Metabolism of prostaglandins and xenobiotics by adrenal microsomal monooxygenase in the guinea pig

The possibility that prostaglandins could serve as substrates for the guinea pig adrenal microsomal monooxygenase was investigated. The binding of PGE₁ to adrenal microsomes was found to exhibit a reverse type I spectral change. Also PGE₁ diminished the magnitude of type I spectrum elicited by cortisol binding to adrenal microsomes. The incubation of [³H]PGE₁ or of [³H]PGE₂ with adrenal microsomes supplemented with NADPH yielded primarily the respective 19-hydroxy metabolite. The enzymatic activity catalyzing this hydroxylation appears to be a typical monooxygenase, requiring NADPH for activity and being strongly inhibited by metyrapone, SKF 525A, and cytochrome c. Carbon monoxide at a ratio of 9:1 to oxygen moderately inhibited the hydroxylation of PGE₁. Whereas the liver catalyzed the hydroxylation of PGE₁ and PGA₁ equally well, the adrenal microsomes preferentially catalyzed the hydroxylation of PGE₁. This finding and the observation that α-naphthoflavone is a weak inhibitor of the adrenal PGE₁ hydroxylation points to significant differences between the adrenal and liver prostaglandin hydroxylation activities. Cortisol, which is a substrate for adrenal monooxygenase, strongly inhibited PGE₁ and PGE₂ hydroxylation. By contrast, certain xenobiotics (ethylmorphine, hexobarbital, benzpyrene), which are also metabolized by adrenal microsomes, only slightly inhibited the hydroxylation of PGE₁. Similarly, PGE₁ only weakly inhibited ethylmorphine and benzphetamine demethylation and hexobarbital hydroxylation. These observations suggest that adrenal microsomes contain several monooxygenases with different affinities for prostaglandins and for the different xenobiotic substrates.     

Prostaglandin and fatty acid omega- and (omega-1)-oxidation in rabbit lung. Acetylenic fatty acid mechanism-based inactivators as specific inhibitors

Terminal acetylenic fatty acid mechanism-based inhibitors (Ortiz de Montellano, P. R., and Reich, N. O. (1984) J. Biol. Chem. 259, 4136-4141) were used as probes in determining the substrate specificity of rabbit lung cytochrome P-450 isozymes of pregnant animals in both microsomes and reconstituted systems. Lung microsomal and reconstituted P-450 form 5-catalyzed lauric acid omega- and (omega-1)-hydroxylase activities were inhibited by a 12-carbon terminal acetylenic fatty acid, 11-dodecynoic acid (11-DDYA), and an 18-carbon terminal acetylenic fatty acid, 17-octadecynoic acid (17-ODYA). Rabbit lung microsomal lauric acid omega-hydroxylase activity was more sensitive to inhibition by 11-DDYA than was (omega-1)-hydroxylase activity. In reconstituted systems containing purified P-450 form 5, both omega- and (omega-1)-hydroxylation of lauric acid were inhibited in parallel when either 11-DDYA or 17-ODYA was used. These data suggest the presence of at least two P-450 isozymes in rabbit lung microsomes capable of lauric acid omega-hydroxylation. This is the first report indicating the multiplicity of lauric acid hydroxylases in lung microsomes. Lung microsomal prostaglandin omega-hydroxylation, mediated by the pregnancy-inducible P-450PG-omega (Williams, D. E., Hale, S. E., Okita, R. T., and Masters, B. S. S. (1984) J. Biol. Chem. 259, 14600-14608) was subject to inhibition by 17-ODYA only, whereas 11-DDYA acid was not an effective inhibitor of this hydroxylase. We have recently developed a new terminal acetylenic fatty acid, 12-hydroxy-16-heptadecynoic acid (12-HHDYA), that contains a hydroxyl group at the omega-6 position. We show that 12-HHDYA possesses a high degree of selectivity for the inactivation of rabbit lung microsomal prostaglandin omega-hydroxylase activity which cannot be obtained with the long chain acetylenic inhibitor, 17-ODYA. In addition, 12-HHDYA has no effect on lauric acid omega- or omega-1-hydroxylation or on benzphetamine N-demethylation. The development of this new terminal acetylenic fatty acid inhibitor provides us with a useful tool with which to study the physiological role of prostaglandin omega-hydroxylation in the rabbit lung during pregnancy.     

