The use of 3-[2-(N,N-diethyl-N-methylammonium)ethyl]-7-methoxy-4-methylcoumarin (AMMC) as a specific CYP2D6 probe in human liver microsomes.

Recently, a novel nonfluorescent probe 3-[2-(N,N-diethyl-N-methylammonium)-ethyl]-7-methoxy-4-methylcoumarin (AMMC), which produces a fluorescent metabolite AMHC (3-[2-(N,N-diethyl-N-methylammonium)ethyl]-7-hydroxy-4-methylcoumarin) was used with microsomes containing recombinant enzymes (rCYP) to monitor CYP2D6 inhibition in a microtiter plate assay. This article describes the studies that were performed in human liver microsomes (HLM) to establish the selectivity of AMMC toward CYP2D6. Metabolism studies in HLM showed that AMMC was converted to one metabolite identified by mass spectrometry as AMHC. Kinetic studies indicated an apparent K(m) of 3 microM with a V(max) of 20 pmol/min. mg of protein for the O-demethylation reaction. The O-demethylation of AMMC in HLM was inhibited significantly in the presence of a CYP2D6 inhibitory antibody. Using a panel of various HLM preparations (n = 12), a good correlation (r(2) = 0.95) was obtained between AMMC O-demethylation and bufuralol metabolism, a known CYP2D6 substrate, but not with probes for the other major xenobiotic metabolizing CYPs. Finally, only rCYP2D6 showed detectable metabolism in experiments conducted with rCYPs using AMMC at a concentration of 1.5 microM (near K(m)). However, at a concentration of 25 microM AMMC, rCYP1A also contributed significantly to the formation of AMHC. Knowing the experimental conditions under which AMMC was selective for CYP2D6, a microtiter assay was developed to study the inhibition of various compounds in HLM using the fluorescence of AMHC as an indication of CYP2D6 activity. The inhibition potential of various chemicals was found to be comparable to those determined using the standard CYP2D6 probe, bufuralol, which requires high-performance liquid chromatography separation for the analysis of its CYP2D6-mediated 1'-hydoxylated metabolite.

In vitro metabolism considerations, including activity testing of metabolites, in the discovery and selection of the COX-2 inhibitor etoricoxib (MK-0663).

Characterization of the metabolites of the COX-2 inhibitor etoricoxib (MK-0663 and L-791,456) produced in vitro indicate formation of an N-oxide pyridine and hydroxymethyl pyridine that can further be glucuronidated or oxidized to an acid. Significant turnover is observed in human hepatocytes. Several CYPs are involved in the oxidative biotranformations and, from in vitro studies, etoricoxib is not a potent CYP3A4 inducer or inhibitor. Based on an in vitro whole blood assay, none of the metabolites of etoricoxib inhibits COX-1 or contributes significantly to the inhibition of COX-2.

Reduction of animal usage by serial bleeding of mice for pharmacokinetic studies: application of robotic sample preparation and fast liquid chromatography-mass spectrometry.

Typically, pharmacokinetic studies in mice require one animal per time point, thus resulting in differences due to dosing error, animal to animal variation and more importantly the euthanasia of a large number of animals. A method for the determination of pharmacokinetic data from serially bled mice to support early drug discovery is described. Sample analysis relies on liquid chromatography coupled with tandem mass spectrometry permitting robust and reproducible analysis requiring approximately 3 min per sample. Several parameters are discussed including the method of sample collection, preparation and analysis. The use of serially bled mice has lead to a remarkable reduction in animal usage and a corresponding reduction in compound required for such experiments. Using conventional methodology, a nine-point pharmacokinetic curve with four animals per time point would require 36 mice. With the method described below, only four mice in total are used and euthanasia is not required, permitting reuse after several weeks recovery and washout. Also, pharmacodynamic-pharmacokinetic correlation is possible and is demonstrated using a mouse model of diabetes.

In vitro metabolism of the COX-2 inhibitor DFU, including a novel glutathione adduct rearomatization.

