Human liver cytosolic epoxide hydrolases

Human liver epoxide hydrolases were characterized by several criteria and a cytosolic cis-stilbene oxide hydrolase (cEHCSO) was purified to apparent homogeneity. Styrene oxide and five phenylmethyloxiranes were tested as substrates for human liver epoxide hydrolases. With microsomes activity was highest with trans-2-methylstyrene oxide, followed by styrene 7,8-oxide, cis-2-methylstyrene oxide, cis-1,2-dimethylstyrene oxide, trans-1,2-dimethylstyrene oxide and 2,2-dimethylstyrene oxide. With cytosol the same order was obtained for the first three substrates, whereas activity with 2,2-dimethylstyrene oxide was higher than with cis-1,2-dimethylstyrene oxide and no hydrolysis occurred with trans-1,2-dimethylstyrene oxide. Generally, activities were lower with cytosol than with microsomes. The isoelectric point for both microsomal styrene 7,8-oxide and cis-stilbene oxide hydrolyzing activity was 7.0, whereas cEHCSO had an isoelectric point of 9.2 and cytosolic trans-stilbene oxide hydrolase (cEHTSO) of 5.7. The cytosolic epoxide hydrolases could be separated by anion-exchange chromatography and gel filtration. The latter technique revealed a higher molecular mass for cEHCSO than for cEHTSO. Both cytosolic epoxide hydrolases showed higher activities at pH 7.4 than at pH 9.0, whereas the opposite was true for microsomal epoxide hydrolase. The effects of ethanol, methanol, tetrahydrofuran, acetonitrile, acetone and dimethylsulfoxide on microsomal epoxide hydrolase depended on the substrate tested, whereas both cytosolic enzymes were not at all, or only slightly, affected by these solvents. Effects of different enzyme modulators on microsomal epoxide hydrolase also depended on the substrates used. Trichloropropene oxide and styrene 7,8-oxide strongly inhibited cEHCSO whereas cEHTSO was moderately affected by these compounds. Immunochemical investigations revealed a close relationship between cEHCSO and rat liver microsomal, but not cytosolic, epoxide hydrolase. Interestingly, cEHTSO has no immunological relationship to rat microsomal, nor to rat cytosolic epoxide hydrolase. cEHTSO from human liver differed also from its counterpart in the rat in that it was only moderately affected by tetrahydrofuran, acetonitrile and trichloropropene oxide. Five steps were necessary to purify cEHCSO. The enzyme has a molecular mass (49 kDa) identical to that of rat liver microsomal epoxide hydrolase.     

Assay and partial purification of epoxide hydrase from rat liver microsomes

Solubilized cytochrome P-450 monooxygenase and epoxide hydrase activities from rat liver microsomes have been separated by column chromatography. The highly active epoxide hydrase fraction is still contaminated with cytochrome P-450, which has very low monooxygenase activity. The highly purified cytochrome P-450 fraction possesses high monooxygenase activity and is essentially devoid of epoxide hydrase activity. Purification factors for the epoxide hydrase through four purification steps are similar with [³H]styrene oxide, [³H]naphthalene oxide, [³H]cyclohexene oxide, and benzene oxide as substrates. Failure of benzene oxide to inhibit hydration of styrene or naphthalene oxide in the most purified preparations in indicative of the presence of at least two hydrases. These purified cytochrome monooxygenase and hydrase preparations represent valuable tools for the study of the intermediacy of arene oxides in drug metabolism. Thus, with naphthalene, only naphthol is formed with the monooxygenase, while both naphthol and the dihydrodiol are formed in the presence of monooxygenase and hydrase. A convenient radiochemical synthesis of [³H]naphthalene 1,2-oxide and assays for the measurement of the hydration of [³H]naphthalene oxide and benzene oxide, based on differential extractions and high-pressure liquid chromatography, respectively, are described.     

