Liver microsomal uptake of [ 14C]vinyl chloride and transformation to protein alkylating metabolites in vitro

Abstract

[1,2- 14C]Vinyl chloride gas was incubated with rat liver microsomes in an all-glass vacuum system. Microsomal uptake and irreversible protein binding of vinyl chloride radioactivity was determined. Both uptake of vinyl chloride by microsomes and alkylation of proteins by vinyl chloride metabolites were dependent on incubation time, enzymatically active microsomes, NADPH, oxygen, and the partial pressure of vinyl chloride in the atmosphere, and could be inhibited by carbon monoxide. During incubation in presence of NADPH, 10 times more vinyl chloride was taken up by microsomes than in absence of NADPH. Uptake of vinyl chloride by albumin solutions and liposomal suspensions was in a similar range compared to the microsomal uptake without NADPH. Addition of glutathione and cytoplasmic fractions to microsomal incubations with NADPH led to an increase in microsomal uptake of vinyl chloride and to a decrease in protein alkylation by vinyl chloride metabolites. If trichloropropene oxide was present in the microsomal incubation, the protein alkylation reaction by vinyl chloride metabolites was increased twofold, while the microsomal uptake of vinyl chloride was not influenced. Our results are consistent with the view that the microsomal uptake of vinyl chloride radioactivity is due to transformation of vinyl chloride gas to nonvolatile metabolites by microsomal enzymes and that chloroethylene oxide might be the primary microsomal metabolite of vinyl chloride capable of reacting with proteins.