ON THE MECHANISM OF DRUG HYDROXYLATION IN RAT LIVER MICROSOMES

The TPNH- and O₂-dependent drug hydroxylation system of liver microsomes has been studied using normal rats and rats in which the drug-hydroxylating activity has been enhanced by repeated injections of phenobarbital. The oxidative demethylation of aminopyrine is employed as an assay. Optimal conditions for the assay with regard to the concentrations of TPNH and aminopyrine are established. TPN inhibits the reaction in a competitive manner, similarly to its effect on the microsomal TPNH-cytochrome c reductase. Drug hydroxylation, but not the "TPNH oxidase," TPNH-cytochrome c, -2,6-dichlorophenolindophenol, or -neotetrazolium reductase reaction, or the TPNH-dependent lipid peroxidation, is blocked by carbon monoxide. Microsomes from phenobarbital-treated rats exhibit increased activities of the various TPNH-linked reductase reactions, parallel to the increased drug hydroxylation activity, whereas the "TPNH oxidase" activity does not change appreciably. Measurements with microsomes from drug-treated animals reveal a 1:1:1 stoichiometry of aminopyrine-dependent oxygen uptake, TPNH oxidation, and formaldehyde formation. Attempts to solubilize the drug-hydroxylating enzyme system are also presented. It is concluded that the drug-hydroxylating enzyme system involves the microsomal TPNH-cytochrome c reductase and CO-binding pigment, and a hypothetic reaction scheme accounting for the data presented is proposed.     

The cytochemical localization of oxidative enzymes. I. Diphosphopyridine nucleotide diaphorase and triphosphopyridine nucleotide diaphorase

Cytochemical methods involving metal chelation of the formazan of an N-thiazol-2-yl tetrazolium salt are described for the localization of diphosphopyridine nucleotide diaphorase (DPND) and triphosphopyridine nucleotide diaphorase (TPND) in mitochondria. These methods utilize the reduced coenzymes DPNH or TPNH as substrate. The reaction involves a direct transfer of electrons from reduced coenzyme to the respective diaphorase which in turn transfers the electrons to tetrazolium salt, reducing it to the insoluble formazan. Competition for electrons by preferential acceptors in the respiratory chain was prevented by various inhibitors. In the presence of respiratory inhibitors the rate of tetrazolium reduction was markedly increased. The greatest reduction was observed when amytal was used. Sites of diaphorase activity appeared as deposits of blue-black metal formazan chelate measuring 0.2 to 0.3 micro in diameter. Small mitochondria contained 2 deposits, while larger ones contained up to 6. Considerable differences were observed in the rate of tetrazolium reduction and cellular localization of diaphorase activity when DPNH was used as substrate as compared to TPNH. In each instance DPNH was oxidized more rapidly by tissues than TPNH. These findings support the concept that the oxidation of coenzymes I and II is mediated through separate diaphorases.     

Properties of the System for the Mixed Function Oxidation of Kaurene and Kaurene Derivatives in Microsomes of the Immature Seed of Marah macrocarpus: Cofactor Requirements

The rates of oxidation of ent-kaur-16-ene to ent-kaur-16-en-19-ol, ent-kaur-16-en-19-al, ent-kaur-16-en-19-oic acid, and ent-kaur-16-en-7alpha-ol-19-oic acid are maximal in microsomes prepared from the endosperm of immature Marah macrocarpus seeds in which the cotyledons are approximately one-half the overall length of the seed. The supernatant fraction remaining from the preparation of the microsomes contains factors which stimulate the rates of oxidation catalyzed by the microsomes. Added TPNH is more effective than added DPNH in meeting the requirement for reduced pyridine nucleotide. A mixture of DPNH, ATP, and TPN(+) is much more effective than DPNH alone. Experiments with 2,4-dinitrophenol as a selective inhibitor indicate that the ATP-stimulated synthesis of TPNH which occurs in these microsomes in the presence of this mixture of coenzymes provide TPNH for use in the mixed function oxidations. Relatively low concentrations of DPNH and TPNH together are much more effective than either alone at equivalent concentration. This is consistent with the involvement of two pathways of electron transfer associated with the mixed function oxidations, one of which preferentially utilizes TPNH and the other favoring DPNH. FAD added to microsomes at an optimal concentration of about 10 mum in the presence of TPNH stimulates the rate of the oxidations; higher concentrations are inhibitory. FMN by itself does not produce this stimulation. However, FMN and FAD added together at low concentrations (0.5 mum each) have approximately the same effectiveness as FAD alone at 10 mum. This suggests a role for both flavin nucleotides in the normal electron transfer pathways associated with these oxidations. Some of the stimulatory properties of the supernatant fraction may be accounted for by its content of reduced pyridine nucleotides, FAD, and FMN; the concentrations of FAD and FMN were determined to be 1.1 mum and 0.4 mum, respectively. However, the effects of the supernatant fraction are not completely explained by its content of these coenzymes since other experiments indicate the presence of a heat-labile, nondialyzable stimulatory factor(s) in the supernatant fraction in addition to heat-stable, dialyzable fractors.     