Regioselectivity of hydroxylation of prostaglandins by liver microsomes supported by NADPH versus H2O2 in methylcholanthrene-treated and control rats: formation of novel prostaglandin metabolites

The effects of methylcholanthrene (MC) treatment of male rats on the regioselectivity of hydroxylation of prostaglandins E1 and E2 (PGE1 and PGE2) by liver microsomes, supplemented with NADPH or H2O2, was examined. In the presence of NADPH, control microsomes catalyzed the hydroxylation at omega-1 (C19) and at omega-(C20) sites with minimal formation of novel monohydroxy metabolites of PGE1 and PGE2, referred to as compounds X1 and X2, respectively. Similarly, H2O2 supported the 19-hydroxylation and the formation of compounds X1 and X2, but yielded only minimal amounts of 20-hydroxy products. With NADPH, MC-treated microsomal incubations demonstrated only minor quantitative change in the 19- and 20-hydroxylation as compared with controls, but showed a 7- to 11-fold increase in formation of compound X1 and a 10-fold increase in formation of X2. By contrast with H2O2, MC-treatment increased by about 3-fold the 19- and 20-hydroxylation of PGE1 and by 35- to 46-fold the formation of X1; similarly, there was an approximate 2-fold increase in 19- and 20-hydroxylation of PGE2 and a 10-fold increase in formation of X2. These findings suggest that several monooxygenases are involved in catalyzing the hydroxylation at the various sites of the PGE molecule. Inhibitors of monooxygenases (SKF 525A, alpha-naphthoflavone, and imidazole derivatives) provided further evidence that the hydroxylation at the three sites of PGEs is catalyzed by different P-450 monooxygenases. It is striking that the inhibitors had a much lesser effect on the 20-hydroxylation of PGE1 as compared with other sites of hydroxylation. Structural identification of compounds X1 and X2 was elucidated as follows. Resistance of the PGB derivative of X1 to periodate oxidation and mass fragmentation analysis of the t-butyldimethylsilyl ether methyl ester, placed the hydroxylation at C17 or C18. Finally, mass fragmentation of trimethylsilyl ether methyl ester PGB derivatives of X1 and X2 provided conclusive evidence that X1 and X2 are 18-hydroxy-PGE1 and 18-hydroxy-PGE2, respectively. The above findings indicate that the high regioselectivity of hydroxylation of PGE1 and PGE2, resulting in the formation of 18-hydroxy-PGE1 and 18-hydroxy-PGE2, respectively, is catalyzed by P-450 isozyme(s) which are induced by MC, possibly by P-450c.     

Monoclonal antibody-directed characterization of rat hepatic P450 catalyzing the omega-1 and omega-2 hydroxylation of prostaglandins

