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.     

Analysis of NAT2 point mutations with biological microchips

The NAT2 product, N-acetyltransferase 2, is involved in biotransformation and detoxification of several aromatic amines (in particular, 2-aminofluorene, 4-aminobiphenyl, and 4-naphthylamine), which are strongly mutagenic and carcinogenic, and acetylates some drugs, affecting their metabolism. A biological microchip was developed to detect 16 point mutations, which determine 36 alleles and 660 genotypes of NAT2. The genotypes can be divided into four groups according to the acetylator phenotype: groups with rapid (R/R), intermediate (R/S), or slow (S/S) acetylation and a group combining intermediate and slow alleles (“R/S or S/S”). The last group includes the alleles determined by combinations of seven mutations (191G/A, 282C/T, 341T/C, 481C/T, 590G/A, 803A/G, and 857G/A), whose cis or trans position is detectable by restriction enzyme analysis. The NAT2 genotype was unequivocally established for 37 out of 71 DNA specimens, while the other 34 specimens were characterized by more than two genotypes. By the acetylator phenotype, 16 out of the 34 genotypes were assigned to the group “R/S or S/S,” combining mutations 282C/T, 341T/C, 481C/T, 590G/A, and 803A/G. Thus, the biochip allows primary analysis of most NAT2 polymorphic substitutions, the acetylator genotype being important to know in predictive medicine and individualized therapy.     

Identification of functionally significant mutations in NAT2 gene using biological microchips

The product of gene NAT2 (N-acetyltransferase 2) is involved in the biotransformation system and participates in detoxication of some arylamine derivatives (in particular 2-aminofluorene, 4-aminobiphenyl and 4-naphthylamine) which are strongly mutagenic and carcinogenic. It also renders toxicological and pharmacological influence on a metabolism of medical products metabolized by the enzyme. We developed a microchip for detection of 16 functionally significant mutations coding 36 alleles of gene NAT2. Combinations of these alleles allow us to reveal more than 660 genotypes, which can be divided into four groups according acetylation phenotype: "fast" (R/R), "intermediate" (R/S), "slow" (S/S) and group with average or slow acetylating (R/S or S/S) alleles. The groups "R/S or S/S" include alleles, formed by a combination of 7 mutations (191G/A, 282C/T, 341T/C, 481C/T, 590G/A, 803A/G, 857G/A), theirs cis-trans position can be revealed by restriction analysis. In 37 of 71 DNA samples we unequivocally defined NAT2-genotypes, and other 34 samples have been characterized by more than two genotypes. 16 samples out of 34 had acetylation phenotype of group "R/S or S/S", which is characterized by the following combination of mutations: 282C/T, 341T/C, 481C/T, 590G/A and 803A/G. Thus, the developed biochip is a convenient screening method for primary detection of the majority of polymorphic replacements in gene NAT2.     

Genetic profile of the arylamine N-acetyltransferase 2 coding gene among individuals from two different regions of Brazil

Arylamine N-acetyltranferase 2 is the main enzyme responsible for the isoniazid metabolization into hepatotoxic intermediates and the degree of hepatotoxicity severity has been attributed to genetic variability in the NAT2 gene. The main goal of this study was to describe the genetic profile of the NAT2 gene in individuals from two different regions of Brazil: Rio de Janeiro and Goiás States. Therefore, after preparation of DNA samples from 404 individuals, genotyping of the coding region of NAT2 was performed by direct PCR sequencing. Thirteen previously described SNPs were detected in these Brazilian populations, from which seven: 191 G>A; 282 C>T; 341 T>C; 481 C>T; 590 G>A; 803 A>G and 857 G>A are the most frequent in other populations. The presence of so-called ethnic-specific SNPs in our population is in accordance with the Brazilians' multiple ancestry. Upon allele and genotype analysis, the most frequent NAT2 alleles were respectively NAT2*5B (33%), NAT2*6A (26%) and NAT2*4 (20%) being NAT2*5/*5 the more prevalent genotype (31.7%). These results clearly demonstrate the predominance in the studied Brazilian groups of NAT2 alleles associated with slow over the fast and intermediate acetylator genotypes. Additionally, in Rio de Janeiro, a significantly higher frequency of intermediate acetylation status was found when compared to Goiás (42.5% versus 25%) (p=0.05), demonstrating that different regions of a country with a population characterized by a multi-ethnic ancestry may present a large degree of variability in NAT2 allelic frequencies. This finding has implications in the determination of nationwide policies for use of appropriate anti-TB drugs.     