Oxidation of reduced triphosphopyridine nucleotide by submitochondrial particles from beef heart

Submitochondrial particles prepared from beef heart are capable of oxidizing TPNH, in the absence of added DPN, at a rate of approximately 50 nmoles/min × mg protein at 30°. TPNH oxidation by these particles occurs through the respiratory chain as evidenced from TPNH-induced reduction of the cytochromes and the inhibitory effects of rotenone, piericidin A, amytal, antimycin A and cyanide. The latter studies have indicated that the site of TPNH interaction with the respiratory chain is on the substrate side of the rotenone-piericidin block and close to that of DPNH.     

The Cytochemical Localization of Oxidative Enzymes : I. Diphosphopyridine Nucleotide Diaphorase and Triphosphopyridine Nucleotide Diaphorase

Cytochemical methods involving metal chelation of the formazan of an N-thiazol-2-yl tetrazolium salt are described for the localization of diphosphopyridine nucleotide diaphorase (DPND) and triphosphopyridine nucleotide diaphorase (TPND) in mitochondria. These methods utilize the reduced coenzymes DPNH or TPNH as substrate. The reaction involves a direct transfer of electrons from reduced coenzyme to the respective diaphorase which in turn transfers the electrons to tetrazolium salt, reducing it to the insoluble formazan. Competition for electrons by preferential acceptors in the respiratory chain was prevented by various inhibitors. In the presence of respiratory inhibitors the rate of tetrazolium reduction was markedly increased. The greatest reduction was observed when amytal was used. Sites of diaphorase activity appeared as deposits of blue-black metal formazan chelate measuring 0.2 to 0.3 µ in diameter. Small mitochondria contained 2 deposits, while larger ones contained up to 6. Considerable differences were observed in the rate of tetrazolium reduction and cellular localization of diaphorase activity when DPNH was used as substrate as compared to TPNH. In each instance DPNH was oxidized more rapidly by tissues than TPNH. These findings support the concept that the oxidation of coenzymes I and II is mediated through separate diaphorases.     

PYRIDINE NUCLEOTIDE-LINKED REACTIONS OF PSEUDOMONAS NATRIEGENS.

Eagon, R. G. (University of Georgia, Athens). Pyridine nucleotide-linked reactions of Pseudomonas natriegens. J. Bacteriol. 84:819-821. 1962-The observation that Pseudomonas natriegens utilizes the Embden-Meyerhof pathway and the hexose monophosphate-pentose cycle only very slightly, even though the necessary enzymes are present, was explained by the existence of a sluggish system for the oxidation of reduced triphosphopyridine nucleotide (TPNH). Pyridine nucleotide transhydrogenase could not be detected in cell-free extracts. A very active system for the oxidation of reduced diphosphopyridine nucleotide (DPNH) was observed. Thus, since lactic acid is a major end product of glucose dissimilation and since the lactic dehydrogenase of P. natriegens does not utilize DPNH as cofactor, the Embden-Meyerhof pathway apparently operates aerobically by direct oxidation of DPNH, presumably by coupling with the terminal oxidase system rather than by coupling to synthetic reactions requiring DPNH as cofactor. A TPNH-specific glutathione reductase was detected which was inhibited by adenosine-2'-monophosphate.     

Solubilization and partial purification of heme oxygenase from rat liver.

