Regulation of arachidonic acid metabolism by cytochrome P-450 in rabbit kidney.

Renal microsomal cytochrome P-450-dependent arachidonic acid metabolism was correlated with the level of cytochrome P-450 in the rabbit kidney. Cobalt, an inducer of haem oxygenase, reduced cytochrome P-450 in both the cortex and medulla in association with a 2-fold decrease in aryl-hydrocarbon hydroxylase, an index of cytochrome P-450 activity, and a similar decrease in the formation of cytochrome P-450-dependent arachidonic acid metabolites by renal microsomes (microsomal fractions). Formation of the latter was absolutely dependent on NADPH addition and was prevented by SKF-525A, an inhibitor of cytochrome P-450-dependent enzymes. Arachidonate metabolites of cortical microsomes were identified by g.c.-m.s. as 20- and 19-hydroxyeicosatetraenoic acid, 11,12-epoxyeicosatrienoic acid and 11,12-dihydroxyeicosatrienoic acid. The profile of arachidonic acid metabolites was the same for the medullary microsomes. Induction of cytochrome P-450 by 3-methylcholanthrene and beta-naphthoflavone increased cytochrome P-450 content and aryl-hydrocarbon hydroxylase activity by 2-fold in the cortex and medulla, and this correlated with a 2-fold increase in arachidonic acid metabolites via the cytochrome P-450 pathway. These changes can also be demonstrated in cells isolated from the medullary segment of the thick ascending limb of the loop of Henle, which previously have been shown to metabolize arachidonic acid specifically via the cytochrome P-450-dependent pathway. The specific activity for the formation of arachidonic acid metabolites by this pathway is higher in the kidney than in the liver, the highest activity being in the outer medulla, namely 7.9 microgram as against 2.5 micrograms of arachidonic acid transformed/30 min per nmol of cytochrome P-450 for microsomes obtained from outer medulla and liver respectively. These findings are consistent with high levels of cytochrome P-450 isoenzyme(s), specific for arachidonic acid metabolism, primarily localized in the outer medulla.     

Transformation of arachidonic acid by 5- and 15-lipoxygenase pathways in bovine adrenal fasciculata cells

[1-14C]Arachidonic acid was incubated with isolated bovine adrenal fasciculata cells for 15 min at 37gC. The metabolites were separated and purified by reverse- and straight-phase high performance liquid chromatography, and identified by gas chromatography-mass spectrometry or radioimmunoassay. Identified metabolites were 5-hydroxy-6,8,11,14-eicosatetraenoic acid (5-HETE), 15-hydroxy-5,8,11,13-eicosatetraenoic acid (15-HETE), leukotriene B4 and 11,14,15-trihydroxy-5,8,12-eicosatrienoic acid (11,14,15-THET). Addition of 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid (15-HPETE), an intermediate metabolite of 15-lipoxygenase pathway to microsomes of bovine adrenal fasciculata cells resulted in the formation of 11,14,15-THET. The formation of 11,14,15-THET by microsomes was not dependent on the presence of NADPH, while it was dose-dependently suppressed by ketoconazole, a potent inhibitor of cytochrome P-450 dependent enzymes. These results indicate that 5- and 15-lipoxygenase pathways of arachidonic acid may exist in bovine adrenal fasciculata cells and that 15-HPETE is further metabolized to 11,14,15-THET by adrenal microsomal cytochrome P-450.     

The mechanism of cumene hydroperoxide-dependent lipid peroxidation: the function of cytochrome P-450

The addition of limiting amounts of cumene hydroperoxide to rat liver microsomes resulted in the rapid uptake of molecular oxygen, the formation of thiobarbituric acid reactive products, and the loss of hydroperoxide. The stoichiometry of lipid peroxidation and the yields of 2-phenyl-2-propanol (a major product of the reaction) and acetophenone (a minor product) observed with liver microsomes prepared from untreated rats is greater than that seen with liver microsomes from ciprofibrate-treated rats which, in turn, is greater than that observed with liver microsomes from phenobarbital-treated rats. The Km's and Vmax's of oxygen uptake varied with the type of rat liver microsomes used. Cytochrome P-450 substrates and inhibitors decreased the extents and initial rates of oxygen uptake and thiobarbituric acid reactive product formation. A mechanism is proposed involving the cytochrome P-450-catalyzed homolytic cleavage of the cumene hydroperoxide O-O bond to give the cumyloxyl radical. It is proposed that this oxygen-centered radical abstracts a hydrogen atom from an unsaturated fatty acid associated with a lipid (initiating lipid peroxidation) to give 2-phenyl-2-propanol or that the radical undergoes beta-scission to produce acetophenone and a methyl radical.     