Arylamine N-acetyltransferase 2 genotypes in a Mexican population

The acetylating activity of N-acetyltransferase 2 (NAT2) has critical implications for therapeutics and disease susceptibility. To date, several polymorphisms that alter the enzymatic activity and/or protein stability of NAT2 have been identified. We examined the distribution and frequency of NAT2 genotypes in the Mexican population. Among 250 samples amplified and sequenced for the NAT2 gene, we found seven different SNPs; the most frequent allele was 803 A>G (35.8%), followed by 282 C>T, 341 T>C, and 481 C>T. There were no differences in the distribution of SNPs between healthy subjects and cancer patients. These eight polymorphisms defined 26 diplotypes; 11.6% were wild type (NAT2*4/NAT2*4), while the most common diplotype was NAT2*4/NAT2*5B, present in 17.2%. We did not identify other common polymorphisms. The results were compared with the NAT2 SNPs reported from other populations. All but the Turkish population was significantly different from ours. We conclude that the mixed-race Mexican population requires special attention because NAT2 genotype frequencies differ from those in other regions of the world.     

Functional genomics of C190T single nucleotide polymorphism in human N-acetyltransferase 2

N-acetyltransferase 2 (NAT2) catalyzes N-acetylation and O-acetylation of many drugs and environmental carcinogens. Genetic polymorphisms in the NAT2 gene have been associated with differential susceptibility to cancers and drug toxicity from these compounds. Single nucleotide polymorphisms (SNPs) have been identified in the human NAT2 coding region. A new allele, NAT2*19, possessing the C190T (R64W) exchange, was recently identified. In order to understand the effect of this new SNP, recombinant NAT2*4 (reference) and NAT2*19 were expressed in yeast (Schizosaccharomyces pombe). The C190T (R64W) SNP in NAT2*19 caused substantial reduction in the NAT2 protein level and stability, but did not cause significant reduction in transformation efficiency or mRNA level. The enzymatic activities for N-acetylation of two arylamine carcinogens (2-aminofluorene, 4-aminobiphenyl), and a sulfonamide drug (sulfamethazine) were over 100-fold lower for NAT2 19 compared to reference NAT2 4. Kinetic studies showed a reduction in Vmax but no significant change in substrate Km. In addition, the SNP caused significant reduction in the O-acetylation of the N-hydroxy-2-amino-1-methyl-6-phenylimidazo [4,5-b] pyridine. These results show that NAT2*19 possessing the C190T (R64W) SNP encodes a slow acetylator phenotype for both N- and O-acetylation, due to a reduction in the amount and stability of the NAT2 19 allozyme.     

Slow acetylator mutations in the human polymorphic N-acetyltransferase gene in 786 Asians, blacks, Hispanics, and whites: application to metabolic epidemiology.

Our aim was to determine the population frequencies of the major slow acetylator alleles of the polymorphic N-acetyltransferase (NAT2) gene, whose locus maps to chromosome 8. We used allele-specific PCR amplification on 786 dried blood spots obtained from Hong Kong Chinese, U.S. Koreans, U.S. blacks, U.S. Hispanics, Germans, and U.S. whites. Our results show that four slow acetylator alleles can be detected as mutations at positions 481, 590, and 857 in the NAT2 gene. Recognized base substitutions at positions 341 and 803 need not be determined, because they were almost always associated with the 481T mutation. The known mutation at position 282 was strongly associated with the 590A mutation. The 481T, 590A, and 857A mutations accounted for virtually all of the slow acetylator alleles in Asian and white populations. The 857A mutation proved to be an Asiatic allele. The results will be useful in large-scale epidemiologic studies of cancer and other conditions potentially associated with the acetylator polymorphism.     