Hepatic microsomal heme oxygenase was solubilized, partially purified, and characterized from Co2+-treated rats. The enzyme on sodium dodecyl sulfate-polyacrylamide gel electrophoresis exhibited a minimum molecular weight of greater than or equal to 68,000. The solubilized enzyme was totally devoid of contamination with cytochrome P-450 or b5. The requirement for reduced pyridine nucleotides was absolute, and ascorbate could not support heme oxidative activity. However, both TPNH and DPNH could serve as electron donors, with TPNH being more effective. The presence of an appropriate flavoprotein reductase was essential for heme oxidation. The enzyme had an apparent Km of 40 micrometer, a pH optimum of 7.5, and lost substantial activity upon freezing and thawing. Methemoglobin was 30% as effective a substrate for the enzyme as was heme. Free porphyrins could not serve as substrates for the enzyme. The activity of the enzyme was inhibited by HgCl2, p-chloromercuribenzoate, iodoacetamide, mercaptoethanol, and dithiothrietol indicating that free -SH group(s) is necessary for enzyme activity.     

Affinity labeling of a regulatory site of bovine liver glutamate dehydrogenase.

A new adenosine analog, 3'-p-fluorosulfonyl-benzoyladenosine (3'-FSBA), has been synthesized which reacts covalently with bovine liver glutamate dehydrogenase. Native glutamate dehydrogenase is activated by ADP and inhibited by high concentrations of DPNH. Both of these effects are irreversibly decreased upon incubation of the enzyme with the adenosine analog, 3'-p-fluorosulfonyl-benzoyladenosine (3'-FSBA), while the intrinsic enzymatic activity as measured in the absence of regulatory compounds remains unaltered. A plot of the rate constant for modification as a function of the 3'-FSBA concentration is not linear, suggesting that the adenosine derivative binds to the enzyme (Ki equals 1.0 times 10-4 M) prior to the irreversible modification. Protection against modification by 3'-FSBA is provided by ADP and by high concentrations of DPNH, but not by the inhibitor GTP, the substrate alpha-keto glutarate, the coenzyme TPNH, or low concentrations of the coenzyme DPNH. The isolated altered enzyme contains approximately 1 mol of sulfonylbenzoyladenosine per peptide chain, indicating that a single specific regulatory site has reacted with 3'-tfsba. the modified enzyme exhibits normal Michaelis constants for its substrates and is still inhibited by GTP, albeit at a higher concentration, but it is not inhibited by high concentrations of DPNH. Although ADP does not appreciably activate the modified enzyme, it does (as in the case of the native enzyme) overcome the inhibition of the modified enzyme by GTP. These results suggest that ADP can bind to the modified enzyme, but that its ability to activate is affected indirectly by the modification of the adjacent tdpnh inhibitory site. It is proposed that the regulatory sites for ADP and DPNH are partially overlapping and that 3'FSBA functions as a specific affinity label for the DPNH inhibitory site of glutamate dehydrogenase. It is anticipated that 3'-p-fluorosulfonylbenzolyadenosine may act as an affinity label of other dehydrogenases as well as of other classes of enzymes which use adenine nucleotides as substrates or regulators.     

Affinity labeling of the reduced diphosphopyridine nucleotide inhibitory site of glutamate dehydrogenase by 6-[(4-bromo-2,3-dioxobutyl)thio]-6-deaminoadenosine 5'-diphosphate

