Role of human CYP1A1 and NAT2 in 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine-induced mutagenicity and DNA adducts.

2-Amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) is carcinogenic in multiple organs and numerous species. Bioactivation of PhIP is initiated by PhIP N(2)-hydroxylation catalysed by cytochrome P450s. Following N-hydroxylation, O-acetylation catalysed by N-acetyltransferase 2 (NAT2) is considered a further possible activation pathway. Genetic polymorphisms in NAT2 may modify cancer risk following exposure. Nucleotide excision repair-deficient Chinese hamster ovary (CHO) cells stably transfected with human cytochrome P4501A1 (CYP1A1) and a single copy of either NAT2*4 (rapid acetylator) or NAT2*5B (slow acetylator) alleles were used to test the effect of CYP1A1 and NAT2 polymorphism on PhIP genotoxicity. Cells transfected with NAT2*4 had significantly higher levels of N-hydroxy-PhIP O-acetyltransferase (p = 0.0150) activity than cells transfected with NAT2*5B. Following PhIP treatment, CHO cell lines transfected with CYP1A1, CYP1A1/NAT2*4 and CYP1A1/NAT2*5B each showed concentration-dependent cytotoxicity and hypoxanthine phosphoribosyl transferase (hprt) mutagenesis not observed in untransfected CHO cells. dG-C8-PhIP was the primary DNA adduct formed and levels were dose dependent in transfected CHO cells in the order: CYP1A1 < CYP1A1 and NAT2*5B < CYP1A1 and NAT2*4, although levels did not differ significantly (p > 0.05) following one-way analysis of variance. These results strongly support activation of PhIP by CYP1A1 with little effect of human NAT2 genetic polymorphism on mutagenesis and DNA damage.

Functional characterization of nucleotide polymorphisms in the coding region of N-acetyltransferase 1.

N-acetyltransferase 1 (NAT1) catalyses the activation and/or deactivation of aromatic and heterocyclic amine carcinogens. A genetic polymorphism in NAT1 is associated with an increased risk of various cancers and drug toxicities, but epidemiological investigations are severely compromised by a poor understanding of the relationship between NAT1 genotype and phenotype. Human reference NAT1*4 and 12 known human NAT1 allelic variants possessing nucleotide polymorphisms in the NAT1 coding region were cloned and expressed in yeast (Schizosaccharomyces pombe). Large reductions in N- and O-acetyltransferase catalytic activities were observed for recombinant NAT1 allozymes encoded by NAT1*14B, NAT1*15, NAT1*17, NAT1*19 and NAT1*22. Each of these alleles exhibited NAT1 protein expression levels below the limit of detection as measured by Western blot. No differences between high and low activity NAT1 alleles were observed in relative mRNA expression or relative transformation efficiency. The recombinant NAT1 17 and NAT1 22 allozymes showed reduced intrinsic stability when compared with NAT1 4. 2-Amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) N-acetylation was not catalysed by any of the NAT1 allozymes. Large differences in the metabolic activation via O-acetylation of 2-hydroxyamino-1-methyl-6-phenylimidazo[4,5-b]pyridine (N-hydroxy-PhIP) were noted for NAT1 allelic variants. The results of these studies suggest an important role for the NAT1 genetic polymorphism in metabolism of aromatic and heterocyclic amine carcinogens. Furthermore, these results suggest that low NAT1 phenotype results from NAT1 allelic variants that encode reduced expression of NAT1 and/or less-stable NAT1 protein.

Functional characterization of human N-acetyltransferase 2 (NAT2) single nucleotide polymorphisms.

