CYP17A1 polymorphisms and clinical outcome of patients with metastatic castration-resistant prostate cancer treated with abiraterone

Background. Abiraterone acetate is a potent inhibitor of cytochrome P450 17 α-hydrolase (CYP17A1) that causes a reduction in the synthesis of testosterone in the adrenal glands, testes and tumor microenvironment. Blocking androgen production, abiraterone has been shown to prolong progression-free survival (PFS) and overall survival (OS) in patients with metastatic castration-resistant prostate cancer (CRPC) previously submitted to chemotherapy. The aim of our study was to verify the role of single nucleotide polymorphisms (SNPs) in predicting clinical outcome in CRPC patients treated with abiraterone after chemotherapy. Methods. We analyzed 48 CRPC consecutive patients treated with abiraterone after at least one chemotherapeutic regimen with docetaxel. DNA was extracted from peripheral blood and genotyped for four polymorphisms in the CYP17A1 gene (rs743572, rs10883783, rs17115100, rs284849). PFS and OS survival curves were used to identify statistical associations between haplotypes and clinical outcome. Results. Forty-eight Caucasian patients with metastatic CRPC treated with abiraterone were genotyped for polymorphisms in the CYP17A1 gene. All samples were evaluable for both sequencing and TaqMan Genotyping assay. The CRPC patients treated with abiraterone had a median PFS and OS of 7.6 months (95% CI: 4.3-10.5) and 17.6 months (95% CI: 10.5-19.0), respectively Statistical analyses highlighted a difference approaching statistical significance (log-rank test p = 0.0534) between rs10883783 and PFS. Other polymorphisms were not associated with a benefit from treatment with abiraterone. Conclusions. In our case series of 48 treated patients, rs10883783 only was identified as a possible predictive marker, results showing a trend toward statistical significance. Further analysis of this polymorphism is needed in larger series of patients to confirm our findings.

Small Molecules as Modulators of Different Targets Involved in Tumor Progression

Tumor is a lesion that may be formed by an abnormal growth of neoplastic cells. Many factors increase the risk of cancer and different targets are involved in tumor progression. Within this thesis, we have addressed two different biological targets, independently connected with tumor formation, e.g. Hsp90 and androgen receptor. The ATP-dependent chaperone Hsp90 is responsible for the conformational maturation and the renaturation of proteins. “Client” proteins are associated with the cancer hallmarks, as cell proliferation and tumor progression. Consequently, Hsp90 has evolved into promising anticancer target. Over the past decade, radicicol has been identified as potential anticancer agent targeting Hsp90, but it is not active in vivo. With that aim of obtaining radicicol-related derivatives, we developed the design and synthesis of new chalcones analogs. Chalcones, which are abundant in edible plants, own a diverse array of pharmacological activities and are considered a versatile scaffold for drug design. Antiproliferative assays and western blot analysis on the new compounds showed that some of those display an interesting cytotoxic effect and the ability to modulate Hsp90 client proteins expression. Androgen Receptor (AR) hypersensitivity plays crucial role in prostate cancer, which progression is stimulated by androgens. The therapy consists in a combination of surgical or chemical castration, along with antiandrogens treatment. Casodex® (bicalutamide), is the most widespread antiandrogen used in clinic. However, hormonal therapy is time-limited since many patients develop resistance. Commercially available antiandrogens show a common scaffold, e.g. two substituted aromatic rings linked by a linear or a cyclic spacer. With the aim of obtaining novel pure AR antagonists, we developed a new synthetic methodology, which allowed us to introduce, as linker between two suitably chosen aromatic rings, a triazole moiety. Preliminary data suggest that the herein reported new molecules generally decrease PSA expression, thus confirming their potential AR antagonistic activity.