Molecular and genetic analyses of arylamine N-acetyltransferase polymorphism of rabbit liver

A cDNA clone encoding the full coding region of polymorphic arylamine N-acetyltransferase was isolated from rabbit liver and expressed in Chinese hamster ovary cells. The expressed enzyme acetylated 2-aminofluorene, procainamide, sulfamethazine, and p-aminobenzoic acid at equivalent rates. N-Acetyltransferase activity was measured in 17 rabbits from an inbred colony which were classified into rapid, intermediate, and slow acetylators. The livers of the rapid and intermediate acetylators efficiently acetylated all four substrates, while the liver from the slow acetylator showed a low but significant activity with p-aminobenzoic acid. Immunoblot and Northern blot analyses of rabbit livers indicated that the differences in N-acetyltransferase activity were due to differences in N-acetyltransferase protein and mRNA content. Genomic clones of N-acetyltransferase were isolated from the rapid and slow acetylator rabbits. The nucleotide sequence of the gene from rapid acetylator rabbit was identical to that of the cDNA, while the sequence of the gene from slow acetylator rabbit was homologous, but not identical, to the cDNA sequence. Genomic Southern blot and polymerase chain reaction analyses of the genomic DNAs and cDNAs from the three types of acetylator indicated that the gene for polymorphic arylamine N-acetyltransferase is totally deleted in the slow acetylator rabbit, while the gene from slow acetylator rabbit is expressed in all rabbits and might encode another N-acetyltransferase. Thus the genetic mechanism of N-acetyltransferase polymorphism in rabbit liver is essentially different from that of human liver as demonstrated in this laboratory (Ohsako, S., and Deguchi, T. (1990) J. Biol. Chem. 265, 4630-4634; Deguchi, T., Mashimo, M., and Suzuki, T. (1990) J. Biol. Chem. 265, 12757-12760).     

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.     

Berberine inhibits arylamine N-acetyltransferase activity and gene expression in mouse leukemia L 1210 cells

N-acetyltransferases (NATs) are recognized to play a key role in the primary step of arylamine compounds metabolism. Polymorphic NAT is coded for rapid or slow acetylators, which are being thought to involve cancer risk related to environmental exposure. Berberine has been shown to induce apoptosis and affect NAT activity in human leukemia cells. The purpose of this study is to examine whether or not berberine could affect arylamine NAT activity and gene expression (NAT mRNA) and the levels of NAT protein in mouse leukemia cells (L 1210). N-acetylated and non-N-acetylated AF were determined and quantited by using high performance liquid chromatography. NAT mRNA was determined and quantited by using RT-PCR. The levels of NAT protein were examined by western blotting and determined by using flow cytometry. Berberine displayed a dose-dependent inhibition to cytosolic NAT activity and intact mice leukemia cells. Time-course experiments indicated that N-acetylation of AF measured from intact mice leukemia cells were inhibited by berberine for up to 24 h. The NAT1 mRNA and NAT proteins in mouse leukemia cells were also inhibited by berberine. This report is the first demonstration, which showed berberine affect mice leukemia cells NAT activity, gene expression (NAT1 mRNA) and levels of NAT protein.     

Correlation between acetylator phenotypes and genotypes of polymorphic arylamine N-acetyltransferase in human liver

Southern blot analysis was performed with genomic DNAs from 86 human subjects using the 32P-labeled cDNA for polymorphic arylamine N-acetyltransferase (EC 2.3.1.5) in human liver recently cloned in our laboratory. Three types of N-acetyltransferase gene were identified. Gene 1 contains a 5.5-kilobase (kb) KpnI fragment with a BamHI site; gene 2 contains a 5.5-kb KpnI fragment without a BamHI site; and gene 3 contains a 5.0-kb KpnI fragment with a BamHI site. The combination of these three genes generated five genotypes. Acetylator phenotypes were determined in 29 healthy volunteers by isoniazid loading tests, and they were classified as rapid (10 subjects), intermediate (16 subjects), or slow (3 subjects) acetylators. Rapid acetylators were homozygotes of gene 1. Intermediate acetylators were heterozygotes of either genes 1 and 2 or genes 1 and 3. There were two exceptional cases who were classified as intermediate acetylators but were homozygotes of gene 1. Slow acetylators were either heterozygote of genes 2 and 3 or homozygotes of gene 3. These results indicate that gene 1 corresponds to high N-acetyltransferase activity, while gene 2 and gene 3 give rise to low N-acetyltransferase activity.     