N-acetyltransferase 2 polymorphism in patients with diabetes mellitus

The arylamine N-acetyltransferases (NATs) are a unique family of enzymes that catalyse the transfer of an acetyl group from acetyl-CoA to the terminal nitrogen of hydrazine and arylamine drugs and carcinogens. Human arylamine NATs are known to exist as two isoenzymes, NAT1 and NAT2. The objective of this study was to identify whether the genetic polymorphism of NAT2 plays a role in susceptibility to Diabetes Mellitus (DM). Ninety-seven patients with DM and 104 healthy controls were enrolled in the study. NAT2*5A, NAT2*6A, NAT2*7A/B and NAT2*14A polymorphisms were detected by using real time PCR with LightCycler (Roche Diagnostics GmbH, Mannheim, Germany). According to our data, the NAT2*5A and NAT2*6A mutant genotypes and NAT2*14A heterozygous genotype were associated with an increased risk of development of DM (OR = 47.06; 95%CI: 10.55-209.77 for NAT 2*5A, OR = 18.48; 95%CI: 3.83-89.11 for NAT2*6A and OR = 18.22; 95%CI: 6.29-52.76 for NAT2*14A). However, the NAT2*7A/B gene polymorphism carried no increased risk for developing DM disease. After grouping according to phenotypes as either slow or fast acetylators, NAT2*6A slow acetylator was found to be a significant risk factor for DM (OR = 6.09; 95%CI: 1.99-18.6, p = 0.02). The results indicate that NAT2 slow acetylator genotypes may be an important genetic determinant for DM in the Turkish population.     

Comparative analysis of N-acetylation polymorphism in humans as determined by phenotyping and genotyping

The N-acetylation polymorphisms of volunteers from the Moscow population analyzed by phenotyping and genotyping have been compared. The ratios between the proportions of fast acetylators (FAs) and slow acetylators (SAs) estimated by phenotyping and genotyping do not differ significantly from each other (47 and 44%, respectively). The absolute acetylation rate widely varies in both FAs and SAs. The NAT2 genotype and allele frequencies in the population sample have been calculated. The most frequent alleles are NAT2*4 (a "fast" allele), NAT2*5, and NAT2*6 ("slow" alleles); the most frequent genotypes are NAT2*5/*5, NAT2*4/*6, and NAT2*4/*5. Comparative analysis of N-acetylation polymorphism estimated by phenotyping and genotyping in the same subjects has shown a complete concordance between the phenotype and genotype in only 62 out of 75 subjects (87%). Comparative characteristics and presumed applications of the two approaches (quantitative estimation of acetylation rate and qualitative determination of the acetylator genotype) to the identification of individual acetylation status are presented.     

Arylamine N-acetyltransferase (NAT2) mutations and their allelic linkage in unrelated Caucasian individuals: correlation with phenotypic activity.

