Project description:In spite of its prevalence as one of the world’s leading malignancies, prostate cancer (PCa) continues to evade molecular taxonomic sub-classification. However, gross clinical differences are observed within the umbrella term ‘prostate adenocarcinoma’; the majority of tumors appear indolent in nature, whilst a subset manifest aggressively. Contributing factors towards this resistance to molecular classification are an atypically low mutation frequency and a poorly delineated pathobiology. Conversely, epigenetic changes are evidenced to be amongst the earliest and most-widespread aberrations in PCa . We thus hypothesized that delineating epigenomic alterations during the stepwise progression of PCa would improve our understanding of the disease pathobiology and the molecular underpinning of indolent and aggressive tumors. Herein, we report the first epigenomic roadmap of prostate tumorigenesis, in which we dissected DNA methylation and microRNA expression in enriched epithelial cells across the entire trajectory of PCa, through tumor initiation, primary disease and metastatic dissemination. We provide evidence in support of proliferative inflammatory atrophy (PIA) as a precursor lesion, distinct from high-grade prostatic intraepithelial neoplasia (HGPIN) and show that indolent and aggressive tumors display unique sets of epigenetically dysregulated loci, which we further investigated as potential discriminatory markers. This study also establishes the importance of DNA methylation beyond the gene promoter in human cancer, with pronounced intra- and inter-genic CpG methylation observed.

Project description:Prostate cancer (PCa) is one of the most prevalent cancers among men and the fifth leading cause of cancer-related death in men. Currently, PCa suspicion is based on abnormal digital rectal examination and/or raised PSA serum levels, with prostate needle biopsy being required for a definitive diagnosis. Histopathological classification of tumours based on GS grading, cancer staging and PSA levels are used to predict the indolent or aggressive progression of the tumour as well as the likelihood of disease recurrence. These diagnosis and prognosis tools for PCa have revealed limited usefulness, especially PSA testing, which despite organ-specificity is not cancer-specific, being associated with low specificity. In this vein, new markers have been proposed in order to increase the accuracy of PCa detection, most of them proteins. Despite the significant efforts that have been undertaken for discovering other biomarkers for PCa management, few were translated into clinical practice. The simple and non-invasive nature of urine collection along with its proteome stability and storing many secreted proteins of prostate origin, makes the identification of PCa urinary biomarkers an attractive approach. With this in mind, we aimed to compare the urinary proteome profile of PCa patients with non-cancer patients in order to identify non-invasive candidate biomarkers for PCa prediction. To fulfil this task, we followed a shotgun LC-MS/MS approach using an Orbitrap instrument. A combination of two different software packages, MaxQuant and Proteome Discover was used to increase the robustness of analysis and enhance the search for new biomarkers. Proteins quantification was based on a label-free quantification approach (false discovery rate (FDR) 1%). The present dataset was used to disclosure potential markers in PCa management.

Project description:Prostate cancer (PCa) remains a prevalent and deadly disease. The histology-based Gleason score (GS) of PCa tissue biopsy is the most accurate predictor of disease aggressiveness and an important measure to guide decision-making with respect to treatment strategies and patient management. However, inherent variability associated with PCa tumour sampling and the subjective determination of the GS are still key challenges precluding accurate diagnostication and prognostication. Thus, novel molecular signatures are urgently needed to distinguish between indolent and aggressive forms of PCa for better patient management and outcomes. Herein, we have used label-free LC-MS/MS-based proteomics to profile the proteome of 50 PCa tissues spanning five GS-based PCa grades (n = 10 per group) relative to five tissues from individuals with benign prostatic hyperplasia (BPH). Over 2,000 proteins were consistently identified albeit at different levels between and within the patient groups, revealing biological processes associated with specific grades. Excitingly, a panel of 11 prostate-derived proteins including IGKV3D-20, RNASET2, TACC2, ANXA7, LMOD1, PRCP, GYG1, NDUFV1, H1FX, APOBEC3C, CTSZ displayed the potential to accurately stratify patients displaying low and high GS. This is the first study to characterise the prostate tissue proteome signatures of the five PCa grades relative to BPH. We report a panel of proteins that accurately can distinguish low and high GS PCa tissues. These promising proteins can be further explored as candidate biomarkers for PCa aggressiveness.