N-Acetyltransferase 2 (NAT2) catalyses the activation and/or deactivation of a variety of aromatic amine drugs and carcinogens. Polymorphisms in the N-acetyltransferase 2 (NAT2) gene have been associated with a variety of drug-induced toxicities, as well as cancer in various tissues. Eleven single nucleotide polymorphisms (SNPs) have been identified in the NAT2 coding region, but the specific effects of each of these SNPs on expression of NAT2 protein and N-acetyltransferase enzymatic activity are poorly understood. To investigate the functional consequences of SNPs in the NAT2 coding region, reference NAT2*4 and NAT2 variant alleles possessing one of the 11 SNPs in the NAT2 coding region were cloned and expressed in yeast (Schizosaccharomyces pombe). Reductions in catalytic activity for the N-acetylation of a sulfonamide drug (sulfamethazine) and an aromatic amine carcinogen (2-aminofluorene) were observed for NAT2 variants possessing G191A (R64Q), T341C (I114T), A434C (E145P), G590A (R197Q), A845C (K282T) or G857A (G286T). Reductions in expression of NAT2 immunoreactive protein were observed for NAT2 variants possessing T341C, A434C or G590A. Reductions in protein stability were noted for NAT2 variants possessing G191A, A845C, G857A or, to some extent, G590A. No significant differences in mRNA expression or transformation efficiency were observed among any of the NAT2 alleles. These results suggest two mechanisms for slow acetylator phenotype(s) and more clearly define the effects of individual SNPs on human NAT2 expression, stability and catalytic activity.

DNA adduct levels and absence of tumors in female rapid and slow acetylator congenic hamsters administered the rat mammary carcinogen 2-amino-1-methyl-6-phenylimidazo[4,5-b] pyridine.

N-acetyltransferases (EC 2.3.1.5) catalyze O-acetylation of heterocyclic amine carcinogens to DNA-reactive electrophiles that bind and mutate DNA. An acetylation polymorphism exists in humans and Syrian hamsters regulated by N-acetyltransferase-2 (NAT2) genotype. Some human epidemiological studies suggest a role for NAT2 phenotype in predisposition to cancers related to heterocyclic amine exposures, including breast cancer. 2-Amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) is a heterocyclic amine carcinogen prevalent in the human environment and induces a high incidence of mammary tumors in female rats. PhIP-induced carcinogenesis was examined in female rapid and slow acetylator Syrian hamsters congenic at the NAT2 locus. In both rapid and slow acetylators, PhIP-DNA adduct levels were highest in pancreas, lower in heart, small intestine, and colon, and lowest in mammary gland and liver. Metabolic activation of N-hydroxy-PhIP by O-acetyltransferase was highest in mammary epithelial cells, lower in liver and colon, and lowest in pancreas. Metabolic activation of N-hydroxy-PhIP by O-sulfotransferase was low in liver and colon and below the limit of detection in mammary epithelial cells and pancreas. Unlike the rat, PhIP did not induce breast or any other tumors in female rapid and slow acetylator congenic hamsters administered high-dose PhIP (10 doses of 75 mg/kg) and a high-fat diet.

N-Acetyltransferase-2 genetic polymorphism, well-done meat intake, and breast cancer risk among postmenopausal women.

Heterocyclic amines found in well-done meat require host-mediated metabolic activation before initiating DNA mutations and tumors in target organs. Polymorphic N-acetyltransferase-2 (NAT2) catalyzes the activation of heterocyclic amines via O-acetylation, suggesting that NAT2 genotypes with high O-acetyltransferase activity (rapid/intermediate acetylator phenotype) increase the risk of breast cancer in women who consume well-done meat. To test this hypothesis, DNA samples and information on diet and other breast cancer risk factors were obtained from a nested case-control study of postmenopausal women. Twenty-seven NAT2 genotypes were determined and assigned to rapid, intermediate, or slow acetylator groups based on published characterizations of recombinant NAT2 allozymes. NAT2 genotype alone was not associated with breast cancer risk. A significant dose-response relationship was observed between breast cancer risk and consumption of well-done meat among women with the rapid/intermediate NAT2 genotype (trend test, P = 0.003) that was not evident among women with the slow acetylator genotype (trend test, P = 0.22). These results suggest an interaction between NAT2 genotype and meat doneness, although a test for multiplicative interaction was not statistically significant (P = 0.06). Among women with the rapid/intermediate NAT2 genotype, consumption of well-done meat was associated with a nearly 8-fold (odds ratio, 7.6; 95% confidence interval, 1.1-50.4) elevated breast cancer risk compared with those consuming rare or medium-done meats. These results are consistent with a role for O-acetylation in the activation of heterocyclic amine carcinogens and support the hypothesis that the NAT2 acetylation polymorphism is a breast cancer risk factor among postmenopausal women with high levels of heterocyclic amine exposure.