The polymorphic arylamine N-acetyltransferase (NAT2; EC 2.3.1.5) is supposed to be a susceptibility factor for several drug side effects and certain malignancies. A group of 844 unrelated German subjects was genotyped for their acetylation type, and 563 of them were also phenotyped. Seven mutations of the NAT2 gene were evaluated by allele-specific PCR (mutation 341C to T) and PCR-RFLP for mutations at nt positions 191, 282, 481, 590, 803, and 857. From the mutation pattern eight different alleles, including the wild type coding for rapid acetylation and seven alleles coding for slow phenotype, were determined. Four hundred ninety-seven subjects had a genotype of slow acetylation (58.9%; 95% confidence limits 55.5%-62.2%). Phenotypic acetylation capacity was expressed as the ratio of 5-acetylamino-6-formylamino-3-methyluracil and 1-methylxanthine in urine after caffeine intake. Some 6.7% of the cases deviated in genotype and phenotype, but sequencing DNA of these probands revealed no new mutations. Furthermore, linkage pattern of the mutations was always confirmed, as tested in 533 subjects. In vivo acetylation capacity of homozygous wild-type subjects (NAT2*4/*4) was significantly higher than in heterozygous genotypes (P = .001). All mutant alleles showed low in vivo acetylation capacities, including the previously not-yet-defined alleles *5A, *5C, and *13. Moreover, distinct slow genotypes differed significantly among each other, as reflected in lower acetylation capacity of *6A, *7B, and *13 alleles than the group of *5 alleles. The study demonstrated differential phenotypic activity of various NAT2 genes and gives a solid basis for clinical and molecular-epidemiological investigations.     

Study of NAT2 genetic polymorphism in West African subjects: example of an healthy non-smoker Senegalese population

The NAT2 genetic polymorphism determines the individual acetylator status and, consequently, the capacity to metabolize, or not, drugs and xenobiotics which are substrates of NAT2. As the nature and frequency of the NAT2 polymorphisms vary remarkably between populations of different ethnic origins, genotyping strategies used to predict the acetylation phenotype need to be adapted for each particular population regarding their genetic backgrounds at this locus. As few data on the genetic polymorphism of NAT2 are available in the Senegalese population, we performed an extensive identification of NAT2 variants in 105 healthy non-smoker Senegalese subjects by direct PCR sequencing of the coding region. Eleven previously described SNPs were identified in this Senegalese population. Upon allele analysis, the four most frequent alleles were of the NAT2*5- (35.7?%), NAT2*6- (21.0?%), NAT2*12- (16.7?%) and NAT2*14- (10.0?%) type, the remaining alleles, including the wild-type NAT2*4, having each a frequency lower than 10?%. According to the observed genotypes, 51 and 50 subjects were predicted to be of the rapid (48.6?%) and slow (47.6?%) acetylator phenotype, respectively, while four individuals (3.8?%) were considered of unknown phenotype as they carry at least one allele with a yet unknown functional effect. These baseline data would be of particular interest to set up an efficient genotyping strategy to predict the acetylation status of Senegalese patients with tuberculosis and, thus, to optimize their isoniazid treatment.     

Effect of NAT2 gene polymorphism on bladder cancer risk in Slovak population

N-acetyltransferase 2 (NAT2) is phase II enzyme with major roles in catalyzing the detoxification of aromatic amines, which are known risk factors for bladder cancer, and are ubiquitously present in the environment. We assessed the association between common polymorphisms in NAT2 gene and the risk of bladder cancer in 90 Slovak patients and 274 ethnicity-matched healthy controls. Effect modifications by smoking, age and gender were also evaluated. Overall, NAT2 slow acetylation was associated with significantly increased risk of bladder cancer (OR = 1.90; 95% CI, 1.15–3.16). In stratified analyses by age and gender, the elevated risk conferred by slow acetylator genotype was evident in older individuals (OR = 3.55; 95% CI, 1.77–7.35) and males (OR = 4.65; 95% CI, 1.68–16.10), with further increasing in NAT2*5B/*6A genotype carriers. Smoking was confirmed to be important risk factor, moreover, the risk was markedly increased in smokers with NAT2 slow acetylator genotype, and NAT2*5B/*6A carriers especially. In summary, these findings are consistent with previous literature suggesting that individual susceptibility to bladder cancer may be modulated by NAT2 polymorphisms, particularly in interaction with relevant environmental exposures such as smoking.     

