Extrahepatic metabolism of carbamate and organophosphate thioether compounds by the flavin-containing monooxygenase and cytochrome P450 systems.

The cytochrome P450 (P450) and flavin-containing monooxygenase (FMO) enzymes are the major oxidative enzymes in phase I metabolism. Many organophosphate and carbamate thioether compounds are excellent substrates for these enzymes. Stereoselective sulfoxidation of fenthion and methiocarb by human liver, kidney, and microsomes was investigated. A high level of stereoselectivity in the formation of fenthion +-sulfoxide was observed in kidney and intestinal microsomes. This activity was not inhibited by the P450 inhibitor 1-aminobenzotriazole but was dramatically reduced following mild heat treatment. In liver, fenthion was metabolized to its sulfoxide in a nonstereoselective manner, and the activity was sensitive to both 1-aminobenzotriazole and heat treatment. The carbamate pesticide methiocarb also was sulfoxidated with a high degree of stereoselectivity in human kidney microsomes. Human liver microsomes formed both stereoisomers in equal amounts. Sulfoxide formation in kidney was not inhibited by 1-aminobenzotriazole but was abolished in liver microsomes. Formation of methiocarb sulfoxides was not observed in intestinal microsomes. The relative contribution of FMO1 and FMO3 to the sulfoxidation of carbophenothion, demeton-O, ethiofencarb, fonofos, and methiocarb also was investigated by using baculovirus-expressed recombinant proteins. FMO1 showed the highest catalytic activity for all pesticides. This study indicates that FMO1 may have a bigger role in extrahepatic metabolism than previously thought.     

Use of thiocarbamides as selective substrate probes for isoforms of flavin-containing monooxygenases.

The oxidation of thiourea, phenylthiourea, 1,3-diphenylthiourea, 1,3-bis-(3,4-dichlorophenyl)-2-thiourea and 1,1-dibenzyl-3-phenyl-2-thiourea was measured in reactions catalyzed by purified pig liver flavin-containing monooxygenase (FMO-1) and by microsomal fractions isolated from pig, guinea pig, chicken, rat and rabbit tissues. The reactions, followed by measuring substrate-dependent thiocholine oxidation [Guo and Ziegler, Anal Biochem 198: 143-148, 1991], were carried out in the presence of 2 mM 1-benzylimidazole to minimize potential interference from reactions other than those catalyzed by isoforms of the flavin-containing monooxygenase (FMO). While at saturating substrate concentrations the Vmax for purified FMO-1 catalyzed oxidation of all five thiocarbamides was essentially constant, velocities for the microsomal catalyzed reactions varied not only with tissue and species but also with the van der Waals' surface area of the thiocarbamide. Rat liver, rat kidney and rabbit liver microsomes failed to catalyze detectable oxidation of thiocarbamides larger than 1,3-diphenylthiourea and lung microsomes from a female rabbit only accepted substrates smaller than 1,3-diphenylthiourea. On the other hand, liver microsomes from chickens, pigs and guinea pigs catalyzed the oxidation of larger thiocarbamides, but the rates decreased with increasing substrate size and chicken liver microsomes showed no detectable activity with the largest thiocarbamide tested. To define more precisely the parameters affecting thiocarbamide substrate specificity of microsomal preparations, activities present in detergent extracts of guinea pig liver microsomes were separated into three distinct fractions. The substrate specificities of these partially purified fractions were different and consistent with the difference observed with microsomal catalyzed reactions. This strongly suggests that thiocarbamides that differ in size may be useful probes for measuring the number of activities of FMO isoforms in crude tissue preparations.     

