The oxidation of azaheterocycles with mammalian liver aldehyde oxidase

1. Isoquinoline, cinnoline, quinoxaline, quinazoline and phthalazine were incubated with preparations of rabbit liver aldehyde oxidase. 2. The oxidation products, 1-hydroxyisoquinoline, 4-hydroxycinnoline, 2-hydroxy- and 2,3-dihydroxy-quinoxaline, 4-hydroxy- and 2,4-dihydroxy-quinazoline, and 1-hydroxyphthalazine were identified by comparison of their spectral and chromatographic characteristics with those of authentic compounds. 3. Michaelis-Menten constants are reported for the action of the parent heterocycles with aldehyde oxidase. The compounds reported in this study are among the most efficient substrates yet described for rabbit liver aldehyde oxidase. 4. The compounds in 1 above were incubated with bovine milk xanthine oxidase: only quinazoline and phthalazine yielded significant amounts of metabolites. Km values were calculated for these compounds. 5. Incubation of the heterocycles with rat liver preparations gave qualitatively the same results as those obtained using rabbit liver, but smaller amounts of the oxidation products were detected from rat liver incubations.     

Species variation in hepatic aldehyde oxidase activity

The activity of hepatic aldehyde oxidase from rabbit, guinea pig, rat, marmoset, dog, baboon and man was investigated in vitro with charged and uncharged N-heterocyclic substrates: Km and Vmax values were determined for phthalazine, 6,7-dimethoxy-1-[-4-(ethylcarbamoyloxy)piperidino]phthalazine (carbazeran), quinine and quinidine. The oxidation of N-phenylquinolinium chloride to N-phenyl-2-quinolone and N-phenyl-4-quinolone was followed spectrophotometrically. Rat or dog liver showed low and negligible enzyme activity respectively, whereas baboon liver contained a highly active aldehyde oxidase. Enzyme from marmoset and guinea pig liver had the closest spectrum of activity to human liver aldehyde oxidase. Unlike that from man, rabbit hepatic aldehyde oxidase was refractory towards carbazeran and converted N-phenylquinolinium chloride predominantly to the 2-quinolone. N-Phenyl-4-quinolone was the major oxidation product with enzyme from guinea pig, marmoset, baboon and man.     

Oxidation of selected pteridine derivatives by mamalian liver xanthine oxidase and aldehyde oxidase.

Considerable information is available concerning the oxidation of pteridine derivatives by bovine milk xanthine oxidase, but few investigations have been carried out on the oxidation of such compounds by mammalian liver xanthine oxidase and the related aldehyde oxidase. Xanthine oxidase, obtained from rat liver, oxidizes a variety of substituted amino- and hydroxypteridines in a manner identical to that previously observed for milk xanthine oxidase. For example, 2-aminopteridine and its 4- and 7-hydroxy derivatives were oxidized efficiently to 2-amino-4,7-dihydroxypteridine (isoxanthopterin) by the rat liver enzyme, and 4-aminopteridine and its 2- and 7-hydroxy derivatives were oxidized to 4-amino-2,7-dihydroxypteridine.4-Hydroxypteridine and the isomeric 2- and 7-hydroxypteridines were oxidized by rat liver xanthine oxidase to 2,4,7-trihydroxypteridine. Rabbit liver aldehyde oxidase, but not rat liver xanthine oxidase, was able to catalyze the oxidation in position 7 of 2,4-diaminopteridine and its 6-methyl and 6-hydroxymethyl derivatives. 2-Aminopteridine and 4-aminopteridine were both oxidized to the corresponding 7-hydroxy derivatives in the aldehyde oxidase system; 2-amino-4-hydroxypteridine appeared to be a minor product in the oxidation of 2-aminopteridine by rabbit liver aldehyde oxidase. Both aldehyde oxidase and xanthine oxidase were able to catalyze the oxidation of 2-amino-6,7-disubstituted pteridines to the corresponding 4-hydroxy derivatives; 4-hydroxy-6,7-disubstituted pteridines were oxidized in position 2 by both enzymes. 4-Amino-6,7-disubstituted pteridines were not oxidized by either enzyme. 2-Amino-4-methylpteridine was oxidized in position 7 by aldehyde oxidase but was not an effective substrate for xanthine oxidase; 2-hydroxypteridine and 7-hydroxypteridine were not oxidized to a detectably extent by aldehyde oxidase. All oxidations mediated by xanthine oxidase were strongly inhibited by allopurinol (4-hydroxypyrazolo[3,4-d]pyrimidine), and all oxidations mediated by aldehyde oxidase were inhibited by menadione (2-methyl-1,4-naphthoquinone). Rat liver xanthine oxidase and, to a lesser extent, rabbit liver aldehyde oxidase were inhibited by 4-chloro-6,7-dimethylpteridine; 2-amino-3-pyrazinecarboxylic acid inhibited xanthine oxidase but not aldehyde oxidase. The oxidations of 2- and 4-aminopteridines by aldehyde oxidase resulted in concomitant reduction of cytochrome c.     