Previous studies have demonstrated that methylcholanthrene (MC) treatment of rats increases 10-fold the omega-2 hydroxylation of prostaglandin E2 (PGE2) by liver microsomes (K. A. Holm, R. J. Engell, and D. Kupfer (1985) Arch. Biochem. Biophys. 237, 477-489). The current study identifies the cytochrome P450 form, which catalyzes a major portion of the omega-2 hydroxylation of prostaglandins in liver microsomes of MC-treated rats (MC-microsomes) and examines whether the same enzyme catalyzes this reaction in microsomes from untreated rats (control microsomes). Three monoclonal antibodies (MAbs), MC 1-7-1, 1-31-2, and 1-36-1, raised against the major liver P450 from MC-treated rats were used. MAb 1-7-1 binds P450(57K) and P450(56K) (P450c and P450d, respectively); MAb 1-31-2 binds primarily P450(57K); and 1-36-1 binds solely P450(57k). MAb 1-7-1 inhibited omega-2 and omega-1 PGE2 hydroxylations in MC-microsomes by 70 and 45%, respectively. By contrast, MAb 1-31-2 and 1-36-1 were not inhibitory. MAb 1-7-1 did not inhibit PGE2 omega-2 hydroxylation in control or in microsomes from phenobarbital-treated rats (PB-microsomes). Since MAb 1-7-1 binds to both P450c and P450d, and 1-31-2 and 1-36-1 bind to P450c but are not inhibitory, these findings did not permit the determination of whether in MC microsomes a single isozyme (P450c or P450d) or both isozymes catalyze the omega-2 hydroxylation. This question was partially resolved by the observation that immunoaffinity-isolated P450c, supplemented with purified NADPH-P450 reductase, catalyzes effectively the omega-2 hydroxylation and to a lesser extent the omega-1 hydroxylation. There was no activity in the absence of reductase. The P450 antibody complex exhibits characteristics similar to those of the omega-2 hydroxylating activity in intact MC-microsomes supported by H2O2, by demonstrating a much higher activity when H2O2 is used instead of reductase and NADPH. Furthermore, a reconstituted monooxygenase composed of rat liver reductase and P450c, purified by conventional means, hydroxylated PGE2 at the omega-2 and omega-1 sites at a ratio of 2.8, similar to that obtained with the P450-antibody complex. These findings demonstrate that a major portion of the omega-2 hydroxylation of PGs in MC-microsomes is catalyzed by P450c; however, the possibility that some omega-2 hydroxylating activity is due to P450d was not ruled out.(ABSTRACT TRUNCATED AT 400 WORDS)     

Induction and suppression of hepatic and extrahepatic microsomal foreign-compound-metabolizing enzyme systems by 2,3,7,8-tetrachlorodibenzo-p-dioxin

The effects of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) on a number of hepatic and extrahepatic foreign-compound-metabolizing enzyme systems in microsomes from rats, rabbits and guinea pigs were investigated.Following TCDD treatment, the N-demethylation of benzphetamine, aminopyrine and ethylmorphine was suppressed in hepatic microsomes from male but not from female rats. However, both cytochrome P-450 and benzpyrene hydroxylase were significantly stimulated in hepatic microsomes from both male and female rate at doses as small as 1 μg TCDD/kg body weight. The inductive effect on rat hepatic microsomal enzymes was considerably more persistent than the suppressive effect. Following a single oral dose of 25 μg TCDD/kg body weight, benzpyrene hydroxylase of male rat liver microsomes remained significantly elevated for 73 days but the suppression of benzphetamine N-demethylase had gone after 35 days.The induction of benzpyrene hydroxylase in male rat liver microsomes by TCDD was independent of the age of the rat and the levels to which this enzyme was increased was similar in male rats of all ages. However, the suppression of benzphetamine N-demethylase in male rat liver microsomes was age related: the suppression was seen only in adult animals and in the very young (10 days old) the enzyme was actually induced by TCDD. Inductive effects appeared in both smooth and rough-surfaced hepatic microsomes from male rats but the suppression of N-demethylidon occurred perhaps the derepression arises through the interaction of TCDD or metabolite of TCDD, with the operator gene itself.     

omega-1 and omega-2 hydroxylation of prostaglandins by rabbit hepatic microsomal cytochrome P-450 isozyme 6

Incubation of prostaglandin E1 (PGE1) with liver microsomes from control rabbits and from rabbits treated with ethanol or imidazole yielded 18-, 19-, and 20-hydroxy metabolites, representing hydroxylation at omega-2, omega-1, and omega carbons, respectively. The current investigation demonstrates that rabbit liver P-450 isozyme 6 effectively catalyzes the omega-1 and omega-2 hydroxylation of PGE1 and PGE2. Additionally, a small amount of product with chromatographic characteristics of the corresponding 20-hydroxy metabolite has been detected. The incorporation of cytochrome b5 into the reconstituted system did not enhance the rate of PGE1 hydroxylation and had no effect on the ratio of products formed. The Km value for the omega-1 and omega-2 hydroxylation of PGE1 with P-450 isozyme 6 from imidazole-treated rabbits was approximately 140 microM; the Vmax's (nmol product min-1 nmol P-450-1) were 2.1 and 1.1 for the omega-1 and omega-2 hydroxylations, respectively. These rates represent the highest activities by hepatic P-450 isozymes for hydroxylation of PGs, and suggest that isozyme 6 is responsible for the omega-2 hydroxylation of PGEs observed in rabbit liver microsomes.     