Metabolism of phosphorus-containing compounds by pig liver microsomal FAD-containing monooxygenase

Oxidative desulfuration of phosphonate insecticides such as fonofos (S-phenyl ethyl ethylphosphonodithioate) and its analogs is catalyzed by pig liver microsomal FAD-containing monooxygenase, although desulfuration of phosphorodithioates, such as parathion, is not. Substitution of an alkyl group for the remaining alkoxy group, as in S-phenyl diethylphosphinodithioate, did not increase its oxidation rate. Diethylphenylphosphine sulfide, containing 3 phosphorus-carbon bonds, was actually a poorer substrate than fonofos. Replacement of the S-phenyl group of fonofos with an O-phenyl group increased the Km value above the solubility limit. Trivalent phosphorus-containing compounds were also excellent substrates for this enzyme. Diethylphenylphosphine had a Km value lower than 2.5 microM. Diethyl phenylphosphonite also appeared to be an excellent substrate but its rapid nonenzymatic hydrolysis and/or oxidation precluded accurate Km determinations. Stoichiometry studies with diethylphenylphosphine and its sulfide showed that O2 and NADPH consumption were approximately equal to the substrate consumed. The major metabolite of both diethylphenylphosphine and its sulfide was the phosphine oxide. These results show that microsomal FAD-containing monooxygenase of pig liver has activity as a phosphorus-oxidase, in addition to its well characterized nitrogen- and sulfur-oxidase roles.     

The role of the flavin-containing monooxygenase (EC 1.14.13.8) in the metabolism and mode of action of agricultural chemicals.

1. The flavin-containing monooxygenase (FMO) (EC 1.14.13.8) is a versatile enzyme that catalyses the monooxygenation of a large number of xenobiotic soft nucleophiles ranging from inorganic ions to organic compounds with nitrogen, sulphur, phosphorus or selenium heteroatoms. 2. The substrate specificity relative to agricultural chemicals is discussed and compared with that of the cytochrome P-450-dependent monooxygenase system. The relative activity of these two enzymes towards common substrates varies from substrate to substrate and from tissue to tissue as is shown in the case of the insecticide, phorate and the hepatotoxicant, thiobenzamide. 3. The products of FMO action may be chemically different (e.g. nicotine) to those from P-450, or the two enzymes may produce different isomers of the same product (e.g. phorate). 4. Recent studies have demonstrated that, in the rabbit, the FMOs from liver and lung are different gene products which differ not only in primary sequence but also in physical, catalytic and immunochemical properties. These studies are being extended to include other tissues such as skin and brain. 5. Immunocytochemical localization of FMO in lung and skin correlates well with measurements of the oxidation of methimazole, a specific FMO substrate.     

The role of the flavin-containing monooxygenase (EC 1.14.13.8) in the metabolism and mode of action of agricultural chemicals

1. The flavin-containing monooxygenase (FMO) (EC 1.14.13.8) is a versatile enzyme that catalyses the monooxygenation of a large number of xenobiotic soft nucleophiles ranging from inorganic ions to organic compounds with nitrogen, sulphur, phosphorus or selenium heteroatoms.

2. The substrate specificity relative to agricultural chemicals is discussed and compared with that of the cytochrome P-450-dependent monooxygenase system. The relative activity of these two enzymes towards common substrates varies from substrate to substrate and from tissue to tissue as is shown in the case of the insecticide, phorate and the hepatotoxicant, thiobenzamide.

3. The products of FMO action may be chemically different (e.g. nicotine) to those from P-450, or the two enzymes may produce different isomers of the same product (e.g. phorate).

4. Recent studies have demonstrated that, in the rabbit, the FMOs from liver and lung are different gene products which differ not only in primary sequence but also in physical, catalytic and immunochemical properties. These studies are being extended to include other tissues such as skin and brain.

5. Immunocytochemical localization of FMO in lung and skin correlates well with measurements of the oxidation of methimazole, a specific FMO substrate.     

Evaluation of xenobiotic N- and S-oxidation by variant flavin-containing monooxygenase 1 (FMO1) enzymes.