The metabolic profile of DFU [5,5-dimethyl-3-(3-fluorophenyl)-4-(4-methylsulphonyl)phenyl-2(5H)-furanone], a potent and selective COX-2 inhibitor, was characterized using in vitro microsomal and hepatocyte incubations. A single product, corresponding to p-hydroxylation, p-OH-DFU [(5,5-dimethyl-3-(3-fluoro-4-hydroxyphenyl)-4-(4-methylsulphonyl)phenyl-2(5H)-furanone)], was produced in rat microsomal incubations of DFU. In contrast, three metabolites were produced in incubations using suspensions of freshly isolated rat hepatocytes. Microsomal production of the p-O-glucuronide metabolite of DFU from synthetic p-OH-DFU was shown to have chromatographic and mass spectrometric properties identical to the earliest eluting hepatocyte metabolite (M1). The molecular weights of the other two hepatocyte metabolites were readily obtained using capillary high-performance liquid chromatography continuous-flow liquid secondary ion mass spectrometry (HPLC/CF-LSIMS); however, the elemental composition of these metabolites was not. Unlike typical metabolic products, which produce readily identified increments in molecular weight, metabolites M2 and M3 produced molecular ions in positive- and negative-ion CF-LSIMS that were consistent with oxidation of DFU (+16 Da), followed by addition of glutathione (+306 Da) and subsequent loss of 20 and 18 Da, respectively. Capillary HPLC/high-resolution CF-LSIMS was used to generate accurate mass data for M2 and M3 that provided evidence that the losses of 20 and 18 Da, respectively, corresponded to a rearomatization through loss of HF or H(2)O. Isolation and NMR characterization provided the definitive structural proof for these metabolites. Overall, the metabolism of DFU in rat hepatocytes is proposed to proceed through an epoxide intermediate, which then either rearranges to the p-OH-DFU and is conjugated with glucuronic acid, or is trapped with glutathione, followed by rearomatization with loss of HF (M2) or H(2)O (M3).

Novel enzymological profiles of human 11beta-hydroxysteroid dehydrogenase type 1.

The human enzyme 11beta-hydroxysteroid dehydrogenase (11beta-HSD) catalyzes the reversible oxidoreduction of 11beta-OH/11-oxo groups of glucocorticoid hormones. Besides this important endocrinological property, the type 1 isozyme (11beta-HSD1) mediates reductive phase I reactions of several carbonyl group bearing xenobiotics, including drugs, insecticides and carcinogens. The aim of this study was to explore novel substrate specificities of human 11beta-HSD1, using heterologously expressed protein in the yeast system Pichia pastoris. In addition to established phase I xenobiotic substrates, it is now demonstrated that transformed yeast strains catalyze the reduction of ketoprofen to its hydroxy metabolite, and the oxidation of the prodrug DFU-lactol to the pharmacologically active lactone compound. Purified recombinant 11beta-HSD1 mediated oxidative reactions, however, the labile reductive activity component could not be maintained. In conclusion, evidence is provided that human 11beta-HSD1 in vitro is involved in phase I reactions of anti-inflammatory non-steroidal drugs like ketoprofen and DFU-lactol.

Investigation of the in vitro metabolism profile of a phosphodiesterase-IV inhibitor, CDP-840: leading to structural optimization.

CDP-840 is a selective and potent phosphodiesterase type IV inhibitor, whose in vitro metabolism profile was first investigated using liver microsomes from different species. At least 10 phase I oxidative metabolites (M1-M10) were detected in the microsomal incubations and characterized by capillary high-performance liquid chromatography continuous-flow liquid secondary ion mass spectrometry (CF-LSIMS). Significant differences in the microsomal metabolism of CDP-840 were found between rat and other species. The major route of metabolism in rat involved para-hydroxylation on the R4 phenyl. This pathway was not observed in human and several other species. The in vitro metabolism profile of CDP-840 was further examined using freshly isolated hepatocytes from rat, rabbit, and human. The hepatocyte incubations indicated more extensive metabolism relative to that in microsomes. In addition to the phase I oxidative metabolites observed in microsomal incubations, several phase II conjugates were identified and characterized by CF-LSIMS. Interspecies differences in phase II metabolism were also found in these hepatocyte incubations. The major metabolite in human hepatocytes was identified as the pyridinium glucuronide, which was not detected in rat hepatocytes. Simple structural modification on R4, such as p-Cl substitution, greatly reduced the species differences in microsomal metabolism. Furthermore, modifications on R3, such as the N-oxide, eliminated the N-glucuronide formation in human. These results not only helped in determining the suitability of animal species used in the preclinical safety studies but also provided valuable directions for the synthetic efforts in finding backup compounds that are more metabolically stable.

Application of rat hepatocyte culture to predict in vivo metabolic auto-induction: studies with DFP, a cyclooxygenase-2 inhibitor.