A role for bioactivation and covalent binding within epidermal keratinocytes in sulfonamide-induced cutaneous drug reactions.

Cutaneous reactions are the most common manifestation of delayed-type hypersensitivity caused by sulfamethoxazole and dapsone. In light of the recognized metabolic and immunologic activity of the skin, we investigated the potential role of normal human epidermal keratinocytes in the development of these reactions. Adult and neonatal normal human epidermal keratinocytes metabolized sulfamethoxazole and dapsone to N-4-hydroxylamine and N-acetyl derivatives in a time-dependent manner. The latter was catalyzed by N-acetyltransferase 1 alone as normal human epidermal keratinocytes did not express mRNA for N-acetyltransferase 2. Investigation of metabolism-dependent toxicity of sulfamethoxazole and dapsone, and subsequent incubation of normal human epidermal keratinocytes with the respective hydroxylamine metabolites, demonstrated that these cells were resistant to the cytotoxic effects of sulfamethoxazole hydroxylamine but not dapsone hydroxylamine. With prior depletion of glutathione, however, normal human epidermal keratinocytes became susceptible to the toxicity of sulfamethoxazole hydroxylamine. Covalent adduct formation by sulfamethoxazole hydroxylamine was detected in normal human epidermal keratinocytes, even in the absence of cell death, and was increased with glutathione depletion. Major protein targets of sulfamethoxazole hydroxylamine were observed in the region of 160, 125, 95, and 57 kDa. Dapsone hydroxylamine also caused covalent adduct formation in normal human epidermal keratinocytes. Together, these observations provide a basis for our hypothesis that normal human epidermal keratinocytes are involved in the initiation and propagation of a cutaneous hypersensitivity response to these drugs.

Acetylator phenotype and genotype in patients infected with HIV: discordance between methods for phenotype determination and genotype.

The acetylator phenotype and genotype of AIDS patients, with and without an acute illness, was compared with that of healthy control subjects (30 per group). Two probe drugs, caffeine and dapsone, were used to determine the phenotype in the acutely ill cohort. Polymerase chain reaction amplification and restriction fragment length polymorphism analysis served to distinguish between the 26 known NAT2 alleles and the 21 most common NAT1 alleles. The distribution (%) of slow:rapid acetylator phenotype seen among acutely ill AIDS patients differed with the probe substrate used: 70:30 with caffeine versus 53:47 with dapsone. Phenotype assignment differed considerably between the two methods and there were numerous discrepancies between phenotype and genotype. The NAT2 genotype distribution was 45:55 slow:rapid. Control subjects, phenotyped only with caffeine, were 67:33 slow:rapid versus 60:40 genotypically. Stable AIDS patients, phenotyped only with dapsone, were 55:45 slow:rapid versus 46:54 genotypically. Following resolution of their acute infections, 12 of the acutely ill subjects were rephenotyped with dapsone. Phenotype assignment remained unchanged in all cases. The distribution of NAT1 alleles was similar in all three groups. It is evident from the amount of discordance between caffeine phenotype and dapsone phenotype or genotype that caution should be exercised in the use of caffeine as a probe for NAT2 in acutely ill patients. It is also clear that meaningful study of the acetylation polymorphism requires both phenotypic and genotypic data.