The flavin-containing monooxygenase gene family (FMO1-6) in humans encodes five functional isoforms that catalyze the monooxygenation of numerous N-, P- and S-containing drugs and toxicants. A previous single nucleotide polymorphism (SNP) analysis of FMO1 in African-Americans identified seven novel SNPs. To determine the functional relevance of the coding FMO1 variants (H97Q, I303V, I303T, R502X), they were heterologously expressed using a baculovirus system. Catalytic efficiency and stereoselectivity of N- and S-oxygenation was determined in the FMO1 variants using several substrates. The I303V variant showed catalytic constants equal to wild-type FMO1 for methimazole and methyl p-tolyl sulfide. Catalytic efficiency (V(max)/K(m)) of methyl p-tolyl sulfide oxidation by R502X was unaltered. In contrast, methimazole oxidation by R502X was not detected. Both H97Q and I303T had elevated catalytic efficiency with regards to methyl p-tolyl sulfide (162% and 212%, respectively), but slightly reduced efficiency with regards to methimazole (81% and 78%). All the variants demonstrated the same stereoselectivity for methyl p-tolyl sulfide oxidation as wild-type FMO1. FMO1 also metabolized the commonly used insecticide fenthion to its (+)-sulfoxide, with relatively high catalytic efficiency. FMO3 metabolized fenthion to its sulfoxide at a lower catalytic efficiency than FMO1 (27%) and with less stereoselectivity (74% (+)-sulfoxide). Racemic fenthion sulfoxide was a weaker inhibitor of acetylcholinesterase than its parent compound (IC(50) 0.26 and 0.015 mM, respectively). The (+)- and (-)-sulfoxides were equally potent inhibitors of acetylcholinesterase. These data indicate that all the currently known FMO1 variants are catalytically active, but alterations in kinetic parameters were observed.     

The flavin-containing monooxygenase of mouse kidney. A comparison with the liver enzyme

Flavin-containing monooxygenase (FMO; EC 1.14.13.8) was purified from mouse kidney microsomes and compared to that isolated from mouse liver microsomes. The purified enzymes from kidney and liver appeared as a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with an apparent molecular weight of 58,000 daltons. On wide range (pH 3.5 to 9.0) isoelectric focusing, FMOs from kidney and liver resolved as a single band with an isoelectric point of 8.2. The enzymes from both kidney and liver have a pH optimum of 9.2. Thiobenzamide-S-oxidation catalyzed by both enzymes was sensitive to inhibition by the competitive inhibitors thiourea and methimazole. At an n-octylamine concentration of 3 mM, thiobenzamide-S-oxidation by the kidney FMO was increased by 122% and that by the liver FMO by 148%. Km and Vmax values were determined and compared between the two tissue enzymes for xenobiotic substrates containing nucleophilic nitrogen, sulfur or phosphorus atoms. In general, for most FMO substrates, Km and Vmax values were similar between kidney and liver FMO with only a few exceptions. The Km and Vmax values for fenthion for kidney were only half of those observed for liver FMO. Fonofos was unusual in having a low Km as well as a low Vmax for both tissue enzymes. Anti-sera developed to the FMO purified from kidney and liver showed cross-reactivity with each purified enzyme as well as with a protein with the same molecular weight as the purified FMO present in both kidney and liver microsomes. These bands showed equal intensity based on an equivalent amount of protein. Analysis of kidney and liver FMO by proteolytic digestion followed by visualization of peptides by silver staining or immunoblotting showed only minor differences between the enzymes of the two tissues. The amino acid composition of both mouse kidney and liver FMO was low in methionine and histidine and rich in aspartate/asparagine, glutamate/glutamine, leucine, valine and glycine. Edman degradation of the purified mouse kidney and liver FMO provided a single amino acid sequence of the NH2-terminus. This sequence matched exactly with the cDNA-deduced sequence reported for the pig and rabbit liver beginning with the fifth amino acid and contained the highly conserved FAD-binding domain Gly-X-Gly-X-X-Gly, commonly found in a number of other FAD-binding proteins. These studies indicate that the renal and hepatic forms of FMO from mouse are similar enzymes that are immunologically related and show only a few minor differences.     