Smoking (active and passive), N-acetyltransferase 2, and risk of breast cancer

Background: The relationship between smoking and breast cancer remains controversial. The study aim was to assess the relationship of passive and active smoking to breast cancer risk by N-acetyltransferase 2 (NAT2) phenotype, using a comprehensive assessment of both passive and active smoking. Methods: We undertook a population-based case–control study in Northeastern Ontario, Canada of 347 women diagnosed (2002–2004) with breast cancer and 775 population-based controls. The mailed study package included a questionnaire requesting information about established breast cancer risk factors, passive and active smoking, and a buccal swab for genetic analyses. Results: Among never-active smokers, a long duration of passive smoking was associated with an increased risk of breast cancer (odds ratio (OR) 1.86 (95% confidence interval (95% CI) 1.01–3.44) (test for trend (p = 0.07)); that risk was more elevated for NAT2 slow acetylators (OR 2.76, 95% CI 1.16–6.59) (and highest in extremely slow acetylators), but not elevated for NAT2 fast acetylators (OR 1.17, 95% CI 0.42–3.23). Among active smokers more than 20 pack-years of smoking was associated with an OR of 1.34 (95% CI 0.92-1.96); more elevated among NAT2 fast acetylators OR 1.93 (95% CI 1.01–3.69) but not elevated among NAT2 slow acetylators. Women who were NAT2 fast acetylators in the highest quartile for duration of active smoking had an OR of 2.74 (95% CI 1.42–5.27), with a significant test of trend (p = 0.005). Conclusions: These findings suggest that passive and active smoking may be related to breast cancer, and the effect may be differentially modified by NAT2 phenotype. Further research into the genetic modification of a breast cancer–smoking relationship may help to reconcile earlier discrepant findings.     

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.     

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.     

Acetylation phenotypes in patients with bladder carcinoma

The present study was done to evaluate the possible association of bladder carcinoma with the slow acetylator phenotype in a portuguese population. 49 patients with bladder carcinoma were compared to a normal control group of 84 individuals. No statistically significant association was detected. But when subdividing the group of slow acetylators it is found that in the subgroup with 12-36% acetylation there is a higher percentage of patients, which is statistically significant. These results are in agreement with two other studies, using populations of similar ethnic origin.     

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.     

Metabolic Populational in vivo Construction of Tumors under Conditions of Individual Genetic Predisposition: Communication II

The results of the analysis of the literature data on the ethnic distribution of xenobiotic biotransformation phenotypes and on tumor incidence (for all organs in total) are presented from the standpoint of the concept by L.A. Piruzyan [1]. For a number of ethnic groups, a possibility is theoretically shown of the metabolic populational in vivo construction of tumors (depending on the genetically determined metabolic status of certain populations), i.e., of the ethnic dependence of tumors. In the American population, the higher incidence of the slow acetylation phenotype than in Swedes and in the Chinese was associated with the higher incidence of morbidity. In populations of the English, the Germans, the Swedes, and the Swiss, characterized by a low incidence of the slow acetylation phenotype, the tumor morbidity was higher than in the Chinese with a higher incidence of slow acetylators. Americans are more predisposed to tumors than the Swedes. Caucasoids with either the slow or the fast acetylation phenotype are more predisposed to tumors than the Chinese. The prevalence of the fast acetylation phenotype in the Chinese and Japanese populations was associated with the lower cancer morbidity: in the Chinese compared to Australians, Danes, Swedes; in the Japanese compared to Australians, Americans, the English, Danes, Canadians, the German, the Portuguese, Finns, Czechs, and Slovaks. The lower incidence of the slow acetylators in the Chinese than in Americans, English, Danes, Canadians, Germans, Finns, Czechs, Slovaks, and Swedes was associated with a lower rate of morbidity. In the Portuguese, the higher incidence of fast acetylators than in Danes and the lower incidence of slow acetylators than in Czechs, Slovaks, and Afro-Americans was associated with the lower rate of morbidity. In the Hong Kong and Singapore Chinese with the lower incidence of slow acetylators than in the Madras Negroids, the morbidity was higher. In Australians and Swedes, the greater fraction of slow acetylators was associated with a lower morbidity than in Afro-Americans. In the Russian population of St. Petersburg, the higher incidence of slow acetylators was associated with the lower morbidity compared to the Hong Kong Chinese. Among Poles, the slow acetylator incidence was higher and the morbidity was lower than in the Portuguese. The Japanese and the Chinese (fast acetylators) are less predisposed to cancer than the above-listed Caucasoids; among Caucasoids, the Portuguese (fast acetylators) were less predisposed to cancer than the Danes, Czechs, Slovaks, and Afro-Americans. The tumor predisposition of the Hong Kong and Singapore Chinese was higher than the predisposition of the Madras Negroids. Australians, Russians (St. Petersburg residents), and Poles were less predisposed to cancer than Afro-Americans, the Hong Kong Chinese, and the Portuguese. The morbidity of the Madras Negroids with the higher incidence of the slow acetylation phenotype was lower than the morbidity of the Hong Kong and Singapore Chinese. The incidence of the slow acetylation phenotype in Afro-Americans was lower than in the Australians and Swedes and higher than in the Portuguese, Chinese, and Japanese; this was associated with the higher cancer morbidity, i.e., with the increased predisposition to tumors. The lower incidence of the T1-0 phenotype of glutathione-S-transferase in the English than in the Singapore and Shanghai Chinese and in the Japanese was associated with the higher morbidity of the English. In the Singapore Chinese, the higher incidence of the M1-0 and of T1-0 phenotypes of glutathione-S-transferase than in the Japanese was associated with the increased morbidity. In some populations, different morbidities were associated with similar incidences of one or another metabolic phenotype, or different phenotype incidences in different populations were associated with similar morbidities. The morbidity under consideration did not include chemical carcinogenesis, i.e., the conversion of procarcinogens to true carcinogens or the carcinogen inactivation. Because the results presented are preliminary, this article outlines the directions of theoretical studies that are required for definite conclusions concerning the ethnic dependence of tumors.     

