Roles of cytochrome P450IIE1 in the dealkylation and denitrosation of N-nitrosodimethylamine and N-nitrosodiethylamine in rat liver microsomes

N-Nitrosodimethylamine (NDMA) and N-nitrosodiethylamine (NDEA) are widely occurring nitrosamines and require enzyme-catalyzed activation for their carcinogenic actions. The low Km forms of the enzyme are generally considered to be important in the activation of environmental carcinogens. In this work we examined the role of cytochrome P450IIE1--a constitutive enzyme that is also inducible by acetone, ethanol, fasting and other factors--in catalyzing the dealkylation and denitrosation of these two carcinogens. The experimentally determined Km value of NDMA demethylase depended upon the experimental conditions and was lower when lower protein concentrations were used. Low Km values of 15-20 microM were observed for NDMA demethylase with different preparations of microsomes. In the deethylation of NDEA, a low Km of approximately 40 microM was observed for both control and acetone-induced microsomes. Immunoinhibition studies indicated that P450IIE1 was responsible for almost all the low Km NDMA demethylase activity in acetone-induced microsomes and greater than 80% in control microsomes. This enzyme was also responsible for about three-quarters of the low Km NDEA deethylase activity in acetone-induced microsomes and about half in control microsomes. The denitrosation of NDMA and NDEA was inhibited to approximately the same extents as the dealkylation reactions under different experimental conditions, suggesting the involvement of the same enzyme and perhaps a common initial intermediate in these two types of reactions. The relevance of this work and its relationship to related information in the literature are discussed.     

Molecular basis for the sex-related difference in renal N-nitrosodimethylamine demethylase in C3H/HeJ mice

Previous work with rat and rabbit liver enzymes has demonstrated that cytochrome P450IIE1 is responsible for the metabolism of N-nitrosodimethylamine (NDMA), a widely occurring carcinogen. The present study demonstrated that a similar enzyme also exists in the mouse kidney and is regulated by testosterone. These results can account for the reported sex-related difference in the renal metabolism of NDMA in mouse strains such as C3H/HeJ. NDMA demethylase activities (expressed as pmol/min/mg protein) in kidney microsomes of female and male C3H/HeJ mice were 3.0 +/- 0.7 and 51.9 +/- 11.2, respectively. After testosterone treatment (500 mg/kg b.w. in olive oil, s.c.) for 2 days, the renal NDMA demethylase activity of the female mice was elevated 17-fold. The difference and change in NDMA demethylase activity were accompanied by corresponding differences and changes in P450IIE1 as quantified by immunoblot analysis (using antibodies prepared against rat P450IIE1) as well as in the mRNA level for P450IIE1 as determined by Northern and slot blot analyses (using a cDNA probe containing the coding sequence of rat P450IIE1 gene). Based on gel electrophoresis, the molecular weight of mouse renal P450IIE1 was 52,000 and the size of mouse renal P450IIE1 mRNA was approximately 1.8 kilobases; both were similar to those found in rat liver and kidney. Renal P450IIE1 mRNA levels in female, male, and testosterone-treated female mice were at a ratio of 1:22:20. On the other hand, this testosterone-related difference was not observed in hepatic P450IIE1. In liver microsomes, there were no significant differences in NDMA demethylase activity, P450IIE1 content, and P450IIE1 mRNA level between male and female mice or between untreated and testosterone-treated female mice. The apparent Km value of NDMA demethylase in mouse kidney microsomes (22 to 27 microM NDMA) were similar to that in rat liver microsomes. Renal NDMA demethylase activity was inhibited by a monoclonal antibody prepared against rat P450IIE1. These results suggest that mouse renal P450IIE1 is similar to rat P450IIE1 and is responsible for the low Km form of NDMA demethylase activity. Nevertheless, only the mouse renal enzyme is regulated by testosterone.     

Differential rates of metabolic activation and detoxication of the food mutagen 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine by different cytochrome P450 enzymes

Rat liver microsomes metabolized the food mutagen 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) to the genotoxic metabolite 2-hydroxamino-1-methyl-6-phenylimidazo[4,5-b]pyridine (2-hydroxamino-PhIP) and to the detoxified product 2-amino-4'-hydroxy-1-methyl-6-phenylimidazo[4,5-b]pyridine (4'-hydroxy-PhIP). A 25-fold higher rate of metabolism was measured in microsomes from polychlorinated-biphenyl-treated rats (94 nmol/mg proteins/30 min) in comparison with those from untreated rats. Other effective inducers of PhIP metabolism were beta-naphthoflavone and isosafrole (ISF), whereas phenobarbital was ineffective. About twice as much 2-hydroxamino-PhIP as 4'-hydroxy-PhIP was formed in microsomes irrespective of the inducer the rats had been treated with. The metabolism was dependent on NADPH and was abolished by the cytochrome P450 inhibitor alpha-naphthoflavone. In a reconstituted enzyme system purified rat cytochrome P450 IA2 (P450ISF-G) had the highest N-hydroxylation rate (30 nmol/nmol P450/30 min) closely followed by the rat cytochrome P450 IA1 (P450BNF-B). Less activity was seen with rat P450 IIC11 (P450UT-A) and rabbit P450 IA2 (P450 LM4). Rat P450 IIE1 (P450j), P450 IIB1 (P450PB-B) and rabbit P450 IIB4 (P450 LM-2) and P450 IIE1 (P450 LM3a) were essentially inactive. Rat P450 IA1 (P450BNF-B) produced five times more 4'-hydroxy-PhIP (32 +/- 2 nmol/nmol P450/30 min) than did P450 IA2 (P450ISF-G). Hence, the measured ratio of activation to detoxication for rat P450 IA2 (P450ISF-G) enzyme was 7-fold higher than that of the other active P450 enzymes.     