Molecular genetics and epidemiology of the NAT1 and NAT2 acetylation polymorphisms.

The focus of this review is the molecular genetics, including consensus NAT1 and NAT2 nomenclature, and cancer epidemiology of the NAT1 and NAT2 acetylation polymorphisms. Two N-acetyltransferase isozymes, NAT1 and NAT2, are polymorphic and catalyze both N-acetylation (usually deactivation) and O-acetylation (usually activation) of aromatic and heterocyclic amine carcinogens. Epidemiological studies suggest that the NAT1 and NAT2 acetylation polymorphisms modify risk of developing urinary bladder, colorectal, breast, head and neck, lung, and possibly prostate cancers. Associations between slow NAT2 acetylator genotypes and urinary bladder cancer and between rapid NAT2 acetylator genotypes and colorectal cancer are the most consistently reported. The individual risks associated with NAT1 and/or NAT2 acetylator genotypes are small, but they increase when considered in conjunction with other susceptibility genes and/or aromatic and heterocyclic amine carcinogen exposures. Because of the relatively high frequency of some NAT1 and NAT2 genotypes in the population, the attributable cancer risk may be high. The effect of NAT1 and NAT2 genotype on cancer risk varies with organ site, probably reflecting tissue-specific expression of NAT1 and NAT2. Ethnic differences exist in NAT1 and NAT2 genotype frequencies that may be a factor in cancer incidence. Large-scale molecular epidemiological studies that investigate the role of NAT1 and NAT2 genotypes and/or phenotypes together with other genetic susceptibility gene polymorphisms and biomarkers of carcinogen exposure are necessary to expand our current understanding of the role of NAT1 and NAT2 acetylation polymorphisms in cancer risk.

Novel human N-acetyltransferase 2 alleles that differ in mechanism for slow acetylator phenotype.

Three novel human NAT2 alleles (NAT2*5D, NAT2*6D, and NAT2*14G) were identified and characterized in a yeast expression system. The common rapid (NAT2*4) and slow (NAT2*5B) acetylator human NAT2 alleles were also characterized for comparison. The novel recombinant NAT2 allozymes catalyzed both N- and O-acetyltransferase activities at levels comparable with NAT2 5B and significantly below NAT2 4, suggesting that they confer slow acetylation phenotype. In order to investigate the molecular mechanism of slow acetylation in the novel NAT2 alleles, we assessed mRNA and protein expression levels and protein stability. No differences were observed in NAT2 mRNA expression among the novel alleles, NAT2*4 and NAT2*5B. However NAT2 5B and NAT2 5D, but not NAT2 6D and NAT2 14G protein expression were significantly lower than NAT2 4. In contrast, NAT2 6D was slightly (3.4-fold) and NAT2 14G was substantially (29-fold) less stable than NAT2 4. These results suggest that the 341T --> C (Ile(114) --> Thr) common to the NAT2*5 cluster is sufficient for reduction in NAT2 protein expression, but that mechanisms for slow acetylator phenotype differ for NAT2 alleles that do not contain 341T --> C, such as the NAT2*6 and NAT2*14 clusters. Different mechanisms for slow acetylator phenotype in humans are consistent with multiple slow acetylator phenotypes.

Prostate-specific human N-acetyltransferase 2 (NAT2) expression in the mouse.