Comparative analysis of N-acetylation polymorphism in humans as determined by phenotyping and genotyping

The N-acetylation polymorphisms of volunteers from the Moscow population analyzed by phenotyping and genotyping have been compared. The ratios between the proportions of fast acetylators (FAs) and slow acetylators (SAs) estimated by phenotyping and genotyping do not differ significantly from each other (47 and 44%, respectively). The absolute acetylation rate widely varies in both FAs and SAs. The NAT2 genotype and allele frequencies in the population sample have been calculated. The most frequent alleles are NAT2*4 (a “fast” allele), NAT2*5, and NAT2*6 (“slow” alleles); the most frequent genotypes are NAT2*5/*5, NAT2*4/*6, and NAT2*4/*5. Comparative analysis of N-acetylation polymorphism estimated by phenotyping and genotyping in the same subjects has shown a complete concordance between the phenotype and genotype in only 62 out of 75 subjects (87%). Comparative characteristics and presumed applications of the two approaches (quantitative estimation of acetylation rate and qualitative determination of the acetylator genotype) to the identification of individual acetylation status are presented.     

Effects of N-acetyl transferase 1 and 2 polymorphisms on bladder cancer risk in Caucasians

Cigarette smoking is the predominant risk factor for bladder cancer (BC). Major carcinogens present in tobacco smoke include a number of aromatic and heterocyclic amines. Two distinct N-acetyl transferase (NAT) enzymes, NAT1 and NAT2, play important roles in the bio-activation and detoxification of these carcinogens. Genes encoding NAT1 and NAT2 are highly polymorphic among human populations, and these polymorphisms result in rapid or slow acetylator phenotypes. Recent studies have suggested that variant alleles leading to slow acetylation by the NAT2 enzyme or rapid acetylation by the NAT1 enzyme constitute possible risk factors for bladder cancer. In this case-control study, we sought to determine whether NAT1 and NAT2 polymorphisms are associated with bladder cancer risk in the largest sample size to date. PCR-RFLP assay was used to determine the presence of NAT1 and NAT2 polymorphisms in 507 Caucasian BC patients and 513 age-, gender-, and ethnicity-matched healthy controls. Overall, we found no significant association between BC risk and NAT1 NAT1*10 allele (OR=0.95; 95% CI 0.73-1.25). However, our data suggested that NAT2 slow acetylator genotypes were associated with a significant increased risk of BC (OR=1.31; 95% CI, 1.01-1.70). This elevated risk appeared more evident in older individuals (OR=1.41; 95% CI, 1.01-1.98) than in younger individuals (OR=1.15; 95% CI, 0.76-1.74). Moreover, the risk was greater for heavy smokers (OR=2.11; 95% CI, 1.33-3.35) than light smokers (OR=0.96; 95% CI, 0.61-1.53) and never smokers (OR=1.23; 95% CI, 0.79-1.90). Finally, a joint effect between NAT2 slow acetylators and heavy smokers was observed. Using never smokers with NAT2 rapid acetylator genotypes as a reference group, heavy smokers with NAT2 slow acetylator genotypes showed an over six-fold increase in BC risk. In a multiplicative interaction model, the interaction term was statistically significant (P=0.02). Our data suggest that having a NAT2 slow acetylator genotype is a significant risk factor for BC, particularly in smokers and older individuals.     

Proteasomal degradation of N-acetyltransferase 1 is prevented by acetylation of the active site cysteine: a mechanism for the slow acetylator phenotype and substrate-dependent down-regulation