Bovine liver glutamate dehydrogenase reacts covalently with the new adenosine analogue 6-[(4-bromo-2,3-dioxobutyl)thio]-6-deaminoadenosine 5'-diphosphate with incorporation of about 1 mol of reagent/mol of enzyme subunit. Modified enzyme completely loses its normal ability to be inhibited by high concentrations of reduced diphosphopyridine nucleotide (DPNH) (greater than 100 microM), which binds at a regulatory site distinct from the catalytic site; however, the modified enzyme retains its full activity when assayed at 100 microM DPNH in the absence of allosteric compounds. The enzyme is still activated by ADP, is inhibited by GTP (albeit at higher concentrations), and binds 1.5-2 mol of [14C]GTP/subunit. A plot of initial velocity vs. DPNH concentration for the modified enzyme, in contrast to the native enzyme, followed Michaelis-Menten kinetics. The rate constant (k) for loss of DPNH inhibition (as measured at 0.6 mM DPNH) exhibits a nonlinear dependence on reagent concentration, suggesting a reversible binding of reagent (Kd = 0.19 mM) prior to irreversible modification. At 0.1 mM 6-[(4-bromo-2,3-dioxobutyl)thio]-6-deaminoadenosine 5'-diphosphate, k = 0.036 min-1 and is not affected by alpha-ketoglutarate, 100 microM DPNH, or GTP alone but is decreased to 0.0094 min-1 by 5 mM DPNH and essentially to zero by 5 mM DPNH plus 100 microM GTP. Incorporation after incubation with 0.25 mM 6-[(4-bromo-2,3-dioxobutyl)thio]-6-deaminoadenosine 5'-diphosphate for 2 h at pH 7.1 is 1.14 mol/mol of subunit in the absence but only 0.24 mol/mol of subunit in the presence of DPNH plus GTP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reduced diphosphopyridine nucleotide peroxidase. Intermediates formed on reduction of the enzyme with dithionite or reduced diphosphopyridine nucleotide.

DPNH peroxidase is a flavin adenine dinucleotide-containing flavoprotein. Anaerobic titration of enzyme with dithionite has shown that the active site of the enzyme contains 2 mol of flavin and in addition 1 mol of a non-flavin electron acceptor that is tentatively identified as a disulfide group. Thus complete reduction of the enzyme requires 3 mol of dithionite per mole of active site. The first mole of dithionite reduces the non-flavin acceptor; complex formation between the reduced acceptor and one of the bound flavin molecules causes the formation of a long wavelength absorption band between 500 and 670 nm. The second mole of dithionite reduces the flavin that interacts with the reduced non-flavin group, and the long wavelength band disappears. The third mole of dithionite reduces the second mole of flavin. All groups are reoxidized in the presence of air. DPNH reacts with only two of the enzyme-bound electron acceptors. The first mole of DPNH reduces the non-flavin group to form an intermediate (I) that is almost identical with that formed by dithionite. The second mole of DPNH complexes with the second flavin of Intermediate I to form Intermediate II. This reaction causes a further absorbance increase in the long wavelength region; the tail of the absorption band now extends to 960 nm. The titration data (potassium phosphate, 0.05 M, pH 7.0) can be fitted with dissociation constants of 1 times 10-7 M for the formation of I, and 3 times 10-6 M for the conversion of I to II. In air, species II is oxidized to I; I is stable in air, but is oxidized stoichiometrically to oxidized enzyme by H2O2. Present evidence suggests that bound DPN-plus is responsible for the air stability of species I. Intermediate I, but not oxidized enzyme, reacts slowly with phenylmercuric acetate. This reaction causes loss of the air-stable intermediate and parallel loss in enzyme activity. The inactive enzyme cannot be reduced by DPNH to Species I; DPNH can, however, still react with the second flavin to form the autoxidizable complex. With other methods of enzyme inactivation there is also a direct correlation between residual enzyme activity and the ability of enzyme to form the air-stable intermediate. It is concluded that the air-stable intermediate is an important catalytic species.     

The relative participation of liver microsomal amine oxidase and cytochrome P-450 in N-demethylation reactions.

N-Demethylation of benzphetamine and p-chloro-N-methylaniline measured in the presence and absence of specific antibodies to NADPH-cytochrome c (P-450) reductase demonstrates that part of the formaldehyde formed from the sec-N-methylamine arises from non-cytochrome P-450-dependent oxidation catalyzed by pig, hamster, and rat liver microsomes. The additional formaldehyde formed can be inhibited by adding methimazole, a non-formaldehyde-producing substrate specific for the microsomal mixed-function amine oxidase, to the reaction media. Purified amine oxidase catalyzes the oxidation of sec-N-methylamines to sec-N-methylhydroxylamines that, upon oxidation and hydrolysis, yield formaldehyde. Approximately 65, 40, and 15% of total formaldehyde is formed by this route during oxidation of p-chloro-N-methylaniline catalyzed by pig, hamster, and rat liver microsomes, respectively.     