The involvement of cytochrome P-450 in hepatic microsomal steroid hydroxylation reactions supported by sodium periodate, sodium chlorite, and organic hydroperoxides.

The mechanism of steroid hydroxylation in rat liver microsomes has been investigated by employing NaIO4, NaClO2, and various organic hydroperoxides as hydroxylating agents and comparing the reaction rates and steroid products formed with those of the NADPH-dependent reaction. Androstenedione, testosterone, progesterone, and 17beta-estradiol were found to act as good substrates. NaIO4 was by far the most effective hydroxylating agent followed by cumene hydroperoxide, NADPH, NaClO2, pregnenolone 17alpha-hydroperoxide, tert-butyl hydroperoxide, and linoleic acid hydroperoxide. Androstenedione was chosen as the model substrate for inducer and inhibitor studies. The steroid was converted to its respective 6beta-, 7alpha, 15-, and 16alpha-hydroxy derivatives when incubated with microsomal fractions fortified with hydroxylating agent. Evidence for cytochrome P-450 involvement in androstenedione hydroxylation included a marked inhibition by substrates and modifiers of cytochrome P-450 and by reagents which convert cytochrome P-450 to cytochrome P-420. The ratios of the steroid products varied according to the type of hydroxylating agent used and were also modified by in vivo phenobarbital pretreatment. It was suggested that multiple forms of cytochrome P-450 exhibiting different affinities for hydroxylating agent are responsible for these different ratios. Horse-radish peroxidase, catalase, and metmyoglobin could not catalyze androstenedione hydroxylation. Addition of NaIO4, NaClO2, cumene hydroperoxide and other organic hydroperoxides to microsomal suspensions resulted in the appearance of a transient spectral change in the difference spectrum characterized by a peak at about 440 nm and a trough at 420 nm. The efficiency of these oxidizing agents in promoting steroid hydroxylation in microsomes appeared to be related to their effectiveness in eliciting the spectral complex. Electron donors, substrates, and modifiers of cytochrome P-450 greatly diminished the magnitude of the spectral change. It is proposed that NaIO4, NaClO2, and organic hydroperoxides promote steroid hydroxylation by forming a transient ferryl ion (compound I) of cytochrome P-450 which may be the common intermediate hydroxylating species involved in hydroxylations catalyzed by cytochrome P-450.     

Heterogeneity of liver microsomal cytochrome P-450: the spectral characterization of reactants with reduced cytochrome P-450.

The aerobic metabolism of benzphetamine by liver microsomes, during a cytochrome P-450-catalyzed mixed-function oxidation reaction, results in the formation of an easily detected spectral complex with an absorption band maximum at 456 nm. Electron paramagnetic resonance studies, as well as studies with the chemical reductant, sodium dithionite, or the oxidant, potassium ferricyanide, indicate that the spectral complex results from the formation of a product adduct with reduced cytochrome P-450. The spectral properties of this product complex of cytochrome P-450 have been compared to those observed with carbon monoxide, metyrapone, and ethylisocyanide. The reaction of these reagents to specific pools of microsomal cytochrome P-450 permits the identification of at least two major and two minor types of cytochrome P-450 in liver microsomes prepared from phenobarbital-treated rats.     

Formation of epoxyeicosatrienoic acids from arachidonic acid by cultured rat aortic smooth muscle cell microsomes.

The vasodilatory effect of epoxyeicosatrienoic acids (EpETrE), especially 5(6)-EpETrE, has been reported recently and a role of P-450-dependent arachidonic acid monooxygenase metabolites was suggested in vasoregulation. Accordingly, the presence of P-450-dependent arachidonic acid monooxygenase was investigated in rat aortic smooth muscle cells. Incubation of the microsomes of rat cultured aortic smooth muscle cells with 14C-arachidonic acid in the presence of 1 mM NADPH resulted in the formation of oxygenated metabolites. The metabolites were separated and purified by reverse phase and straight phase high performance liquid chromatography and identified by gas chromatography-mass spectrometry. Identified metabolites were 5(6)-EpETrE, 5,6-dihydroxyeicosatrienoic acid (DiHETrE), and 14,15-DiHETrE. The formation of these metabolites was totally dependent on the presence of NADPH, and inhibitors of cytochrome P-450-dependent enzymes, SKF-525A and metyrapone, reduced the formation of these metabolites. This is the first report that cytochrome P-450-dependent arachidonic acid metabolites, especially 5(6)-EpETrE and 14(15)-EpETrE, can be produced in the microsomes of vascular smooth muscle cells of rats.     

