Comparative formation and removal of aflatoxin B1-DNA adducts in cultured mammalian tracheal epithelium

Aflatoxin B1 (AFB1) DNA binding, adduct formation, and AFB1-DNA adduct repair were studied in tracheal explants from rabbit, hamster, and rat. These species vary in populations of cytochrome P-450-containing nonciliated tracheal epithelial cells. Explants were cultured in media containing 0.5 microM AFB1 for 12 h. After the 12-h treatment, the explants were cultured for time intervals up to 84 h and then analyzed for AFB1-DNA adducts. Binding of AFB1 to DNA was highest in rabbit tracheal explants (78 pmol/mg DNA), followed by the hamster (28 pmol/mg DNA), with the rat (3 pmol/mg DNA) showing minimal AFB1-DNA binding. Repair rates in the hamster and rat were constant over time with removal of the 8,9-dihydro-8-(N7-guanyl)-9-hydroxyaflatoxin B1 accounting for the majority of adduct disappearance. The rabbit demonstrated biphasic repair of adducts; all adduct types [8,9-dihydro-8-(2-amino-6-formamido-4-oxo-3,4-dihydropyrimid-5- ylamino)-9- hydroxyaflatoxin B1] were rapidly removed during the first 12 h posttreatment with AFB1, followed by a slower removal phase of primarily 8,9-dihydro-8-N7-guanyl)-9-hydroxyaflatoxin B1. After 84 h, 90, 72, and 55% of the initial adducts were removed in the rabbit, hamster, and rat, respectively. Labeled thymidine studies showed that cells of the tracheal epithelium did not turn over sufficiently to bias the apparent repair rates. These results demonstrated that carcinogen activation and repair capabilities of tracheal epithelium vary among species and that these processes likely relate to the presence of smooth endoplasmic reticulum containing nonciliated tracheal epithelial cells in those species.     

Comparative action of aflatoxin B1 in mammalian airway epithelium

Aflatoxin B1 (AFB1) is thought to be an occupational risk factor for airway carcinogenesis where exposure to AFB1-laden grain dusts is common. Since activation of AFB1 is catalyzed by cytochromes P-450 associated with the smooth endoplasmic reticulum, we compared the response to AFB1 in cultured tracheal epithelium from species with abundant (rabbit and hamster) and scarce (rat and monkey) distributions of smooth endoplasmic reticulum in nonciliated tracheal epithelial cells. Explants from each species, incubated in medium containing 0.5 microM [14C]-AFB1 for selected intervals up to 24 h, were compared on the basis of binding of [14C]-AFB1 to tracheal DNA, amount and type of AFB1 metabolites in the medium, ultrastructurally determined population densities of epithelial cells, and distribution of bound material in epithelium as determined by autoradiographic grain densities. Cultures derived from rabbits were most active in metabolic conversion and formation of AFB1-DNA adducts, followed by those from hamsters, rats, and monkeys. Rabbit tracheal epithelium formed a significantly greater proportion of glutathione conjugates, while that from hamster formed a greater amount of AFB1-dihydrodiol, compared to rats and monkeys. The monkey formed significantly greater proportions of aflatoxin Q1 and the rabbit more aflatoxicol, compared to other species. There was selective degeneration and accumulation of labeled material in nonciliated cells in both rabbits and hamsters but not in rats or monkeys. Explants from rabbit tracheas were much more susceptible to cytotoxic injury and had higher autoradiographic grain densities than explants from hamsters. We conclude that the presence of smooth endoplasmic reticulum-containing nonciliated epithelial cells is qualitatively associated with the activation and toxicity of AFB1.     

Metabolism of benzo[a]pyrene and benzo[a]pyrene-7,8-diol by human cytochrome P450 1B1