Sulfoxidation of thioether-containing pesticides by the flavin-adenine dinucleotide-dependent monooxygenase of pig liver microsomes

In the presence of NADPH and under aerobic conditions, thioether-containing organophosphorus and carbamate pesticides were oxidized by the FAD-dependent monooxygenase (EC 1.14.13.8) purified from pig liver microsomes. The stoichiometric relationship between NADPH and substrate during the course of the reaction was 1:1, and the product, in the case of disulfoton and phorate, was the sulfoxide. The product was optically active and further oxidation to the sulfone was not apparent. Furthermore, the sulfoxides of disulfoton, phorate and croneton were not substrates for this enzyme. n-Octylamine, a known cytochrome P-450 inhibitor, increased the rate of sulfoxidation reactions catalyzed by the FAD-dependent monooxygenase. Structure-activity relationships were investigated using thirty-nine possible substrates. Structural changes around the thioether sulfur that affect nucleophilicity or that cause steric hindrance tended to decrease the sulfoxidation rate. With phosphorodithioates, changes around the phosphorus atom also affected oxidation of the thioether sulfur. Although neither the thiono nor the thiol sulfur atoms were attacked, substitution of either sulfur by oxygen decreased sulfoxidation. Thioether-containing O,O-dimethyl phosphorodithioates were not oxidized as readily as their O,O-diethyl analogs. Tetram and its analogs, which contain a tertiary amine group, were also substrates for this enzyme, presumably forming the N-oxide.     

Separation, purification, and characterization of digitoxigenin-monodigitoxoside UDP-glucuronosyltransferase activity

Glucuronidation of digitoxigenin-monodigitoxoside was investigated in liver microsomes from spironolactone-induced male Wistar rats. Isolation of a specific digitoxigenin-monodigitoxoside UDP-glucuronosyltransferase was possible utilizing chromatofocusing chromatography with a gradient from pH 10.1 to 8.0 after solubilizing the microsomal protein with the nonionic detergent Emulgen 911. The digitoxigenin-monodigitoxoside UDP-glucuronosyltransferase was further purified using UDP-hexanolamine Sepharose 4B affinity chromatography. The highly purified (75-fold) enzyme showed activity toward digitoxigenin-monodigitoxoside and slight activity toward digitoxigenin-bisdigitoxoside, whereas digitoxin and substrates for p-nitrophenol, 17 beta-OH steroid, and 3 alpha-OH steroid UDP-glucuronosyltransferases were not glucuronidated. In addition, bilirubin, morphine, estrone, 4-hydroxybiphenyl, and aromatic amines were not glucuronidated by this protein. These results strongly confirm the presence of a form of UDP-glucuronosyltransferase, which is highly specific for the glucuronidation of digitoxigenin-monodigitoxoside.     

Polyamine effects on cytochrome P-450- and flavin-containing monooxygenase-mediated oxidation of xenobiotics

The effects of in vitro addition of polyamines on the female mouse hepatic microsomal cytochrome P-450- and flavin-containing monooxygenase-dependent oxidation of xenobiotics were examined. Putrescine, spermine, and spermidine all caused a different degree of stimulation of oxidative dearylation of parathion and O-ethyl-O-p-nitrophenylphosphonothioate, epoxidation of aldrin, and O-deethylation of 7-ethoxycoumarin. The degree of stimulation was greatest in the presence of spermidine. Enhancement of aldrin epoxidation by spermidine was higher in pregnant mice as compared to nonpregnant mice. Total phorate S-oxidation was stimulated by all the polyamines tested. Phorate S-oxidation, mediated by microsomal flavin-containing monooxygenase, was only slightly increased by spermine and spermidine while putrescine caused slight inhibition. Of the various steps involved in the monooxygenation cycle examined, only the rates of NADPH oxidation and cytochrome P-450 reduction were significantly increased. Efficient coupling of NADPH utilization with substrate oxidation appears to be the underlying mechanism responsible for the polyamine-stimulated xenobiotic oxidation.     

Size limits of thiocarbamides accepted as substrates by human flavin-containing monooxygenase 1.

