Project description:Inherited genetic risk factors play an important role in cancer. However, other than cancer susceptibility genes found in familial cancer syndromes and inherited in a Mendelian fashion, little is known about modifier genes (germline variants that interact with each other and with environmental factors) that contribute to individual susceptibility. Here we develop a strategy “parental strain expression mapping” (PSEM), which utilizes the homogeneity of inbred mice and genome-wide mRNA expression analyses, to directly identify candidate germline modifier genes and pathways underlying phenotypic differences among murine strains exposed to transgenic activation of AKT1. We identified multiple candidate modifier pathways and specifically, the glycolysis pathway as a candidate negative modulator of AKT1-induced proliferation. In keeping with findings in murine models, the expression of the glycolysis pathway was strongly enriched in the non-cancer prostate tissue from patients with prostate cancer who did not recur after surgical resection. Together these data suggest that PSEM can directly identify germline modifier pathways of relevance to human disease. Keywords: genetic modifier

Project description:Identification of novel, highly penetrant, breast cancer susceptibility genes will require the application of additional strategies beyond that of traditional linkage and candidate gene approaches. Approximately one-third of inherited genetic diseases, including breast cancer susceptibility, are caused by frameshift or nonsense mutations that truncate the protein product [1]. Transcripts harbouring premature termination codons are selectively and rapidly degraded by the nonsense-mediated mRNA decay (NMD) pathway. Blocking the NMD pathway in any given cell will stabilise these mutant transcripts, which can then be detected using gene expression microarrays. This technique, known as gene identification by nonsense-mediated mRNA decay inhibition (GINI), has proved successful in identifying sporadic nonsense mutations involved in many different cancer types. However, the approach has not yet been applied to identify germline mutations involved in breast cancer. We therefore attempted to use GINI on lymphoblastoid cell lines (LCLs) from multiple-case, non-BRCA1/2 breast cancer families in order to identify additional high-risk breast cancer susceptibility genes. We applied GINI to a total of 24 LCLs,established from breast-cancer affected and unaffected women from three multiple-case non-BRCA1/2 breast cancer families. We then used Illumina gene expression microarrays to identify transcripts stabilised by the NMD inhibition. Total RNA obtained from the lymphoblastoid cell lines derived from 24 individuals.

Project description:Identification of novel, highly penetrant, breast cancer susceptibility genes will require the application of additional strategies beyond that of traditional linkage and candidate gene approaches. Approximately one-third of inherited genetic diseases, including breast cancer susceptibility, are caused by frameshift or nonsense mutations that truncate the protein product [1]. Transcripts harbouring premature termination codons are selectively and rapidly degraded by the nonsense-mediated mRNA decay (NMD) pathway. Blocking the NMD pathway in any given cell will stabilise these mutant transcripts, which can then be detected using gene expression microarrays. This technique, known as gene identification by nonsense-mediated mRNA decay inhibition (GINI), has proved successful in identifying sporadic nonsense mutations involved in many different cancer types. However, the approach has not yet been applied to identify germline mutations involved in breast cancer. We therefore attempted to use GINI on lymphoblastoid cell lines (LCLs) from multiple-case, non-BRCA1/2 breast cancer families in order to identify additional high-risk breast cancer susceptibility genes. We applied GINI to a total of 24 LCLs,established from breast-cancer affected and unaffected women from three multiple-case non-BRCA1/2 breast cancer families. We then used Illumina gene expression microarrays to identify transcripts stabilised by the NMD inhibition.

Project description:Prostate cancer is a unique disease from a metabolic perspective. Early stage localized prostate cancer does not typically display increased aerobic glycolysis (the Warburg effect), as seen in other malignancies. However, increasing evidence suggests that advanced prostate cancer exhibits the Warburg effect and displays high glucose uptake. We describe here that trans-gnetin H (TGH), a naturally-occurring resveratrol trimer extracted from Paeonia suffruticosa, displays significant anti-cancer effects in advanced prostate cancer cells in vitro. TGH perturbs energy metabolism by blocking the availability of glucose, inducing unfolded protein response (UPR) and C-MYC pathway downregulation in PC-3 cells. Our studies demonstrate the feasibility of targeting aerobic glucose metabolism in advanced prostate cancer and identify TGH as a potential therapeutic candidate.

Project description:Prostate cancer is a unique disease from a metabolic perspective. Early stage localized prostate cancer does not typically display increased aerobic glycolysis (the Warburg effect), as seen in other malignancies. However, increasing evidence suggests that advanced prostate cancer exhibits the Warburg effect and displays high glucose uptake. We describe here that trans-gnetin H (TGH), a naturally-occurring resveratrol trimer extracted from Paeonia suffruticosa, displays significant anti-cancer effects in advanced prostate cancer cells xenografted PC-3 cells in vivo.TGH perturbs energy metabolism by blocking the availability of glucose and inducing profound metabolic and transcriptomic changes in prostate cancer cells as demonstrated by RNA-seq. C-MYC, a known driver oncogene in prostate cancer, is downregulated in TGH-treated cells. Our studies demonstrate the feasibility of targeting aerobic glucose metabolism in advanced prostate cancer and identify TGH as a potential therapeutic candidate.

Project description:We hypothesize that germline variation influences susceptibility to aggressive prostate tumor We examined the changes in gene expression in tumors obtained from TRAMPxPWK/PhJ F2 mice

Project description:MicroRNA expression levels in the lymphoblastic cells of prostate cancer patients and their healthy brothers from HPCX1 linked prostate cancer families were analyzed to trace variants that might alter miRNA expression and explain partly an inherited genetic predisposion to prostate cancer.

Project description:We hypothesize that germline variation influences susceptibility to aggressive prostate tumor We examined the changes in gene expression in tumors obtain from TRAMPxNOD/ShiLtJ F2 mice in groups exhibiting metastasis versus no metastasis

Project description:The androgen receptor (AR) is the major therapeutic target in prostate cancer, although the important targets of the AR have remained obscure. Here we report a detailed genomic profile of AR signalling and find that the AR directly regulates glycolysis, anabolic metabolism and cell cycle regulators in prostate cancer. This coordinated transcriptional program promotes cancer cell proliferation and enhances the macromolecular synthesis needed to produce daughter cells. Clinical gene expression profiles and mechanistic studies highlight the importance of CAMKK2, an AR target which regulates both cell proliferation and metabolism. Thus our genomics study identifies a direct link between AR signalling and aerobic glycolysis (the Warburg effect), providing a new perspective on the oncogenic function of the AR in prostate cancer. 8 Samples: Chromatin IP using AR and PolII in stimulated and unstimulated LNCaP and VCaP cells.

Project description:The study is being conducted to determine the prevalence and risk factors for germline cancer susceptibility genetic mutations among patients with advanced colorectal polyps.