unfavorable environments and metabolic reprogramming. The role of TRAP1 in the adaptive response to hypoxia was investigated in human colorectal cancer.