The drug candidate DFP [5,5-dimethyl-3-(2-isopropoxy)-4-(4-methanesulfonylphenyl)-2(5H)-furanone] is a selective cyclooxygenase-2 inhibitor under evaluation for analgesic and anti-inflammatory therapy. The in vitro metabolic pathways (rat microsomes) involve hydroxylation of the isopropyl side chain at either of two positions, the methyl or the methine, thus producing a hydroxylated metabolite (DFHP) or a dealkylated metabolite (DFH). DFH formation was the major pathway. Using hepatic microsomes from rats treated with agents that induce specific CYP isozymes, it was shown that the dexamethasone-inducible rat CYP3A isozyme(s) play a major role in DFH formation. The roles of CYP3A1 and -3A2 were confirmed with genetically engineered rat CYP enzymes. The potential for induction of rat CYP3A by DFP was evaluated by incubating DFP in rat hepatocyte cultures and measuring the CYP3A levels. Both CYP3A immunoreactive protein and enzyme activity were induced in a dose-dependent manner. The induction was confirmed in vivo by dosing rats with DFP at 100 mg/kg for 4 days. Microsomes prepared from the excised livers showed that DFP gave approximately 55% of the induction observed with dexamethasone, as determined by Western blot. In vitro metabolic auto-induction of DFP was assessed by measuring the metabolism of DFP in hepatocytes treated with DFP. DFH formation was significantly enhanced in the DFP-treated cells. In vivo, treating rats with DFP at doses of 10 to 100 mg/(kg.day) for 13 weeks indicated that DFP induced its own metabolism. The C(max) and plasma drug area under the curve values during the thirteenth week were significantly lower than that on the first day, and the effect was dose-dependent.

Synthesis, characterization, and activity of metabolites derived from the cyclooxygenase-2 inhibitor rofecoxib (MK-0966, Vioxx).

Metabolites of the COX-2 inhibitor rofecoxib (MK-0966, Vioxx) were prepared by synthetic or biosynthetic methods. Metabolites include products of oxidation, glucuronidation, reduction and hydrolytic ring opening. Based on an in vitro whole blood assay, none of the known human metabolites of rofecoxib inhibits COX-1 nor contributes significantly to the inhibition of COX-2.

Description of a 96-well plate assay to measure cytochrome P4503A inhibition in human liver microsomes using a selective fluorescent probe.

The standard method to evaluate CYP3A inhibition is to study the conversion of the specific CYP3A probe testosterone to its 6 beta-hydroxy metabolite in human liver microsomes, in the absence and presence of potential inhibitors. Quantification of the 6 beta-hydroxy metabolite is achieved by HPLC resulting in a tedious and time-consuming assay. In order to increase the P450 inhibition throughput, efforts were made to find a CYP3A probe that would produce a fluorescent metabolite. This paper reports the discovery of DFB as a potential CYP3A fluorescent probe. DFB was significantly metabolized in human microsomes (approximately 1-2 nmol/(min. mg protein)) to give the fluorescent compound DFH. The involvement of CYP3A in the metabolism of DFB was determined using multiple approaches. First, incubations conducted with microsomes made from cell lines expressing single CYPs (Gentest Supersomes) indicated that CYP3A played a major role in the metabolism of DFB. Secondly, immunoinhibition studies conducted with CYP3A antibody resulted in >95% inhibition of DFB metabolism in HLM. Thirdly, inhibition studies with specific CYP1A1, 1A2, 2C8/9, 2C19, 2D6, and 2E1 chemical inhibitors did not suppress DFB activity in HLM. However, ketoconazole, miconazole, nicardipine, and nifedipine, all known CYP3A inhibitors, completely abolished the formation of DFH in HLM. The potency of several inhibitors determined using DFB and testosterone as CYP3A probes was consistent (R = 0.98). Finally, a good agreement was obtained for the formation of DFH and production of 6 beta-hydroxytestosterone when DFB and testosterone were incubated separately with various human liver microsome preparations (R = 0.94, N = 11). In order to use DFH as a fluorescent CYP3A marker in a 96-well plate format, it was important to remove the excess of NADPH at the end of the incubation because the fluorescence of NADPH interferes with DFH detection. This was achieved by adding oxidized glutathione and glutathione reductase to convert NADPH to NADP(+) which is not fluorescent. The liquid-handling steps were fully automated in a 96-well plate format and a template was designed to generate IC(50) curves and to address potential fluorescent interferences from the test compounds. The assay was found to be reproducible (intraday variability <10% and interday variability indicated less than a 2-fold variation in the IC(50) values) and is now routinely used in our laboratory to evaluate CYP3A inhibition of NCEs.

Induction of cytochrome-P450 in cryopreserved rat and human hepatocytes.