The formation of aminopyrine cation radical by the peroxidase activity of prostaglandin H synthase and subsequent reactions of the radical

The oxidation of aminopyrine to an aminopyrine cation radical was investigated using a solubilized microsomal preparation or prostaglandin H synthase purified from ram seminal vesicles. Aminopyrine was oxidized to an aminopyrine cation radical in the presence of arachidonic acid, hydrogen peroxide, t-butyl hydroperoxide or 15-hydroperoxyarachidonic acid. Highly purified prostaglandin H synthase, which processes both cyclo-oxygenase and hydroperoxidase activity, oxidized aminopyrine to the free radical. Purified prostaglandin H synthase reconstituted with Mn2+ protoporphyrin IX, which processes only cyclo-oxygenase activity, did not catalyze the formation of the aminopyrine free radical. Aminopyrine stimulated the reduction of 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid to 15-hydroxy-5,8,11-13-eicosatetraenoic acid. Approximately 1 molecule of 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid was reduced for every 2 molecules of aminopyrine free radical formed, giving a stoichiometry of 1:2. The decay of the aminopyrine radical obeyed second-order kinetics. These results support the proposed mechanism in which aminopyrine is oxidized by prostaglandin H synthase hydroperoxidase to the aminopyrine free radical, which then disproportionates to the iminium cation. The iminium cation is further hydrolyzed to the demethylated amine and formaldehyde. Glutathione reduced the aminopyrine radical to aminopyrine with the concomitant oxidation of GSH to its thiyl radical as detected by ESR of the glutathione thiyl radical adduct.     

Cimetidine and ranitidine: comparison of effects on hepatic drug metabolism.

Paired studies of hepatic microsomal function were conducted in eight subjects during treatment with two histamine H2 antagonists, cimetidine and ranitidine. Cimetidine but not ranitidine inhibited the metabolism of antipyrine (phenazone) and demethylation of aminopyrine (aminophenazone) as measured by breath 14CO2 production after intravenous injection of 14C-aminopyrine. These results suggest that the metabolic inhibitory actions on the liver may be separated from H2 antagonist effects, and that ranitidine has an advantage over cimetidine by not inhibiting microsomal drug oxidative function.     

Influence of substrates and coenzymes on the role of manganous ion in reactions catalyzed by pig heart triphosphopyridine nucleotide-dependent isocitrate dehydrogenase.

The interaction of manganous ions with pig heart triphosphopyridine nucleotide (TPN) specific isocitrate dehydrogenase has been studied by kinetic experiments and by direct ultrafiltration measurements of manganous ion binding. At low metal ion concentrations, a lag is observed in the time-dependent production of reduced triphosphopyridine nucleotide (TPNH) that can be eliminated by adding 20 muM TPNH to the initial reaction mixture. A plot of 1/upsilon vs. 1/ (Mn2+) obtained at relatively high TPNH concentrations (20 muM) is linear and yields of Km value of 2 muM for metal ion, which is comparable to the direct binding constant measured in the presence of isocitrate. A similar plot at low TPNH concentrations (2 muM) reveals a biphasic relationship: at high metal concentrations the points are collinear with those obtained at high levels of TPNH, but at low metal concentrations that line is characterized by a Km of 19 muM for Mn2+. A difference in the deuterium oxide solvent isotope effect on Vmax observed with 20 muM TPNH as compared with 2 muM TPNH suggests that at high TPNH concentrations or high manganous ion concentrations the rate-limiting step is the dehydrogenation of isocitrate, while at low manganous ion concentrations and low TPNH concentrations, the slow step is the decarboxylation of enzyme-bound oxalosuccinate. Evidence to support this hypothesis is provided by the sensitivity to isocitrate concentration of the Km for total manganese measured in the presence of 20 muM TPNH that contrasts with the relative insensitivity to isocitrate of the Km measured at 2 muM TPNH and low manganous ion concentration. Direct measurements of oxalosuccinate decarboxylation reveal that the Vmax and the Km for manganous ion are influenced by the presence of oxidized or reduced TPN with the Km being lowest (5-7 muM) in the presence of TPNH. The dependence of the Km for manganous ion on the presence of substrate, TPN, and TPNH, is responsible for the variation with conditions in the rate-determining step. The enzyme binds only 1 mol of metal ion and 1 mol of isocitrate/mol of protein under all conditions. The pH dependence of the binding of free manganous ion, free isocitrate, and manganous-isocitrate complex indicates differences in the interaction of these species with isocitrate dehydrogenase. These results can be described in terms of two functions for manganous ion in the reactions catalyzed by isocitrate dehydrogenase, each of which requires a distinct binding site for metal ion: in the dehydrogenation step, Mn2+ facilitates the binding of the substrate isocitrate, and in the decarboxylation step it may stabilize the enolate of alpha-ketoglutarate which is generated.     