Cytosolic and microsomal epoxide hydrolases are immunologically distinguishable from each other in the rat and mouse

Antibodies raised to homogeneous rat liver microsomal epoxide hydrolase were used to distinguish microsomal epoxide hydrolase from epoxide hydrolase of cytosolic origin in mice and rats. Using double diffusion analysis in agarose gels, we show that anti-rat liver microsomal epoxide hydrolase forms a single precipitin line with solubilized microsomes from rat and mouse liver, but no reaction is seen with the corresponding cytosolic fractions. Rat or mouse microsomal epoxide hydrolase activity (using benzo[a]pyrene 4,5-oxide as substrate) can be completely precipitated out of solubilized preparations by the antibody, which is equipotent against rat and mouse microsomal epoxide hydrolase. No precipitation of cytosolic hydrolase activity (using trans-beta-ethyl styrene oxide as substrate) is seen with any concentration of the antibody tested. Thus, in the case of microsomal epoxide hydrolase, extensive immunological cross-reactivity exists between the two species, rat and mouse. In contrast, no cross-reactivity is detectable between cytosolic and microsomal epoxide hydrolase, even when enzymes from the same species are compared. We conclude that microsomal and cytosolic epoxide hydrolase activities represent distinct and immunologically non-cross-reactive protein species.     

The effects of metyrapone, chalcone epoxide, benzil, clotrimazole and related compounds on the activity of microsomal epoxide hydrolase in situ, in purified form and in reconstituted systems towards different substrates

The influence of metyrapone, chalcone epoxide, benzil and clotrimazole on the activity of microsomal epoxide hydrolase towards styrene oxide, benzo[a]pyrene 4,5-oxide, estroxide and androstene oxide was investigated. The studies were performed using liver microsomes from rats, rabbits, mice and humans; epoxide hydrolase purified from rat liver microsomes to apparent homogeneity; and the purified enzyme incorporated into liposomes composed of egg-yolk phosphatidylcholine or total rat liver microsomal lipids. All four effectors were found to activate the hydrolysis of styrene oxide by epoxide hydrolase in situ in rat liver microsomal membranes, in agreement with earlier findings. Epoxide hydrolase activity towards styrene oxide in liver microsomes from mouse, rabbit and man was also increased by all four effectors. The most striking effect was a 680% activation by clotrimazole in rat liver microsomes. However, none of the effectors activated microsomal epoxide hydrolase more than 50% when benzo[a]pyrene 4,5-oxide, estroxide or androstene oxide was used as substrate. Indeed, clotrimazole was found to inhibit microsomal epoxide hydrolase activity towards estroxide 30-50% and towards androstene oxide 60-90%. The effects of these four compounds were found to be virtually identical in the preparations from rats, rabbits, mice and humans. The effects of metyrapone, chalcone epoxide, benzil and clotrimazole on purified epoxide hydrolase were qualitatively the same as those on epoxide hydrolase in intact microsomes, but much smaller in magnitude. These effects were increased in magnitude only slightly by incorporation of the purified enzyme into liposomes made from egg-yolk phosphatidylcholine. However, when incorporation into liposomes composed of total microsomal lipids was performed, the effects seen were essentially of the same magnitude as with intact microsomes. When the extent of activation was plotted against effector concentration, three different patterns were found with different effectors. Activation of epoxide hydrolase activity towards styrene oxide by clotrimazole was found to be uncompetitive with the substrate and highly structure specific. On the other hand, inhibition of epoxide hydrolase activity towards androstene oxide by clotrimazole was found to be competitive in microsomes. It is concluded that the marked effects of these four modulators on microsomal epoxide hydrolase activity are due to an interaction with the enzyme protein itself, but that the presence of total microsomal phospholipids allows the maximal expression leading to similar degrees of modulation as those observed in intact microsomes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nuclear metabolism. II. Further studies on epoxide hydrolase activity