2-Amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) is a heterocyclic amine identified in the human diet and in cigarette smoke that produces prostate tumors in the rat. PhIP is bioactivated by cytochrome P-450 enzymes to N-hydroxylated metabolites that undergo further activation by conjugation enzymes, including the N-acetyltransferases, NAT1 and NAT2. To investigate the role of prostate-specific expression of human N-acetyltransferase 2 (NAT2) on PhIP-induced prostate cancer, we constructed a transgenic mouse model that targeted expression of human NAT2 to the prostate. Following construction, prostate, liver, lung, colon, small intestine, urinary bladder, and kidney cytosols were tested for human NAT1- and NAT2-specific N-acetyltransferase activities. Human NAT2-specific N-acetyltransferase activities were 15-fold higher in prostate of transgenic mice versus control mice, but were equivalent between transgenic mice and control mice in all other tissues tested. Human NAT1-specific N-acetyltransferase activities did not differ between transgenic and control mice in any tissue tested. Prostate cytosols from transgenic and control mice did not differ in their capacity to catalyze the N-acetylation of 2-aminofluorene, the O-acetylation of N-hydroxy-2-aminofluorene and N-hydroxy-PhIP or the N,O-acetylation of N-hydroxy-2-acetylaminofluorene. Transgenic and control mice administered PhIP did not differ in PhIP-DNA adduct levels in the prostate. This study is the first to report transgenic expression of human NAT2 in the mouse. The results do not support a critical role for bioactivation of heterocyclic amine carcinogens by human N-acetyltransferase-2 in the prostate. However, the lack of an effect may relate to the level of overexpression achieved and the presence of endogenous mouse acetyltransferases and/or sulfotransferases.

A restriction fragment length polymorphism assay that differentiates human N-acetyltransferase-1 (NAT1) alleles.

Currently there is much interest in the N-acetyltransferase-1 (NAT1) genetic polymorphism and its relationship to cancer. Previous studies have described methods to distinguish NAT1 alleles through polymerase chain reaction (PCR) restriction fragment length polymorphism (RFLP) and/or allele-specific amplification. However, these methods detect at most only four of the NAT1 alleles identified in human populations. In this paper we describe a PCR-RFLP-based assay that differentiates among eight human NAT1 alleles (NAT1*3, *4, *5, *10, *11, *14, *15, *16). This method should prove useful in molecular epidemiological studies investigating associations between NAT1 genotype and cancer.

Rodent models of the human acetylation polymorphism: comparisons of recombinant acetyltransferases.

The acetylation polymorphism is associated with differential susceptibility to drug toxicity and cancers related to aromatic and heterocyclic amine exposures. N-Acetylation is catalyzed by two cytosolic N-acetyltransferases (NAT1 and NAT2) which detoxify many carcinogenic aromatic amines. NAT1 and NAT2 also activate (via O-acetylation) the N-hydroxy metabolites of aromatic and heterocyclic amine carcinogens to electrophilic intermediates which form DNA adducts and initiate cancer. The classical N-acetylation polymorphism is regulated at the NAT2 locus, which segregates individuals into rapid, intermediate, and slow acetylator phenotypes. Some human epidemiological studies associate slow acetylator and rapid acetylator phenotypes with increased susceptibility to urinary bladder and colorectal cancers, respectively. The acetylation polymorphism has been characterized in three rodent species (mouse, Syrian hamster, and rat) to test associations between NAT2 acetylator phenotype and susceptibility to aromatic and heterocyclic amine-induced cancers in various tumor target organs. NAT1 and NAT2 from rapid and slow acetylator mouse, Syrian hamster, and rat each have been cloned and sequenced. Recombinant NAT1 and NAT2 enzymes enzymes encoded by these genes have been characterized with respect to their catalytic activities for both activation (O-acetylation) and deactivation (N-acetylation) of aromatic and heterocyclic amine carcinogens. The acetylation polymorphisms in mouse, Syrian hamster, and rat are herein reviewed and compared as models of the human acetylation polymorphism.

Identification of a novel allele at the human NAT1 acetyltransferase locus.

