Aminobiphenyls (ABPs) in tobacco have been implicated in bladder cancer eti
ology in smokers. N-Acetylation of ABPs in the liver, predominantly by the
N-acetyltransferase 2 (NAT2) isozyme, represents a detoxification pathway,
whereas O-acetylation of N-hydroxy-ABPs in the bladder, predominantly by th
e N-acetyltransferase 1 (NAT1) isozyme, represents a bioactivation pathway,
We and others have demonstrated that NAT2 phenotype affects 3- and 4-ABP-h
emoglobin adduct levels (higher levels in slow acetylators), which are cons
idered valid biomarkers of the internal dose of ABP to the bladder, We have
also shown that NAT1 genotype (NAT1*10 allele) is associated with increase
d DNA adduct levels in urothelial tissue and higher risk of bladder cancer
among smokers. It is not known whether NAT1*10 genotype influences ABP-hemo
globin adduct levels. Therefore, me assessed 403 primarily non-Hispanic whi
te residents of Los Angeles County for their NAT2 acetylator phenotype, NAT
1*10 acetylator genotype, and 3- and 1-ABP-hemoglobin adduct levels. Eighty
-two subjects were current tobacco smokers of varying intensities, Tobacco
smokers had significantly higher mean 3- and I-ABP-hemoglobin adduct levels
relative to nonsmokers. The levels increased with increased amounts smoked
per day (two-sided, P < 0.0001 in all cases). With adjustment for NAT1 gen
otype and race, the smoking-adjusted geometric mean level of 3-ABP-hemoglob
in adducts in NAT2 slow acetylators was 47% higher than that in NAT2 rapid
acetylators (P = 0.01), The comparable value for 4-ABP-hemoglobin adducts w
as 17% (P = 0.02). In contrast, no association between NAT1*10 genotype and
3- or 4 ABP-hemoglobin adduct levels was observed after adjustment for NAT
2 phenotype, smoking, and race. The present study suggests that the impact
of the NAT1*10 genotype on 3- and 4-ABP-hemoglobin adducts is noninformativ
e on the possible association between NAT1 activity and bladder cancer risk
.