Acetylation pharmacogenetics: experimental models for human toxicity

Hereditary acetylation polymorphisms well-suited to experimental pharmacogenetic investigation are now known in three laboratory animal species (rabbit, mouse, and hamster). These animal models provide new evidence for the profound influence of this trait on the metabolic fate of arylamines and hydrazines, and on their pharmacological and toxicological profiles. The rabbit polymorphism most closely resembles that in humans. For the rabbit model, studies have shown that 1) monoacetylhydrazine is a polymorphic substrate for liver N-acetyltransferase in rapid and slow acetylators. This observation, in conjunction with human epidemiological data of others, opposes the commonly held view that rapid acetylators are predisposed to isoniazid (INH)-induced hepatotoxicity. 2) Slow acetylators are much more sensitive than rapid acetylators to the lethal central nervous system toxicity of INH. 3) In hepatocytes in short-term culture and exposed to arylamines and hydrazines, DNA damage is produced by hydralazine in slow acetylator hepatocytes but not in rapid acetylator hepatocytes, whereas hepatocytes from rapid acetylators are more sensitive to toxicity and DNA damage from 2-aminofluorene and benzidine. These investigations in animal models of the acetylation polymorphism provide new insights into human toxicity resulting from environmental arylamines and hydrazines.     

Characterization of human lymphocyte N-acetyltransferase and its relationship to the isoniazid acetylator polymorphism

Characterization of human lymphocyte N-acetyltransferase (NAT) for specific activity, substrate specificity, inhibition, pH optimum, apparent K_m, kinetic mechanism, trypsin stability, freezing stability, and heat stability was carried out in rapid and slow isoniazid (INH) acetylators. There is a statistically significant difference in the heat stability of lymphocyte NAT from rapid and slow INH phenotypes. The lymphocyte enzyme from rapid INH acetylators is less heat stable than the lymphocyte enzyme from slow INH acetylators. This is an indication of a structural, possibly polymorphic, difference in lymphocyte NAT from the two acetylator phenotypes.     

AKT as locus of fragility in robust cancer system

Metastatic cancer is a complex positive feedback loop system. Such as system has a tendency to acquire extreme robustness. Signaling pathways controlling that robustness can fail completely if an essential element from the signaling is removed. That element is a locus of fragility. Targeting that locus represents the best way to target the cancer robustness. This prospect presents another locus of fragility in signaling complex system network, controlling the cell cycle progression through the PI3K/AKT/mTOR/RAN pathway and cell migration and angiogenesis through the VEGF/PI3K/AKT/NO/ICAM-1 pathway. The locus of fragility of these pathways is AKT, which is regulated by a balance of catalase/H2O2 or by AKT inhibitor. Tiny and trivial perturbations such as change in redox state in the cells by antioxidant enzyme catalase, scavenging H2O2 signaling molecule, regulates robust signaling molecule AKT, abolishing its phosporilation and inducing cascading failure of robust signaling pathways for cell growth, proliferation, migration, and angiogenesis. An anticancer effect of the antioxidant is achieved through the AKT locus, by abolishing signals from growth factors VEGF, HGF, HIF-1alpha and H2O2. Previously reported locus of fragility nitric oxide (NO) and locus AKT are close in the complex signaling interactome network, but they regulate distinct signaling modules. Simultaneously targeted loci represents new principles in cancer robustness chemotherapy by blocking cell proliferation, migration, angiogenesis and inducing rather slow then fast apoptosis leading to slow eradication of cancer.     

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.     

Diabetic dimorphism according to acetylator status.

