Acetylator genotype-dependent metabolic activation of carcinogenic N-hydroxyarylamines by S-acetyl coenzyme A-dependent enzymes of inbred hamster tissue cytosols: relationship to arylamine N-acetyltransferase

A genetic polymorphism in S-acetyl coenzyme A (AcCoA)-dependentN-acetyltransferase has been associated with a differentialrisk for certain cancers in humans. In this study, several tissuesfrom the inbred Syrian hamster with a genetically defined AcCoA-dependentN-acetyltransferase polymorphism (homozygous rapid acetylator,Bio. 87.20; homozygous slow acetylator, Bio. 82.73/H; and heterozygousacetylator, Bio. 87.20 x Bio. 82.73/H F₁), were investigatedfor the relationship of arylamine N-acetyltransferase to theAcCoA-dependent metabolic activation of carcinogenic N-hydroxy(N-OH)-arylamines to bind to DNA (O-acetyltransferase). Thelevels of both 2-aminofluorene (AF) N-acetyltransferase andN-OH-AF O-acetyltransferase activity reflected the N-acetylatorgenotype in liver, intestine, kidney and lung cytosols. A significantacetylator gene—dose response for AF N-acetyltransferaseand N-OH-AF O-acetyltransferase activities was observed in liverand lung cytosols. In contrast, acetylator genotype was notconsistently expressed for the AcCoA-dependent N-acetylationof 4-aminobiphenyl (ABP), nor for the AcCoA-dependent metabolicactivation of N-OH ABP and N-OH-3,2'-dimethyl-4-aminobiphenylin these me tissue cytosols. Two peaks of acetyltransferaseactivity were partially purified by ion exchange FPLC chromatographyfrom the hepatic cytosol of both the homozygous rapid and homozygousslow acetylator hamster. In contrast to unfractionated cytosol,the isozyme(s) eluting first clearly demonstrated levels ofAcCoA-dependent arylamine N-acetyltransferase and N-OH-arylamineO-acetyltransferase activities that were consistent with N-acetylatorgenotype (polymorphic) for all substrates tested. In contrast,the slower eluting isozyme(s) in each acetylator cytosol showedlevels of AcCoA-dependent N-and O-acetyltransferase activitiesthat did not vary with N-acetylator genotype (monomorphic).The AcCoA-dependent O-acetyltransferase activity of both themonomorphic and polymorphic peaks was paraoxon resistant. Thesestudies demonstrate acetylator genotype-dependent control ofAcCoA-dependent metabolic activation of N-OH-arylamines(O-acetylation)by polymorphic isozyme(s) similar to that for AcCoA-dependentN-acetylation of arylamines in the hamster. The polymorphicgenetic control of N-OH arylamine O-acetyltransferase may bean important risk factor for arylamine-induced cancer, in thosespecies and tissues expressing appreciable levels of O-acetyltransferaseactivity.