Microsomes isolated from Spodoptera frugiperda (Sf)9 cells infected with human flavin-containing monooxygenase (FMO)1 recombinant baculovirus catalyzed the NADPH- and O2-dependent oxidation of methimazole, thiourea, and phenylthiourea. However, there was no detectable activity with 1,3-diphenylthiourea or larger thiocarbamides. Microsomes from control Sf9 cells were devoid of methimazole or thiourea S-oxygenase activity. Trimethylamine up to 1.0 mM had no detectable effect on the oxidation of 10 microM methimazole (Km = 5 microM) but 1.0 mM N,N-dimethylaniline or chlorpromazine inhibited the oxidation of 1.0 mM methimazole 50 and 70%, respectively. Although products were not isolated, the pronounced inhibition of methimazole S-oxygenation suggests that these amines are alternate substrates for human FMO1. Because 1,3-diphenylthiourea is apparently completely excluded from the catalytic site, tricyclic amine drugs are probably approaching the upper size limits of xenobiotics accepted by human FMO1. The substrate specificity of this isoform in humans appears considerably more restricted than that of pig or guinea pig FMO1. Differences in the size of nucleophiles accepted must be considered in attempting to extrapolate the extensive structure-activity studies available for pig FMO1 to this FMO isoform in humans.     

Stereospecific and regioselective hydrolysis of cannabinoid esters by ES46.5K, an esterase from mouse hepatic microsomes, and its differences from carboxylesterases of rabbit and porcine liver

The properties of ES46.5K, an esterase from mouse hepatic microsomes, were compared with those of carboxylesterases from rabbit and porcine liver. The inhibitory profile with a serine hydrolase inhibitor (bis-p-nitrophenylphosphate) and detergents (sodium dodecylsulfate, Emulgen 911) was different between ES46.5K and the carboxylesterases. Bis-p-nitrophenylphosphate (0.1 mM) markedly inhibited the catalytic activity of the carboxylesterases but not that of ES46.5K. Emulgen 911 (0.05-0.25%) inhibited the catalytic activity of the carboxylesterases, whereas the detergent conversely stimulated that of ES46.5K by 150%. The two carboxylesterases catalyzed the hydrolysis of acetate esters of tetrahydrocannabinol (THC) analogues with different side chain lengths (C1-C5), although ES46.5K showed marginal activity only against the acetate of Delta8-tetrahydrocannabiorcol, a methyl side chain derivative of Delta8-THC. ES46.5K hydrolyzed cannabinoid esters stereospecifically and regioselectively. The esterase hydrolyzed 8alpha-acetoxy-Delta9-tetrahydrocannabinol (8alpha-acetoxy-Delta9-THC, 5.62 nmol/min/mg protein), while the enzyme did not hydrolyze 8beta-acetoxy-Delta9-THC, 7alpha-acetoxy-, and 7beta-acetoxy-Delta8-THC at all. In contrast, the carboxylesterases from rabbit and porcine liver hydrolyzed 8beta-acetoxy-Delta9-THC efficiently but not 8alpha-acetoxy-Delta9-THC. ES46.5K hydrolyzed side chain acetoxy derivatives of Delta8-THC at the 3'- and 4'-positions, and a methyl ester of 5'-nor-Delta8-THC-4'-oic acid. The enzyme, however, could not hydrolyze methyl esters of Delta8- and Delta9-THC-11-oic acid, while both carboxylesterases hydrolyzed side chain acetoxy derivatives of Delta8-THC and three methyl esters of THC-oic acids. These differences in stereospecificity and regioselectivity between ES46.5K and carboxylesterases suggest that the configurations of important amino acids for the catalytic activities of these enzymes are different from each other.     