Apparent K_m- and V_max-values of nuclear styrene 7,8-oxide hydrolase were determined at different protein concentrations. In the protein concentrations range used no significant differences in the apparent K_m-values were observed. The influence of the incubation with different modifiers (i.e. SKF-525A, metyrapone, 1,2-epoxy-3,3,3 trichloropropane, cyclohexene oxide) at two different concentrations on this enzyme activity was also determined. Cyclohexene oxide and 1,2-epoxy-3,3,3-trichloropropane, two well known inhibitors of the microsomal epoxide hydrolase(s) caused a marked inhibition, metyrapone had a strong activating effect whereas SKF-525A had no effect. In vivo pretreatment with phenobarbital significantly induced the nuclear epoxide hydrolase whereas β-naphthoflavone caused a lower degree of induction. This pattern is quantitatively different but qualitatively very similar to the microsomal one. Moreover a toxifying to detoxifying enzymatic activity balance is attempted for the metabolization of the alkenic double bond of styrene, taking into account the ratio between the styrene monooxygenase (toxifying enzyme) and the styrene 7,8-oxide hydrolase (detoxifying enzyme) after the above mentioned pretreatments, both in the microsomal and nuclear fractions.     

Epoxide hydrase and mixed-function oxidase activities of rat liver nuclear membranes.

Rat liver nuclei have 2 to 12% of the corresponding microsomal aryl hydrocarbon hydroxylase, aminopyrine and benzphetamine N-demethylase, NADPH-cytochrome c reductase, and epoxide hydrase activities. Nuclear membranes were prepared from isolated liver nuclei by a sucrose density centrifugation technique. A 2.5- to 10.2-fold increase in the specific enzyme activities was observed in nuclear membrane as compared to intact nuclei. Several properties of the rat liver nuclear membrane and microsomal epoxide hydrase have been compared. Nuclear epoxide hydrase was similar to the corresponding microsomal enzyme in being induced by phenobarbital whereas 3-methylcholanthrene did not produce any effects. Nuclear membrane and microsomal epoxide hydrase were inhibited to a similar degree by 1,1,1-trichloropropene oxide, cyclohexene oxide, an trans-stilbene oxide. The apparent K_m value of nuclear membrane epoxide hydrase was 20 μm for benzo(a)pyrene 4,5-oxide, which is 5.5-fold lower than the corresponding microsomal K_m value (112 μm). Nuclear membranes were prepared from isolated nuclei of rat kidney, lung, spleen, and heart by the DNase digestion method. Epoxide hydrase activity in intact nuclei was in the following order: kidney > lung ? spleen, or heart. Increases of 2.2- and 2.5-fold in specific epoxide hydrase activity were observed in kidney and lung when nuclear membranes were compared to intact nuclei. DMSO, dimethylsulfoxide     

Selective inhibition of cytosolic epoxide hydrolase activity in vitro by compounds that inhibit catalase

The ability of a number of known inhibitors of catalase activity to affect cytosolic and microsomal epoxide hydrolase activities in vitro, measured as enzymatic trans-stilbene oxide hydrolysis and styrene oxide hydrolysis, respectively, was investigated. Catalase and cytosolic epoxide hydrolase activities are inhibited by hydroxylated metabolites of 2-amino-4,5-diphenylthiazole (DPT). The metabolite hydroxylated on the 4-phenyl ring (4OH-DPT) and the metabolite hydroxylated on both phenyl rings (4,5-DIOH-DPT) are potent inhibitors of both enzymes; the metabolite hydroxylated on the 5-phenyl ring (5OH-DPT) is less potent. Unmetabolized DPT has no effect on either enzyme. 4OH-DPT inhibits, but 5OH-DPT enhances, microsomal epoxide hydrolase activity. 4,5-DIOH-DPT and DPT have no effect on this enzyme. Other compounds that inhibit both catalase and cytosolic epoxide hydrolase activities, but do not inhibit microsomal epoxide hydrolase activity, are nordihydroguaiaretic acid and 2-aminothiazole. Microsomal epoxide hydrolase activity is enhanced by 2-aminothiazole and levamisole in vitro. Thus these inhibitors of catalase are selective epoxide hydrolase inhibitors in that they inhibit cytosolic epoxide hydrolase activity in vitro, but have either no effect on, or increase the activity of, microsomal epoxide hydrolase in vitro. Conversely, the selective cytosolic epoxide hydrolase inhibitors 4-phenylchalcone oxide and 4'-phenylchalcone oxide do not inhibit catalase activity, nor does trichloropropene oxide, a selective microsomal epoxide hydrolase inhibitor.     