Substrate specificity of guinea pig liver aldehyde oxidase and bovine milk xanthine oxidase for methyl- and nitrobenzaldehydes.

Both aldehyde oxidase and xanthine oxidase catalyze the oxidation of a wide range of N-heterocycles and aldehydes. These enzymes are important in the oxidation of N-heterocyclic xenobiotics, whereas their role in the oxidation of xenobiotic aldehydes is usually ignored. The present investigation describes the interaction of methyl- and nitrosubstituted benzaldehydes, in the ortho-, meta- and parapositions, with guinea pig liver aldehyde oxidase and bovine milk xanthine oxidase. The kinetic constants showed that most substituted benzaldehydes are excellent substrates of aldehyde oxidase with lower affinities for xanthine oxidase. Low Km values for aldehyde oxidase were observed with most benzaldehydes tested, with 3-nitrobenzaldehyde having the lowest Km value and 3-methylbenzaldehyde being the best substrate in terms of substrate efficiency (Ks). Additionally, low Km values for xanthine oxidase were found with most benzaldehydes tested. However, all benzaldehydes also had low Vmax values, which made them poor substrates of xanthine oxidase. It is therefore possible that aldehyde oxidase may be critical in the oxidation of xenobiotic and endobiotic derived aldehydes and its role in such reactions should not be ignored.     

Hydralazine: a potent inhibitor of aldehyde oxidase activity in vitro and in vivo

The interaction of the vasodilator, hydralazine, with the molybdenum hydroxylases, aldehyde oxidase and xanthine oxidase has been investigated. A potent progressive inhibition of rabbit liver aldehyde oxidase, in the presence of substrate, by low concentrations of hydralazine (0.1-1 microM) was observed in vitro but no effect was seen with bovine milk xanthine oxidase. This activity was mirrored in vivo when levels of aldehyde oxidase were significantly decreased in rabbits administered hydralazine (10 mg/kg/day for seven days) whereas hepatic xanthine oxidase activity was unaltered by hydralazine treatment. Various metabolites of hydralazine were synthesized but found to be devoid of in vitro inhibitory activity. Aldehyde oxidase prepared from either guinea pig or baboon liver was inhibited in a similar way to that of rabbit liver.     

Contribution of aldehyde oxidase, xanthine oxidase, and aldehyde dehydrogenase on the oxidation of aromatic aldehydes

Aliphatic aldehydes have a high affinity toward aldehyde dehydrogenase activity but are relatively poor substrates of aldehyde oxidase and xanthine oxidase. In addition, the oxidation of xenobiotic-derived aromatic aldehydes by the latter enzymes has not been studied to any great extent. The present investigation compares the relative contribution of aldehyde dehydrogenase, aldehyde oxidase, and xanthine oxidase activities in the oxidation of substituted benzaldehydes in separate preparations. The incubation of vanillin, isovanillin, and protocatechuic aldehyde with either guinea pig liver aldehyde oxidase, bovine milk xanthine oxidase, or guinea pig liver aldehyde dehydrogenase demonstrated that the three aldehyde oxidizing enzymes had a complementary substrate specificity. Incubations were also performed with specific inhibitors of each enzyme (isovanillin for aldehyde oxidase, allopurinol for xanthine oxidase, and disulfiram for aldehyde dehydrogenase) to determine the relative contribution of each enzyme in the oxidation of these aldehydes. Under these conditions, vanillin was rapidly oxidized by aldehyde oxidase, isovanillin was predominantly metabolized by aldehyde dehydrogenase activity, and protocatechuic aldehyde was slowly oxidized, possibly by all three enzymes. Thus, aldehyde oxidase activity may be a significant factor in the oxidation of aromatic aldehydes generated from amines and alkyl benzenes during drug metabolism. In addition, this enzyme may also have a role in the catabolism of biogenic amines such as dopamine and noradrenaline where 3-methoxyphenylacetic acids are major metabolites.     