Purification and properties of a metyrapone-reducing enzyme from mouse liver microsomes--this ketone is reduced by an aldehyde reductase

A ketone reducing enzyme was purified to homogeneity from female mouse liver microsomes, using the diagnostic cytochrome P-450 inhibitor metyrapone as a substrate. In contrast to the usually employed indirect spectrophotometric recording of pyridine nucleotide oxidation at 340 nm, a HPLC method was applied for direct alcohol metabolite determination. Purification of the carbonyl reductase resulted in a 360-fold increase in specific activity together with a single band in the 34 kD region after SDS-polyacrylamide gel electrophoresis. Phenobarbital, indomethacin, dicoumarol and 5 alpha-dihydrotestosterone inhibited the enzyme, whereas quercitrin did not affect the enzyme activity. Thus, by inhibitor classification of carbonyl reductases the ketone metyrapone is reduced by an aldehyde reductase, rather than by a ketone reductase. Dihydrotestosterone, the strongest inhibitor, is supposed to be the physiological substrate for the purified enzyme. It was demonstrated that during the steps of purification both NADPH and NADH can supply the required reducing equivalents, although the activity with NADH is weaker. The highest activity was obtained using an NADPH-regenerating system. Ethanol and the nonionic detergent Emulgen 913 led to an increased specific activity, indicating that the enzyme is bound to the membranes of the endoplasmic reticulum in a latent state. From these results it is concluded that the microsomal metyrapone-reducing enzyme belongs to the family of carbonyl reductases, but differs from the common patterns of their classification with regard to cofactor requirement and inhibitor susceptibility.     

Identification of human drug-metabolizing enzymes involved in the metabolism of SNI-2011.

In vitro studies were conducted to identify human drug-metabolizing enzymes involved in the metabolism of SNI-2011 ((+/-)-cis-2-methylspiro [1,3-oxathiolane-5,3'-quinuclidine] monohydrochloride hemihydrate, cevimeline hydrochloride hydrate). When 14C-SNI-2011 was incubated with human liver microsomes, SNI-2011 trans-sulfoxide and cis-sulfoxide were detected as major metabolites. These oxidations required NADPH, and were markedly inhibited by SKF-525A, indicating that cytochrome P450 (CYP) was involved. In a chemical inhibition study, metabolism of SNI-2011 in liver microsomes was inhibited (35-65%) by CYP3A4 inhibitors (ketoconazole and troleandomycin) and CYP2D6 inhibitors (quinidine and chlorpromazine). Furthermore, using microsomes containing cDNA-expressed CYPs, it was found that high rates of sulfoxidation activities were observed with CYP2D6 and CYP3A4. On the other hand, when 14C-SNI-2011 was incubated with human kidney microsomes, SNI-2011 N-oxide was identified as a major metabolite. This N-oxidation required NADPH, and was completely inhibited by thiourea, indicating that flavin-containing monooxygenase (FMO) was involved. In addition, microsomes containing cDNA-expressed FMO1, a major isoform in human kidney, mainly catalyzed N-oxidation of SNI-2011, but microsomes containing FMO3, a major isoform in adult human liver, did not. These results suggest that SNI-2011 is mainly catalyzed to sulfoxides and N-oxide by CYP2D6/3A4 in liver and FMOI in kidney, respectively.     

Substrate specificities of rabbit lung and porcine liver flavin-containing monooxygenases: differences due to substrate size

Phenothiazine, 2-(trifluoromethyl)phenothiazine, and a series of 10-(N,N-dimethylamino-alkyl)-2-(trifluoromethyl)phenothiazines with alkyl side chains varying in length from C2 to C7 were tested for substrate activity with purified rabbit lung and porcine liver flavin-containing monooxygenases (FMO). While all were substrates for the hepatic FMO, only phenothiazines bearing C6 and C7 alkyl side chains were oxidized at significant rates by the pulmonary FMO. Kinetic constants calculated from reaction velocities for the oxidation of thiourea, phenylthiourea, and naphthylthiourea indicate that a nucleophilic heteroatom on the end of a molecule not much larger than a six-membered ring in cross section is oxidized by both enzymes, but the addition of bulky lipophilic substituents increases the Km of N-substituted thioureas for rabbit lung FMO and 1,3-diphenylthiourea (thiocarbanilide) is excluded entirely. From the dimensions of compounds excluded and from those oxidized, it would appear that the hydroperoxyflavin in rabbit lung FMO lies about 6-8 A below the surface in a channel no more than 8 A in diameter in its longest axis. The channel leading to this oxidant in hepatic FMO appears more open and readily admits compounds bearing a tricyclic ring. Differences in dimensions of the substrate channel appear responsible for some of the differences in substrate specificities between liver and lung FMO.     