Mechanism of benzylselenocyanate inhibition of azoxymethane-induced colon carcinogenesis in F344 rats

Benzylselenocyanate (BSC), a novel organoselenium compound, has been found to inhibit azoxymethane (AOM)-induced colon carcinogenesis in rats during initiation. To investigate its mechanism of action, we examined the effects of BSC feeding on the following parameters: (a) metabolism of [14C]AOM to 14CO2 in vivo; (b) metabolic activation of AOM to MAM and of MAM to formic acid and methanol by rat liver microsomes in vitro; and (c) AOM-induced DNA methylation in rat livers and colons. Five-week-old male F344 rats were fed modified (23% corn oil) AIN-76A diets containing 0 (control), 25, or 50 ppm of BSC or benzylthiocyanate (BTC), a sulfur analogue of BSC which does not inhibit the colon carcinogenicity of AOM. After 3 weeks, rats were either sacrificed for the isolation of liver microsomes or were given 15 mg/kg of [14C]AOM s.c. to determine the rate of carcinogen metabolism in vivo. No difference in [14C]AOM metabolism was found between rats fed the BTC diets and those fed the control diet. In contrast, the rate of [14C]AOM metabolism, as determined by exhaled radioactivity, was 2-3 times higher in rats fed the BSC diets. While liver microsomes from rats fed the BTC diets metabolized AOM and MAM at rates not significantly different from those obtained with control liver microsomes, the metabolic activation of AOM as well as of MAM was stimulated severalfold when assayed with liver microsomes from rats fed the BSC diets. An increase in total liver cytochrome P-450 was also observed in the BSC-fed rats. Following the administration of 15 mg/kg AOM, significantly less O6-methylguanine and 7-methylguanine was present in the colon DNA from rats consuming the BSC diets than in rats fed the BTC or control diets. The body weight gains of rats fed the 25- and 50-ppm BSC-containing diets for 3 weeks were less (27 and 43%, respectively) than those of rats fed either the control or BTC-containing diets. These results indicate that dietary BSC significantly induces the hydroxylation of AOM and the oxidation of MAM in rat liver. An increase in the rates of AOM and MAM metabolism in the liver due to enzyme induction by BSC will result in decreased delivery of MAM to the colon via the bloodstream. This will be reflected in decreased DNA alkylation, as observed, and is likely to be a major factor in the inhibition of AOM-induced colon carcinogenesis by BSC.     

Substrate specificity and alkyl group selectivity in the metabolism of N-nitrosodialkylamines

Metabolic activation may be a key step in determining the tissue specificity of carcinogenic nitrosamines. In previous work, we characterized P450IIE1 (an acetone/ethanol-inducible form of cytochrome P-450) as the major enzyme for the metabolic activation of N-nitrosodimethylamine. In this work, we investigated the metabolism of other N-nitrosodialkylamines in rat liver microsomes and in reconstituted monooxygenase systems containing purified cytochrome P-450 isozymes. The enzyme specificities in the metabolism of N-nitrosoethylmethylamine and N-nitrosodiethylamine were similar to those of N-nitrosodimethylamine; i.e., these substrates were more efficiently metabolized by acetone- or ethanol-induced microsomes than by other types of microsomes. However, substituting one methyl group with a benzyl or butyl group, as in N-nitrosobenzylmethylamine or N-nitrosobutylmethylamine (NBMA), substantially changed the enzyme specificity. P450IIE1 efficiently catalyzed the demethylation but not the debutylation of NBMA, whereas P450IIB1 (a phenobarbital-inducible form) efficiently catalyzed both the debutylation and demethylation reactions. In the demethylation of NBMA by P450IIE1, the addition of cytochrome b5 markedly increased the activity at low but not at high substrate concentrations, suggesting a decrease in Km value. This effect, however, was not observed in the debutylation of NBMA by P450IIE1 or P450IIB1, and in the demethylation of NBMA by P450IIB1. These studies demonstrate the substrate specificity and alkyl group selectivity in the metabolism of nitrosamines by cytochrome P-450 isozymes.     