Elevation of molybdenum hydroxylase levels in rabbit liver after ingestion of phthalazine or its hydroxylated metabolite

Oral administration of phthalazine (50 mg/kg/day) or 1-hydroxyphthalazine (10 mg/kg/day) to female rabbits caused an increase in the specific activity of the hepatic molybdenum hydroxylases aldehyde oxidase and xanthine oxidase, whereas no effect on microsomal cytochrome P-450 activity was observed. The rise in the specific activity of purified aldehyde oxidase fractions was accompanied by a similar increase in molybdenum content. A significant lowering of the Km value for phthalazine was demonstrated with enzyme from treated rabbits whereas Km values for structurally similar substrates such as isoquinoline were unchanged from control values. Iso-electric focusing of DEAE-cellulose fractions showed the presence of an additional band of activity indicating that genuine induction of aldehyde oxidase had occurred in rabbits treated with phthalazine or 1-hydroxyphthalazine.     

Role of guinea pig and rabbit hepatic aldehyde oxidase in oxidative in vitro metabolism of cinchona antimalarials.

Cinchona alkaloids (quinine, quinidine, cinchonine, and cinchonidine) were incubated with partially purified aldehyde oxidase from rabbit or guinea pig liver. Reversed-phase HPLC methods were developed to separate the oxidation products from the parent drugs, and the metabolites were identified on the basis of their infrared and mass spectral characteristics. All four alkaloids were oxidized at carbon 2 of the quinoline ring to give the corresponding lactams. In addition, the dihydro contaminants of the cinchona alkaloids were also metabolized by aldehyde oxidase to the 2-quinolone derivatives. Kinetic constants for the oxidation reactions were determined spectrophotometrically and showed that these substrates have a low affinity (KM values of around 10(-5) M) for hepatic aldehyde oxidase, coupled with a relatively low oxidation rate. However, the overall efficiency of the enzyme (Vmax/KM) toward this group of compounds indicates that in vivo biotransformation by aldehyde oxidase will be a significant pathway. Microsomal metabolites were also isolated from quinine and quinidine incubations with rabbit or guinea pig liver fractions. 3-Hydroxyquinine (quinidine) and O-desmethylquinine (quinidine) were identified in microsomal and 10,000g supernatant extracts from quinine and quinidine, respectively. Oxidation of quinine via aldehyde oxidase appeared to be the predominant pathway in rabbit 10,000g fractions, because 2'-quininone was the major metabolite under these conditions with lower concentrations of the microsomal metabolites produced along with a dioxygenated derivative thought to be 3-hydroxy-2'-quininone.     

Diurnal variation and melatonin induction of hepatic molybdenum hydroxylase activity in the guinea-pig

The activities of the xenobiotic metabolizing enzymes, aldehyde oxidase and xanthine oxidase, were determined in partially purified fractions of adult guinea-pig liver at given times in the day or night. A marked circadian variation in aldehyde oxidase activity was observed with several substrates (phthalazine, phenanthridine, N-phenylquinolinium and 3,4-dihydro-4-hydroxy-3-methyl-2-quinazolinone). The main peak occurred at 0300 hr with minimum activity from 1200 to 1800 hr, the differences between rhythmic extremes being statistically significant (P less than 0.005). Xanthine oxidase activity also exhibited a daily rhythm but with a lower amplitude. Guinea-pig serum melatonin showed a synchronous circadian fluctuation with peak values at 0300 hr falling throughout the day to a minimum at 1800 hr. Exogenously administered melatonin caused a significant increase in aldehyde oxidase activity at 0900 and 1200 hr and in xanthine oxidase activity at 0900 hr. It was concluded that melatonin concentrations may be related to the circadian variation in liver molybdenum hydroxylase activity.     

