Genetics and Molecular Mechanisms of Prostate Cancer
Division Of Basic Sciences - Nci
Investigators
Linked publications, trials & patents
Abstract
We have conducted translational research to understand the genetic and molecular mechanism that govern prostate cancer development and progression, to identify novel pathways for drug development, and investigate mechanisms of resistance to treatment paradigms. Prostate cancer has entered into the era of precision medicine with the recent approvals of targeted therapeutics (olaparib and rucaparib). The presence of germline mutations has important hereditary cancer implications for patients with prostate cancer, and germline testing is increasingly important in cancer screening, risk assessment, and the overall treatment and management of the disease. We are interested in understanding germline variants associated with inherited predisposition, prostate cancer risk and outcomes. Understanding the role of germline (heritable) mutations that affect prostate cancer biology and risk as well as the subsequent effect of these alterations on potential therapies is critical as the treatment paradigm shifts towards precision medicine. We have a longstanding collaboration with the Prostate Cancer Prevention Trial (PCPT) investigators to elucidate the molecular and genetic mechanisms that may help explain the trial outcomes of the PCPT. The overall goals of this project are: a) to better understand associations between important androgen regulatory gene polymorphisms and PCa risk; and b) to evaluate the effects of these polymorphisms and serum hormone concentrations on the use of finasteride as a chemopreventive agent for PCa. Studies are ongoing examining the effects of obesity-related serum markers on modulating the association of obesity with prostate cancer risk. The introduction of second-generation androgen receptor antagonists (SG-ARAs) has greatly impacted the treatment of metastatic prostate cancer, providing tolerable and efficacious alternatives to chemotherapy. Despite considerable improvements in clinical outcomes in the settings of both castration sensitivity and castration resistance, the durability of clinical response to the SG-ARAs enzalutamide, apalutamide and darolutamide, similar to abiraterone, is limited by inevitable acquired resistance. Genomic aberrations that confer resistance to SG-ARAs or provide potential alternative treatment modalities have been identified in numerous studies, including alterations of the androgen receptor, DNA repair, cell cycle, PI3K-AKT-mTOR and Wnt-beta-catenin pathways. To combat resistance, we are investigating these novel combination strategies. The results of ongoing studies will help to shape precision medicine in prostate cancer and further optimize treatment paradigms to maximize clinical outcomes. We are also interested in understanding the molecular genetics of androgen transport. The organic anion transporter OATP1B3, encoded by SLCO1B3, is involved in the transport of steroid hormones. We have shown that prostate cancer overexpresses OATP1B3 compared to normal or benign hyperplastic tissue, and the common SLCO1B3 GG/AA haplotype is associated with impaired testosterone transport and improved survival in patients with CaP. We found that a polymorphism in this transporter increases testosterone import is associated with a shorter time to androgen independence in patients with CaP who are treated with ADT. Castration-resistant prostate cancer (CRPC) has greater intratumoral testosterone concentrations than similar tumors from eugonadal men; simple diffusion does not account for this observation. We recently conducted studies to ascertain the androgen uptake kinetics, functional, and clinical relevance of de novo expression of OATP1B3. We found that de novo OATP1B3 expression in prostate cancer drives greater androgen uptake and is consistent with previous observations that greater OATP1B3 activity results in the development of androgen deprivation therapy resistance and shorter overall survival. Studies are ongoing to characterize the molecular mechanisms of SLCO1B3 transcription including transcription factor complexes that assemble at distinct regulatory elements in the SLCO1B3 promoter for driving tissue-specific expression of OATP1B3 in prostate cancer. We discovered that abiraterone treatment increased SLCO1B3 expression in 22Rv1 cells in vitro and in the 22Rv1 xenograft model in vivo. MicroRNA profiling of abiraterone-treated 22Rv1 cells was performed using a NanoString nCounter miRNA panel followed by miRNA target prediction. TargetScan and miRanda prediction tools identified hsa-miR-579-3p as binding to the 3'-untranslated region (3'UTR) of the SLCO1B3. Using dual luciferase reporter assays, we verified that hsa-miR-579-3p indeed binds to the SLCO1B3 3'UTR and significantly inhibited SLCO1B3 reporter activity. Treatment with abiraterone significantly downregulated hsa-miR-579-3p, indicating its potential role in upregulating SLCO1B3 expression. In this study, we demonstrated a novel miRNA-mediated mechanism of abiraterone-induced SLCO1B3 expression, a transporter that is also responsible for driving androgen deprivation therapy resistance. Understanding mechanisms of abiraterone resistance mediated via differential miRNA expression will also assist in the identification of potential miRNA biomarkers of treatment resistance and the development of future therapeutics.
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