Enzymatic mechanisms in the metabolic activation of N-nitrosodialkylamines

The metabolism of several N-nitrosodialkylamines was studied using rat liver microsomes and purified cytochrome P450 isozymes in a reconstituted monooxygenase system. With purified acetone/ethanol-inducible cytochrome P450 (P450ac), high N-nitrosodimethylamine (NDMA) demethylase activity was observed. Cytochrome b5 was also involved in NDMA metabolism by decreasing the Km of NDMA demethylase. A close relationship between the demethylation and denitrosation of this substrate was observed. P450ac was also active in the metabolism of N-nitrosoethylmethylamine (NEMA), but was less active than phenobarbital-inducible cytochrome P450 (P450b) in the metabolism of N-nitrosobutylmethylamine (NBMA), especially in catalysing the debutylation reaction. Similar substrate specificity was demonstrated with liver microsomes from rats treated with other inducers. With different P450 isozymes and microsomes, a close relationship between metabolism and activation of nitrosamines to mutagens to V79 cells was demonstrated. DNA alkylation by NDMA in vitro was correlated with the rate of metabolism of these compounds, whereas DNA alkylation in vivo was more complex and was dose-dependent. The work demonstrates the importance of knowledge of the substrate specificity of cytochrome P450 isozymes in understanding the mechanisms of the metabolic activation of nitrosamines.     

Metabolism and activation of N-nitrosodimethylamine by hamster and rat microsomes: comparative study with weanling and adult animals

It has been reported that hamster liver preparations are more effective for the metabolic activation of N-nitrosodimethylamine (NDMA) to a mutagen than rat liver preparations. The enzymatic basis for this phenomenon, however, has not been clearly elucidated. The present study was undertaken to examine the enzymology of NDMA metabolism by different hepatic subcellular fractions prepared from hamsters and rats of two different ages, and to investigate the correlation between the metabolism and the activation of NDMA to a mutagen for Chinese hamster V79 cells. The content of cytochrome P-450 was approximately 1.5-fold higher in hamster microsomes than in rat microsomes from both ages (1.19-1.38 versus 0.73-0.83 nmol P-450/mg protein). Weanling hamster microsomes exhibited multiple apparent Km values for NDMA metabolism as did weanling rat microsomes. The apparent Km I value of NDMA demethylase (NDMAd) in hamster microsomes was about one-half that in rat microsomes (36 versus 83 microM) with corresponding Vmax values of 2.09 and 2.57 nmol/min/nmol P-450. The Km I values for denitrosation did not differ from the corresponding values for NDMAd with Vmax values of 0.17 and 0.22 nmol/min/nmol P-450 for hamster and rat microsomes, respectively. These apparent Km values were affected neither by sonication nor by the presence of cytosolic proteins in S9 fractions. Adult rat liver microsomes showed less than one-half the NDMAd activity in weanling rat liver microsomes, whereas such age difference was not observed in hamster liver microsomes. This result was confirmed by Western blotting showing the levels of P-450ac (an acetone-inducible form of P-450) of these microsomes at comparable levels to their NDMAd activities. NDMAd was highly correlated to the metabolic activation of NDMA to a mutagen for V79 cells in an activation system mediated by microsomes prepared from hamsters and rats of different ages. The results from this study clearly demonstrate the enzymatic basis for the more effective metabolism of NDMA in adult hamsters than in adult rats.     

Reductive metabolism and protein binding of chromium(VI) by P450 protein enzymes

The cytochrome P450-dependent reduction of Cr(VI) using reconstituted phospholipid vesicles containing purified preparation of various forms of rabbit and rat liver microsomal cytochrome P450 has been investigated. The alcohol-induced form of the rat, P450IIE1, was the most efficient enzyme, 7.2 +/- 0.40 nmol Cr/nmol P450/min, whereas the corresponding rates for rat P450IA1, rat IIB1, rabbit IIB4, rabbit IA2 and rabbit IIE1 were 1.7 +/- 0.09, 2.5 +/- 0.08, 1.6 +/- 0.08, 2.5 +/- 0.15 and 1.6 +/- 0.08 nmol Cr/nmol P450/min respectively. NADPH-cytochrome P450 reductase had Cr(VI) reductase activity which was dependent on enzyme concentration. Below 0.15 nmol P450 reductase/ml the sp. act. was low and constant, while at a higher concentration the activity was markedly dependent upon the amount of enzyme present. In a quantitative binding assay it was shown that binding of [51Cr]Cr(VI) to the catalytic enzymes was proportional to the enzyme concentration up to 0.8 nmol P450/ml, which caused binding of 70% of the total radioactivity. Analysis by SDS-PAGE and autoradiography exhibited binding to the individual catalytic proteins of [51Cr]Cr. EDTA treatment removed the radioactivity from the bands matching P450 and P450 reductase, indicating that Cr(III) is bound to the proteins. The reducing activity of both P450 and P450 reductase was potently inhibited by oxygen. The inhibitory effect of oxygen is not due to reoxidation of the reduced Cr and redox cycling. Rat P450IA1 ethoxycoumarin O deethylase activity was inhibited after preincubation with chromate (CrO4(2-). The P450 reductase inhibitor 2'-AMP stimulated the anaerobic P450 reductase dependent Cr(VI) reductase rate approximately 2-fold. Both CO and CCl4 inhibited the different P450 enzymes to various extents. With rabbit P450IIE1 CCl4 stimulated the Cr(VI) reduction approximately 4-fold, whereas the activity of the other enzymes was inhibited when the reconstituted system was incubated with CrO4(2-) and CCl4 prior to NADPH addition. Neither CO nor CCl4 affected the Cr(VI) reducing activity of the P450 reductase. The difference in CrO4(2-) reducing activity of the P450 enzymes and binding to the enzymes may be important for in vivo endoplasmic catalytic metabolism of CrO4(2-).     