Differential control of adrenal drug and steroid metabolism in the guinea pig.

Studies were carried out to compare the effects of several physiological variables on adrenal microsomal drug (ethylmorphine demethylation) and steroid (21-hydroxylation) metabolism in guinea pigs. The rate of adrenal ethylmorphine (EM) metabolism increased with maturation in males but not females, resulting in a sex difference (M > F) in adrenal enzyme activity in adult guinea pigs. Twenty-one hydroxylase activity, in contrast, was similar in adrenals from males and females. The concentration of adrenal microsomal cytochrome P-450 was unaffected by age or sex. ACTH administration decreased adrenal EM demethylase activity but did not affect 21-hydroxylation. Testosterone, when given to female guinea pigs, increased the rate of EM metabolism and decreased 21-hydroxylase activity. Various compounds known to interact with adrenal microsomal cytochrome P-450 had divergent effects on EM metabolism and 21-hydroxylation $\text{in}$$\text{vitro}$. Prostaglandins E₁ and F_2α, spironolactone, and canrenone inhibited EM demethylation but not 21-hydroxylation. Simple aromatic hydrocarbons (benzene, toluene), in contrast, inhibited 21-hydroxylation but did not affect EM metabolism. The results indicate that adrenal drug and steroid metabolism are independently regulated and that different terminal oxidases (cytochrome P-450) are probably involved in adrenal 21-hydroxylation and EM demethylation.     

Omega- and (omega-1)-hydroxylation of lauric acid and arachidonic acid by rat renal cytochrome P-450

We resolved four cytochrome P-450s, designated as P450 K-2, K-3, K-4, and K-5, from the renal microsomes of untreated male rats by high-performance liquid chromatography (HPLC) and investigated the lauric acid and arachidonic acid hydroxylation activities of these fractions. P450 K-4 and K-5 had high omega- and (omega-1)-hydroxylation activities toward lauric acid. The ratio of the omega-/(omega-1)-hydroxylation activity of P450 K-4 and K-5 was 3 and 6, respectively. Also, P450 K-4 and K-5 effectively catalyzed the omega- and (omega-1)-hydroxylation of arachidonic acid. P450 K-3 was not efficient in the hydroxylation of either lauric acid or arachidonic acid. P450 K-2 had low omega- and (omega-1)-hydroxylation activities toward arachidonic acid, and efficiently catalyzed the hydroxylation of lauric acid at the (omega-1)-position only, not at the omega-position.     

Regioselective hydroxylation of prostaglandins by constitutive forms of cytochrome P-450 from rat liver: formation of a novel metabolite by a female-specific P-450

Previous studies demonstrated that liver microsomes from untreated rats catalyze the omega, omega-1, and omega-2 hydroxylation of prostaglandins [K. A. Holm, R. J. Engell, and D. Kupfer (1985) Arch. Biochem. Biophys. 237, 477-489]. The current study examined the regioselectivity of hydroxylation of PGE1 and PGE2 by purified forms of P-450 from untreated male and female rat liver microsomes. PGE1 was incubated with a reconstituted system containing cytochrome P-450 RLM 2, 3, 5, 5a, 5b, 6, or f4, NADPH-P-450 reductase, and dilauroylphosphatidylcholine in the presence or absence of cytochrome b5. Among the P-450 forms examined, only RLM 5 (male specific), 5a (present in both sexes), and f4 (female specific) yielded high levels of PGE hydroxylation. With PGE1, RLM 5 catalyzed solely the omega-1 hydroxylation and 5a catalyzed primarily the omega-1 and little omega and omega-2 hydroxylation. By contrast, f4 effectively hydroxylated PGE1 and PGE2 at the omega-1 and at a novel site. Based on retention on HPLC and on limited mass fragmentation, we speculate that this site is omega-3 (i.e., 17-hydroxylation). Kinetic analysis of PGE1 hydroxylation demonstrated that the affinity of f4 for PGE1 is approximately 100-fold higher than that of RLM 5; the Km values for f4, monitoring 19- and 17-hydroxylation of PGE1, were about 10 microM. Surprisingly, cytochrome b5 stimulated the activity of RLM 5a and f4, but not that of RLM 5. Hydroxylation of PGE2 by RLM 5 was at the omega, omega-1, and omega-2 sites, demonstrating a lesser regioselectivity than with PGE1. These findings show that the constitutive P-450s differ dramatically in their ability to hydroxylate PGs, in their regioselectivity of hydroxylation, and in their cytochrome b5 requirement.     