Platelet cytochrome P-450: A possible role in arachidonate-induced aggregation

Platelet microsomes were shown to contain cytochromes P-450 and b₅ and their respective reductases, NADPH-cytochrome c reductase and NADH-cytochrome b₅ reductase. Metyrapone and carbon monoxide (CO), two inhibitors of cytochrome P-450, inhibited both the arachidonic acid-induced platelet aggregation and the formation of aggregating factors from arachidonic acid by isolated microsomes. In addition metyrapone produced a type II spectral change with platelet microsomal cytochrome P-450. The data suggest that cytochrome P-450 may play a role in the complex enzyme systems which convert arachidonic acid to the platelet aggregating factors, cyclic endoperoxides and thromboxane A₂.     

Possible higher valence states of cytochrome P-450 during oxidative reactions

The addition of the organic hydroperoxide, cumene hydroperoxide, to liver microsomes results in the appearance of a transient spectral change associated with cytochrome P-450. In addition, unique electron paramagnetic resonance signals are observed with liver microsomal cytochrome P-450 comparable to signals obtained when peroxides interact with metmyoglobin. It is suggested that higher valence states of cytochrome P-450 may function during the activation of oxygen for the hydroxylation of a variety of xenobiotics.     

Gas chromatographic—mass spectrometric characterisation of some novel hydroxyeicosatetraenoic acids formed on incubation of arachidonic acid with microsomes from induced rat livers

The biotransformation of arachidonic acid by rat liver microsomes from both control animals and animals pretreated with known inducers of cytochrome P-450 isoenzymes has been studied using a combination of reversed- and normal-phase high-performance liquid chromatography and combined gas chromatography—electron-impact mass spectrometry. The metabolite profiles observed were found to be dependent upon the inducing agent. Five metabolites were identified, namely 16-, 17-, 18-, 19- and 20-hydroxylated arachidonic acids. Of these the 16- and 17-isomers have not been reported as products of arachidonic acid metabolism by any biological system and the 18-isomer has not been reported as a product of liver metabolism.     

In vitro metabolism of 3-t-butyl-4-hydroxyanisole and its irreversible binding to proteins

A method for the preparation of methyl-labelled 3-t-butyl-4-hydroxyanisole (BHA) is described. Metabolism of [14C]BHA using four different enzyme systems (liver microsomes + NADPH; liver microsomes + cumene hydroperoxide (CHP); sheep seminal vesicle (SSV) microsomes (as a source of prostaglandin synthetase) + arachidonic acid (AA); horseradish peroxidase (HRP) + hydrogen peroxide) was investigated. In all systems, BHA was oxidized to a variety of products including formaldehyde, a dimer di-BHA, polar and water soluble metabolites as well as a reactive intermediate(s) that binds irreversibly to proteins. With liver microsomes and NADPH, phenobarbital (PB) induction gave increased yields of all products while 3-methylcholanthrene (MC) induction specifically increased protein binding but decreased other metabolite formation. BHA addition effectively discharged the activated oxygen complex of cytochrome P-450 (liver microsomes) as well as Comp. I and Comp. II of HRP suggesting that it is a good one electron peroxidase donor. BHA addition also increased the net rate of NADPH oxidation in the presence of liver microsomes suggesting uncoupling. It is proposed that in all system investigated BHA is oxidized predominantly via a one electron oxidation process to yield first the BHA free radical which then dimerizes, forms more products or binds to proteins.     