Participation of rat liver cytochrome P450 2E1 in the activation of N-nitrosodimethylamine and N-nitrosodiethylamine to products genotoxic in an acetyltransferase-overexpressing Salmonella typhimurium strain (NM2009).

The possible roles of cytochrome P450 (P450) enzymes in the metabolic activation of N-nitrosodimethylamine (NDMA) and N-nitrosodiethylamine (NDEA) by rat liver microsomes have been examined in a system containing the bacterial tester strain Salmonella typhimurium NM2009, a newly developed strain showing high O-acetyltransfer activities. The DNA-damaging activity could be determined by measuring expression of the umu gene in a plasmid containing the fused umuC-lacZ gene construct in the bacteria. The following lines of evidence support the view that both NDMA and NDEA are principally oxidized to reactive products by P450 2E1 in rat liver microsomes. First, NDMA and NDEA were activated by rat liver microsomes in a protein- and substrate-dependent manner and the former chemical was more active than the latter; both activities were induced in rats treated with P450 2E1 inducers such as ethanol, acetone and isoniazid and by starvation. Second, activation of NDMA and NDEA were both inhibited significantly by antibodies raised against rat P450 2E1 and by P450 2E1 inhibitors such as diethyldithiocarbamate and 4-methylpyrazole in rat liver microsomes. Finally, in reconstituted monooxygenase systems containing purified rat P450 enzymes, P450 2E1 gave the highest rates of the activation of both NDMA and NDEA; the addition of rabbit cytochrome b5 to the system caused about a 1.5-fold increase in both reactions. In separate experiments we also found that N-nitrosomethylacethoxymethylamine, a compound that reacts with DNA after ester cleavage, is more genotoxic in S.typhimurium NM2009 than in S.typhimurium NM2000, a strain that is defective in O-acetyltransferase activity. Part of the pathway involved in the activation of nitrosamines is suggested to be acetylation of alkyldiazohydroxides formed by P450 or acetylesterase, because the genotoxic activity of N-nitrosomethylacethoxymethylamine in S.typhimurium NM2009 could be inhibited by the O-acetyltransferase inhibitor pentachlorophenol. These results indicate that NDMA and NDEA are oxidized to gentoxoic products by rat liver microsomes and that a P450 2E1 enzyme plays a major role in the activation of these two potent carcinogens. The activation pathway of N-nitrosodialkylamines through acetylation by O-acetyltransferase has been proposed. This simple bacterial system for measuring genotoxicity should facilitate studies on the activation of N-nitroso alkylamines.     

Metabolism of N-nitroso-2,6-dimethylmorpholine by isozymes of rabbit liver microsomal cytochrome P-450

The cis isomer of N-nitroso-2,6-dimethylmorpholine (NNDM), a pancreatic carcinogen for the Syrian golden hamster, is metabolized by hamster liver microsomes to yield N-nitroso(2-hydroxypropyl)(2-oxopropyl)amine (HPOP) as the major product. Rabbit liver microsomes catalyze the metabolism of cis-NNDM to HPOP at a rate slower than that observed with hamster microsomes, but significantly faster than that obtained with rat microsomes. Pretreatment of rabbits with phenobarbital results in a 6-fold increase in the cis-NNDM hydroxylase activity of the rabbit microsomes to levels equal to that observed with the hamster; pretreatment of rabbits with other xenobiotics had no effect on the hydroxylation of cis-NNDM. The role of rabbit liver microsomal cytochrome P-450 in the metabolism of the cis isomer of NNDM was studied in the reconstituted system consisting of NADPH:cytochrome P-450 reductase, phospholipid, and cytochrome P-450. Cytochrome P-450LM2, which is induced by pretreatment with phenobarbital, exhibited the highest activity for the metabolism of cis-NNDM. The Vmax for the formation of HPOP was 1.78 nmol/min/nmol cytochrome P-450LM2, and the apparent Km was 360 microM. Cytochrome P-450LM3a also catalyzed the metabolism of NNDM to HPOP at a significant rate (0.25 nmol/min/nmol cytochrome P-450). Of the four other isozymes of cytochrome P-450 (forms 3b, 3c, 4, and 6) tested in the reconstituted system, only forms 3b and 3c exhibited measurable activities (approximately 0.04 nmol of HPOP formed/min/nmol cytochrome P-450). The addition of antibodies to isozyme 2 to microsomes from phenobarbital-treated rabbits resulted in approximately 95% inhibition of the metabolism of NNDM, while the addition of antibodies to LM3a inhibited NNDM metabolism by only 7%. In microsomes from untreated rabbits, inhibition by anti-LM2 and anti-LM3a antibodies was 50 and 64%, respectively. The addition of antibodies to isozyme 3a to microsomes isolated from ethanol-treated rabbits caused approximately 90% inhibition of the metabolism of NNDM. These data conclusively demonstrate that several forms of cytochrome P-450 can catalyze the metabolism of cis-NNDM and that isozymes 2 and 3a play important roles in the rabbit hepatic metabolism of NNDM to HPOP, the proximate carcinogenic metabolite.     