Occurrence of cytochrome P-450 with prostaglandin omega-hydroxylase activity in rabbit placental microsomes

The microsomes of placenta and uterus from pregnant rabbits have been found to catalyze the omega-hydroxylation of PGE1, PGE2, PGF2 alpha, and PGA1 as well as the omega- and (omega-1)-hydroxylation of palmitate and myristate in the presence of NADPH. These activities were greatly inhibited by carbon monoxide, indicating the involvement of cytochrome P-450. The apparent Km for PGE1 was 2.38 microM and 2.1 microM with the placental and uterus microsomes, respectively. Cytochrome P-450 has been solubilized with 1% cholate from the placental microsomes, and partially purified by chromatography on 6-amino-n-hexyl Sepharose 4B, DEAE-Sephadex A-50 and hydroxylapatite columns. The partially purified cytochrome P-450 efficiently catalyzed the omega-hydroxylation of various prostaglandins such as PGE1, PGE2, PGF2 alpha, PGD2, and PGA1 in a reconstituted system containing NADPH-cytochrome P-450 reductase, cytochrome b5, and phosphatidylcholine. The reconstituted system also hydroxylated palmitate and myristate at the omega- and (omega-1)-position, but could not hydroxylate laurate. These catalytic properties resemble those of a new form of cytochrome P-450 highly purified from the lung microsomes of progesterone-treated rabbits (Yamamoto, S., Kusunose, E., Ogita, K., Kaku, M., Ichihara, K., and Kusunose, M. (1984) J. Biochem. 96, 593-603). This type of cytochrome P-450, viz., cytochrome P-450 with high prostaglandin omega-hydroxylase activity may play a role in the regulation of prostaglandin levels in pregnancy.     

N-aralkylated derivatives of 1-aminobenzotriazole as isozyme-selective, mechanism-based inhibitors of guinea pig hepatic cytochrome P-450 dependent monooxygenase activity

The mechanism-based inactivation of hepatic cytochrome P-450 by the suicide inhibitor 1-aminobenzotriazole and two of its derivatives, N-benzyl-1-aminobenzotriazole and N-alpha-methylbenzyl-1-aminobenzotriazole, was investigated in microsomes from untreated, phenobarbital-induced, and beta-naphthoflavone-induced guinea pigs. Microsomal 7-ethoxyresorufin O-deethylase, 7-pentoxyresorufin O-dealkylase, and benzphetamine N-demethylase activities, and cytochrome P-450 content were determined following incubation with 1-aminobenzotriazole and its analogues. The loss of hepatic cytochrome P-450 content and monooxygenase activity was dependent on inhibitor concentration and required NADPH. N-Benzyl-1-aminobenzotriazole and N-alpha-methylbenzyl-1-aminobenzotriazole were more potent inhibitors of monooxygenase activity than the parent compound in microsomes from untreated and phenobarbital-induced guinea pigs. In microsomes from phenobarbital-induced guinea pigs, N-alpha-methylbenzyl-1-aminobenzotriazole (10 microM) was highly selective for the inactivation of the major cytochrome P-450 isozyme catalyzing 7-pentoxyresorufin O-dealkylation (the guinea pig ortholog of P-450IIB1) compared with those isozymes catalyzing 7-ethoxyresorufin O-deethylation or benzphetamine N-demethylation (88 +/- 3% loss of activity vs. 35 +/- 11 and 13 +/- 7%, respectively). N-Benzyl-1-aminobenzotriazole was also selective for the inactivation of 7-pentoxyresorufin O-dealkylase activity, but to a lesser degree (56 +/- 6 vs. 31 +/- 8 and 21 +/- 8%, respectively). In hepatic microsomes from untreated guinea pigs, the two N-substituted analogues were selective for the inhibition of 7-pentoxyresorufin O-dealkylation compared with benzphetamine N-demethylation, but not 7-ethoxyresorufin O-deethylation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative kinetic studies of the dealkylation reaction and steroid hydroxylations in various oxygen and carbon monoxide:oxygen atmospheres