Reaction of 1-amino- and 1-chlorophthalazine with mammalian molybdenum hydroxylases in vitro

1-Amino- and 1-chlorophthalazine were tested for possible substrate activity with partially purified rabbit-liver aldehyde oxidase and bovine-milk xanthine oxidase. 1-Chlorophthalazine was a more efficient substrate than the parent compound, phthalazine, with either aldehyde oxidase or xanthine oxidase. The oxidation product of 1-chlorophthalazine was identified as 4-chloro-1-(2H)-phthalazinone on the basis of chromatographic, infra-red and mass-spectral data. 1-Aminophthalazine was oxidized by aldehyde oxidase to 4-amino-1-(2H)-phthalazinone but was a competitive inhibitor of xanthine oxidase. Kinetic studies at different pH values indicated that, in each case, it is the unprotonated form of 1-aminophthalazine that reacts with the molybdenum hydroxylases.     

Hydroxylation of 4-amino-antifolates by partially purified aldehyde oxidase from rabbit liver

This paper explores the interaction between 4-amino-antifolates and aldehyde oxidase (aldehyde: O2 oxidoreductase, EC 1.2.3.1) that was purified 60- to 120-fold from rabbit liver with yields of 5-15%. The purification procedure consisted of one heat and two ammonium sulfate precipitations followed by chromatography on hydroxylapatite and then Sephacryl S-200. Analysis of initial rates of hydroxylation of methotrexate, aminopterin and dichloromethotrexate indicated an order of affinities of dichloromethotrexate (10 microM) greater than methotrexate (35 microM) greater than aminopterin (272 microM). There was no difference in the Vmax of methotrexate and dichloromethotrexate (248 and 231 nmoles/min/mg protein respectively); aminopterin (130 nmoles/min/mg protein) was less than that of the other two. The Vmax/Km ratios were 24.1, 7.20 and 0.48 for dichloromethotrexate, methotrexate and aminopterin respectively. This enzyme preparation also mediated the hydroxylation of methotrexate polyglutamyl derivatives with a decrease in the rates of hydroxylation, as the total number of glutamyl residues was increased to four, a consequence of a marked increase in Km values and/or decrease in Vmax; the ratios of the Vmax/Km for the di-, tri-, and tetraglutamates were 0.94, 0.31 and 0.21 respectively. This low activity of the polyglutamyl derivatives of methotrexate for aldehyde oxidase is consistent with the observations that the predominant forms of 4-amino-antifolate polyglutamates found in human liver after administration of methotrexate are the polyglutamyl derivatives of the parent compound. Finally, substrate inhibition for methotrexate and dichloromethotrexate was observed at concentrations in excess of 150 and 30 microM, respectively, about 5- and 3-fold higher than their respective Km values. Hence, while dichloromethotrexate had the lowest Km for aldehyde oxidase amongst the 4-amino-antifolates studied, the actual rates of hydroxylation depended upon the concentration employed because of substrate inhibition. Aminopterin was a very poor substrate for this enzyme at low and saturating concentrations. These properties of the hydroxylation of 4-amino-antifolates may be of importance in the design of clinical regimens with these agents--in particular, regimens that employ infusion of these drugs into the hepatic artery. However, the relevance of these observations to the hydroxylation of 4-amino-antifolates by human liver remains to be established.     

Aldehyde oxidase-catalysed oxidation of methotrexate in the liver of guinea-pig, rabbit and man.

Although 7-hydroxymethotrexate is a major metabolite of methotrexate during high-dose therapy, negligible methotrexate-oxidizing activity has been found in-vitro in the liver in man. The goals of this study were to determine the role of aldehyde oxidase in the metabolism of methotrexate to 7-hydroxymethotrexate in the liver and to study the effects of inhibitors and other substrates on the metabolism of methotrexate. Methotrexate, (+/-)-methotrexate and (-)-methotrexate were incubated with partially purified aldehyde oxidase from the liver of rabbit, guinea-pig and man and the products analysed by HPLC. Rabbit liver aldehyde oxidase was used for purposes of comparison. In-vitro aldehyde oxidase from the liver of man catalyses the oxidation of methotrexate to 7-hydroxymethotrexate, but the turnover is low. However, formation of 7-hydroxy-methotrexate from all forms of methotrexate by the liver in guinea-pig and man was significantly inhibited in the presence of 100 microM menadione and chlorpromazine, potent inhibitors of aldehyde oxidase. Allopurinol (100 microM) had a negligible inhibitory effect on liver aldehyde oxidase from guinea-pig and man. Allopurinol is a xanthine oxidase inhibitor. The production of 7-hydroxymethotrexate was enhanced in the presence of allopurinol. Although aldehyde oxidase is also responsible for some of this conversion, it is also possible that the closely related xanthine oxidase is responsible for the formation of 7-hydroxymethotrexate. By employing potent selective inhibitors of aldehyde oxidase, menadione and chlorpromazine, we have demonstrated for the first time that liver aldehyde oxidase from man is minimally involved in methotrexate oxidation.     