Project description:There is an unmet need for improved diagnostic testing and risk prediction for cases of prostate cancer (PCa) to improve care and reduce overtreatment of indolent disease. Here we have analysed the serum proteome and lipidome of 262 study participants by liquid chromatography-mass spectrometry, including participants with a diagnosis of PCa, benign prostatic hyperplasia (BPH), or otherwise healthy volunteers, with the aim of improving biomarker specificity. Although a two-class machine learning model was able to separate PCa from controls with sensitivity of 0.82 and specificity of 0.95, adding BPH resulted in a statistically significant decline in specificity for prostate cancer to 0.76, with half of BPH cases being misclassified by the model as PCa. A small number of biomarkers differentiating between BPH and prostate cancer were identified, including proteins in MAP Kinase pathways, as well as in lipids containing oleic acid; these may offer a route to greater specificity. These results highlight, however, that whilst there are opportunities for machine learning, these will only be achieved by use of appropriate training sets that include confounding comorbidities, especially when calculating the specificity of a test.

Project description:Many human cancers present as multi-focal lesions. Understanding the clonal origin of multi-focal cancers is of both etiological and clinical importance. The molecular basis of multi-focal prostate cancer has previously been explored using only a limited number of isolated markers and, although independent origin is widely believed, the clonal origin of multi-focal prostate cancer is still debatable. We attempted to address clonal origin using a genome-wide copy-number analysis of individual cancer and high-grade prostatic intraepithelial neoplasia (HGPIN) lesions. Using Affymetrix array 6.0 copy-number analysis, we compared the genomic changes detected in 54 individual cancer and HGPIN lesions, isolated from 20 clinically localized prostate cancer cases. Identical genomic copy-number changes, shared by all same-case cancer foci, were detected in all 16 informative multi-tumor cases. In addition, both HGPIN lesions in the two multi-HGPIN cases available shared identical genomic changes. Commonly known genomic alterations, including losses at 6q15, 8p21.3-8p21.2, 10q23.2-10q23.31, 13q21.31-13q21.32, 16q22.3, 16q23.2-16q23.3 and 21q22.2-21q22.3 regions and gain of 8q24.3 were the most frequently detected changes in this multi-focal prostate cancer study, occurring in all same-case foci in at least one case. Microarray data were confirmed by fluorescence in situ hybridization in selected foci. Our high-resolution genome-wide copy-number data suggest that many multi-focal cases derive from a single prostate cancer precursor clone and that this precursor may give rise to separate HGPIN foci, which through clonal expansion may progress to multi-focal invasive prostate cancer. These findings, which demonstrate the monoclonal origin of multi-focal prostate cancer, should significantly enhance our understanding of prostate carcinogenesis and potentially improve clinical management of the disease. Copy number analysis of Affymetrix SNP 6.0 array was performed for a total of 48 cancer and HGPIN lesions from 18 prostate cancer cases. All samples have case-matched normal controls. PL = high grade PIN from left side, PR = high grade PIN from right side, PM = high grade PIN from middle of the tissue, TL = tumour from left side, TR = tumour from right side.

Project description:The clinical course of prostate cancer (PCa) is highly variable, demanding an individualized approach to therapy and robust prognostic markers for treatment decisions. We here present a random forest-based classification model to predict aggressive behaviour of PCa. DNA methylation changes between PCa cases with good or poor prognosis (discovery cohort with n=78) were used as input. The model was validated with data from two independent PCa cohorts from ICGC and TCGA. Ranking of cancer progression-related DNA methylation changes allowed selection of candidate genes for additional validation by immunohistochemistry. We identified loss of ZIC2 protein expression as a promising novel prognostic biomarker for PCa in >12,000 tissue micro-array tumors. The prognostic value of ZIC2 proved to be independent from established clinico-pathological variables including Gleason, stage, nodal stage and PSA. In summary, we have developed a PCa classification model which either directly or via expression analyses of the identified top ranked candidate genes might help in decision making related to the treatment of prostate cancer patients.