The time-course kinetics of the cytochrome P-450-catalyzed dealkylations of the exogenous compounds benzphetamine, ethylmorphine, codeine, and 7-ethoxycoumarin were compared to the hydroxylation of the endogenous compound testosterone. Using liver microsomes from phenobarbital-induced rats, the time course of the demethylations of ethylmorphine, codeine, and especially benzphetamine was characterized by a fast initial phase of enzymatic activity and then a steady decline in the rate throughout the remainder of the reaction. In contrast, under the same experimental conditions, both the dealkylation of 7-ethoxycoumarin and the hydroxylation of testosterone showed no initial fast phase of activity and a constant rate of product formation for most of the remainder of the time course. The difference also held for the carbon monoxide inhibition studies in which the degree of inhibition of the demethylation reactions by a variety of CO:O₂ mixtures was time dependent, in contrast to the constant, time-independent degree of CO inhibition of the other two reactions. The kinetics of the demethylation reactions could not be explained by enzyme destruction, back reaction, or product adduct formation and were further confirmed by measurements of the rate of O₂ utilization and NADPH oxidation. The complexity of the demethylation reaction should be taken into consideration in any detailed studies of the monooxygenation reaction system.     

Purification and characterization of two forms of chicken liver cytochrome P-450 induced by 3,4,5,3',4'-pentachlorobiphenyl

3,4,5,3',4'-Pentachlorobiphenyl (PenCB), one of the most potent 3-methylcholanthrene (MC)-type inducers of hepatic enzymes in animals, caused a remarkable induction of liver microsomal monooxygenases, particularly 7-ethoxyresorufin (7-ER) O-deethylase, benzo(a)pyrene (BP) 3-hydroxylase, and testosterone 16 alpha-hydroxylase in chickens, but not NADPH-cytochrome c(P-450) reductase and cytochrome b5. Two forms of cytochrome P-450 (P-450) in liver microsomes of PenCB-treated chickens were purified and characterized. The absorption maxima of the CO-reduced difference spectra of both enzymes (chicken P-448 L and chicken P-448 H) were at 448 nm. From the oxidized form of their absolute spectra, chicken P-448 L was a low-spin form and chicken P-448 H was a high-spin form. They had molecular masses of 56 and 54 kDa, respectively. In a reconstituted system, 7-ER O-deethylation, BP 3-hydroxylation, and testosterone 16 alpha-hydroxylation were catalyzed at high rates by chicken P-448 L but not by chicken P-448 H. Chicken P-448 L also catalyzed N-demethylation of aminopyrine, benzphetamine, and ethylmorphine with relatively low activity. On the other hand, chicken P-448 H functioned only in catalyzing estradiol 2-hydroxylation. These results were supported by an inhibition study of microsomal monooxygenases using an antibody against each enzyme. Immunochemical studies revealed that the enzymes differ from each other but are both inducible by PenCB-treatment. Chicken P-448 L and chicken P-448 H respectively comprise about 82 and 7% of the total P-450 content in chicken liver microsomes.     