Humans possess two N-acetyltransferase isozymes (NAT1 and NAT2). We cloned and sequenced a novel NAT1 allele (Genbank HSU 80835) that contained nucleotide substitutions at -344 (C-->T), -40 (A-->T), 445 [G-->A(Val-->Ile)], 459 [G-->A(silent)], 640 [T-->G(Ser-->Ala)], a 9 base pair deletion between nucleotides 1065 and 1090, and 1095 (C-->A). The novel NAT1 allele which we have designated NAT1*17 is similar to NAT1*11 except for a G445A substitution (Val149-->Ile) in the NAT1 coding region. The G445A (Val149-->Ile) substitution yielded no significant changes in levels of immunoreactivity, as detected by Western blot, nor in intrinsic stability of the recombinant N-acetyltransferase protein. However, the G445A (Val149-->Ile) substitution yielded expression of recombinant NAT1 protein that catalyzed the N-acetylation of aromatic amines and the O- and N,O-acetylation of their N-hydroxylated metabolites at rates up to 2-fold higher than wild-type recombinant human NAT1.

Cloning, sequencing, and recombinant expression of NAT1, NAT2, and NAT3 derived from the C3H/HeJ (rapid) and A/HeJ (slow) acetylator inbred mouse: functional characterization of the activation and deactivation of aromatic amine carcinogens.

An acetylator polymorphism has been described in the mouse and the inbred strains C3H/HeJ and A/HeJ constitute rapid and slow acetylators, respectively. The NAT1, NAT2, and NAT3 genes from C3H/HeJ and A/HeJ acetylator inbred mouse strains were amplified using the polymerase chain reaction, cloned into the plasmid vector pUC19, and sequenced. They were then subcloned into the prokaryotic expression vector pKK223-3 and expressed in Escherichia coli strain JM105. The 870-bp nucleotide coding region of NAT1 and NAT3 did not differ between the rapid and slow acetylator mouse strains, or from that of previously published mouse NAT1 and NAT3 sequences. However, NAT2 did differ between the rapid and slow acetylator strains with an A296 T transition which causes a (Asn99-->Ile) substitution in the deduced amino acid sequence. Recombinant NAT1, NAT2, and NAT3 proteins catalyzed N-, O-, and N,O-acetyltransferase activities. NAT3 catalyzed aromatic amine N-acetyltransferase activities at very low rates, which confirms a previous study. Apparent K(m) and Vmax kinetic constants for N-acetylation were 5- to 10-fold lower for recombinant mouse NAT1 than NAT2. Intrinsic clearances for recombinant mouse NAT1- and NAT2-catalyzed N-acetylation of aromatic amine carcinogens were comparable. Both recombinant mouse NAT1 and NAT2 catalyzed the metabolic activation of N-hydroxyarylamine (O-acetylation) and N-hydroxyarylamide (N,O-acetylation) carcinogens. Recombinant mouse NAT3 catalyzed N,O-acetylation at very low rates, while O-acetylation was undetectable. No difference was observed between rapid and slow acetylator recombinant NAT2 proteins to activate aromatic amines by O- or N,O-acetylation, in substrate specificity, expression of immunoreactive protein, electrophoretic mobility, or N-acetyltransferase Michaelis-Menten kinetic constants. However, the slow acetylator recombinant NAT2 protein was over 10-fold less stable than rapid acetylator recombinant NAT2. These studies demonstrate metabolic activation and deactivation by recombinant mouse NAT1, NAT2, and NAT3 proteins and confirm and extend previous studies on the molecular basis for the acetylation polymorphism in the mouse.

Recombinant expression and catalytic analysis of rapid and slow acetylator Syrian hamster chimeric NAT2 alleles.