Role of P450IIE1 in the metabolism of 3-hydroxypyridine, a constituent of tobacco smoke: redox cycling and DNA strand scission by the metabolite 2,5-dihydroxypyridine

The metabolism of 3-hydroxypyridine, a significant constituent of tobacco smoke, to 2,5-dihydroxypyridine has been characterized in hepatic microsomes and in the reconstituted enzyme system using purified forms of P450. The redox cycling activity of the metabolite and its ability to damage DNA in vitro have been examined. Pyridine-induced microsomes, which contain elevated levels of P450IIE1 (Kim et al., J. Pharmacol. Exp. Ther., 246: 1175-1182, 1988), catalyzed an 8-fold increase in the production of 2,5-dihydroxypyridine, relative to control, which showed biphasic kinetics. Pyridine-induced rabbit hepatic microsomes exhibited a Vmax of 5.9 nmol 2,5-dihydroxypyridine/min/mg protein and a Km value of 110 microM. In contrast, phenobarbital- and isosafrole-induced microsomes had Vmax values of 2.5 and 1.2 nmol/min/mg protein and Km values of 590 and 134 microM, respectively. Pyridine-induced rat hepatic microsomes also exhibited elevated catalytic activity toward the hydroxylation of 3-hydroxypyridine, with an 8-fold increase in Vmax (2.74 nmol/min/mg protein) relative to uninduced rat hepatic microsomes (Vmax = 0.34 nmol/min/mg protein). In the reconstituted system, cytochrome P450IIE1 displayed the greatest activity in the production of 2,5-dihydroxypyridine of the major forms of rabbit P450 examined. P450IIE1 was 34-fold more active than P450IIB1 and 12-fold more active than P450IA2 in the production of 2,5-dihydroxypyridine. The redox cycling activity of 2,5-dihydroxypyridine has been characterized. The rate of NADPH oxidation in the presence of 0.5 mM 2,5-dihydroxypyridine was stimulated approximately 4-fold (69.2 nmol NADPH oxidized/min/mg protein), relative to control (16 nmol/min/mg protein). 2,5-Dihydroxypyridine at 0.5 and 1.0 mM produced a 12- and 17-fold increase, respectively, in the rate of superoxide anion production compared to control, as monitored by the SOD-inhibitable reduction of acetylated cytochrome c. 3-Hydroxypyridine alone failed to increase the rate of superoxide production. Inclusion of reduced glutathione in the incubation resulted in a pronounced decrease in the 2,5-dihydroxypyridine-stimulated rate of cofactor oxidation and superoxide production. The ability of 2,5-dihydroxypyridine to damage DNA was assessed by monitoring phi X-174 DNA strand scission. The band intensity of the supercoiled form of DNA, when incubated with 1 mM 2,5-dihydroxypyridine, decreased substantially, with a concomitant increase in intensity of the band associated with the open circular form of DNA. The change in phi X-174 DNA topology produced by 2,5-dihydroxypyridine was accelerated in a dose-dependent manner, with an estimated EC50 of approximately 60 microM.(ABSTRACT TRUNCATED AT 400 WORDS)     

Metabolism of N-nitrosomethyl-n-amylamine by microsomes from human and rat esophagus.

Asymmetric dialkylnitrosamines induce esophageal cancer in rats and hence might be involved in the etiology of this cancer in humans. As a test of this hypothesis, we examined whether nitrosamines can be activated by segments of human esophagus and by microsomes of human and rat esophagus and liver. Specimens of 8 human esophagi were removed less than 6 h after death, and segments were incubated for 6 h with 23 and 300 microM N-nitrosomethyl-n-amylamine (NMAA). Hydroxy-NMAA yields were determined by gas chromatography-thermal energy analysis and were insignificant except for those of 5-hydroxy-NMAA, which were low. Microsomes were prepared from 4 batches of human esophagi and samples with 0.6 mg protein were incubated for 20 min with NMAA and cytochrome P-450 cofactors. We determined hydroxy-NMAAs as before and aldehydes by high-performance liquid chromatography of their 2,4-dinitrophenylhydrazones. Incubation of these microsomes with 12 mM NMAA yielded mean values of 0.64 nmol formaldehyde ("demethylation"), 0.21 nmol pentaldehyde ("depentylation"), and 0.56 nmol total hydroxy-NMAAs/min/mg protein. Metabolite yields under various conditions were determined, including a demonstration that carbon monoxide inhibited 81% of NMAA demethylation, indicating that cytochrome P-450 enzymes were involved. We also examined N-nitrosodimethylamine (NDMA) demethylation by the same microsomes. Rat esophageal microsomes dealkylated NMAA and NDMA similarly to human esophageal microsomes, but with 2-6 times and twice the activity, respectively. Human and rat esophageal microsomes demethylated 6 mM NMAA 18-20 times as rapidly as they demethylated 5 mM NDMA, in contrast to liver microsomes of these species, which demethylated 6 mM NMAA only 0.9-1.4 times as rapidly as they demethylated 5 mM NDMA. However, liver microsomes of both species were more active than esophageal microsomes for NMAA depentylation. The occurrence of NMAA demethylation and (to a lesser extent) depentylation with both human and rat esophageal microsomes is important because these are the activating reactions, and suggests that both human and rat esophagus contain P-450 isozymes that specifically dealkylate asymmetric dialkylnitrosamines.     