Many drugs and chemicals found in the environment are either detoxified by N-acetyltransferase 1 (NAT1, EC 2.3.1.5) and eliminated from the body or bioactivated to metabolites that have the potential to cause toxicity and/or cancer. NAT1 activity in the body is regulated by genetic polymorphisms as well as environmental factors such as substrate-dependent down-regulation and oxidative stress. Here we report the molecular mechanism for the low protein expression from mutant NAT1 alleles that gives rise to the slow acetylator phenotype and show that a similar process accounts for enzyme down-regulation by NAT1 substrates. NAT1 allozymes NAT1 14, NAT1 15, NAT1 17, and NAT1 22 are devoid of enzyme activity and have short intracellular half-lives ( approximately 4 h) compared with wild-type NAT1 4 and the active allozyme NAT1 24. The inactive allozymes are unable to be acetylated by cofactor, resulting in ubiquitination and rapid degradation by the 26 S proteasome. This was confirmed by site-directed mutagenesis of the active site cysteine 68. The NAT1 substrate p-aminobenzoic acid induced ubiquitination of the usually stable NAT1 4, leading to its rapid degradation. From this study, we conclude that NAT1 exists in the cell in either a stable acetylated state or an unstable non-acetylated state and that mutations in the NAT1 gene that prevent protein acetylation produce a slow acetylator phenotype.     

Association of <Emphasis Type="Italic">NAT2</Emphasis> polymorphisms with susceptibility to psoriasis in the Moscow population

N-acetyltransferase 2 (NAT2) is a key enzyme of biotransformation phase II that metabolizes genotoxic compounds such as carcinogens and mutagens in different types of cells. A decreased NAT2 activity may correlate with sensitivity to harmful environmental factors, thus increasing susceptibility to different multifactorial diseases, including dermatologic conditions like psoriasis. A biochip developed in our lab to detect 17 NAT2 SNPs was tested on 279 clinical DNA samples from 180 patients with psoriasis and 99 healthy individuals, all residents of Moscow. Six polymorphisms that are most common in European populations (282C > T, 341T > C, 481C > T, 590G > A, 803A > G, and 857G > A) were detected. The NAT2 allele and genotype frequencies for individual SNPs did not differ between patients and healthy individuals. The frequency of the slow acetylation phenotype was increased in patients with type II psoriasis and in normosthenic patients as compared to controls (OR = 1.76, P = 0.177 and OR = 2.07, P = 0.050, respectively). Genotype 341C/C,481T/T,803G/G was significantly more frequent in patients who smoked at least one pack of cigarettes per day and in those who regularly consumed alcohol than in controls (OR = 7.42, P = 0.008 and OR = 106.11, P = 0.003, respectively). The frequency of genotype 341T/T, 481C/C, 590A/-, 803A/A was increased in patients with adverse reactions to medications (OR = 2.05, P = 0.099). Thus, our data suggest that some NAT2 genotypes in combination with certain lifestyles can be considered risk factors of psoriasis in the Moscow population.     

Identification of N-acetyltransferase 2 genotypes by continuous monitoring of fluorogenic hybridization probes.

Three polymorphic sites in the N-acetyltransferase 2 (NAT2) gene were detected using rapid cycle DNA amplification with allele-specific fluorescent probes and melting curve analysis. Two fluorogenic adjacent hybridization probes were designed to NAT2*5A (C(481)T), NAT2*6A (G(590)A), and NAT2*7A (G(857)A). During amplification, probe hybridization is observed as fluorescence resonance energy transfer. The fluorescence increases every cycle as the product accumulates during amplification. A single base mismatch resulted in a melting temperature shift (T(m)) of 5 to 6 degrees C, allowing for the easy distinction of a wild-type allele from the mutant allele. The protocol is rapid, requiring 40 min for the completion of 45 cycles including the melting curves. It is also a simple and flexible method, since DNA templates prepared from different sources, including DNA from serum and paraffin-embedded tissue sections, could be used without adverse effects. Fluorescence genotyping of all three polymorphisms in a total of 155 DNA samples correlated perfectly with our previously validated genotyping by restriction enzyme digestion (PCR-RFLP). This new facile approach allows for the easy detection of NAT2 polymorphisms in hundreds of samples in only a day.     

