Stimulation of microsomal dimethylnitrosamine-N-demethylase by pretreatment of mice with acetone

To further investigate the relationship between in vivo microsomal enzyme modifiers and in vitro dimethylnitrosamine (DMN) metabolism, male C57BL/6J mice were pretreated with acetone or Aroclor 1254, two compounds known to influence DMN-N-demethylase activity. Pretreatment with acetone enhanced the in vitro microsomal activity of DMN-N-demethylase, as measured by formaldehyde production from DMN. Accompanying this acetone-enhanced demethylase activity was an increase in the covalent binding of [14C]DMN to RNA, protein and DNA. Four distinct Km values dependent on the substrate concentration were observed for the N-demethylase present in control microsomes. Only one Km value was observed for the demethylase in microsomes from acetone-treated animals, but it was significantly lower than the lowest Km observed in the control microsomes. At DMN concentrations of 1 and 10 mM, acetone significantly increased N-demethylation of DMN as compared to control, but not at 100 mM DMN. Aroclor 1254 pretreatment repressed DMN-N-demethylase at 1 mM DMN but enhanced it at 100 mM. These results suggest that there may be multiple forms of DMN-N-demethylase which are dependent on DMN concentration and respond differently to modifiers of the microsomal drug-metabolizing enzymes.     

Vinyl chloride dependent mutagensis: effects of liver extracts and free radicals.

The mutagenic effects of vinyl chloride (VC) on Salmonella typhimurium strain TA1530 are enhanced by mouse or rat liver extracts. The extracts prepared from mice pretreated either with vinyl chloride or the microsomal enzyme inducer, Aroclor 1254, did not produce any greater stimulation of VC-dependent mutagenesis than extracts from untreated animals. These same extracts, however, differed markedly in their capacity to stimulate the mutagenicity of dimethylnitrosamine (DMN), a compound which is converted to a mutagen by an NADPH dependent microsomal mixed function oxidase. The order of activity of the extracts with DMN was Aroclor pretreated is greater than untreated is greater than VC pretreated. Furthermore, the stimulatory effect of the liver extracts on VC mediated mutagenesis did not require NADPH and was still evident in liver extracts in which the microsomal mixed function oxidase system had been heat inactivated. The mutagenic activity of VC also was found to be stimulated by riboflavin in the presence of light suggesting that free radicals may be involved in VC dependent mutagenesis.     

Metabolism of di-, tri-, tetra-, penta- and hexachlorobiphenyls by hepatic microsomes isolated from control animals and animals treated with aroclor 1254, a commercial mixture of polychlorinated biphenyls (pcbs)

1. The metabolism of a wide range of di-, tri-, tetra-, penta- and hexachlorobiphenyls by hepatic microsomes isolated from control animals and animals treated with Aroclor 1254 was studied.2. Hepatic microsomes isolated from control rats expressed higher rates of oxidations than avians.3. Treatment of rats and pigeons with Aroclor 1254 induced cytochrome P450 dependent mono-oxygenases leading to an increased regioselective metabolism of PCB isomer and congeneres.4. There was an inverse relationship between the degree of halosubstitution and microsomal oxidation. Meta-para carbon atoms free of halosubstitution were the preferred side for oxidation.5. A good correlation was found between the in vitro metabolism of PCBs and their relative abundance in tissue extracts, thus suggesting oxidative metabolism to be the major route of metabolic disposal.     

Effects of dimethylnitrosamine on metabolism of N,N-dimethylaniline by rat liver microsomes. A comparative study of treatment in vivo,in isolated liver perfusion and in the microsomal system

The effect of dimethylnitrosamine (DMN) on rat liver microsomal detoxication was studied, using the non-carcinogenic aromatic amine N,N-dimethylaniline (dimethylaniline) as substrate. Prior to the preparation of microsomes, the rat liver was exposed to DMN either in vivo (by i.p. injection) or in the isolated liver perfusion system (by addition to the perfusion medium). DMN treatment in vivo (20 mg/kg body wt.) caused a 40% increase in dimethylaniline N-oxygenation and a 30% decrease in dimethylaniline C-oxygenation. When DMN was added to the perfusion medium to a final concentration of 5 or 25 mM, a similar effect was observed. With the 5 mM dose, C-oxygenation was decreased by 20% with a non-significant increase in N-oxygenation. The higher dose caused a 50% increase in N-oxygenation, whereas the decrease in C-oxygenation remained at 20%.When microsomes were incubated with both DMN (5 mM) and dimethylaniline (5 mM) in the system, a small but significant decrease in both N- and C-oxygenation of dimethylaniline was observed. The effect of DMN on the amino acid incorporation into liver and plasma proteins was also studied in the liver perfusion system. The synthesis of both liver and plasma proteins was reduced by DMN.     