Metabolism of N-nitrosodialkylamines by human liver microsomes

The metabolism of N-nitrosodimethylamine (NDMA), N-nitrosodiethylamine, N-nitrosobenzylmethylamine, and N-nitrosobutylmethylamine was investigated in incubations with human liver microsomes. All of the 16 microsomal samples studied were able to oxidize NDMA to both formaldehyde and nitrite at NDMA concentrations as low as 0.2 mM; the rates of product formation of the samples ranged from 0.18 to 2.99 nmol formaldehyde/min/mg microsomal protein (median, 0.53 nmol). At a concentration of 0.2 mM NDMA, the rates of denitrosation (nitrite formation) were 5 to 10% (median, 6.3%) those of demethylation (formaldehyde formation); the ratio of denitrosation to demethylation increased with increases in NDMA concentration, in a similar manner to rat liver microsomes. Immunoblot analysis with antibodies prepared against rat P-450ac (an acetone-inducible form of cytochrome P-450) indicated that the P-450ac [P-450j (isoniazid-inducible form)] orthologue in human liver microsomes had a slightly higher molecular weight than rat P-450ac and the amounts of P-450ac orthologue in human liver microsomes were highly correlated with NDMA demethylase activities (r = 0.971; P less than 0.001). Analysis of four selected microsomal samples showed that human liver microsomes exhibited at least three apparent Km and corresponding Vmax values for NDMA demethylase. This result, suggesting the metabolism of NDMA by different P-450 enzymes, is similar to that obtained with rat liver microsomes, even though most of the human samples had lower activities than did the rat liver microsomes. The high affinity Km values of the four human samples ranged from 27 to 48 microM (median, 35 microM), which were similar to or slightly lower than those observed in rat liver microsomes, indicating that human liver microsomes are as efficient as rat liver microsomes in the metabolism of NDMA. The human liver microsomes also catalyzed the dealkylation and denitrosation of other nitrosamines examined. The rates of product formation and the ratios of denitrosation to dealkylation varied with the structures and concentrations of the substrates as well as with the microsomal samples tested. The results indicate that human liver microsomes are capable of metabolizing N-nitrosodialkylamines via the pathways that have been established with rat liver microsomes.     

Roles of different cytochrome P450 enzymes in bioactivation of the potent hepatocarcinogen 3-methoxy-4-aminoazobenzene by rat and human liver microsomes

The potent hepatocarcinogen 3-methoxy-4-aminoazobenzene (3-MeO-AAB) has been reported to be bioactivated to mutagenic intermediates by rat liver microsomal cytochrome P450 (P450) and to be a selective inducer of rat P450IA2. In this study we have further investigated the roles of individual rat and human P450 enzymes in the bioactivation of this hepatocarcinogen in a Salmonella typhimurium TA1535/pSK1002 system where umu response is indicative of DNA damage. 3-MeO-AAB was found to be bioactivated by liver microsomal enzymes from rats and humans in this assay system. The liver microsomal activities are increased by pretreatment of rats with various P450 inducers such as phenobarbital (PB), beta-naphthoflavone (BNF), dexamethasone (DEX), acetone, ethanol, isoniazid (INH), diphenylhydantoin and valproic acid, and can be inhibited considerably by SKF-525A and metyrapone. alpha-Naphthoflavone (ANF) is also an inhibitor for the reaction catalyzed in BNF-treated rats, but stimulated the microsomal activity in DEX-treated rats. Evidence has also been obtained that specific antibodies raised against P450IIB1, P450IA1 or IA2, P450IIE1, and P450IIIA2 inhibited the activation in liver microsomes from rats pretreated with PB, BNF, INH and DEX respectively, suggesting the possible roles of several P450 enzymes in the bioactivation of 3-MeO-AAB. The results obtained with reconstituted monooxygenase systems containing various rat P450 enzymes are highly supportive of this conclusion. Human liver microsomal activation of 3-MeO-AAB was also inhibited to various extents by antibodies raised against P450IA2, P450MP, P450IIE1 and P450IIIA4. In a reconstituted system containing purified forms of human P450, P450IA2 was the most active in catalyzing 3-MeO-AAB, followed by P450IIIA4 and P450MP. ANF, a known activator of P450IIIA-catalyzed reactions, caused an increase in activation of 3-MeO-AAB in human liver microsomal and P450IIIA4- and P450MP-containing reconstituted systems. From these results it is concluded that multiple P450 enzymes in rat and human liver microsomes are involved in the bioactivation of 3-MeO-AAB, regardless of its selective induction of the rat P450IA2 gene.     