Properties of human hepatic UDP-glucuronosyltransferases. Relationship to other inducible enzymes in patients with cholestasis

Summary Glucuronidation of 4-nitrophenol, nopol (a monoterpenoid alcohol) and bilirubin, which in the rat, are catalyzed by three different enzymes, has been examined in liver biopsies from patients with various liver diseases, in particular cholestasis.These different activities were not correlated, which strongly suggests that at least three independently regulated forms of UDP-glucuronosyltransferases were present in the microsomes.Non ionic detergents (Triton X100, Emulgen 911) and deoxycholate produced similar activation (more than 2-fold) of the glucuronidation of 4-nitrophenol.Amphipathic substances, such as CHAPS (3-[3-cholamidopropyl-dimethylammonio]-1-propane sulfonate), and lysophosphatidylcholines maximally increased this UDP-glucuronosyltransferase activity, the most potent being oleoyl lysophosphatidylcholine (4-fold increase).Discriminant analysis of the data revealed no correlation between the three different UDP-glucuronosyltransferase activities and the age or sex of the patients.A good correlation was found on multidimensional analysis between form 1 of the enzyme (4-nitrophenol glucuronidation) and, in decreasing order of magnitude, epoxide hydrolase (measured with benzo(a)pyrene-4,5-oxide as substrate), cytochrome P-450, 7-ethoxycoumarin deethylase, aspartate aminotransferase and gamma-glutamyltransferase (r = 0.89); and between Form 3 of the enzyme (bilirubin glucuronidation) and NADPH cytochrome c reductase, alkaline phosphatase, (r=0.81).These relation ships may reflect the differential variation in enzymatic activities in various hepatobiliary diseases.     

Synthesis of fenthion sulfoxide and fenoxon sulfoxide enantiomers: effect of sulfur chirality on acetylcholinesterase activity

Earlier reports have demonstrated that recombinant flavin-containing monooxygenase 1 (FMO1) catalyzes the oxidation of the organophosphate pesticide fenthion to (+)-fenthion sulfoxide in a stereoselective fashion. In order to elucidate the absolute configuration of the sulfoxide metabolite produced, we established an efficient synthesis of both enantiomers of fenthion sulfoxide, which were transformed into chiral fenoxon sulfoxides using a two-step protocol. The use of chiral oxidants, namely, N-(phenylsulfonyl)(3,3-dichlorocamphoryl) oxaziridines, afforded enantioenriched fenthion sulfoxides with high ee (>82%) from the parent sulfide. Single recrystallizations afforded chiral fenthion sulfoxides with >99% ee, measured by chiral HPLC analysis. The absolute configuration of the (+)-sulfoxide generated from fenthion metabolism by FMO1 was determined to be (R)-(+)-fenthion sulfoxide, confirmed by X-ray crystallographic analysis of the (S)-(-)-antipode. Inhibition of human recombinant (hrAChE) and electric eel (eeAChE) acetylcholinesterase were assayed with fenthion, fenoxon, and the racemates and enantiomers of fenthion sulfoxide and fenoxon sulfoxide. Results revealed stereoselective inhibition with (R)-(+)-fenoxon sulfoxide when compared with that of (S)-(-)-fenoxon sulfoxide (IC50 of 6.9 and 6.5 microM vs 230 and 111 microM in hrAChE and eeAChE, respectively). Fenthion sulfoxide (R or S enantiomers) did not present anti-AChE properties. Although the stereoselective sulfoxidation of fenthion to (R)-(+)-fenthion sulfoxide by FMO represents a detoxification pathway, the results of this study support the notion that subsequent oxidative desulfuration of (R)-(+)-fenthion sulfoxide (in vivo) may represent a critical bioactivation pathway, resulting in the production of (R)-(+)-fenoxon sulfoxide, a potent AChE inhibitor.     