Our laboratory has been routinely using suspended and cultured human hepatocytes for predicting drug metabolism and enzyme induction by drug candidates to aid drug discovery. Increasing limitation and irregular availability of human tissue has indicated the need for maximizing the use of this valuable resource. Cryopreservation of surplus hepatocytes after isolation would greatly increase the potential of this model. However, cryopreservation of hepatocytes by various methods has resulted in cells with poor metabolic activity and unacceptably low survival rates in culture. Recently, Zaleski et al. (Biochem. Pharmacol. 46 (1993) 111-116) reported that cryopreserved rat hepatocytes retained metabolic capacity similar to fresh hepatocytes when the cells were preincubated for 30 min at 37 degrees C in Krebs Ringer bicarbonate buffer prior to freezing. To further explore this methodology, both the functional capacity of the cells in culture as well as their ability to retain CYP inducibility were investigated with thawed cryopreserved hepatocytes. Although human hepatocytes were used in this study the initial work focused on rat hepatocytes as a cell model. Our results showed that while the preincubation step did not appear to effect the initial viability of cryopreserved hepatocytes, survival of the cells in culture was greatly enhanced. Plating efficiencies for nonpreincubated cryopreserved hepatocytes were decreased to approximately 15% of fresh cells after 48 h in culture. In contrast, cells that had been preincubated prior to freezing had an excellent plating efficiency (approximately 60%) and responded to classical CYP inducers dexamethasone, beta-naphthoflavone and phenobarbital in a manner indistinguishable from that of fresh hepatocytes. Experiments with human hepatocytes have also demonstrated similar results. This is the first time to our knowledge that cryopreserved hepatocytes from both rat and human have been shown to reproducibly respond to CYP inducers in culture.

2,3-Diarylcyclopentenones as orally active, highly selective cyclooxygenase-2 inhibitors.

Cyclopentenones containing a 4-(methylsulfonyl)phenyl group in the 3-position and a phenyl ring in the 2-position are selective inhibitors of cyclooxygenase-2 (COX-2). The selectivity for COX-2 over COX-1 is dramatically improved by substituting the 2-phenyl group with halogens in the meta position or by replacing the phenyl ring with a 2- or 3-pyridyl ring. Thus the 3,5-difluorophenyl derivative 7 (L-776,967) and the 3-pyridyl derivative 13 (L-784,506) are particularly interesting as potential antiinflammatory agents with reduced side-effect profiles. Both exhibit good oral bioavailability and are potent in standard models of pain, fever, and inflammation yet have a much reduced effect on the GI integrity of rats compared to standard nonsteroidal antiflammatory drugs.

Cryopreservation of rat and human liver slices by rapid freezing.

The cryopreservation of human liver slices is a promising way to enhance the ability to test the metabolism of drug candidates. This study demonstrates the use of a novel technique for the cryopreservation of both rat and human liver slices. In this technique the slices are treated with Me2SO and sandwiched between aluminum plates separated by a thin gasket. The device is then submerged in liquid nitrogen to freeze the slices, which can then be stored until use. To thaw the slices, the apparatus is submerged in a water bath at 37 degrees C. Slices frozen and thawed in this manner were compared to those frozen in conventional cryovials. The viability of the slices was determined by incubating them in 12-well plates and measuring urea synthesis, ethoxycoumarin metabolism, and cytosolic enzyme leakage (LDH and ALT). The viability of rat slices frozen between plates approached that of fresh slices and was consistently higher than slices frozen in cryovials. Slices from two human samples gave similar results. The technique was found to work over a wide range of Me2SO concentrations (4.5 to 22% was tested) with an optimal concentration between 10 and 15%.

Oxidative bioactivation of the lactol prodrug of a lactone cyclooxygenase-2 inhibitor.

The lactol derivative of a lactone cyclooxygenase-2 inhibitor (DFU) was evaluated in vivo and in vitro for its potential suitability as a prodrug. DFU-lactol was found to be 10 to 20 times more soluble than DFU in a variety of aqueous vehicles. After administration of DFU-lactol at 20 mg kg-1 p.o. in rats, a Cmax of 7.5 microM DFU was reached in the plasma. After oral administration, the ED50s of DFU-lactol in the carrageenan-induced paw edema and lipopolysaccharide-induced pyresis assays in rats are comparable with the ED50s observed when dosing with DFU. Incubations of DFU-lactol with rat and human hepatocytes demonstrated that the oxidation of DFU-lactol can be mediated by liver enzymes and that a competing pathway is direct glucuronidation of the DFU-lactol hydroxyl group. Assays with subcellular fractions from rat liver indicated that most of the oxidation of DFU-lactol occurs in the cytosolic fraction and requires NAD(P)+. Human liver cytosol can also support the oxidation of DFU-lactol to DFU when NAD(P)+ is added to the incubations. Fractionation of human liver cytosolic proteins showed that at least three enzymes are capable of efficiently effecting the oxidation of DFU-lactol to DFU. Incubations with commercially available dehydrogenases suggest that alcohol and hydroxysteroid dehydrogenases are involved in this oxidative process. These data together suggest that lactols may represent useful prodrugs for lactone-containing drugs.

