3580 Background: Pharmacogenetic research holds the promise of individualizing cancer therapy by reducing inter-individual variability in drug response, thus enhancing efficacy and reducing toxicity. Past research has been limited due to the lack of a robust genotyping platform that can screen for single nucleotide polymorphisms (SNPs) in the dozens of genes known to be involved in drug disposition. We pilot tested the new Affymetrix Targeted Human Drug Metabolizing Enzymes and Transporter (DMET) 1.0 panel in an exploratory study of docetaxel and thalidomide. The DMET 1.0 panel tests for 1,229 genetic variations in 169 drug disposition genes, including 49 CYP450 genes, 73 non-CYP genes, and 47 transporters. Methods: DNA samples from 47 patients with AIPC enrolled in a randomized phase II trial using docetaxel and thalidomide vs. docetaxel alone were genotyped using the DMET 1.0 panel. Patients’ response was determined using RECIST criteria. Toxicities were graded using the NCI-CTC, and patients were identified if they experienced grade 3 or 4 toxicity. Given the distinct side effect profiles of these two drugs, specific toxicities were assigned as being due to either docetaxel or thalidomide. An association between the SNP parameters and clinical response or toxicity was tested using Mehta’s modification to Fisher’s exact test. Reported results were limited to those where p<0.01. Results: Six SNPs in three genes were associated with response to therapy: PPAR-delta (p=0.0011), SULT1C2 (p=0.0083), and CHST3 (4 SNPs, p=0.0001 to 0.0034). For toxicities associated with docetaxel, five SNPs in three genes were identified: UGT1A1 (2 SNPs, p=0.0009 to 0.0094), UGT1A9 (2 SNPs, p=0.0016 to 0.0096), and CYP2A7 (p=0.0027). SNPs in CYP2B6 (p=0.0033), ABCC1 (p=0.0036), and ABCC6 (p=0.0075) were associated with toxicities from thalidomide. Conclusion: We identified nine genes in which SNPs were potentially significantly associated with clinical response and toxicity to treatment. These results highlight the important role that non-CYP450 and phase II drug metabolizing enzymes may play in the efficacy and disposition of docetaxel and thalidomide. Confirmatory studies are warranted. No significant financial relationships to disclose.
Phase I and Phase II drug-metabolizing enzymes are expressed and heterogeneously distributed in the biliary epithelium