Benzo[a]pyrene (B[a]P), a ubiquitous environmental, tobacco and dietary carcinogen, has been implicated in human cancer etiology. The role of human cytochrome P450 1B1 in the metabolism of B[a]P is poorly understood. Using microsomal preparations of human P450 1A1, 1A2 and 1B1 expressed in baculovirus-infected insect cells, as well as human and rat P450 1B1 expressed in yeast, we have determined the metabolism of B[a]P, with and without the addition of exogenous epoxide hydrolase, and B[a]P-7,8-dihydrodiol (7,8-diol), each substrate at a concentration of 10 microM. HPLC analysis detected eight major metabolites of B[a]P and four metabolites of the 7,8-diol. The results of these studies indicate that cytochrome P450 1B1 carries out metabolism of B[a]P along the pathway to the postulated ultimate carcinogen, the diol epoxide 2, at rates much higher than P450 1A2 but less than P450 1A1. The rates of formation of the 7,8-diol metabolite in incubations with epoxide hydrolase are 0.17 and 0.38 nmol/min/nmol P450 for human P450 1B1 and 1A1, respectively, and undetectable for 1A2. The rates of total tetrol metabolite formation from the 7,8-diol, which are indicative of diol epoxide formation, are 0.60, 0.43 and 2.58 nmol/min/nmol P450 for 1B1, 1A2 and 1A1 respectively. In agreement with other reports of rat P450 1B1 activity, our data show this rat enzyme to be very active for B[a]P and 7,8-diol, with rates higher than human P450 1B1. In addition to the established role of P450 1A1 in B[a]P metabolism, P450 1B1 may significantly contribute to B[a]P and 7,8-diol metabolism and carcinogenesis in rodent tumor models and in humans.      

The role of 12 cDNA-expressed human,rodent, and rabbit cytochromes P450 in the metabolism of benzo[a]pyrene and benzo[a]pyrene trans-7, 8-dihydrodiol

The potent carcinogen benzo[a]pyrene (B[a]P) and its metabolite B[a]P trans-7, 8-dihydrodiol (7, 8-diol) require metabolic activation by the microsomal cytochrome P450s (P450s) to exert several adverse biological effects, including binding to DNA, toxicity, mutagenicity, and carcinogenicity. In the study reported here, we defined the role of each of 12 individual cDNA-expressed cytochrome P450s in the metabolism of B[a]P and 7, 8-diol. Human P450s 1A1 and 1A2 were expressed in the absence or presence of epoxide hydrolase (EH) in a human lymphoblastoid cell line, and six human and five rodent and rabbit P450s were expressed from cDNA with vaccinia virus vectors in the hepatoma cell line Hep G2. B[a]P metabolism resulted in nine metabolites (three diols, three quinones, and three phenols), which were separated, identified, and quantitated by high-pressure liquid chromatography. In the human lymphoblastoid cells, human 1A1 metabolized B[a]P at a rate 4.5 times greater than that for 1A2. EH was shown to be directly involved in B[a]P activation, since increasing the amount of EH resulted in less 7-hydroxybenzo[a]pyrene and more 7, 8-diol formation. Of the human P450s expressed with the vaccinia virus vectors in Hep G2 cells, 1A2 and 2C9 showed the highest activity and 2B6 showed moderate activity for B[a]P metabolism. Mouse 1A1 had activity 40 times higher than any human, rabbit, or rodent P450s, indicating the potential pitfalls of extrapolating P450 activity across species. Metabolism of the 7, 8-diol resulted in six metabolites (four tetrols and two triols). In the lymphoblastoid cells, human 1A1 was shown to be 4.2 times more active than 1A2 for 7, 8-diol metabolism. Among human P450s expressed from vaccinia virus, 1A2, 2E1, and 2C9 gave the highest activity, and 2C8 and 3A4 showed moderate activity for 7, 8-diol metabolism to the diol epoxides. Again, mouse 1A1 was much more active than any other P450. These studies, in which we determined the capacity of individual P450 in the metabolism and activation of B[a]P and 7, 8-diol, may thus lead to a better understanding of how P450s control the detoxification and activation of polycyclic aromatic hydrocarbons. © 1994 Wiley-Liss, Inc.     

Cytochrome P450 species involved in the metabolism of quinoline

Quinoline is a hepatocarcinogen in rats and mice and a well-knownmutagen in bacteria after incubation with rat liver microsomes.The specific cytochrome P450 enzymes involved in quinoline metabolismin human and rat liver microsomes were determined using cDNA-expressedcytochrome P450s, correlations with specific cytochrome P450-linkedmonooxygenase activities in human liver microsomes and inhibitionby specific inhibitors and antibodies. CYP2A6 is the principalcytochrome P450 involved in the formation of quinoline-1-oxidein human liver micro-somes (correlation coefficient r = 0.95),but is formed in only minute quantities in rat liver microsomes.CYP2E1 is the principal cytochrome P450 involved in the formationof 3-hydroxyquinoline (r = 0.93) in human liver microsomes andis involved in the formation in rat liver microsomes. A highcorrelation coefficient (r = 0.91) between CYP2A6 activity andquinoline-5,6-diol formation in human liver microsomes was observed,but this most likely reflects the involvement of CYP2A6 in theformation of quinoline-5,6-epoxide, from which the quinoline-5,6-diolis formed, as conversion of quinoline-5,6-epoxide to quinoline-5,6-diolon incubation of the epoxide with CYP2A6 could not be demonstrated.A cDNA-expressed human microsomal epoxide hydrolase, however,efficiently converted the epoxide to the diol and the microsomalepoxide inhibitor cyclohexene oxide inhibited quinoline-5,6-diolformation in rat liver microsomes. A preliminary kinetic analysisof quinoline metabolism in human liver microsomes was carriedout and Eadie-Hofstee plots indicate that the formation of quinoline-5,6-diolis monophasic, while that of quinoline-1-oxide and 3-hydroxyquinolineis biphasic.     