Metabolism of valproic acid by hepatic microsomal cytochrome P-450

Incubation of valproic acid with rat liver microsomes led to the formation of 3-, 4- and 5-hydroxy-valproic acid. The latter two metabolites, which have been characterized previously from in vivo studies, may be regarded as products of fatty acid ω-1 and ω hydroxylation, respectively. 3-Hydroxy-valproic acid, however, had been thought to derive from the β-oxidation pathway in mitochondria. Conversion of valproic acid to all three metabolites in microsomes required NADPH (NADH was less effective), utilized molecular oxygen, was suppressed by inhibitors of cytochrome P-450 and was stimulated (notably at C-3 and C-4) by phenobarbital pretreatment of the rats. It is concluded that rat liver microsomal cytochrome P-450 catalyzes ω-2 hydroxylation of valproic acid, a reaction not detected previously with fatty acids in mammalian systems, and that the product, 3-hydroxyvalproic acid, should not be used to assess in vivo metabolism of valproate via the β-oxidation pathway.     

Cytochrome P-450 enzyme-specific control of the regio- and enantiofacial selectivity of the microsomal arachidonic acid epoxygenase

Chiral analysis of the rat liver microsomal arachidonic acid epoxygenase metabolites shows enantioselective formation of 8,9-, 11,12-, and 14,15-cis-epoxyeicosatrienoic acids in an approximately 2:1, 4:1, and 2:1 ratio of antipodes, respectively. Animal treatment with the cytochrome P-450 inducer phenobarbital increased the overall enantiofacial selectivity of the microsomal epoxygenase and caused a concomitant inversion in the absolute configurations of its metabolites. These effects of phenobarbital were time-dependent and temporally linked to increases in the concentration of microsomal cytochrome P-450 enzymes. Reconstitution of the epoxygenase reaction utilizing several purified cytochrome P-450 demonstrated that the asymmetry of epoxidation is under cytochrome P-450 enzyme control. These results established that the chirality of the hepatic arachidonic acid epoxygenase is under regulatory control and confirm cytochromes P-450 IIB1 and IIB2 as two of the endogenous epoxygenases induced in vivo by phenobarbital.     

Hydroperoxidation by cytochrome P-450 oxygenase: metabolism of 9-methylfluorene

9-Methylfluorene was metabolized by rat liver microsomes to 9-hydroperoxy-9-methylfluorene and 9-hydroxy-9-methylfluorene. The results were confirmed by using a reconstituted cytochrome P-450 oxygenase system purified from phenobarbital-induced rat liver which established its involvement. SKF-525A strongly inhibited the formation of both oxygenation products. Cytochrome P-450 alone brought about the conversion of the hydroperoxide to its alcohol. NADPH augmented the peroxidative reaction, but the presence of NADPH-cytochrome P-450 reductase was without effect. Certain microsomal preparations and reconstituted enzyme yielded little or no detectable amounts of hydroperoxide. This was due to a too rapid conversion of the hydroperoxide to its alcohol. The addition of metyrapone, a compound that inhibited such conversion, resulted in accumulation of 9-hydroperoxy-9-methylfluorene for positive identification. Incubation of 9-methylfluorene with microsomes and NADPH resulted in covalent binding of its metabolite to microsomal proteins. Incubation of 14C-labeled 9-hydroperoxy-9-methylfluorene caused covalent binding of label to proteins, RNA, and DNA.     

Immunochemical studies on the contribution of NADPH cytochrome P-450 reductase to the cytochrome P-450-dependent metabolism of arachidonic acid

We have studied the role of NADPH cytochrome P-450 reductase in the metabolism of arachidonic acid and in two other monooxygenase systems: aryl hydrocarbon hydroxylase and 7-ethoxyresorufin-o-deethylase. Human liver NADPH cytochrome P-450 reductase was purified to homogeneity as evidenced by its migration as a single band on SDS gel electrophoresis, having a molecular weight of 71,000 Da. Rabbits were immunized with the purified enzyme and the resulting antibodies were used to evaluate the involvement of the reductase in cytochrome P-450-dependent arachidonic acid metabolism by bovine corneal epithelial and rabbit renal cortical microsomes. A highly sensitive immunoblotting method was used to identify the presence of NADPH cytochrome P-450 reductase in both tissues. We used these antibodies to demonstrate for the first time the presence of cytochrome c reductase in the cornea. Anti-NADPH cytochrome P-450 reductase IgG, but not anti-heme oxygenase IgG, inhibited the NADPH-dependent arachidonic acid metabolism in both renal and corneal microsomes. The inhibition was dependent on the ratio of IgG to microsomal protein where 50% inhibition of arachidonic acid conversion by cortical microsomes was achieved with a ratio of 1:1. A higher concentration of IgG was needed to achieve the same degree of inhibition in the corneal microsomes. The antibody also inhibited rabbit renal cortical 7-ethoxyresorufin-o-deethylase activity, a cytochrome P-450-dependent enzyme. However, the anti-NADPH cytochrome P-450 reductase IgG was much less effective in inhibiting rabbit cortical aryl hydrocarbon hydroxylase. Thus, the degree of inhibition of monooxygenases by anti-NADPH cytochrome P-450 reductase IgG is variable. However, with respect to arachidonic acid, NADPH cytochrome P-450 reductase appears to be an integral component for the electron transfer to cytochrome P-450 in the oxidation of arachidonic acid.     