Styrene metabolism in Exophiala jeanselmei and involvement of a cytochrome P-450-dependent styrene monooxygenase.

The yeast-like fungus Exophiala jeanselmei degrades styrene via initial oxidation of the vinyl side chain to phenylacetic acid, which is subsequently hydroxylated to homogentisic acid. The initial reactions are catalyzed by a NADPH- and flavin adenine dinucleotide-dependent styrene monooxygenase, a styrene oxide isomerase, and a NAD(+)-dependent phenylacetaldehyde dehydrogenase. The reduced CO-difference spectrum of microsomal preparations of styrene-grown cells shows a characteristic absorption maximum at 450 nm, which strongly suggests the involvement of a cytochrome P-450-dependent styrene monooxygenase. Inhibition of styrene monooxygenase activity in cell extracts by cytochrome P-450 inhibitors SKF-525-A, metyrapone, and CO confirms this assumption.     

Inhibition of epoxide hydrolases and glutathione S-transferases by 2-, 3-, and 4-substituted derivatives of 4'-phenylchalcone and its oxide

4'-Phenylchalcones, chalcone oxides, and related compounds were synthesized and tested as inhibitors of cytosolic epoxide hydrolase, microsomal epoxide hydrolase, and glutathione S-transferases from mouse and rat liver. Several compounds were more potent inhibitors of the cytosolic epoxide hydrolase than the parent 4'-phenylchalcone oxide while large substituents in the 4- and especially the 2-position caused a reduction in inhibition. The chalcone oxides showed selectivity as inhibitors of the cytosolic epoxide hydrolase acting on trans-stilbene oxide, while chalcones were inhibitors of cytosolic glutathione S-transferase acting on cis-stilbene oxide. Data are consistent with the hypothesis that much of the inhibition of the glutathione S-transferase is caused by the glutathione conjugate of the chalcone.     

Detection of a system of microsomal monooxygenases in the rodent malaria parasite Plasmodium berghei

A microsomal fraction from the cells of the malaria parasite of rodent Plasmodium berghei was obtained. The spectral properties of microsomal preparations suggest that P. berghei microsomes contain cytochromes b5 and P-420. Electrophoretic separation of microsomal proteins revealed the presence of proteins whose molecular mass corresponds to NADPH-cytochrome c reductase, cytochrome P-450 and epoxide hydratase. The activities of NADPH-cytochrome c reductase and benzpyrene hydroxylase were determined. The spectral parameters, electrophoretic data and enzymatic activities of microsomal proteins indicate that P. berghei cells contain a cytochrome P-450 monooxygenase system. The interrelationship between the activity of the microsomal monooxygenase system and the resistance of P. berghei cells to the antimalaria preparation chloroquine is discussed.     

Is nuclear styrene monooxygenase activity a microsomal artifact?

Microsomal contamination in nuclear preparations could represent one of the main sources of bias in the evaluation of the real metabolic capacity of the nuclear envelope. In this paper we present a quantitative study of the level of nuclear styrene monooxygenase enzymatic activity after artificially increasing the native microsomes to nuclei ratio. In our experimental conditions no significant elevation of the nuclear monooxygenase was observed. These data indicate that, if any microsomal contamination is present, it cannot account for more than 30% of the total enzymatic activity found in nuclear preparations.     