Enhancing effect of ethanol on aflatoxin b1-induced DNA-damage in glutathione-depleted rat hepatocytes

The effect of reduced glutathione (GSH) and ethanol on aflatoxin B1 (AFB1)-induced DNA single strand breaks was studied in primary cultured hepatocytes. Buthionine sulfoximine (BSO) which decreased intracellular GSH to 13% of those of the control levels increased DNA fragmentation of AFB1-treated hepatocytes by over 17% of those without BSO. Thus, a decrease in hepatocyte GSH levels increased AFB1-induced DNA damage. Although ethanol in itself did not induce DNA damage, a combination of BSO and ethanol increased the percentage by over 23% of that with BSO only. Ethanol did not affect the amount of GSH, total cytochrome P-450 (P450), glutathione S-transferase (GST) and epoxide hydrolase (EHase) in cultured hepatocytes. However, GSH-depleted rat hepatocytes exposed to ethanol significantly increased the level of P450IIIA, which activates AFB1. The enhancing effects of ethanol in the presence of BSO are probably due to the induction of this isozyme in rat hepatocytes. The GSH-depleted hepatocytes are more susceptible to chemical carcinogens in the presence of ethanol.     

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.     

Rapid and sensitive enzyme-linked immunosorbent assay for the microsomal epoxide hydrolase

A rapid and sensitive indirect enzyme-linked immunosorbent assay(ELISA) was developed for micrsomal epoxide hydrolase of ratliver. The assay, which is easily and readily performed, issignificantly more sensitive than most enzymatic epoxide hydrolaseassays routinely used and electroimmunoassays previously developed.The limit of sensitivity of the ELISA is between 2–5 ngof microsomal epoxide hydrolase. Using the ELISA microsomalepoxide hydrolases of mouse and rat liver were shown to be antigenicallyvery similar, while microsomal epoxide hydrolases of guineapig, monkey and human liver are antigenically distinct fromthose of rat and mouse. The ELISA developed here is capableof detecting microsomal epoxide hydrolase of rat and mouse livereven when significant enzymatic activity is lost. These resultsindicate that the antigenic sites recognized by the antibodiesused are distinct from the catalytic site of the epoxide hydrolase.Approximately 1.9% of rat microsomal protein was quantifiedas microsomal epoxide hydrolase by the ELISA. Low levels ofmicrosomal epoxide hydrolase were also detected in rat livercytosol (0.02% of the cytosolic protein) demonstrating thatmicrosomal epoxide hydrolase is not totally membrane bound orthat an immunologically related protein occurs in the cytosolof normal rat liver. The ELISA developed here will be valuablein investigating further the role of microsomal epoxide hydrolase.     

Development of a human cell line by selection and drug-metabolizing gene transfection with increased capacity to activate promutagens

We have isolated a human lymphoblastoid cell line with higher levels of native cytochrome P450IA1 activity and by DNA transfection introduced human cDNAs for a putative cytochrome P450IIA2 and epoxide hydrolase (E.C. 3.3.2.3). The resultant cell line, designated MCL-1, was substantially more sensitive to the mutagenicity of dimethylnitrosamine and benzo[a]pyrene than the AHH-1 cell line and was found to have increased metabolism of benzo[a]pyrene to dihydrodiols. The increase in native cytochrome P450IA1 activity was achieved by mutation and selection based on resistance to the phototoxicity of benzo[ghi]perylene. One resistant clone, designated L3, was used for subsequent studies. Two complete cDNAs, one encoding a putative cytochrome P450IIA2 and the other a microsomal epoxide hydrolase, were isolated from a human liver cDNA library. After introduction of the cDNAs into an expression vector and transfection into AHH-1 cells, gene expression was detected at the level of enzyme activity (epoxide hydrolase) or by increased sensitivity to dimethylnitrosamine cytotoxicity/mutagenicity (putative P450IIA2). A vector containing both cDNAs was then constructed and transfected into L3 cells to produce MCL-1 cells. The potential usefulness of drug-metabolizing gene transfection and of the MCL-1 cell line, in particular, for genetic toxicity testing is discussed.     