The drug and carcinogen metabolism system of rat colon microsomes

The hydroxylation of N- and O-methyl drugs and polycyclic hydrocarbons has been demonstrated in microsomes prepared from colon mucosal cells. The hydroxylation of the drugs benzphetamine, ethylmorphine, p-nitroanisole, and p-nitrophenetole by colon microsomes is inducible two- to fourfold by pretreatment with phenobarbital/hydrocortisone. Colon microsomal benzo[α]pyrene hydroxylation is inducible 35-fold by pretreatment with β-naphthoflavone. Phenobarbital/hydrocortisone pretreatment also induces a fourfold increase in the specific content of colon microsomal cytochrome P-450, while β-naphthoflavone pretreatment causes a shift in the reduced CO difference spectrum peak to 448 nm and an eightfold increase in the specific content of this cytochrome. SKF 525-A inhibits the hydroxylation of the drug benzphetamine by colon microsomes or liver microsomes by 77% at a concentration of 2.0 mm. 7,8-Benzoflavone, on the other hand, inhibits the hydroxylation of the polycyclic hydrocarbon benzo[α]pyrene by colon microsomes by 76% and by liver microsomes by 44% at a concentration of 10 μm. Carbon monoxide, an inhibitor of oxygen interaction with cytochromes P-450 and P-448, inhibits benzphetamine hydroxylation and benzpyrene hydroxylation by colon microsomes 30 and 51%, respectively, at an oxygen to carbon monoxide ratio of 1:10. The K_m values of colon microsomal cytochrome P-450 reductase for the artificial electron acceptors cytochrome c, dichloroindophenol, and ferricyanide (10–77 μm) are in agreement with those for purified rat liver cytochrome P-450 reductase. These data support the conclusions that hydroxylation of drugs and polycyclic hydrocarbons is catalyzed by colon mucosal microsomes and that the hydroxylation activity is attributable to a cytochrome P-450-dependent drug metabolism system similar to that found in liver microsomes.     

Multiple forms of cytochrome P-450 from kidney cortex microsomes of rabbits treated with phenobarbital

Two distinct forms of cytochrome P-450 (P-450), referred to as P-450a and P-450b, were separated and purified from kidney cortex microsomes of rabbits treated with phenobarbital. P-450a had a monomeric molecular weight of 53,000, and its CO-reduced difference spectral peak was at 450 nm. It catalyzed the omega-hydroxylation of prostaglandin A1 (PGA1), and the omega- and (omega-1)-hydroxylation of myristate, but it was inactive toward exogenous compounds tested. On the other hand, P-450b had a monomeric molecular weight of 49,000, and its CO-reduced difference spectral peak was at 451 nm. This cytochrome was not able to hydroxylate PGA1 at all. It hydroxylated myristate much more slowly than P-450a, and preferentially at the (omega-1)-position. Unlike P-450a, P-450b efficiently metabolized exogenous compounds such as benzphetamine, aminopyrine, 7-ethoxycoumarin and p-nitroanisole. It is suggested that P-450a and P-450b are specialized for the metabolism of PGA1 and exogenous compounds, respectively, in kidney cortex microsomes.     

Interaction of prostaglandins with adrenal microsomal cytochrome P-450 in the guinea pig.

Studies were carried out to investigate the effects of prostaglandins (PG) in vitro on adrenal microsomal steroid and drug metabolism in the guinea pig. The addition of PGE1, PGE2, PGA1, PGF1 alpha or PGF2 alpha to isolated adrenal microsomes produced typical type I difference spectra. The sizes of the spectra (delta A385-420) produced by prostaglandins were smaller than those produced by various steroids including progesterone, 17-hydroxyprogesterone and 11 beta-hydroxyprogesterone. However, the affinities of prostaglandins and steroids for adrenal microsomal cytochrome P-450, as estimated by the spectral dissociation constants, were similar. Prior addition of prostaglandins to isolated adrenal microsomes did not affect steroid binding to cytochrome P-450 or the rate of steroid 21-hydroxylation. In contrast, prostaglandins inhibited adrenal metabolism of ethylmorphine and diminished the magnitude of the ethylmorphine-induced spectral change in adrenal microsomes. The results indicate that prostaglandins inhibit adrenal drug metabolism by interfering with substrate binding to cytochrome P-450. Since 21-hydroxylation was unaffected by PG, different cytochrome P-450 moieties are probably involved in adrenal drug and steroid metabolism.     

The rabbit pulmonary monooxygenase system. Immunochemical and biochemical characterization of enzyme components.