Immuno-electron-microscopic studies on the subcellular distribution of rat liver epoxide hydrolase and the effect of phenobarbitone and 2-acetamidofluorene treatment.

The distribution of rat liver epoxide hydrolase in various subcellular fractions was investigated by immuno-electron-microscopy. Ferritin-linked monospecific anti-(epoxide hydrolase) immunoglobulins bound specifically to the cytoplasmic surfaces of total microsomal preparations and smooth and rough microsomal fractions as well as the nuclear envelope. Specific binding was not observed when the ferritin conjugates were incubated with peroxisomes, lysosomes and mitochondria. The average specific ferritin load of the individual subcellular fractions correlated well with the measured epoxide hydrolase activities. This correlation was observed with fractions prepared from control, phenobarbitone-treated and 2-acetamidofluorene-treated rats.     

Thyroid hormone-induced changes in the hepatic monooxygenase system, heme oxygenase activity and epoxide hydrolase activity in adult male, female and immature rats

In 8-day-old rat pups, pretreatment with a single injection of L-triiodothyronine or L-thyroxine decreased hepatic cytochrome P-450 content, aminopyrine N-demethylase activity and epoxide hydrolase activity but increased hepatic microsomal cytochrome c reductase, 7-ethoxyresorufin O-deethylase and heme oxygenase activities without significantly altering UDP-glucuronosyltransferase activity (towards o-aminophenol) or the microsomal yield.

In adult rats of either sex such single injections of L-triiodothyronine failed to significantly alter these enzyme activities. However, multiple injections evoked changes similar to those observed in the pups, in all these enzyme activities, except that 7-ethoxyresorufin O-deethylase activity was slightly decreased rather than increased.

These findings demonstrate that: (1) The hepatic monooxygenase system in the rat pup is more responsive to thyroid hormones than that in adult. (2) Thyroid hormones can decrease rat liver cytochrome P-450 content and its dependent monooxygenase activity independently of sexual maturity. (3) Thyroid hormones also decrease hepatic epoxide hydrolase activity in both pups and adults. Thus, hyperthyroidism could render the rat pup more susceptible to hepatotoxicity from electrophilic epoxides which utilize microsomal epoxide hydrolase as the major detoxication pathway.     

Induction, activation and inhibition of epoxide hydrase: an anomalous prevention of chlorobenzene-induced hepatotoxicity by an inhibitor of epoxide hydrase

Epoxide hydrase activity, measured with [³H]styrene oxide as substrate, is present in mammalian liver, kidney, lung, intestine and skin. The hepatic level of the enzyme, measured in vitro with [³H]styrene oxide, benzene oxide or naphthalene-1,2-oxide, is elevated substantially by pretreatment of rats with phenobarbital and to a lesser extent by pretreatment with 3-methylcholanthrene. Metyrapone and 1-(2-isopropylphenyl)-imidazole, two monooxygenase inhibitors, activate epoxide hydrase in vitro, but have no demonstrable effect on the enzyme in vivo. 3,3,3-Trichloropropene oxide, a potent in vitro inhibitor of epoxide hydrase, has no effect on monooxygenase activity measured in vitro with [³H]benzenesulfonanilide. Trichloropropene oxide is extremely toxic. In sub-lethal dosages, it does not significantly inhibit epoxide hydrase activity in vivo, although it and several other epoxides do react with and thereby reduce hepatic levels of glutathione. Cyclohexane oxide, another potent in vitro inhibitor of epoxide hydrase, reduces hepatic glutathione levels to 10% of control values. This relatively non-toxic substance should potentiate the hepatotoxicity of chlorobenzene by inhibiting further metabolism of the toxic chlorobenzene oxide intermediate through either hydration or conjugation with glutathione. Instead, co-administration of cyclohexene oxide and chlorobenzene significantly reduces the rate of metabolism of [¹⁴C]chlorobenzene and prevents the hepatic centrilobular necrosis caused by chlorobenzene in rats. Arene oxide-mediated hepatotoxicity apparently is dependent upon a variety of factors including both rates of formation and degradation of arene oxides in tissue. The presently known hydrase inhibitors are not sufficiently selective in their effects on liver cells to permit a quantitative assessment of the relative importance of these factors.     