Characterization of the enzymatic and nonenzymatic peroxidative degradation of iron porphyrins and cytochrome P-450 heme

Both purified cytochrome P-450 (P-450) and free ferriprotoporphyrin IX are destroyed by NADPH-P-450 reductase in the presence of NADPH and O2. The process appears to be mediated by H2O2 generated by reduction of O2. Six major products were identified from the reaction of H2O2 with ferri-protoporphyrin IX-hematinic acid, methylvinylmaleimide, and four dipyrrolic propentdyopents. The structures of the propentdyopents were elucidated by mass spectrometry and 1H NMR methods. Both free ferriprotoporphyrin IX and P-450 yielded these same products in similar relative ratios. P-450 heme in rat liver microsomes was degraded in the presence of O2 and NADPH and either NaN3 (a catalase inhibitor) or Fe-ADP (which promotes lipid peroxidation); the products were primarily hematinic acid, methylvinylmaleimide, and small quantities of one propentdyopent. Only the two maleimides were detected in the destruction of microsomal P-450 heme by cumene hydroperoxide and iodosylbenzene. On the basis of the reaction of H2O2 with several metal-octaethylethylporphyrin complexes and free octaethylporphyrin, the iron chelated in ferriprotoporphyrin IX is required for degradation by H2O2. Biliverdin is not an intermediate in the formation of maleimides and propentdyopents from heme. Experiments using the tetraethylpropentdyopent produced from ferrioctaethylporphyrin suggest that propentdyopents are not further cleaved to form the maleimides. A mechanism for oxidative heme destruction consistent with these observations is proposed.     

Interaction of cytochrome P-450 with a hydroperoxide derived from butylated hydroxytoluene. Mechanism of isomerization

Attack of O2 on the phenoxy radical derived from butylated hydroxytoluene resulted in the formation of 2,6-di-t-butyl-4-hydroperoxy-4-methyl-2,5-cyclohexadienone (BOOH). This hydroperoxide was rapidly consumed when incubated with rat liver microsomes in the absence of NADPH. The destruction of BOOH was accompanied by formation of the corresponding alcohol (BOH) and a derivative of the alcohol (B(OH)2) in which a t-butyl methyl group was hydroxylated. This diol was produced also when BOH was incubated with microsomes and NADPH, but at a slower rate. Mass spectral analyses of B(OH)2 formed from substrates labeled with either 2H or 18O, showed that oxygen was transferred from the peroxy group to a t-butyl group (via the heme iron of P-450) without migration of the intermediate alcohol from the enzyme active site. The results support a mechanism involving heterolytic O-O bond cleavage during isomerization of the hydroperoxide to B(OH)2. The chiral diol was produced from BOOH nonstereoselectively, but the NADPH/O2-supported hydroxylation of BOH resulted in the formation of a 20% excess of one enantiomer of B(OH)2. Analyses of products formed from the interaction of cumene hydroperoxide with cytochrome P-450 showed that this substrate undergoes rearrangement also; 2-phenyl-1,2-propanediol was produced, together with cumyl alcohol and acetophenone. These results indicate that isomerization competes with other pathways of hydroperoxide destruction by cytochrome P-450.     

Rabbit liver microsomal lipid peroxidation. The effect of lipid on the rate of peroxidation

Rat and rabbit liver microsomes catalyze an NADPH-cytochrome P-450 reductase-dependent peroxidation of endogenous lipid in the presence of the chelate, ADP-Fe3+. Although liver microsomes from both species contain comparable levels of NADPH-cytochrome P-450 reductase and cytochrome P-450, the rate of lipid peroxidation (assayed by malondialdehyde and lipid hydroperoxide formation) catalyzed by rabbit liver microsomes is only about 40% of that catalyzed by rat liver microsomes. Microsomal lipid peroxidation was reconstituted with liposomes made from extracted microsomal lipid and purified protease-solubilized NADPH-cytochrome P-450 reductase from both rat and rabbit liver microsomes. The results demonstrated that the lower rates of lipid peroxidation catalyzed by rabbit liver microsomes could not be attributed to the specific activity of the reductase. Microsomal lipid from rabbit liver was found to be much less susceptible to lipid peroxidation. This was due to the lower polyunsaturated fatty acid content rather than the presence of antioxidants in rabbit liver microsomal lipid. Gas-liquid chromatographic analysis of fatty acids lost during microsomal lipid peroxidation revealed that the degree of fatty acid unsaturation correlated well with rates of lipid peroxidation.     

