Ethnic/Racial Differences in 1, 3-Bitadiene Metabolism and DNA Adduct Formation

Butadiene is an important tobacco smoke carcinogen likely to be involved in the induction of lung tumors in smokers. Butadiene is classified as a known human carcinogen based on epidemiological evidence indicating increased cancer incidence in occupationally exposed workers and in inhalation studies in laboratory animals. The recognized critical step in butadiene-mediated carcinogenesis is the chemical modification of DNA by the epoxy metabolites of butadiene to form covalent adducts. Previous studies have shown that genetic variations in metabolism and repair genes can mediate the sensitivity to butadieneinduced mutations and cancer. Because ofthe requirement for metabolic activation of butadiene, enzymes that are involved in the formation and detoxification of butadiene epoxides largely determine the individual sensitivity to butadiene-mediated mutagenesis and carcinogenesis. Many prominent polymorphisms in genes coding for butadiene metabolizing enzymes, e.g. CYP2E1, EPHX1. and GSTT1, have been identified. Because their frequency differs between ethnic/racial groups, these genetic changes may contribute to the observed inter-ethnic/inter-racial differences in the incidence of lung cancer. Future studies are warranted to determine how the expression levels and genetic variations in biotransformation genes influence the metabolism and biological effects of butadiene in humans. We hypothesize that human populations of different ethnicity/race metabolize butadiene differentiy, contributing to differing degrees of cancer risk following exposure to butadiene in tobacco smoke. The obiective of this application is to investigate inter-individual and inter-ethnic/racial differences in the metabolism of butadiene and in the formation of butadiene-induced DNA adducts and to link these differences to specific polymorphisms of carcinogen metabolism and DNA repair genes. Studies proposed here will quantify the major urinary metabolites of butadiene and butadiene-induced DNA adducts in smokers of varying ethnic groups and identify the effects of genetic polymorphisms on the genotoxicity of butadienederived epoxides. Our approach is innovative, because we will, for the flrst time, analyze the effects of ethnicity/race on butadiene metabolism and DNA adduct formation in a large multi-ethnic cohort.