Dealkylation of pentoxyresorufin: A rapid and sensitive assay for measuring induction of cytochrome(s) P-450 by phenobarbital and other xenobiotics in the rat

The O-dealkylation of pentoxyresorufin (7-pentoxyphenoxazone) by rat liver microsomes was examined. The reaction appeared highly specific for certain phenobarbital inducible forms of cytochrome P-450 and was increased 95- to 140-fold by animal pretreatment with phenobarbital (75 mg/kg/day, four ip injections) and ~50-fold by Aroclor 1254 (500 mg/kg, one ip injection) while animal pretreatment with 3-methylcholanthrene (50 mg/kg/day, three ip injections) resulted in less than a 2-fold increase over the rate detected in control microsomes. It was observed that this activity, in microsomes for Aroclor-pretreated rats, was dependent on O₂ and was inhibited by metyrapone and SKF 525-A, indicative of cytochrome(s) P-450 mediation in the reaction. When antibodies directed against purified cytochrome(s) P-450S were employed to inhibit the pentoxyresorufin O-dealkylation reaction, antibodies to P-450_PB-B greatly inhibited the reaction (>90%), while antibodies to P-450_PB-C or P-450_PB/PCN-E had minimal effects. Assay of hepatic microsomes from rats which were pretreated with varying doses of phenobarbital (0.9–75 mg/kg/day, four ip injections) indicated that while aminopyrine-N-demethylase activity was induced only 2-fold at the maximum dose (75 mg/kg/day), pentoxyresorufin O-dealkylase activity was induced ~140-fold at this dose and ~4-fold by a dose of phenobarbital as low as 0.9 mg/kg.     

The effect of liver postmitochondrial fraction concentration from Aroclor 1254-treated rats on promutagen activation in L5178Y cells

L5178Y/TK^+/− cells were treated with either N-acetyl-2-aminofluorene (AAF), 2-aminoanthracene (2A), benzanthracene (BA), benzo[a]pyrene (BP), 3-methylcholanthrene (3MCA), or dimethylnitrosamine (DMN) in the presence of varied concentrations (2.5–10% v/v) of liver S9 (9000 × g) postmitochondrial fraction from Aroclor 1254-dosed male CD rats. Consistent S9 concentration-dependent decreases in trifluorothymidine-resistant (TFT^r) mutant induction were noted following 3 h exposure of L5178Y/TK^+/− cells to either 2.5 μg/ml BP, 50 or 67 μg/ml AAF, 0.96 μg/ml 2A, 7.35 μg/ml BA, or 5.4 μg/ml 3MCA. The exception was DMN which yielded a moderate S9 concentration-dependent increase in TFT^r mutant induction when L5178Y/TK^+/− cells were treated for 3 h with 74.1 μg/ml DMN. Depending upon the promutagen being tested, these results suggest two different metabolic events: (1) activation via non-induced enzymes or other factors whose activities are totally S9 volume-dependent (DMN), and (2) deactivation via induced detoxification pathways, a sequence favored by increasing S9 concentration (all others). Utilization of a single “standard” (10%) concentration of liver S9 from Aroclor 1254-treated rats did not appear to provide optimal metabolic activation for 5 of these 6 promutagens.     

The interference of polychlorinated biphenyls (Aroclor 1254) with membrane regulation of the activities of cytochromes P-450C21 and P-450(17) alpha,lyase in guinea-pig adrenal microsomes.