Fatty acid hydroxylation in rat kidney cortex microsomes

Rat kidney microsomes have been found to catalyze the hydroxylation of medium-chained fatty acids to the omega- and (omego-1)-hydroxy derivatives. This reaction, which requires NADPH and molecular oxygen, is a function of monooxygenase system present in the kidney microsomes, containing NADPH-cytochrome c reductase and cytochrome P-450K. NADH is about half as effective as an electron donor as NADPH and there is an additive effect in the presence of both nucleotides. Cytochrome P-450K absorbs light maximally at 452-3 nm, when it is reduced and bound to carbon monoxide. The extinction coefficient of this complex is 91 mM(-1) cm(-1). Electrons from NADPH are transferred to cytochrome P-450K via the NADPH-cytochrome c reductase. The reduction rate of cytochrome P-450K is stimulated by added fatty acids and the reduction kinetics reveal the presence of endogenous substrates bound to cytochrome P-450K. Both cytochrome P-450K concentration and fatty acid hydroxylation activity in kidney microsomes are increased by starvation. On the other hand, phenobarbital treatment of the rats has no effect on either the hemoprotein or the overall hydroxylation reaction and 3,4-benzpyrene administration induces a new species of cytochrome P-450K not involved in fatty acid hydroxylation. Cytochrome P-450K shows, in contrast to liver P-450, high substrate specificity. The only substances forming enzyme-substrate complexes with cytochrome P-450K are the medium-chained fatty acids and certain derivatives of these acids. The chemical requirements for substrate binding include a carbon chain of medium length and at the end of the chain a carbonyl group and a free electron pair on a neighbouring atom. The distance between the binding site for the carbonyl group and the active oxygen is suggested to be in the order of 16 A. This distance fixes the ratio of omega- and (omega-1)-hydroxylated products formed from a certain fatty acid by the single species of cytochrome P-450K involved. The membrane microenvironment seems also to be of importance for the substrate specificity of cytochrome P-450K, since removal of the cytochrome from the membrane lowers its binding specificity to some extent. A comparison between the liver and kidney cytochrome P-450 systems suggests that the kidney cytochrome P-450K system is specialized for fatty acid hydroxylation.     

Detection of the enzymatic activity of cytochrome P-450 enzymes by high-performance liquid chromatography

The reactions catalysed by the various cytochrome P-450 enzymes are reviewed with respect to the analysis of products by high-performance liquid chromatography (HPLC). Especially biotransformation reactions of purified cytochrome P-450 enzymes in a reconstituted system and in microsomes mainly of rat liver origin are considered. Emphasis is put on the specificity of product formation due to the individual isozymes of cytochrome P-450. It is shown that the presence of eight cytochrome P-450 isozymes can be monitored and determined by specific product formation after HPLC analysis, which is an important parameter in toxicological studies.     

Studies on in vitro antipyrine metabolism by 13C,15N double labeled method

The capacities of forms of cytochrome P-450 to oxidize antipyrine were compared. An isotope dilution gas chromatography/mass spectrometry/selected ion monitoring assay was developed to quantify the three main metabolites, norantipyrine, 3-hydroxymethylantipyrine and 4-hydroxyantipyrine. 13C,15N-Double labeled antipyrine was used as a substrate and the metabolites were analyzed as their trimethylsilyl derivatives. Among forms of cytochrome P-450 examined, a male-specific form of P-450, namely P-450-male, showed higher activity to form all the three metabolites. The other forms were responsible only for the formation of norantipyrine and 4-hydroxyantipyrine. The activities of liver microsomes from untreated male and female rats and rats treated with phenobarbital, 3-methylcholanthrene or polychlorinated biphenyl were expressed dependent on the activities of forms of cytochrome P-450 examined.