Metabolism of aflatoxin B1 in the upper airways of the rabbit: role of the nonciliated tracheal epithelial cell

Short-term tracheal explant cultures from the rabbit were used to study the metabolism of the carcinogen aflatoxin B1 (AFB1) and to determine the cell types that are susceptible to damage by AFB1 and their relative contents of monooxygenase enzymes. Tracheas were cultured in serum-free medium for 0.5-24 h with 0.7 microM [3H]AFB1, and metabolism was measured by determining the level of binding of the carcinogen to DNA and by the release of metabolites into the medium. The binding of aflatoxin B1 was time dependent and appeared to peak at 12 h in culture. In addition, the metabolites aflatoxicol, aflatoxin M1, and aflatoxin Q1 were produced by the explants. Ultrastructural evaluation of cultured tracheas showed degenerative changes exclusively in nonciliated secretory cells after 4 h in culture. Extensive nonciliated secretory cell necrosis was evident by 12 h. Ciliated cells did not show degenerative changes until 12 h and appeared much more viable after 24-h exposure to AFB1 relative to the nonciliated cells. Tracheal sections stained to demonstrate rabbit lung cytochrome P-450, Forms 2 and 5, and cytochrome P-450 reduced nicotinamide adenine dinucleotide phosphate reductase by an immunoperoxidase technique showed intense staining selectively within nonciliated cells. In total, the data revealed that: (a) rabbit tracheal explants are able to metabolize aflatoxin B1; (b) the nonciliated secretory cell population in this tissue is the target cell for cytotoxicity of this carcinogen; and (c) as is the case in the more distal airways, the nonciliated epithelial cells appear to have a high content of components of the pulmonary cytochrome P-450 monooxygenase system, which may be an important factor in the susceptibility of these cells and this region of the airways to suspected airborne carcinogens.     

Effect of beta-naphthoflavone on the metabolism of aflatoxin B1 in hamsters

The effect of beta-naphthoflavone (BNF) pretreatment of hamsters on the hepatic metabolism of aflatoxin B1 (AFB1) has been examined in studies in vitro and in vivo. Pretreatment with BNF not only increased microsomal cytochrome P-450 by 50-80% but also increased microsome-mediated AFB1 epoxidation as measured by AFB1-DNA binding 2.6 fold without significantly affecting other hydroxylations. Neither cytosolic GSH S-transferases' activities nor AFB1-GSH (AFB1-SG) conjugation were affected. In vivo, hepatic AFB1-DNA binding was also increased about 3-4-fold. These results in contrast to those observed in the rat indicate that induced species of cytochrome P-450 are primarily responsible for higher epoxidation of AFB1 in the hamster.     

Aflatoxin B1-DNA binding and aflatoxin B1-glutathione conjugation with isolated hepatocytes from rats and hamsters

Binding of aflatoxin B1 (AFB1) to DNA and AFB1-glutathione conjugation during the metabolism of AFB1 have been examined with freshly isolated hepatocytes from male Fischer rats and Syrian hamsters. Even though there was no significant difference in cytochrome P450 and glutathione contents, there were marked differences in the metabolism of AFB1 (33 nM) in hepatocytes from these two species. Thus, AFB1-DNA binding was six-fold higher in the rat than in hamster hepatocytes, whereas AFB1-glutathione conjugation was 12-fold higher in hamster than in rat hepatocytes. The addition of 0.5 mM diethylmaleate had no significant effect in rats, whereas its presence produced a nine-fold increase in AFB1-DNA binding with 85% inhibition of thiol conjugation in hamster hepatocytes. Styrene oxide (1 mM) produced 50% and 25-fold increases in AFB1-DNA binding in rat and hamster hepatocytes, respectively, with corresponding decreases in thiol conjugation. Triethyltin bromide (50 microM) inhibited both processes by 50% in rat hepatocytes, whereas it produced a nine-fold increase in AFB1-DNA binding with a concomitant decrease in thiol conjugation in hamster hepatocytes. These results suggest that glutathione S-transferases play a more significant role in modulating AFB1-DNA binding in hamster than in rat hepatocytes.     

