Whole-exome Sequencing Reveals Defective CYP3A4 Variants Predictive of Paclitaxel Dose-limiting Neuropathy

Overview

Journal Clin Cancer Res

Specialty Oncology

Date 2014 Nov 16

PMID 25398452

Citations 37

Authors

Maria Apellaniz-Ruiz

Mi-Young Lee

Lara Sanchez-Barroso

Gerardo Gutierrez-Gutierrez

Isabel Calvo

Laura Garcia-Estevez

Maria Sereno

Jesus Garcia-Donas

Beatriz Castelo

Eva Guerra

Luis J Leandro-Garcia

Alberto Cascon

Inger Johansson

Mercedes Robledo

Magnus Ingelman-Sundberg

Cristina Rodriguez-Antona

Affiliations

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Abstract

Purpose: Paclitaxel, a widely used chemotherapeutic drug, can cause peripheral neuropathies leading to dose reductions and treatment suspensions and decreasing the quality of life of patients. It has been suggested that genetic variants altering paclitaxel pharmacokinetics increase neuropathy risk, but the major causes of interindividual differences in susceptibility to paclitaxel toxicity remain unexplained. We carried out a whole-exome sequencing (WES) study to identify genetic susceptibility variants associated with paclitaxel neuropathy.

Experimental Design: Blood samples from 8 patients with severe paclitaxel-induced peripheral neuropathy were selected for WES. An independent cohort of 228 cancer patients with complete paclitaxel neuropathy data was used for variant screening by DHPLC and association analysis. HEK293 cells were used for heterologous expression and characterization of two novel CYP3A4 enzymes.

Results: WES revealed 2 patients with rare CYP3A4 variants, a premature stop codon (CYP3A4*20 allele) and a novel missense variant (CYP3A4*25, p.P389S) causing reduced enzyme expression. Screening for CYP3A4 variants in the independent cohort revealed three additional CYP3A4*20 carriers, and two patients with missense variants exhibiting diminished enzyme activity (CYP3A4*8 and the novel CYP3A4*27 allele, p.L475V). Relative to CYP3A4 wild-type patients, those carrying CYP3A4 defective variants had more severe neuropathy (2- and 1.3-fold higher risk of neuropathy for loss-of-function and missense variants, respectively, P = 0.045) and higher probability of neuropathy-induced paclitaxel treatment modifications (7- and 3-fold higher risk for loss-of-function and missense variants, respectively, P = 5.9 × 10(-5)).

Conclusion: This is the first description of a genetic marker associated with paclitaxel treatment modifications caused by neuropathy. CYP3A4 defective variants may provide a basis for paclitaxel treatment individualization.

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