Metabolism of isovanillin by aldehyde oxidase, xanthine oxidase, aldehyde dehydrogenase and liver slices

Aromatic aldehydes are good substrates of aldehyde dehydrogenase activity but are relatively poor substrates of aldehyde oxidase and xanthine oxidase. However, the oxidation of xenobiotic-derived aromatic aldehydes by the latter enzymes has not been studied to any great extent. The present investigation compares the relative contribution of aldehyde dehydrogenase, aldehyde oxidase and xanthine oxidase activities in the oxidation of isovanillin in separate preparations and also in freshly prepared and cryopreserved liver slices. The oxidation of isovanillin was also examined in the presence of specific inhibitors of each oxidizing enzyme. Minimal transformation of isovanillin to isovanillic acid was observed in partially purified aldehyde oxidase, which is thought to be due to residual xanthine oxidase activity. Isovanillin was rapidly metabolized to isovanillic acid by high amounts of purified xanthine oxidase, but only low amounts are present in guinea pig liver fraction. Thus the contribution of xanthine oxidase to isovanillin oxidation in guinea pig is very low. In contrast, isovanillin was rapidly catalyzed to isovanillic acid by guinea pig liver aldehyde dehydrogenase activity. The inhibitor studies revealed that isovanillin was predominantly metabolized by aldehyde dehydrogenase activity. The oxidation of xenobiotic-derived aromatic aldehydes with freshly prepared or cryopreserved liver slices has not been previously reported. In freshly prepared liver slices, isovanillin was rapidly converted to isovanillic acid, whereas the conversion was very slow in cryopreserved liver slices due to low aldehyde dehydrogenase activity. The formation of isovanillic acid was not altered by allopurinol, but considerably inhibited by disulfiram. It is therefore concluded that isovanillin is predominantly metabolized by aldehyde dehydrogenase activity, with minimal contribution from either aldehyde oxidase or xanthine oxidase.     

Potent inhibition of human liver aldehyde oxidase by raloxifene.

The selective estrogen receptor modulator, raloxifene, has been demonstrated as a potent uncompetitive inhibitor of human liver aldehyde oxidase-catalyzed oxidation of phthalazine, vanillin, and nicotine-Delta1'(5')-iminium ion, with K(i) values of 0.87 to 1.4 nM. Inhibition was not time-dependent. Raloxifene has also been shown to be a noncompetitive inhibitor of an aldehyde oxidase-catalyzed reduction reaction of a hydroxamic acid-containing compound, with a K(i) of 51 nM. However, raloxifene had only small effects on xanthine oxidase, an enzyme related to aldehyde oxidase. In addition, several other compounds of the same therapeutic class as raloxifene were examined for their potential to inhibit aldehyde oxidase. However, none were as potent as raloxifene, since IC(50) values were orders of magnitude higher and ranged from 0.29 to 57 micro M. In an examination of analogs of raloxifene, it was shown that the bisphenol structure with a hydrophobic group on the 3-position of the benzthiophene ring system was the most important element that imparts inhibitory potency. The relevance of these data to the mechanistic understanding of aldehyde oxidase catalysis, as well as to the potential for raloxifene to cause drug interactions with agents for which aldehyde oxidase-mediated metabolism is important, such as zaleplon or famciclovir, is discussed.     