Metabolism of the beta-oxidized intermediates of N-nitrosodi-n-propylamine: N-nitroso-beta-hydroxypropylpropylamine and N-nitroso-beta-oxopropylpropylamine

The rat liver carcinogen N-nitrosodi-n-propylamine (NDPA) is metabolized to a propylating and methylating species in vivo. Metabolism to a methylating species is believed to require an initial hydroxylation by cytochrome P450s (P450s) to N-nitroso-beta-hydroxypropylpropylamine (NHPPA), which is oxidized to N-nitroso-beta-oxopropylpropylamine (NOPPA), followed by a P450-mediated depropylation to beta-oxopropyldiazotate, which non-enzymatically breaks down to the methylating agent. Purified rat liver P450 2B1 and rabbit liver 2E1 in the reconstituted system and liver microsomes from phenobarbital (PB) and pyridine (Pyr) treated rats readily metabolized NOPPA to a methylating species as determined by the in vitro formation of 7-methylguanine (m7Gua) in DNA. Exposure of cells derived from the human liver epithelium transfected with human 2E1 (T5-2E1) to NOPPA resulted in the formation of m7Gua DNA adducts and a dose dependent toxicity. In vitro incubation of NHPPA with microsomes from PB, Pyr and non-treated (NT) rats and a human microsomal sample also resulted in m7Gua formation. P450s 2B1 and 2E1 oxidized NHPPA to NOPPA, forming 16.5 +/- 3.1 and 20.0 +/- 4.4 pmol NOPPA/pmol P450 in 1 h, respectively. Rat liver cytosol, in the presence of NAD+, oxidized NHPPA to NOPPA at a rate of 13.7 +/- 3.0 pmol/min/mg protein while microsomes from NT rats catalyzed this reaction at 95.6 +/- 16.5 pmol/min/mg protein. Cells derived from hamster lung tissue (V79 control) and T5-neo cells oxidized NHPPA to NOPPA. This oxidation was about 15 fold higher in T5-2E1 or V79 cells transfected with human 2E1 or rat 2B1, respectively. The results are consistent with the putative sequential oxidation pathway and suggest that, at the concentrations tested, oxidation of NHPPA to NOPPA may be predominantly mediated by cytochrome P450s. In addition, it appears that rabbit, rat and human P450 2E1 can catalyze both oxidations.     

Cytochrome P450 2E1 and 2A6 enzymes as major catalysts for metabolic activation of N-nitrosodialkylamines and tobacco-related nitrosamines in human liver microsomes.

An acetyltransferase-overexpressing strain of Salmonella typhimurium (NM2009) has been used to investigate roles of human liver microsomal cytochrome P450 (P450) enzymes in the activation of carcinogenic nitrosamine derivatives, including N-nitrosodialkylamines and tobacco-smoke-related nitrosamines, to genotoxic products. Studies employing correlation of activities with several P450-dependent monooxygenase reactions in different human liver samples, inhibition of microsomal activities by antibodies raised against human P450 enzymes and by specific P450 inhibitors, and reconstitution of activities with purified P450 enzymes suggest that the tobacco-smoke-related nitrosamines 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL) and N-nitrosonornicotine (NNN) as well as N-nitrosodimethylamine (NDMA) and N-nitrosodiethylamine (NDEA) are oxidized to genotoxic products by different P450 enzymes, particularly P450 2E1 and 2A6. The activation of NDMA and NNN by liver microsomes was suggested to be catalyzed more actively by P450 2E1 than by other P450 enzymes because the activities were well correlated with NDMA N-demethylation and aniline p-hydroxylation in different human samples, and purified P450 2E1 had the highest activities in reconstituted monooxygenase systems. The relatively high contribution of P450 2A6 to the activation of NDEA and NNK was supported by the correlation seen with coumarin 7-hydroxylation in human liver microsomes, and antibodies raised against P450 2A6 inhibited both activities by approximately 50%. P450 3A4, 2D6 and 2C enzymes appear not to be extensively involved in the activation of these nitrosamines as judged by several criteria examined. Thus, this work indicates that several P450 enzymes, particularly P450 2E1 and 2A6, catalyze metabolic activation of nitrosamine derivatives including N-nitrosodialkylamines and tobacco-smoke-related nitrosamines in human liver microsomes.     

Human cytochrome P450IIA3: cDNA sequence, role of the enzyme in the metabolic activation of promutagens, comparison to nitrosamine activation by human cytochrome P450IIE1

We report that, in a human cell line, human cytochrome P450IIA3 is capable of metabolizing aflatoxin B1, benzo[a]-pyrene, N-nitrosodimethylamine (NDMA) and N-nitrosodiethylamine (NDEA) to cytotoxic and mutagenic species. Cytochrome P450IIA3-mediated activation of NDMA and NDEA was compared with human cytochrome P450IIE1-mediated activation in the same cell system. P450IIE1 was more effective at activating NDMA than P450IIA3, while P450IIA3 was more effective at activating NDEA than P450IIE1. Whole cells and microsomal fractions obtained from control cells and from cells expressing the P450IIA3 cDNA were characterized for expression of P450IIA3. Microsomal coumarin 7-hydroxylase activity was some 40 times greater in the transfected cells than in the control cells and was catalyzed by a protein that was immunochemically related to the rat liver cytochrome P450IIA gene family. Immunoblot analysis demonstrated that this protein was readily detectable in transfected cells but barely detectable in control cells. We also report the DNA and deduced amino acid sequence of the P450IIA3 cDNA isolate used in this study. Our isolate encodes a protein 489 amino acids that is five amino acids shorter at the N terminus but otherwise identical to a previously reported human P450IIA3 cDNA sequence.     