Regulation of cytochromes P-450 21-hydroxylase (P-450C21) and P-450 17 alpha-hydroxylase/C17,20-lyase (P-450(17) alpha,lyase) activities and impairment of this regulation by Aroclor 1254 was studied in guinea-pig adrenal microsomes. In a membrane depleted system, a decrease in the normally predominant, P-450C21 activity and an increase in P-450(17) alpha,lyase activities was observed. The same deviations were observed in intact microsomes with increase in the reaction temperature (0-40 degrees C). Breaks in Arrhenius plots for activities of P-450C21 and P-450(17) alpha,lyase correlate with transition temperatures reported for the microsomal membrane. These results point to: (1) preference of a gel state membrane for catalytic expression of P-450C21 suggesting a clustered organization of this P-450 species with reductase; (2) preference of a fluid membrane for lyase activity suggesting a random collision mechanism for reduction of P-450(17) alpha,lyase. Aroclor 1254 introduced to reaction mixtures containing intact microsomes elicited basically the same changes as caused by depletion of the microsomal membrane or by increase in the incubation temperature. Lack of effect of Aroclor 1254 on P-450C21 and P-450(17) alpha,lyase activities in the membrane depleted system demonstrates that its interference with monooxygenase activities is mediated by the microsomal membrane. The similarities between altered cytochrome P-450 mediated activities in the presence of Aroclor 1254 and the deviations observed in the membrane depleted system or upon increase in the incubation temperature may suggest that this chemical exerts its impacts by influencing membrane fluidity.     

Microsomal oxidation of bromo-, chloro- and fluorobiphenyls

1. The metabolism of 2-, 3-, 4-bromo-, 2-, 4-chloro-, and 2-fluorobiphenyl by hepatic microsomes isolated from control and Aroclor 1254-treated rats and pigeons was studied.2. Meta and para as well as dihydroxylated metabolites were detected, but para hydroxylation was the preferred route of metabolism with all of the substrates used.3. The overall rates of hydroxylation were greater with hepatic microsomes from rats than from pigeons.4. Treatment with Aroclor 1254, a potent inducer of hepatic monooygenases, resulted in increased rates of metabolism and in the enhanced formation of diol metabolites. Metabolism of halobiphenyls by induced P450 isoenzymes altered the regioselective hydroxylation pathways.5. Ortho- and meta halosubstituted biphenyls were less rapidly metabolised when compared with paru substituted isomers.     

Effects of Aroclor 1254 on In Vivo Oocyte Maturation in the Mouse

Polychlorinated biphenyls (PCBs) are stable, lipophilic compounds that accumulate in the environment and in the food chain. Though some studies provided evidence that PCBs had adverse effects on reproductive function, most of these results were from in vitro models. Therefore we investigated the effect of Aroclor 1254 (a commercial PCBs mixture) treatments on in vivo maturation and developmental potential of mouse oocytes. In the present study, female ICR mice were treated with different doses (12.5, 25 and 50 mg/kg) of Aroclor 1254 (a commercial PCB mixture) once every 72 hours by intraperitoneal injection for 9 days. After three treatments of Aroclor 1254, the mice were superovulated to collect oocytes one day after the last exposure. The effects of Aroclor 1254 on oocyte maturation, fertilization, and preimplantation embryonic development were investigated. Immunofluorescence-stained oocytes were observed under a confocal microscope to assess the effects of Aroclor 1254 on spindle morphology. Parthenogenic activation and the incidence of cumulus apoptosis in cumulus-oocyte complexes were observed as well. Oocytes exposed to different doses of Aroclor 1254 in vivo were associated with a significant decrease in outgrowth potential, abnormal spindle configurations, and the inhibition of parthenogenetic activation of ovulated oocytes. Furthermore, the incidence of apoptosis in cumulus cells was increased after exposed to Aroclor 1254. These results may provide reference for the treatment of reproductive diseases such as infertility or miscarriage caused by environmental contaminants.     

Effect of induction by DDT on metabolism and mutagenicity of benzo[a]pyrene

Liver microsomal enzymes are essential for the detection of benzo[a]pyrene (B[a]P)-mediated mutagenesis in the Salmonella/mammalian microsome mutagenicity test and, furthermore, this mutagenicity is considerably enhanced by induction of hepatic enzymes involved with drug metabolism. Although Aroclor 1254 is most commonly used for induction of S9 enzymes, DDT is also capable of this induction. This paper reports a comparison of liver S9 fraction induced by the two agents: there is a marked difference in their concentration optima for metabolism of B[a]P; greater numbers of revertant colonies are seen with Aroclor-induced S9, which is optimal at a concentration of 10% (v/v), whereas DDT-induced S9 is optimal at 2.5% (v/v); Aroclor induces aryl hydrocarbon hydroxylase (AHH), cytochrome P-450 and epoxide hydrase while DDT induces only AHH, to about half the level detected in the Aroclor-induced S9 fraction. A comparison of metabolite distribution for Aroclor- and DDT-induced hepatic microsomes reveals quantitative differences only. DDT-induced microsomes yield a greater proportion of B[a]P-4,5-oxide and its metabolic product B[a]P-4,5-dihydrodiol than do Aroclor-induced microsomes. Time course studies on the mutagen half-life measured on the agar plate provides good evidence that metabolites responsible for mutagenicity were different for each inducer.     