Project description:Many human cancers present as multi-focal lesions. Understanding the clonal origin of multi-focal cancers is of both etiological and clinical importance. The molecular basis of multi-focal prostate cancer has previously been explored using only a limited number of isolated markers and, although independent origin is widely believed, the clonal origin of multi-focal prostate cancer is still debatable. We attempted to address clonal origin using a genome-wide copy-number analysis of individual cancer and high-grade prostatic intraepithelial neoplasia (HGPIN) lesions. Using Affymetrix array 6.0 copy-number analysis, we compared the genomic changes detected in 54 individual cancer and HGPIN lesions, isolated from 20 clinically localized prostate cancer cases. Identical genomic copy-number changes, shared by all same-case cancer foci, were detected in all 16 informative multi-tumor cases. In addition, both HGPIN lesions in the two multi-HGPIN cases available shared identical genomic changes. Commonly known genomic alterations, including losses at 6q15, 8p21.3-8p21.2, 10q23.2-10q23.31, 13q21.31-13q21.32, 16q22.3, 16q23.2-16q23.3 and 21q22.2-21q22.3 regions and gain of 8q24.3 were the most frequently detected changes in this multi-focal prostate cancer study, occurring in all same-case foci in at least one case. Microarray data were confirmed by fluorescence in situ hybridization in selected foci. Our high-resolution genome-wide copy-number data suggest that many multi-focal cases derive from a single prostate cancer precursor clone and that this precursor may give rise to separate HGPIN foci, which through clonal expansion may progress to multi-focal invasive prostate cancer. These findings, which demonstrate the monoclonal origin of multi-focal prostate cancer, should significantly enhance our understanding of prostate carcinogenesis and potentially improve clinical management of the disease.

Project description:Heparan sulfate (HS) is a linear, sulfated polysaccharide, and expresses abundantly in prostate and PCa tissues. Intriguingly, the HS content and sulfation modifications appear to increase when the prostate becomes malignance, suggesting that HS may critically modulate PCa pathogenesis. We specifically ablated Ext1, the enzyme that initiates HS biosynthesis, in mouse prostate at late development stage. And used microarray to detail the gene expressions affected by Ext1 ablation and identified distinct classes of up-regulated genes during this process. Prostate tissues were removed from euthanized mice at 5 weeks old for RNA extraction and hybridization on Affymetrix microarrays. We sought to compare gene expression during tumorigenesis among the wildtype, prostate specific knockout of Pten and double knockout of Pten and Ext1 in prostate.

Project description:We report the changes in gene expression in mouse prostate comparing normal wild type prostate to tumors generated by Cre mediated deletion of Pten or Apc, either with or without deletion of Tgfbr2. Pten single mutant tumors were isolated at either 8 weeks or 22 weeks of age, with high grade prostate intraepithelial neoplasia (HGPIN) as the main phenotype. Pten;Tgfbr2 double mutants were isolated at 8 weeks (primarily HGPIN), or at 11-14 weeks with extensive locally invasive cancer. Apc single mutants were isolated at 36 weeks old with adenosquamous HGPIN, or at 21-24 weeks of age for the Apc:Tgfbr2 double mutants, which had adenosquamous carcinoma. Ages for the two double mutant groups were based on initial signs of excess tumor burden. Wild type control prostates were isolated at around 20 weeks of age.

Project description:PRMT5 is the major type II protein arginine methyltransferase catalyzing the symmetric dimethylation of arginine. Recent reports have indicated that PRMT5 is overexpressed in multiple cancer types, including prostate. However, the exact contribution of PRMT5 to prostate tumorigenesis is unknown. To explore the functional role of PRMT5 in prostate cancer (PCa), we knocked down PRMT5 by lentiviral shRNAs in both AR-dependent LNCaP cells and AR-independent PC3 cells. Our data suggests that PRMT5 regulates PCa cell biology. To further identify PRMT5-regulated genes in PCa, we performed paired-end RNA-seq analysis in PC3 and LNCaP cells with or without PRMT5-knockdown.