The enzymatic components of the rabbit pulmonary monooxygenase system, cytochromes P-450I and P-450II and NADPH-cytochrome P-450 reductase, are immunochemically distinct proteins. In pulmonary microsomes, the N-demethylation of benzphetamine, amino-pyrine, and ethylmorphine, and the O-deethylation of 7-ethoxycoumarin are dependent only on cytochrome P-450I, and the hydroxylation of coumarin is apparently catalyzed by both cytochromes. Cytochrome P-450II is immunochemically distinct from the major forms of hepatic cytochrome P-450 induced by phenobarbital or 3-methylcholanthrene, whereas cytochrome P-450I is indistinguishable from the former on the basis of physical and catalytic as well as immunochemical characteristics. Pulmonary and hepatic NADPH-cytochrome P-450 reductases also have identical physical, catalytic, and immunochemical properties. The lack of response of the lung monooxygenase system to phenobarbital, therefore, is apparently not due to an inability of the lung to synthesize the enzymes induced by phenobarbital in the liver. The relatively high proportion of cytochrome P-450I in the lung appears to be responsible for the higher rates (per nmol of P-450) of N-demethylation that have been observed in rabbit pulmonary as compared to hepatic microsomal fractions.     

A kinetic study comparing the light-reversal properties of carbon monoxide inhibition of ethylmorphine, benzphetamine, and 7-ethoxycoumarin dealkylation with those of hydroxylation of 17-hydroxyprogesterone and testosterone

The light-reversal properties of carbon monoxide (CO) inhibition of the dealkylation of benzphetamine, ethylmorphine, and 7-ethoxycoumarin by microsomes from phenobarbital (PB)-induced rat livers were compared with those of the 6 beta-, 7 alpha-, and 16 alpha-hydroxylations of testosterone by the same rat hepatic microsomes and C-21 hydroxylation of 17-OH progesterone by steer adrenal microsomes. CO inhibited all reactions studied to essentially the same degree. The significant finding was that the dealkylations were reversed most effectively by light of wavelengths between 440 and 445 nm, rather than around 450 nm, the optimal wavelength for steroid hydroxylations. Moreover, the dealkylations required several-fold higher light intensities for equivalent light reversal. These studies suggest that the heme protein-CO complex responsible for dealkylations has a spectrum corresponding to the shape of the pass band of the 445-nm filter, whereas that of the steroid hydroxylations has its light-reversal maximum at 450 nm and appears to be broader. The measurable differences in the light-reversal properties between the monooxygenations of two groups of substrates, (i) dealkylations and (ii) hydroxylations of lipid substrates, furnish biophysical properties that allow a better characterization of microsomal monooxygenases which should be of value in forwarding progress in the study of these systems.     

Specific inactivation of hepatic fatty acid hydroxylases by acetylenic fatty acids

The terminal acetylenic analogue of lauric acid, 11-dodecynoic acid (11-DDYA), specifically inactivates hepatic cytochrome P-450 enzymes that catalyze omega- and omega-1-hydroxylation of lauric acid. The inactivation, as required for a suicidal process, is NADPH- and time-dependent and follows pseudo-first order kinetics. In contrast, 11-DDYA causes no measurable change in the spectroscopically-measured concentration of cytochrome P-450 or in the N-demethylation of benzphetamine or N-methyl p-chloroaniline. 10-Undecynoic acid is as effective a suicide substrate for fatty acid hydroxylases as 11-DDYA but 11-dodecenoic acid is much less effective. 11-DDYA is able to completely inhibit omega-hydroxylation but suppresses no more than 50% of omega-1-hydroxylation despite the fact that both activities are completely inactivated by 1-aminobenzotriazole. At least three hepatic cytochrome P-450 fatty acid hydroxylases, one omega-hydroxylase and two omega-1-hydroxylases, are required by these results. The construction of suicide substrates that specifically inactivate cytochrome P-450 fatty acid hydroxylases provides a new experimental probe of the physiological role of this process.     

Purification and NH2-terminal sequence of cytochrome P-450 from kidney microsomes of untreated male rats

The major form of cytochrome P-450, P-450K-5, was purified from kidney microsomes of untreated male rats with high-performance liquid chromatography with anion-exchange and hydroxylapatite columns. The monomeric molecular weight of P-450K-5 was 52000 on SDS-polyacrylamide gel electrophoresis and the CO-reduced absorption maximum was at 452 nm. P-450K-5 catalyzed the omega- and (omega-1)-hydroxylation of lauric acid, but was inefficient in the N-demethylation of benzphetamine and the O-dealkylation of 7-ethoxycoumarine. The NH2-terminal sequence of P-450K-5 was quite different from cytochrome P-450s purified from rat hepatic microsomes.