A class of strong inhibitors of microsomal monooxygenases: the ellipticines.

Ellipticine (E) and its 9-hydroxy derivative inhibit strongly various liver monooxygenase activities mediated by microsomes from control and phenobarbital (PB), benzo[alpha]pyrene (BP) or Aroclor 1254 (Aroclor)-pretreated rats. The inhibition constants, Ki, are remarkably low, and often smaller than 1 micron, particularly in the case of microsomes containing cytochrome P-448. The inhibitory potency (I50) of 9-hydroxyellipticine (9-OHE) is larger (about ten-fold) than the one of classical inhibitors (metyrapone or 7,8-benzoflavone (7,8-BF)), whatever the activities studied and the induction of microsomes. Differences exist between the mechanisms of inhibition according to the form of cytochrome P-450 present in microsomes of differently pretreated rats; whichever the activities studied, one observes: (a) a competitive inhibition towards the activity of non-induced or PB-induced microsomes and (b) a non-competitive inhibition towards the activity of Aroclor or BP-induced microsomes, at variance with 7,8-BF. These results are in good agreement with the interaction properties of the ellipticines with microsomal cytochromes P-450.     

Neonatal phenobarbital imprinting of rat hepatic microsomal testosterone hydroxylations

The effects of neonatally administered phenobarbital (PB) on adult rat hepatic microsomal metabolism of testosterone were examined in 60-, 90-, and 120-day-old animals. Phenobarbital-induced imprinting was evident at all ages; however, female rats appeared to be more susceptible to the neonatal effects of phenobarbital than did male rats. In 60-day-old female rats, increased testosterone 2α-hydroxylase activity was observed in microsomes from noninduced rats, whereas decreased testosterone oxidation at all positions except 2α and 15β was observed in microsomes from Aroclor 1254-induced rats. The decreased oxidation of testosterone at specific sites in response to Aroclor 1254 induction was quite dramatic, decreasing the activities to near or below control levels. By contrast, phenobarbital-treated 60-day-old males exhibited approximately a twofold increase in Aroclor 1254-induced 16α and 2α-hydroxylase activities. The pattern of changes in testosterone metabolism observed in phenobarbital-treated animals was different at both 90 and 120 days from that at 60 days. Only minor alterations in the oxidation of testosterone were observed in 90-day-old animals of either sex. In 120-day-old animals the greatest effects of neonatal phenobarbital exposure were on Aroclor 1254–induced 16β-hydroxylase activities. In induced female rats 16β-hydroxylase activity was again decreased to noninduced levels, while in induced male rats a fourfold increase in this activity was observed. These results demonstrate that neonatal exposure to phenobarbital can alter both constitutive and Aroclor 1254–induced testosterone metabolism in adult rats and that the effects of neonatal phenobarbital exposure are age and sex differentiated.     

Cytosolic activation of 2-aminoanthracene: implications in its use as diagnostic mutagen in the Ames test.

The metabolic activation of 2-aminoanthracene to mutagens in the Ames test was investigated using hepatic S9, microsomal and cytosolic fractions from control and Aroclor 1254-treated rats as activation systems. Microsomal and S9 preparations from control animals could activate 2-aminoanthracene, but the efficiency of activation was suppressed by pretreatment of animals with Aroclor 1254. Cytosolic fractions from Aroclor 1254-treated rats could readily activate the promutagen more readily than microsomes. The cytosolic activation of 2-aminoanthracene required NADPH and could not be accounted for by possible microsomal contamination. The molybdenum oxygenases appear not to contribute to the cytosolic activation of this promutagen. It is concluded that (a) the microsomal activation of 2-aminoanthracene is catalysed more effectively by enzyme systems other than the P450 I family and (b) an enzyme system capable of activating this carcinogen in vitro is present in the hepatic cytosol. The implications of these findings in the use of 2-aminoanthracene as a positive control in the Ames test are discussed.     