Polymorphic aromatic amine N-acetyltransferase (NAT2) catalyzes the N-acetylation of aromatic amines and the metabolic activation of N-hydroxyarylamines (via O-acetylation) and N-hydroxy-N-acetylarylamines (via N,O-acetylation) to electrophilic intermediates that mutate DNA. Acetylation capacity in humans and other mammalian species such as Syrian hamsters is subject to a genetic polymorphism. NAT2 is regulated by a single gene (NAT2) containing a single coding exon of 870 bp. Syrian hamster slow acetylator differs from the rapid acetylator NAT2 coding region by three nucleotide substitutions at T36C, A633G, and C727T. We measured expression of immunoreactive NAT2 protein and aromatic amine N-acetylation. N-hydroxyarylamine O-acetylation and N-hydroxy-N-acetylarylamine N,O-acetylation by recombinant NAT2 proteins expressed from alleles containing all combinations of the T36C, A633G, and C727T substitutions. The C727T substitution, which creates an opal stop codon in slow acetylator NAT2, was the sole mutation responsible for substantial reduction in expression of a truncated NAT2 protein with reduced capacity for the deactivation of aromatic amines (N-acetylation) and the metabolic activation of N-hydroxyarylamines (O-acetylation) and N-hydroxy-N-acetylarylamines (N,O-acetylation). The reductions in aromatic amine N-acetylation correlated very highly with the reductions in metabolic activation of the corresponding N-hydroxyarylamines and N-hydroxy-N-acetylarylamines.

Acetyl CoA:arylamine N-acetyltransferase activity in rat hepatocytes cultured on different extracellular matrices.

N-Acetyltransferase (NAT) activity towards p-aminobenzoic acid and sulfamethazine was examined in primary cultures of rat hepatocytes cultured on three extracellular matrices (ECM)-type I collagen, thermally denatured type I collagen, and Matrigel((R)). Whereas protein and DNA content declined markedly during the first 24 hr of culture, p-acetylamidobenzoate (AcPABA) and N-acetylsulfamethazine (AcSMZ) formation were readily detectable on all three ECM for the 6-day culture period. Protein and DNA content, as well as NAT activities, were higher on Matrigel than on either of the other two ECM. Additional studies were conducted to confirm the expression of both enzymes during the culture period. The ratio of AcPABA to AcSMZ formation remained relatively stable throughout the 6-day culture period, suggesting that both enzymes continued to be expressed throughout the study period. Further studies in cells cultured on Matrigel revealed that AcPABA formation exhibited a time-dependent decline when cytosol from cultured cells was incubated at 50 degrees C, whereas AcSMZ formation proved to be thermostable. Moreover, methotrexate substantially inhibited AcPABA formation, but had only modest effects on AcSMZ. These studies support the conclusion that AcPABA and AcSMZ are predominantly formed by way of different enzymes throughout the culture period. These findings are supported by the observation that NAT1 and NAT2 mRNA were detectable on all days examined. These data indicate that primary cultures of rat hepatocytes should prove useful in probing the regulation of NAT and its role in toxicity.

Human N-acetylation of benzidine: role of NAT1 and NAT2.

These studies were designed to assess metabolism of benzidine and N-acetylbenzidine by N-acetyltransferase (NAT) NAT1 and NAT2. Metabolism was assessed using human recombinant NAT1 and NAT2 and human liver slices. For benzidine and N-acetylbenzidine, Km and Vmax values were higher for NAT1 than for NAT2. The clearance ratios (NAT1/NAT2) for benzidine and N-acetylbenzidine were 54 and 535, respectively, suggesting that N-acetylbenzidine is a preferred substrate for NAT1. The much higher NAT1 and NAT2 Km values for N-acetylbenzidine (1380 +/- 90 and 471 +/- 23 microM, respectively) compared to benzidine (254 +/- 38 and 33.3 +/- 1.5 microM, respectively) appear to favor benzidine metabolism over N-acetylbenzidine for low exposures. Determination of these kinetic parameters over a 20-fold range of acetyl-CoA concentrations demonstrated that NAT1 and NAT2 catalyzed N-acetylation of benzidine by a binary ping-pong mechanism. In vitro enzymatic data were correlated to intact liver tissue metabolism using human liver slices. Samples incubated with either [3H]benzidine or [3H]N-acetylbenzidine had a similar ratio of N-acetylated benzidines (N-acetylbenzidine + N',N'-diacetylbenzidine/ benzidine) and produced amounts of N-acetylbenzidine > benzidine > N,N'-diacetylbenzidine. With [3H]benzidine, p-aminobenzoic acid, a NAT1-specific substrate, increased the amount of benzidine and decreased the amount of N-acetylbenzidine produced, resulting in a decreased ratio of acetylated products. This is consistent with benzidine being a NAT1 substrate. N-Acetylation of benzidine or N-acetylbenzidine by human liver slices did not correlate with the NAT2 genotype. However, a higher average acetylation ratio was observed in human liver slices possessing the NAT1*10 compared to the NAT1*4 allele. Thus, a combination of human recombinant NAT and liver slice experiments has demonstrated that benzidine and N-acetylbenzidine are both preferred substrates for NAT1. These results also suggest that NAT1 may exhibit a polymorphic expression in human liver.