Two groups of diabetics and 19 normal controls had their rate of acetylation of sulphadimidine measured. Among 47 patients with maturity onset diabetes the 29 fast acetylators were older at diagnosis and, at a given glucose concentration, had a higher pretreatment fasting insulin concentration than slow acetylators. They also had a larger first-phase insulin secretion in response to intravenous glucose both before and after one month''s dietary treatment. The greatest difference between fast and slow acetylators was in the first-phase secretion of insulin after a month''s treatment. The proportion of fast acetylators among the second group of diabetics, who had been admitted to improve their glucose concentrations or for treatment of tissue damage, was similar to that among the normal controls (50% and 47% respectively). The data seem to indicate that diabetics are fast acetylators unexpectedly often, but it is not clear whether the dimorphism according to acetylator status produces a differential risk of neuropathy or of any other type of diabetic tissue damage.     

The role of human glutathione S-transferases M1 and T1 in individual susceptibility to bladder cancer

Several genes involved in the metabolism of carcinogens have been found to be polymorphic in the human population, and specific alleles are associated with increased risk of cancer at various sites. This study is focused on the polymorphic enzymes glutathione S-transferase M1 (GSTM1) and T1 (GSTT1) that are involved in the detoxification of many xenobiotics involved in the etiology of bladder cancer. To investigate the role of GSTM1 and GSTT1 in bladder carcinogenesis, the polymerase chain reaction was used to determine GSTM1 and GSTT1 genotypes of cancer patients (n = 76) and controls (n = 248). The proportion of putative risk GSTM1 null genotype in the case group was 52.6%, compared to 49.6% in the control group, but the GSTT1 0/0 frequency in the bladder cancer group was significantly higher (P = 0.04) in comparison with the control group (27.6 vs 16.9%). Individuals lacking the GSTT1 gene are at an approximately 1.9-fold higher risk (OR = 1.87, C.I. 95% = 1.03-3.42) of developing bladder cancer in comparison with individuals with at least one active allele in the GSTT1 locus. A significantly higher incidence of GSTM1 deletion genotype (P = 0.02) was found in smokers with bladder cancer compared to the controls (70.6 vs 49.6%). Smokers lacking the GSTM1 gene are at an approximately 2.4-fold higher risk of bladder cancer (OR = 2.44, C.I. 95% = 1.10-5.30). The effect of smoking associated with the GSTT1 0/0 genotype was not found to affect the risk of bladder cancer.     

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.     

Arylarnine N-acetyltransferase as a potential biornarker in bladder cancer: fluorescent in situ hybridization and irnmunohistochernistry studies

Arylamine N-acetyltransferase isoenzymes NAT1 and NAT2 are encoded at two polymorphic loci on human chromosome 8p22. The two loci have previously been identified using chimeric Yeast Artificial Chromosome (YAC) clones encoding either NAT1 or NAT2 as probes for metaphase chromosomes using fluorescent in situ hybridization. The 8p22 region has been demonstrated to be deleted in highly invasive bladder tumours and since NAT isoenzymes participate in the metabolism of arylamine bladder carcinogens, it is important to determine whether NAT1 and NAT2 gene loci are included in the region of deletion. We describe here the application of a cosmid clone for NAT2 as a biomarker for Fluorescent In Situ Hybridization (FISH) on interphase nuclei of exfoliated bladder cells. We also describe a 70kb probe for NAT1 which is a candidate for a suitable biomarker for use in similar FISH studies. lmmunohistochemical staining of bladder tumour sections with a polyclonal anti-peptide antibody specific for the NATl isoenzyme as a biomarker for NAT1 protein expression is also shown.     

Loss of heterozygosity studies in tumors from families with breast-ovarian cancer syndrome

A gene (BRCA1) predisposing for familial breast and ovarian cancer has been mapped to chromosome band 17q12-21. Based on the observation that ovarian tumors from families with breast and ovarian cancer lose the wild-type allele in the region for the BRCA1 locus, it has been suggested that the gene functions as a tumor suppressor gene. We have studied chromosomal deletions in the BRCA1 region in seven breast tumors, three ovarian tumors, one bladder cancer, and one colon cancer from patients in six families with breast-ovarian cancer, in order to test the hypothesis of the tumor suppressor mechanism at this locus. We have found a low frequency of loss of heterozygosity at this region, and our results do not support the idea that BRCA1 is a tumor suppressor gene. Alternatively, the disease segregating in these families is linked to one or more different loci.     

Critical evaluation of urinary markers for bladder cancer detection and monitoring

Bladder cancer is currently diagnosed using cystoscopy and cytology in patients with suspicious signs and symptoms. These tests are also used to monitor patients with a history of bladder cancer. The recurrence rate for bladder cancer is high, thus necessitating long-term follow-up. Urine cytology has high specificity but low sensitivity for low-grade bladder tumors. Recently, multiple noninvasive urine-based bladder cancer tests have been developed. Although several markers have been approved by the US Food and Drug Administration for bladder cancer surveillance, only a few are approved for detection of bladder cancer in high-risk patients.