Similarity in the aldehyde oxidases from guinea-pig liver and polymorphonuclear leucocytes

Partially purified enzyme from guinea-pig leucocytes has been shown to have properties similar to both guinea-pig and rabbit liver aldehyde oxidase. The presence of molybdenum in the leucocyte enzyme has been demonstrated and substrate oxidation by either guinea-pig enzyme was found to be completely inhibited by menadione, a potent inhibitor of rabbit liver aldehyde oxidase. The leucocyte enzyme resembles the guinea-pig liver enzyme in terms of substrate specificity but there is considerable variation in substrate oxidation rates between the two species.     

Metabolism of 2-phenylethylamine and phenylacetaldehyde by precision-cut guinea pig fresh liver slices.

2-Phenylethylamine is an endogenous constituent of human brain and is implicated in cerebral transmission. It is also found in certain foodstuffs and may cause toxic side-effects in susceptible individuals. Metabolism of 2-phenylethylamine to phenylacetaldehyde is catalyzed by monoamine oxidase and the oxidation of the reactive aldehyde to its acid derivative is catalyzed mainly by aldehyde dehydrogenase and perhaps aldehyde oxidase, with xanthine oxidase having minimal transformation. The present investigation examines the metabolism of 2-phenylethylamine to phenylacetaldehyde in liver slices and compares the relative contribution of aldehyde oxidase, xanthine oxidase and aldehyde dehydrogenase activity in the oxidation of phenylacetaldehyde with precision-cut fresh liver slices in the presence/absence of specific inhibitors of each enzyme. In liver slices, phenylacetaldehyde was rapidly converted to phenylacetic acid. Phenylacetic acid was the main metabolite of 2-phenylethylamine, via the intermediate phenylacetaldehyde. Phenylacetic acid formation was completely inhibited by disulfiram (specific inhibitor of aldehyde dehydrogenase), whereas isovanillin (specific inhibitor of aldehyde oxidase) inhibited acid formation to a lesser extent and allopurinol (specific inhibitor of xanthine oxidase) had little or no effect. Therefore, in liver slices, phenylacetaldehyde is rapidly oxidized by aldehyde dehydrogenase and aldehyde oxidase with little or no contribution from xanthine oxidase.     

Specificity of amine oxidase for optically active substrates and inhibitors

A number of optically active amines have been tested as substrates or inhibitors of amine oxidase of rabbit and guinea-pig liver. The two stereoisomers of β-hydroxyphenethylamine were oxidized at the same rate by rabbit liver, but the guinea-pig liver extracts oxidized the D form more rapidly than the L form. The two stereoisomers of amphetamine were equally active as inhibitors of the rabbit liver oxidase, but with guinea-pig liver extracts dexamphetamine, the (+) form, was more potent as an inhibitor. In both species, 2-hydroxy-1-phenylethylamine was a weaker inhibitor than 1-phenylethylamine; in the rabbit liver (+) forms of these two amines were more potent as inhibitors.     

Metabolism of 2-phenylethylamine to phenylacetic acid, via the intermediate phenylacetaldehyde, by freshly prepared and cryopreserved guinea pig liver slices

BACKGROUND: 2-Phenylethylamine is an endogenous amine, which acts as a neuromodulator of dopaminergic responses. Exogenous 2-phenylethylamine is found in certain foodstuffs and may cause toxic side-effects in susceptible individuals. MATERIALS AND METHODS: The present investigation examined the metabolism of 2-phenylethylamine to phenylacetic acid, via phenylacetaldehyde, in freshly prepared and cryopreserved liver slices. Additionally, it compared the relative contribution of aldehyde oxidase, xanthine oxidase and aldehyde dehydrogenase by using specific inhibitors for each oxidizing enzyme. RESULTS: In freshly prepared and cryopreserved liver slices, phenylacetic acid was the main metabolite of 2-phenylethalamine. In freshly prepared liver slices, phenylacetic acid was completely inhibited by disulfiram (inhibitor of aldehyde dehydrogenase), whereas isovanillin (inhibitor of aldehyde oxidase) inhibited acid formation to a lesser extent and allopurinol (inhibitor of xanthine oxidase) had no effect. In cryopreserved liver slices, isovanillin inhibited phenylacetic acid by 85%, whereas disulfiram inhibited acid formation to a lesser extent and allopurinol had no effect. CONCLUSION: In liver slices, 2-phenylethylamine is rapidly oxidized to phenylacetic acid, via phenylacetaldehyde, by aldehyde dehydrogenase and aldehyde oxidase with no contribution from xanthine oxidase.     