Cloning, expression, and functional characterization of rapid and slow acetylator polymorphic N-acetyl-transferase encoding genes of the Syrian hamster.

Syrian hamster acetylation capacity is catalysed by two N-acetyltransferase isozymes (NAT1 and NAT2). Hamster NAT2 (polymorphic) displays acetylator-genotype dependent activity resulting in high, intermediate, and low activity levels in homozygous rapid, heterozygous and homozygous slow acetylators, respectively. A lambda gt10 size-selected genomic library was constructed from Eco RI-digested homozygous slow acetylator Bio. 82.73/H-Pats congenic hamster DNA and screened with a hamster NAT1 probe. A 4.2 kb Eco RI insert from a positive clone was subcloned into pUC18 and the intron-free NAT2 coding region was sequenced. The NAT2 coding regions from genomic templates of other homozygous rapid and slow acetylator congenic and inbred hamster lines were amplified by the polymerase chain reaction, cloned, and sequenced. Two NAT2 alleles were found, one (NAT2*15) from each homozygous rapid acetylator line and one (NAT2*16A) from each homozygous slow acetylator line. NAT2*15 contained an 870 bp open reading frame encoding a 290 amino acid protein. NAT2*16A was similar except for two silent (T36C and A633G) and one nonsense (C727T) substitutions yielding a 242 amino acid open reading frame. The NAT2*15 and NAT2*16A alleles were expressed in Escherichia coli JM105 and the recombinant proteins were characterized. Electrophoretic mobilities of the NAT2 15 and NAT2 16A recombinant hamster proteins differed and correlated with the theoretical molecular weights calculated from their respective open reading frames. NAT2 16A exhibited 500-to 1000-fold lower maximum velocities compared to NAT2 15 for N-acetylation of all arylamine and hydrazine substrates tested. NAT2 16A also catalysed the metabolic activation of N-hydroxyarylamines and N-hydroxyarylamides at rates 33- and 23-fold lower than NAT2 15. Intrinsic clearance (Vmax/Km) calculations suggest that N-acetylation of p-aminobenzoic acid and 2-aminofluorene in Syrian hamsters is catalysed primarily by NAT2 (NAT2 15) in rapid acetylators but by NAT1 (NAT1 9) in slow acetylators. These results provide a molecular basis for rapid and slow acetylator phenotype in the Syrian hamster.

Determination of human NAT2 acetylator genotype by restriction fragment-length polymorphism and allele-specific amplification.

The human N-acetylation polymorphism, encoded by the NAT2 gene locus, has been associated with higher incidence and/or severity to the adverse effects of therapeutic drugs, and to the carcinogenic actions of environmental and occupational chemicals. In this paper, we describe an efficient method of restriction fragment-length polymorphism and allele-specific amplification analysis which distinguishes between each of 15 (NAT2*4, *5A, *5B, *5C, *6A, *6B, *7A, *7B, *12A, *12B, *13, *14A, *14B, *17, *18) NAT2 alleles that have been identified in human populations. The method should have broad applicability to improvement of drug therapy and to molecular epidemiology investigations of genetic predisposition to cancer and other diseases.