Genetic polymorphism and cancer risk

Inter-individual variability in carcinogen metabolism has been attributed in part to the polymorphic expression of several phase I and II detoxification enzymes. The role of these genetic polymorphisms in cancer susceptibility has been most extensively evaluated for isozymes of cytochrome P450 (CYP1A1, CYP2D6, and CYP2E1), N-acetyltransferase (NAT1 and NAT2), glutathione S-transferase (GSTM1, GSTT1, and GSTP1), microsomal epoxide hydrolase, and NAD(P)H:quinone oxidoreductase. Our understanding of the genetic basis of cancer risk has been enhanced most recently by establishment of genotype-phenotype correlations in humans and identification of numerous diverse factors, both genetic and environmental, that can modify risk.     

代谢酶基因多态性与肺癌易感性

肺癌的易感性存在个体差异,参与解毒及生物转化的代谢酶的基因多态性被认为与肺癌易感性相关.催化致癌物质代谢过程的酶主要有Ⅰ相代谢酶和Ⅱ相代谢酶,包括细胞色素P450酶系及由N-乙酰转移酶、微粒体环氧化物酶、醌氧化还原酶1(NQO1)等构成的Ⅱ相代谢酶系,均为预测肺癌易感的候选基因.通过研究代谢酶基因多态性与肺癌易感性的关系,发现有意义的肺癌标志物,筛选肺癌易感人群并提前进行干预,有利于降低肺癌的发病风险.     

Bioactivation of aflatoxin B1 by lipoxygenases, prostaglandin H synthase and cytochrome P450 monooxygenase in guinea-pig tissues.

In the present investigation, we have examined the role of lipoxygenases in the bioactivation of aflatoxin B1 (AFB1) in hepatic and extrahepatic tissues. The enzyme activities were evaluated by determining [3H]AFB1-DNA adduct formation. The results demonstrated that both purified soybean lipoxygenase and guinea-pig tissue cytosolic lipoxygenases were able to activate AFB1 to form [3H]AFB1-DNA adduct(s). The reaction was completely inhibited by nordihydroguaiaretic acid (NDGA, 0.1 mM), a lipoxygenase inhibitor and an antioxidant, but not by indomethacin (0.1 mM), an inhibitor of prostaglandin H synthase (PHS), indicating that this reaction is associated with lipoxygenase activity, and/or is involved in a peroxyl radical process. While purified lipoxygenase showed arachidonic acid (AA)-dependent properties, the omission of AA did not diminish guinea-pig tissue cytosolic [3H]AFB1-DNA adduct formation, possibly because AA was released from lipid particles by AFB1. Within the range of hemoglobin (Hb) concentrations found in lung, kidney and liver cytosols (1.4-11.1 microM) and microsomes (0-0.5 microM), neither pure Hb, nor Hb of cytosols or microsomes from whole blood caused detectable AA-dependent AFB1-DNA binding. This indicates that Hb, as a contaminant with quasi-lipoxygenase activity, did not contribute to AFB1 activation attributed to guinea-pig tissue lipoxygenases. [3H]AFB1 concentrations at half-maximal DNA binding rate of pulmonary cytochrome P450 monooxygenases (P450) and lipoxygenases were similar, though P450 had a much higher maximum DNA binding rate. Pulmonary microsomal PHS activity for AFB1 activation was too low for its half-maximal binding concentrations of [3H]AFB1 and maximum rate to be accurately determined. In kidney, maximum rates for lipoxygenase, PHS and P450 were similar, whereas half-maximal binding concentrations for reactions by lipoxygenase and P450 were lower compared to that of PHS. The half-maximal binding concentration of hepatic lipoxygenase was significantly lower than those for PHS and P450. Hepatic half-maximal binding concentrations for PHS and P450 were similar, though P450 had a much higher maximum rate than PHS and lipoxygenases. These data suggest that lipoxygenase-catalyzed AFB1 activation can occur at low AFB1 concentrations. This may be important in view of human exposure to low AFB1 concentrations and predominant lipoxygenase activity in human airway epithelial cells. When expressed per gram of tissue, renal and hepatic PHS activities and renal lipoxygenase activities for AFB1 activation were similar, and higher than the activity of pulmonary PHS, while pulmonary PHS activity for the oxidation of N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) was similar to that in liver and lower than that in kidney.(ABSTRACT TRUNCATED AT 400 WORDS)     

Reduced nicotinamide adenine dinucleotide phosphate-dependent formation of 2,3-dihydro-2,3-dihydroxyaflatoxin B1 from aflatoxin B1 by hepatic microsomes.