The association between N-acetyltransferase 2 gene polymorphisms and pancreatic cancer

Pancreatic cancer has been linked with exposure to environmental chemicals, which generally require metabolic activation to highly reactive toxic or carcinogenic intermediates. N-acetyltransferase 1 (NAT1) and N-acetyltransferase 2 (NAT2) are expressed primarily in extrahepatic and hepatic tissues, respectively. Both enzymes catalyze N- and O-acetylation of aromatic and heterocyclic amines. It is believed that these compounds are activated via O-acetylation and detoxified by N-acetylation. Several polymorphisms of these two genes have been associated with an increased risk of cancer. Twenty-seven cases of pancreatic cancer and 104 controls were included in this study. Blood was collected in EDTA-containing tubes, and genomic DNA was extracted from the white blood cells by using a high pure PCR template preparation kit. Genotyping of NAT2 polymorphisms was detected by a real time PCR instrument. There was a significant difference in the distribution of the NAT2*6A acetylators phenotype between cases and the controls. The odds ratio of pancreatic cancer for the NAT2*6A slow phenotype was 5.7 (95% CI = 1.27-25.55; p = 0.023) compared with the fast type. Our results suggest that slow acetylators have higher risk of developing pancreatic cancer than fast acetylators. NAT2 gene polymorphisms may be associated with genetic susceptibility to pancreatic cancer.     

N-acetyltransferase 1 and 2 gene sequence variants and risk of head and neck cancer

Polymorphisms that alter the function of genes involved in the activation or detoxification of carcinogenic compounds can influence an individuals risk of developing cancer. Polymorphic changes modulating the acetylation capacity of the N-acetyltransferase (NAT) genes have been implicated in the risk of developing cancer. In this study the role of genetically determined individual NAT1 and NAT2 genotypes, haplotypes and haplotype combinations in the predisposition to head and neck cancer was investigated. Polymorphic regions of the NAT1 and NAT2 genes were analyzed in patients with head and neck cancer and healthy individuals by polymerase chain reaction-restriction fragment length polymorphism. Distribution of the genotypes, allele frequencies, diplotypes and haplotypes and correlation with clinical characteristics were evaluated. No association was observed between the NAT1*3, NAT1*10, NAT1*11, NAT2*5 and NAT2*6 genotypes and risk of head and neck cancer. The NAT2*7 slow genotype was associated with reduced risk of disease. A significant association was observed between the fast acetylator NAT2*4/NAT1*10 diplotype and risk of head and neck cancer. Combined haplotypes harboring the T1088A and C1095A variants characterizing the NAT1*10 allele were associated with increased risk. Our results suggest that NAT1 and NAT2 gene combinations may influence the risk of developing head and neck cancer.     

Polymorphisms of arylamine N-acetyltransferase2 and risk of lung and colorectal cancer

The arylamine N-acetyltransferase 2 (NAT2) enzymes detoxify a wide range of naturally occurring xenobiotics including carcinogens and drugs. Point mutations in the NAT2 gene result in the variant alleles M1 (NAT2 *5A), M2 (NAT2*6A), M3 (NAT2*7) and M4 (NAT2 *14A) from the wild-type WT (NAT2 *4) allele. The current study was aimed at screening genetic polymorphisms of NAT2 gene in 49 lung cancer patients, 54 colorectal cancer patients and 99 cancer-free controls, using PCR-RFLP. There were significant differences in allele frequencies between lung cancer patients and controls in the WT, M2 and M3 alleles (p < 0.05). However, only M2 and M3 allele frequencies were different between colorectal cancer patients and controls (p < 0.05). There was a marginal significant difference in the distribution of rapid and slow acetylator genotypes between lung cancer patients and controls (p = 0.06 and p = 0.05, respectively), but not between colorectal cancer patients and controls (p = 1.0 and p = 0.95, respectively). Risk of lung cancer development was found to be lower in slow acetylators [odds ratio (OR): 0.51, 95% confidence interval (95% CI): 0.25, 1.02, p-value = 0.07]. No effect was observed in case of colorectal cancer. Our results showed that NAT2 genotypes and phenotypes might be involved in lung cancer but not colorectal cancer susceptibility in Jordan.