The metabolism of drugs and carcinogens in isolated subcellular fractions of Drosophila melanogaster. II. Enzyme induction and metabolism of benzo[a]pyrene

The effect of various pretreatments on the activities of several drug metabolizing enzymes was investigated in microsomes and postmicrosomal supernatant fractions isolated from whole body homogenates of Drosophila melanogaster larvae of different strains. Pretreatments of larvae with either phenobarbital (PB), β-naphthoflavone (BNF) or a mixture of polychlorinated biphenyls (Aroclor 1254, PCB) for 24 h increased microsomal benzo[a]pyrene (BP) monooxygenase activity 2- to 6-fold in all strains as compared to untreated larvae. A simultaneous increase in the contents of cytochrome P-450 occurred after pretreatment with PB and PCB. Comparison of the turnover rates of BP per molecule of cytochrome P-450 indicated that BP was a poor substrate for control cytochrome P-450 whereas BNF induced a most active hemoprotein for this metabolism. Marked differences in the qualitative pattern of BP metabolites were obtained between microsomes isolated from BNF-treated larvae or rat liver microsomes. 3-Hydroxy-BP (3-OH-BP) was the dominating metabolite with both preparations, while the BP dihydrodiols were formed in minor quantities in Drosophila as compared to rat liver. Metyrapone and SKF 525-A inhibited BP metabolism in microsomes isolated from untreated and BNF treated larvae of all strains. In contrast, α-naphthoflavone (ANF) stimulated the BP monooxygenase activity of microsomes isolated from untreated larvae approx. 3-fold but only slightly influenced the activity of microsomes from BNF treated larvae indicating that the latter species of cytochrome P-450 was less sensitive to ANF.In all strains, PCB and PB treatments approximately doubled microsomal epoxide hydrolase activity and increased cytosolic glutathione-S-transferase activity 25–60%, significant only in strain Berlin K after PB treatment. The activities of epoxide hydrolase and glutathione-S-transferase in control larvae were comparable in the different strains, whereas the content of cytochrome P-450 and BP monooxygenase activity was higher in the Hikone R strain. Variability in the induction response to the various pretreatment was observed among the three strains.     

Removal of Aroclor 1254 by the white rot fungus Coriolus versicolor in the presence of different concentrations of Mn(IV)oxide

Lignin peroxidase (LiP) plays an active role in the biodegradation of lignin and phenolic structures resembling lignin. The role of other enzymes in the biodegradation of recalcitrant compounds, e.g. manganese(II)-peroxidase, is uncertain. Solid manganese(IV)oxide addition improved the production of manganese(II)-dependant peroxidase (MnP) and H₂O₂ and increased the rate of biodegradation of Aroclor 1254 in a nitrogen-limited medium by the white rot fungus Coriolus versicolor. MnP activity was detected 48 h after the addition of MnO₂ to the cultures and was absent in cultures that did not receive MnO₂. The rate of Aroclor 1254 removal by C. versicolor was influenced by the concentration of MnO₂. 34.5 mM concentrations only increased the H₂O₂ production. Removal of Aroclor 1254 in the absence of MnO₂ still took place which implied the presence of (LiP) or nonspecific absorption. The cultures containing 57.5 mM MnO₂ removed ca. 84% of the initial 750 mg l⁻¹ Aroclor in 6 days of incubation. Cultures with no MnO₂ and 34.5 mM removed 79 and 76%, respectively. Cultures with MnP or LiP as the dominant enzyme species removed penta- and hexachlorobiphenyls at a slower rate than tri- and tetrachlorobiphenyl.     

Role of dimethylnitrosamine-demethylase in the metabolic activation of dimethylinitrosamine.

In vivo administration to rats of the mixed-function oxidase modifiers 3-methylcholanthrene (MC), pregnenolone-16 alpha-carbonitrile (PCN) or beta-naphthoflavnoe (beta-f) inhibits the hepatic microsome-catalyzed in vitro binding of dimethylnitrosamine (DMN) to DNA. This parallels their effect on DMN-demethylase I, regarded to be the sole activating step in DMN carcinogenesis and fails to account for the previously observed anomaly that MC and PCN inhibit, while beta-NF enhances, the hepatocarcinogenic activity of DMN. The in vitro binding of DMN is clearly dependent on microsomes and NADPH, and is strongly enhanced by soluble cytoplasmic proteins; the presence of the latter has no effect. however, on the relative response to pretreatment by the modifiers. In mice beta-NF enhances and PCN inhibits DMN-demethylase I; beta-NF has no effect on either the cytochrome P-450 level or on the LD50, while PCN strongly increases the cytochrome P-450 level but without influencing the LD50. Neither of the two modifiers has any effect in mice on the host-mediated mutagenicity of DMN in a dose-response study, except for the highest dose of DMN (200 mg/kg) where PCN pretreatment significantly enhanced mutagenicity. To account for the anomalous observations, other potential pathways of DMN metabolism have been explored. Whole rat liver nuclei or isolated nuclear membrane fractions contain no DMN-demethylase or diethylnitrosamine-deethylase activity. In a microsomal mixed-function amine-oxidase assay system neither purified enzyme preparations nor whole microsomes catalyze NADPH oxidation in the presence of DMN as substrate. In addition, the purified enzyme does not catalyze formaldehyde production in the DMN-demethylase assay system. Benzylamine, a typical inhibitor of mitochondrial monoamine oxidase (MAO), is a potent inhibitor of DMN-demethylase activity, but microsomes are devoid of MAO activity. Furthermore, purified MAO has no DMN-demethylase activity. The differential effect of modifiers on the carcinogenicity of DMN probably involves pathways other than DMN metabolism.     