2,3-Dihydro-2,3-dihydroxyaflatoxin B1 (dihydrodiol) was formed as a major metabolite in the incubation of aflatoxin B1 with rat and hamster liver microsomes. The yield of the dihydrodiol was maximal at pH 6.5, was reduced nicotinmide adenine dinucleotide phosphate- and cytochrome P-450-dependent, and was increased 2- to 4-fold by pretreatment of the animals with phenobarbital; pretreatment with 3-methylcholanthrene did not alter the activity of rat hepatic microsomes. Inhibitors of epoxide hydrase did not lower the yield of the dihydrodiol in these systems. Negligible yields of the dihydrodiol were formed from aflatoxin B1 and rat liver microsomes in the presence of DNA. Little or no formation of the dihydrodiol was noted with microsomes from rat intestinal mucosa, kidney, or lung. These results further support the formation of aflatoxin B1 2,3-oxide as a major electrophilic metabolite of aflatoxin B1 in rat and hamster liver microsomal systems, since this highly reactive epoxide would be expected to hydrolyze readily to form the dihydrodiol.     

Metabolic basis for the protective effect of the antioxidant ethoxyquin on aflatoxin B1 hepatocarcinogenesis in the rat

The effect of dietary administration of 0.5% ethoxyquin (EQ) on the in vivo induction of enzymes and effect on aflatoxin B1 (AFB1)-DNA binding in liver and the consequent in vitro metabolism of AFB1 by male Fischer F344 rat liver-derived fractions have been examined. EQ increased microsomal cytochrome P-450s, in particular those isozymes classed as phenobarbital inducible, and the in vitro rate of metabolism of AFB1. The formation of the presumed detoxified metabolites, aflatoxins M1 and Q1, was enhanced to a greater extent than was the formation of the active metabolite, aflatoxin B1-8,9 epoxide (assessed by the level of aflatoxin B1-8,9-dihydrodiol). Prolonged feeding with EQ was accompanied eventually by a reduction in the initially elevated cytochrome P-450 content, but this was not reflected in any significant decrease in the rate of AFB1 metabolism in vitro. EQ increased the glutathione S-transferase activity of the liver cytosol fractions as assessed with the model substrate 1-chloro-2,4-dinitrobenzene. The capacity of these fractions specifically to catalyze the conjugation of AFB1 with glutathione was induced to a far greater extent than was the conjugation of 1-chloro-2,4-dinitrobenzene. gamma-Glutamyl transpeptidase was induced in the periportal areas of the liver lobule. Reduced in vivo binding of [3H]AFB1 to DNA of liver and kidney was found to result from EQ treatment. It is concluded that the reduced hepatocarcinogenesis which results from feeding EQ simultaneously with AFB1 is due to the reduction in DNA-adduct formation which in turn is due at least in part to increased detoxifying metabolism in the microsomal, cytosolic, and plasma membrane compartments of the liver cells.     

Genetic variations in benzene metabolism and susceptibility to multiple myeloma

We have previously shown that deficiency in the biotransformation enzyme glutathione-S-transferase theta (GSTT1) is a risk factor for multiple myeloma (MM). The present case-control study of 102 MM patients and 205 controls revealed a significant trend in increasing risk of MM with inheritance of multiple putative 'high risk' genetic variants in related pathways of benzene detoxification. Individuals who carried polymorphisms for GSTT1 null and/or high activity microsomal epoxide hydrolase (mEH 113YY+139HR or 113YY+139RR or 113YH+139RR) and/or low activity NAD(P)H:quinone oxidoreductase 1 (NQO1 187PS/SS) were 1.65, 2.49 and 13 times more likely to have MM (P(trend)=0.001).     

Polymorphism of selected enzymes involved in detoxification and biotransformation in relation to lung cancer

Available data indicate that there are significant differences in individual susceptibility to lung cancer within the human population. It is believed to be underlie by inherited genetic predispositions related to the genetic polymorphism of several enzymes involved in the detoxification and xenobiotic metabolism. In this review, we collect and discuss the evidence reported up to date on the association between lung cancer and genetic polymorphism of cytochromes P450, N-acetyltransferase, glutathione S-transferases, microsomal epoxide hydrolase, NAD(P)H:quinone oxidoreductase, myeloperoxidase and glutathione peroxidase. All these genes might appear to be candidates for lung cancer susceptibility genes, nevertheless, the present state of the art still offers only a limited explanation of the link between such polymorphisms and increased risk of lung cancer.