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.     

Comparison of the sex and subcellular distributions, catalytic and immunochemical reactivities of hepatic epoxide hydrolases in seven mammalian species

Sex and species differences in hepatic epoxide hydrolase activities towards cis- and trans-stilbene oxide were examined in common laboratory animals, as well as in monkey and man. In general trans-stilbene oxide was found to be a good substrate for epoxide hydrolase activity in cytosolic fractions, whereas the cis isomer was selectively hydrated by the microsomal fraction (with the exception of man, where the cytosol also hydrated this isomer efficiently). The specific cytosolic epoxide hydrolase activity was highest in mouse, followed by hamster and rabbit. Epoxide hydrolase activity in the crude 'mitochondrial' fraction towards trans-stilbene oxide was also highest in mouse and low in all other species examined. Microsomal epoxide hydrolase activity was highest in monkey, followed by guinea pig, human and rabbit, which all had similar activities. Sex differences were generally small, but where significant, male animals had higher catalytic activities than females of the same species in most cases. Antibodies raised against microsomal epoxide hydrolase purified from rat liver reacted with microsomes from all species investigated, indicating structural conservation of this protein. Antibodies directed towards cytosolic epoxide hydrolase purified from mouse liver reacted only with liver cytosol from mouse and hamster and with the 'mitochondrial' fraction from mouse in immunodiffusion experiments. Immunoblotting also revealed reaction with rat liver cytosol. The cytosolic and 'mitochondrial' epoxide hydrolases in all three mouse strains and in both sexes for each strain were immunochemically identical. The anomalies in human liver epoxide hydrolase activities observed here indicate that no single common laboratory animal is a good model for man with regard to these activities.     

Enzymic hydration of benzene oxide: Assay and properties

A radiometric assay for epoxide hydratase using [¹⁴C]benzene oxide as substrate has been developed. The reaction product trans-1,2-[¹⁴C]dihydroxy-1,2-dihydrobenzene (benzene dihydrodiol) was separated from the other components by simple extraction of the unreacted substrate and phenol (a rearrangement product) into a mixture of light petroleum and diethyl ether followed by extraction of the benzene dihydrodiol into ethyl acetate. The product was then estimated by scintillation counting. Using this assay the enzymic hydration of benzene oxide and the possible existence of a microsomal epoxide hydratase with a greater specificity toward benzene oxide were reinvestigated. The sequence of activities of microsomes from various organs was liver > kidney > lung > skin, the pH optimum of enzymic benzene oxide hydration was about pH 9.0, which is similar to that of styrene oxide hydration and both activities were equally stable when liver microsomal fractions were stored. The effect of low molecular weight inhibitors upon the hydration of styrene and benzene oxide by liver microsomes was similar in some cases and dissimilar in others. However, all the dissimilarities could be explained without recourse to the hypothesis of the existence of a separate benzene oxide hydratase. During enzyme purification studies the activity toward benzene oxide was inhibited by the detergent used (cutscum) but was recovered when the detergent was removed. Solubilization without significant loss of activity was successful using sodium cholate. This allowed immunoprecipitation studies, which were performed using monospecific antiserum raised against homogeneous epoxide hydratase. The dose-response curves of the extent of precipitation of activity with increasing amounts of added antiserum were indistinguishable for benzene oxide and styrene oxide as substrate. At high antiserum concentrations precipitation was complete with both substrates. The findings, taken together, indicate the presence in rat liver microsomes of a single epoxide hydratase catalyzing the hydration of both styrene and benzene oxide or the presence of enzymes so closely related that these cannot be distinguished by any of the criteria tested.     