Enzymic method for the quantitative determination of reduced glutathione

A new specific and sensitive assay method for reduced glutathione has been developed. It is based on the reaction HCHO + NAD⁺ + H₂O → HCOOH + NADH + H⁺, catalyzed by formaldehyde dehydrogenase (formaldehyde: NAD oxidoreductase, EC.1.2.1.1) in the presence of reduced glutathione. Oxidized glutathione and other thiols do not interfere in this reaction. A purification procedure for formaldehyde dehydrogenase from beef liver is presented.The influence of cysteine and some other thiols, leucine, ascorbate, lactate, pyruvate and four acids generally used for deproteinization is reported. The results obtained by this method from human blood and rat tissues are compared with those obtained by Ellman's method.     

The dependence on vitamin E and selenium of drug demethylation in rat liver microsomal fractions.

1. The effects of vitamin E deficiency, and of vitamin E and selenium deficiency, on rat liver microsomal aminopyrine demethylase activity were investigated. It was found that, over a wide range of substrate concentrations, the enzyme activity in preparations from deficient animals was significantly lower than that in controls. 2. Addition of antioxidants in vitro, either to the homogenization or to the assay media, was without significant effect on the depressed enzyme activity. Castration and alteration in dietary protein concentration were also without effect. The rate of oxidation of NADPH was however, lower in preparations from deficient animals. 3. Lineweaver-Burk plots of the reciprocal of enzyme activity and substrate concentration showed a higher Km value in preparations from vitamin E-deficient animals, irrespective of whether selenium was present; the Vmax. was unaffected. These parameters were unchanged when antioxidants were added in vitro. Induction with phenobarbitone and 3-methylcholanthrene showed large changes in Km value which, for preparations from vitamin E-deficient animals, was higher than that for corresponding controls. 4. Examination of the synergism between NADH and NADPH as donors of reducing equivalents for aminopyrine demethylation showed that vitamin E and selenium were only minimally involved in the phenomenon. However, both the initial rate and the extent of demethylation were significantly lower in vitamin E- and selenium-deficient preparations and both nutrients were required for the restoration of full activity. 5. The significance of these results is discussed in the light of our working hypothesis.     

A microsomal ATP-activated pyridine nucleotide transhydrogenase

An ATP-activated transhydrogenase which catalyzes the reduction of TPN⁺ by DPNH has been demonstrated in the microsomal fraction from the endosperm of immature Echinocystis macrocarpa seeds. The activity is specifically dependent on the presence of ATP (K_m of approximately 0.1 mm) of several nucleotides tested. The reaction is stimulated by MgCl₂ addition up to concentrations of 6 mm. When 10^?2m EDTA is added to the assay mixture in the absence of added MgCl₂, a transhydrogenation reaction is observed which no longer shows any dependence on added ATP. A TPN⁺-dependent ATPase activity can be demonstrated in these preparations, but no fixed stoichiometry between ATP cleavage and TPNH formation could be established. A lag in attaining the maximal rate of transhydrogenation is seen unless the enzyme is preincubated for 10 min with ATP before initiating the reaction. It can further be shown that preincubation of the enzyme with ATP followed by removal of the ATP on a Dowex 1 column produces an enzyme capable of catalyzing the transhydrogenation without the further addition of ATP. 2,4-Dinitrophenol and thyroxin are effective inhibitors of the transhydrogenase and 2,4-dinitrophenol was shown to inhibit the activating effect of ATP during the preincubation period. It is concluded that the role of ATP is in the modification of the enzyme rather than direct participation in the transhydrogenation. The transhydrogenase is inhibited by ADP and AMP. This results in a response of the enzyme to adenylate energy charge in a manner characteristic for regulatory enzymes which participate in ATP-utilizing metabolic sequences.     