Metabolism of cyclosporin A. II. Implication of the macrolide antibiotic inducible cytochrome P-450 3c from rabbit liver microsomes

The in vitro metabolism of cyclosporin A (CsA) was investigated by rabbit liver microsomes in order to identify the form(s) of cytochrome P-450 responsible for its biotransformation. Metabolites including monohydroxy-, N-demethylated, dihydroxy- and dihydroxy-N-demethylated derivatives were detected and quantified by HPLC from incubates of liver microsomes, CsA, and NADPH. Kinetic data indicated that monohydroxy- and N-demethylated derivatives were first generated and then served as substrates for production of dihydroxylated derivatives. Liver microsomes from phenobarbital-, beta-naphthoflavone-, triacetyloleandomycin-, erythromycin-, or rifampicin-treated and untreated rabbits were investigated, but only microsomes from animals treated with macrolide antibiotics (specific inducers of form P-450 3c) exhibited a type I binding spectrum upon CsA addition (Ks = 1.5 +/- 0.5 microM) and extensively metabolized the drug to all groups of derivatives (Km = 5.0 +/- 0.5 microM, Vmax = 1.0 +/- 0.2 nmol/mg/min). A linear correlation existed between CsA oxidase activity and P-450 3c specific content. Antibodies to P-450 3c strongly inhibited CsA oxidase activity of microsomes from macrolide antibiotic-induced animals, whereas antibodies to other forms, including P-450 2, 3b, 4, and 6, did not. When highly purified forms of P-450, including P-450 2, 3b, 3c, and 4, were assayed in a reconstituted system, only P-450 3c exhibited type I binding spectrum upon CsA addition (Ks = 1.4 +/- 0.5 microM) and extensively metabolized the drug to all derivatives. We conclude that the macrolide antibiotic-inducible form P-450 3c (or P-450 3c related from(s)) is responsible for the major part of CsA metabolism by rabbit liver microsomes.     

Oxidation of pteridine derivatives in mice

Studies were carried out of the metabolism of a variety of hydroxy-, mercapto- and amino-pteridines following i.p. injection (150 $\text{mg}\text{kg}$) into mice. Urinary oxidation products were isolated and identified by a combination of thin-layer chromatographic and spectrophotometric techniques. Pteridine and its 2- and 4-hydroxy derivatives as well as 2,4-dihydroxypteridine (lumazine) were converted extensively to 2,4,7-trihydroxypteridine. When mice were treated with the xanthine oxidase inhibitor allopurinol (20 $\text{mg}\text{kg}$), formation of 2,4,7-trihydroxypteridine was sharply reduced (to about 25 per cent of its control value). Lumazine was detected in the urine of allopurinol-treated mice which received pteridine, 2-hydroxypteridine and 4-hydroxypteridine. Observations of hydroxypteridine oxidation in the absence and presence of allopurinol suggest that both xanthine oxidase and aldehyde oxidase can play a role in pteridine oxidation, in vivo. The administration of 2-aminopteridine to mice caused severe kidney toxicity, apparently attributable to the crystallization of highly insoluble oxidation products of this pteridine within the lumen of renal tubules. 4-Aminopteridine did not show such a nephrotoxic effect, but was extensively oxidized in vivo to 4-amino-2,7-dihydroxypteridine. Lumazine was found to be a major metabolic product when both 4-aminopteridine and allopurinol were administered. The formation of lumazine from 4-aminopteridine may involve the intermediate formation of 4-hydroxypteridine catalyzed by adenosine deaminase. 2-Mercapto and 4-mercaptopteridines were oxidized in vivo to compounds tentatively identified as the 4,7- and 2,7-dihydroxy derivatives, respectively. An additional compound, possibly resulting from cleavage of the pteridine ring, was detected in the urine of mice treated with 4-mercaptopteridine and allopurinol. A crude xanthine oxidase preparation from mouse liver was able to catalyze the oxidation of a number of pteridines previously found to be substrates for milk or rat liver xanthine oxidase. Catalytic constants (K_m and V_max) using this mouse liver xanthine oxidase preparation were estimated for a number of pteridines. The patterns of substrate oxidation in such studies in vitro are consistent generally with those obtained following the i.p. administration of a number of pteridines to mice.