A comparison of warfarin resistance and liver microsomal vitamin K epoxide reductase activity in rats

Vitamin K-1 epoxide reductase activity was investigated in liver microsomal preparations from warfarin-resistant and -susceptible rats. One rat strain (TAS) is susceptible to the anticoagulant and lethal effects of warfarin and the other two strains are homozygous for warfarin resistance genes from either wild Welsh (HW) or Scottish (HS) rats. The enzyme in microsomal preparations from HW rat livers apparently has a reduced affinity for both warfarin and vitamin K-1 2,3-epoxide. The kinetic parameters for the enzyme activity in HS microsomal preparations indicated, however, that vitamin K-1 epoxide reductase in this warfarin-resistant strain was very similar, in respect of substrate and inhibitor affinities, to that prepared from susceptible (TAS) animals. Analysis of vitamin K-1 epoxide reductase activity in the livers of animals that had been orally treated with sodium warfarin (20 mg/kg body wt.) indicated that enzyme activity was inhibited in all three strains, although this dose is lethal only to animals of the TAS strain.     

Microsomal Flavin-Containing Monooxygenase Activity in Rat Corpus Striatum

Microsomal fractions isolated from rat corpus striatum catalyze the oxidation of thiobenzamide to the sulfoxide. The rate of thiobenzamide sulfoxidation is 6.9 +/- 4.8 nmol(min)-1 (mg microsomal protein)-1. The reaction is inhibited by an excess of sulfur- and nitrogen-containing substrates for the microsomal flavin-containing monooxygenase. These inhibitors of thiobenzamide sulfoxidation include methimazole, cysteamine, and trimethylamine. Enzyme activity is also destroyed by treatment of the microsomal preparation at 60 degrees for 1 min. In parallel experiments, rat liver microsomes exhibit similar inhibition characteristics. The data indicate the presence in corpus striatum of a microsomal monooxygenase with catalytic properties of the hepatic microsomal flavin-containing monooxygenase.     

Differential control of rat microsomal "aryl hydrocarbon" monooxygenase and epoxide hydratase.

A growing body of evidence implicates epoxide metabolites of mutagenic and carcinogenic polycyclic hydrocarbons as either the only species, or one of the contributing species responsible for these adverse effects. Selective induction of epoxide hydratase(s) catalyzing the transformation of epoxides to electrophilically unreactive dihydrodiols, under conditions not leading to increases in monooxygenase(s) responsible for epoxide formation would, therefore, be of interest. All inducers of rat hepatic epoxide hydratase (determined with [7-3H]styrene oxide as substrate) which have been discovered also induced monooxygenase (determined with benzo(a)pyrene as substrate) suggesting a possible common biosynthetic control of these enzymes. The enzyme levels observed in different sexes and at different stages of the ontogenetic development, possibly dependent on endogenous inducers, strengthened this view. No sex difference is epoxide hydratase activity was observed in young rats (1 to 5 days old) while epoxide hydratase levels were about 3-fold higher in adult males than in females, which was remarkably similar to the behavior of monooxygenase. Moreover, the prenatal development of epoxide hydratase and monooxygenase appeared to be similar--although the low enzyme levels precluded accurate determinations of the latter. Although different types of known monooxygenase inducers all led to epoxide hydratase induction in adult rat liver, their effect of epoxide hydratase and monooxygenase could be dissociated by transplacental treatment. Dissociation was clearest with inducers of the polycyclic hydrocarbon type which led to great induction of monooxygenase while epoxide hydratase remained unchanged. The increases in monooxygenase activity were very different when determined by two methods based on different principles, demonstrating that at least two monooxygenases are involved in oxidative metabolism of benzo(a)pyrene, and that the control of epoxide hydratase is not under common control with either of them.