Application of isotopic ratio mass spectrometry for the in vitro determination of demethylation activity in human liver microsomes using N-methyl-13C-labeled substrates

The reaction of demethylation mediated by cytochrome P450 (CYP) leads to the equimolar production of demethylated metabolite and formaldehyde. From a 13C-substrate labeled on a carbon of the methyl moiety, [13C]formaldehyde (H13CHO) is liberated. A highly sensitive and specific assay involving the oxidation of H13CHO to 13CO(2) by a double-enzymatic-step reaction is reported. The 13CO(2) was quantified by the method of reverse isotopic dilution based on gas chromatography-isotope ratio mass spectrometry analysis. The method first involves the limiting step of the CYP-dependent reaction, which is stopped with a mixture of zinc sulfate 5 mM and trichloroacetic acid 100 mM. Then, the transformation of H13CHO to 13CO(2) is performed with the formaldehyde (0.2 unit) and the formate (0.2 unit) dehydrogenase NAD-dependent enzymes. The recovery of 13CO(2) from the incubation mixture was equal to 91.4 +/- 3.0%. The accuracy and the precision of the present method were within 12 and 10%, respectively. The limit of quantification was set to 25 pmol. The performance of the assay was validated on human liver microsomes with five probes: [13C]erythromycin, [1-13C]caffeine, [3-13C]caffeine, [7-13C]caffeine, and [13C(2)]aminopyrine. This method is useful for the rapid determination of N-demethylase activity of human liver microsomes from methyl-13C-substrates.     

On the inhibition of microsomal drug metabolism by polychlorinated biphenyls (PCB) and related phenolic compounds.

The in vitro metabolism of p-nitroanisole, aminopyrine, and aniline by rat liver microsomal monoxygenases were studied in the presence of different polychlorinated biphenyl (PCB) mixtures and some related hydroxybiphenyls. The tested PCB mixtures contained preferably dichloro- (di-CB), tetrachloro- (tetra-CB), or hexachlorobiphenyls (hexa-CB). All PCB were competitive inhibitors of only aminopyrine demethylation by normal microsomes (Ki 22-39 micron). In microsomes of PCB-pretreated rats the aminopyrine demethylation was inhibited noncompetitively by di-CB and hexa-CB whereas tetra-CB remained a competitive inhibitor (Ki 12 micron). Moreover, after PCB pretreatment all PCB were competitive inhibitors of p-nitroanisole demethylation. 2-OH-biphenyl and 4-OH-biphenyl caused competitive inhibition of aminopyrine demethylation and aniline hydroxylation but failed to inhibit p-nitroanisole metabolism by normal microsomes. Chlorinated 4-hydroxybiphenyls inhibited competitively the metabolism of both type I and type II substrates. However, after PCB pretreatment all phenolic compounds caused uncompetitive inhibition of aniline hydroxylation.     

FURTHER STUDIES ON THE INDUCTION OF THE DRUG-HYDROXYLATING ENZYME SYSTEM OF LIVER MICROSOMES

Further studies of the induction of the liver microsomal drug-hydroxylating enzyme system by pretreatment of rats with various drugs are presented. The phenobarbital-induced increase in the microsomal content of CO-binding pigment and in the activities of TPNH-cytochrome c reductase and the oxidative demethylation of aminopyrine is proportional, within certain limits, to the amount of phenobarbital injected. Removal of the inducer results in a parallel decrease in the levels of CO-binding pigment, TPNH-cytochrome c reductase, and aminopyrine demethylation. Other inducing drugs have been investigated and shown to act similarly to phenobarbital. The early increase in these enzymes is found in the microsomal subfraction consisting of rough-surfaced vesicles, whereas repeated administration of the inducing drug results in a concentration of the enzymes in the smooth-surfaced vesicles. The phenobarbital-stimulated formation of endoplasmic membranes is reflected in increased amounts of the various microsomal phospholipid fractions as revealed by thin layer chromatography. There is no significant difference between the stimulated rates of P_i³² incorporation into phospholipids of the two different microsomal subfractions in response to phenobarbital treatment. The drug-induced enzyme synthesis is unaffected by adrenalectomy.