Neurotoxins: 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine, 1,2,3,4-tetrahydroisoquinoline and 1-methyl-6,7-dihydroxy-tetrahydroisoquinoline as substrates for FAD-containing monooxygenase of porcine liver microsomes.

The activity of FAD-containing monooxygenase (FMO) (EC 1.14.13.8) of porcine liver microsomes was examined with the neurotoxins, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), 1,2,3,4-tetrahydroisoquinoline (TIQ) and 1-methyl-6,7-dihydroxy-tetrahydroisoquinoline (MDTIQ), as substrates. FMO catalyses these neurotoxins. The kinetic parameters of FMO for the neurotoxins and electron donors were determined. Km values for MPTP, TIQ and MDTIQ were determined to be 47 microM, 6.9 mM and 5.6 mM, respectively. The Km for the electron donor, NADPH, was variable from 31 to 200 microM depending on the substrate used. The activities of FMO for these neurotoxins were comparable with that for dimethylaniline.     

Selective inhibition of bipyridyl-stimulated NADPH oxidation by ascorbic acid

The effect of the bipyridyl herbicides, paraquat and diquat (0.01-1.0 mM), on NADPH oxidation was determined in vitro using rat lung microsomal preparations. Experiments were performed in the absence of mixed function oxidation (MFO) substrates, in the presence of substrates (ethylmorphine or benzphetamine), and also in the presence of ascorbic acid (0.1-10.0 mM). NADPH oxidation was stimulated by both herbicides in the absence or presence of either substrate in a concentration-dependent manner. When ascorbic acid was included in incubations along with either bipyridyl, the stimulated rate of NADPH oxidation decreased in the presence of benzphetamine but the stimulation was unaltered in the presence of ethylmorphine or in the absence of substrate. These studies indicate that ascorbic acid may offer some protection from bipyridyl-mediated NADPH oxidation in rat lung microsomal fractions, but that protection appears to be dependent upon the simultaneous presence of specific MFO substrates.     

Benzydamine N-oxidation as an index reaction reflecting FMO activity in human liver microsomes and impact of FMO3 polymorphisms on enzyme activity

AIMS: The role of flavin containing monooxygenases (FMO) on the disposition of many drugs has been insufficiently explored. In vitro and in vivo tests are required to study FMO activity in humans. Benzydamine (BZD) N-oxidation was evaluated as an index reaction for FMO as was the impact of genetic polymorphisms of FMO3 on activity. METHODS: BZD was incubated with human liver microsomes (HLM) and recombinant enzymes. Human liver samples were genotyped using PCR-RFLP. RESULTS: BZD N-oxide formation rates in HLM followed Michaelis-Menten kinetics (mean Km = 64.0 microM, mean Vmax = 6.9 nmol mg-1 protein min-1; n = 35). N-benzylimidazole, a nonspecific CYP inhibitor, and various CYP isoform selective inhibitors did not affect BZD N-oxidation. In contrast, formation of BZD N-oxide was almost abolished by heat treatment of microsomes in the absence of NADPH and strongly inhibited by methimazole, a competitive FMO inhibitor. Recombinant FMO3 and FMO1 (which is not expressed in human liver), but not FMO5, showed BZD N-oxidase activity. Respective Km values for FMO3 and FMO1 were 40.4 microM and 23.6 microM, and respective Vmax values for FMO3 and FMO1 were 29.1 and 40.8 nmol mg-1 protein min-1. Human liver samples (n = 35) were analysed for six known FMO3 polymorphisms. The variants I66M, P135L and E305X were not detected. Samples homozygous for the K158 variant showed significantly reduced Vmax values (median 2.7 nmol mg-1 protein min-1) compared to the carriers of at least one wild type allele (median 6.2 nmol mg-1 protein min-1) (P < 0.05, Mann-Whitney-U-test). The V257M and E308G substitutions had no effect on enzyme activity. CONCLUSIONS: BZD N-oxidation in human liver is mainly catalysed by FMO3 and enzyme activity is affected by FMO3 genotype. BZD may be used as a model substrate for human liver FMO3 activity in vitro and may be further developed as an in vivo probe reflecting FMO3 activity.