Biotransformation of aflatoxin B1 in rabbit lung and liver microsomes

Aflatoxin B1 (AFB1) is a potent hepatotoxic and hepatocarcinogenic mycotoxin that requires bioactivation to AFB1-2,3-oxide for activity. In addition to epoxidation, microsomal monooxygenases biotransform AFB1 to the less toxic metabolites, aflatoxin M1 (AFM1) and aflatoxin Q1 (AFQ1). The lung is at risk from AFB1 both via inhalation and via the circulation. In the present study, we have characterized rabbit lung and liver microsomal AFB1-DNA binding (an index of AFB1-2,3-oxide formation), AFM1 formation and AFQ1 formation. Vmax values for AFB1-DNA binding were not different between lung and liver when expressed per mg microsomal protein (1.06 +/- 0.13 and 2.12 +/- 1.30 nmol/mg/h for lung and liver respectively), but lung values were greater than liver when expressed per nmol cytochrome P450 (3.64 +/- 0.31 and 1.29 +/- 0.70 nmol/nmol P450/h for lung and liver respectively). Km values for this reaction were not different between lung and liver. Vmax values for AFM1 formation in liver microsomes were greater than in lung when expressed per mg protein, but not when expressed per nmol P450. No differences were detected for the Km for AFM1 formation between lung and liver microsomes. For AFQ1 formation, no differences were detected between Vmax values of lung and liver, regardless of whether results were expressed per mg protein or per nmol P450, while the Km for AFQ1 formation was lower in liver. SKF-525A inhibited these reactions by 63-74% in lung microsomes and 90-96% in liver microsomes. These results indicate that the lung is capable of activating AFB1, and that rabbit lung microsomes contain high activity for this reaction. Furthermore, little AFM1 and AFQ1 are formed in lung microsomes, leading to minimal shunting of AFB1 from the activation pathway.     

Analysis of the inhibition of N-nitroso-dimethylamine activation in the liver by N-nitro-dimethylamine using a new non-linear statistical method

N-nitro-dimethylamine (NTDMA) is carcinogenic to rats: it induces nasal cavity tumours. It can be demethylated to N-nitromethylamine and formaldehyde and reduced to N-nitroso-dimethylamine (NDMA): a potent liver carcinogen and also of the nasal cavity if activation in the liver is blocked. To explain the mechanism of NTDMA carcinogenicity we compared its demethylation with that of NDMA in liver microsomes from female and male rats, untreated, fasted or treated with ethanol to induce cytochrome P450 2E1 (CYP2E1). Kinetic parameters were analysed by nonlinear statistical methods, which yielded unbiased parameter estimates for the calculated Km and Vmax values. Km for both compounds was very similar in females (24-47 microM) whereas Vmax for NTDMA was consistently higher than for NDMA as substrate: 1.07-4.70 nmol formaldehyde/mg microsomal protein x min and 0.52-2.76 nmol, respectively. In liver microsomes from induced male rats NTDMA was found to be a much more effective inhibitor of NDMA activation (KEI 39.6-73.6 microM) than NDMA of NTDMA demethylation (KEI 224-286 microM). Nasal microsomes can demethylate both NDMA and NTDMA but the kinetics are vastly different. NTDMA is demethylated at a linear rate and approximately 10-fold more effectively than NDMA. The mechanism of carcinogenicity of ingested NTDMA, we propose, is a partial reduction to NDMA in the liver and inhibition of NDMA activation in the liver by residual NTDMA, which enables NDMA to reach the nasal mucosa where it is activated to DNA-alkylating species and the observed tumours are formed.     

Metabolism of carcinogenic nitrosamines by rat nasal mucosa and the effect of diallyl sulfide

Rat nasal cavity is one of the target organs for carcinogenesis induced by N-nitrosodimethylamine (NDMA), N-nitrosodiethylamine (NDEA), and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK). The present work investigated the metabolism of these nitrosamines by rat nasal microsomes, as well as the possible modulating factors. Microsomes prepared from rat nasal mucosa were efficient in metabolizing these nitrosamines. In general, the metabolism of the nitrosamines was slightly higher in 9-week-old rats than in 4-week-old animals, and there was no sex-related difference. Fasting of rats for 48 h, which is known to induce hepatic cytochrome P450IIE1 and NDMA metabolism, did not increase the nasal metabolism of NDMA, NDEA, or NNK. Pretreatment of rats with acetone, another inducer of hepatic P450IIE1, did not increase the metabolism of NDMA. Furthermore, it decreased the nasal metabolism of NDEA and NNK. Immunoinhibition studies suggest that, in the nasal mucosa, P450IIE1 is only partially responsible for the oxidation of NDMA and other P450 isozymes are responsible for the metabolism of NDEA. A single p.o. pretreatment of male rats with diallyl sulfide (DAS), a component of garlic oil, caused a significant decrease in the oxidative metabolism of NDEA and NNK in rat nasal mucosa. Whereas the nasal metabolism of NDMA was reduced by DAS pretreatment, there was no change in the amount of the nasal microsomal proteins immunoreactive with the antibodies against P450IIE1. The inhibitory effect of DAS on the nasal oxidative metabolism of NDMA, NDEA, and NNK was also observed in experiments in vitro. The results demonstrate the ability of nasal mucosa to metabolically activate these nitrosamines and the inhibition of this process by DAS, suggesting that DAS may be effective in inhibiting the related nasal tumorigenesis.