Drug metabolism in adult white leghorn hens--response to enzyme inducers

1. Adult hens were given a mixture of polychlorinated biphenyls (0.5 and 2 g/kg Aroclor 1254), 3-methylcholanthrene (80 mg/kg) or beta-napthoflavone (80 mg/kg). 2. beta-Napthoflavone elevated activities of both microsomal and nonmicrosomal enzymes 48 hr after dosing, with cytochrome P-450 p-nitroanisole O-demethylase, aniline hydroxylase, and glutathione S-epoxytransferase at 319% +/- 25, 157% +/- 12, 410% +/- 26 and 120% +/- 3 of control values, respectively. 3. Aroclor 1254 and 3-methylcholanthrane also elevated microsomal enzyme activities, but did not increase the activity of glutathione S-epoxytransferase. 4. Drug metabolizing capability in control and experimental hens differed from that in rats and mice.     

Immune responses,ROS generation and the haemocyte damage of scallop Chlamys farreri exposed to Aroclor 1254

The toxic effects of Aroclor 1254 (0.05, 0.5, 5 and 50 μg l^?1) on scallop (Chlamys farreri) immune system in vivo were studied. The results showed that Aroclor 1254 had significant toxic effect on the parameters tested in this paper (P < 0.05). The total number of haemocytes, the proportion of granulocytes, phagocytosis in all groups as well as the lysosomal membrane stability (LMS) in 5, 50 μg l^?1 and bacteriolytic activity 0.5, 5, 50 μg l^?1 treatments decreased significantly, while the proportion of hyalinocytes and the production of O₂^- in all treatments remarkably increased during the sampling time and tended to be stable gradually after 6–15 d. The bacteriolytic activity in 0.05 μg l^?1 treatments, LMS in 0.05, 0.5 μg l^?1 groups and the DNA damage (comet ratios and arbitrary values) in all treatments increased at the beginning of exposure and reached their peaks on day 1, day 1, day 6 and day 3, following that they all decreased gradually and became stable after 9–15 d. When the indices reached stability, except for DNA damage was higher than controls, the others were all significantly lower than those of controls (P < 0.05). Thus, Aroclor 1254 has evident toxic effects on scallop immune system, which supports the view that a relationship exists between pollution and immunomodulation in aquatic organisms. Also it supports the speculation that the PCBs pollution is one of the important reasons of the mass mortality of the C. farreri.     

EDTA affects cytochrome P450-dependent biotransformation reactions during incubations for the liver microsomal assay

In order to optimize the condition of the liver microsomal assay (LMA), studies were carried out to determine the effects of EDTA on mixed-function oxidase activity and its stability under the exact incubation conditions for the LMA. Aminopyrine N-demethylase (APD) and p-nitroanisole O-demethylase (p-NAD) activities as well as lipid peroxidation development (LP) in S9 liver fractions from beta-naphthoflavone and sodium phenobarbital (beta-NF + PB)- or Aroclor 1254 (AC)-treated mice were examined during a period of preincubation with EDTA ranging from 1 to 40 mM. At 5 mM EDTA, we obtained a strong inhibition of the microsomal LP as well as the greatest value of the mean specific activity (Asp) for both APD and pNAD activities. In agreement with the biochemical data, the presence of 5 mM EDTA in the incubation mixtures for the LMA significantly increased the mitotic gene conversion, mitotic crossing-over and point-reverse mutation of the well-known premutagen cyclophosphamide (30 mM) on the diploid D7 strain of Saccharomyces cerevisiae as the outcome of a greater metabolic activity. We concluded that the systematic use of 5 mM EDTA in LMA mixtures could improve the reliability and sensitivity of such a test.