Refinement of an in vitro cell model for cytochrome P450 induction.

Induction of cytochromes P450 (P450s) by drugs can lead to drug-drug interactions. Primary hepatocytes have been reported to retain inducible P450s. To optimize the use of primary hepatocytes for predicting induction of P450 (CYP 3A and 2B) expression in vivo, both culture conditions and expression of induction potentials were investigated. In rat hepatocytes, basal CYP 3A1/2 expression was better maintained in cells cultured on Matrigel compared with collagen when low concentrations of dexamethasone were used. However, CYP 3A1/2 induction was not affected by either matrix. In contrast, induction of CYP 2B1/2 by phenobarbital was markedly stronger in hepatocytes cultured on Matrigel. To further validate the in vitro model, Sprague-Dawley rats and isolated hepatocytes cultured on Matrigel were exposed to a series of compounds. In an attempt to minimize large variability between experiments, a novel approach for calculating induction potential was applied. In vitro results for CYP 3A1/2 and 2B1/2 induction correlated well with those observed in vivo. In contrast with rat hepatocytes, basal CYP 3A4 expression in human hepatocytes decreased rapidly in cells cultured on either Matrigel or collagen. However, CYP 3A4 inducibility was retained in cells cultured on either matrix. Interestingly, induction of CYP 3A4 in human hepatocytes by several model compounds did not correlate with the induction of CYP 3A1/2 in rat hepatocytes. This in vitro assay should facilitate the demand for a fast and reproducible method for addressing P450 induction by numerous compounds at the drug discovery stage.

Effect of common organic solvents on in vitro cytochrome P450-mediated metabolic activities in human liver microsomes.

In this study, we report the effect of methanol, dimethyl sulfoxide (DMSO), and acetonitrile on the cytochrome P450 (P450)-mediated metabolism of several substrates in human liver microsomes: phenacetin O-deethylation for P4501A2, coumarin 7-hydroxylation for P4502A6, tolbutamide hydroxylation for P4502C8/2C9, S-mephenytoin 4'-hydroxylation for P4502C19, dextromethorphan O-demethylation for P4502D6, chlorzoxazone 6-hydroxylation for P4502E1, and testosterone 6beta-hydroxylation for P4503A4. DMSO was found to inhibit several P450-mediated reactions (2C8/2C9, 2C19, 2E1, and 3A4) even at low concentrations (0.2%). There was no measurable effect on the catalytic activity of the various P450s when methanol was present at levels

In vitro comparison of cytochrome P450-mediated metabolic activities in human, dog, cat, and horse.

As domestic animals such as cat, horse, and dog increasingly become the clinical targets for drug discovery programs, the need to understand how these animals metabolize xenobiotics becomes more important. In the present study, substrates and inhibitors that were reported to be selective for particular P450 isozymes were used as probes to study in vitro metabolism in horse, dog, cat, and human liver microsomes. Seven selective catalytic activity markers for cytochrome P450-mediated reactions were measured: phenacetin O-deethylase (P4501A1/2), coumarin 7-hydroxylase (P4502A6), tolbutamide hydroxylase (P4502C8/9), S-mephenytoin 4'-hydroxylase (P4502C19), dextromethorphan O-demethylase (P4502D6), chlorzoxazone 6-hydroxylase (P4502E1), and testosterone 6beta-hydroxylase (P4503A4). Metabolic activity was found in every species with each substrate. Under the conditions of this study, it was observed that no one species was more active for any given substrate. However, rather large interspecies differences were observed. There was no marked sex difference in the way the various species metabolized the different substrates. The effect of selective P450 inhibitors on the various activities was tested with furafylline (P4501A2), mouse monoclonal antibody inhibitory to CYP2A6, sulfaphenazole (P4502C9), tranylcypromine (P4502C19), quinidine (P4502D6), diethyldithiocarbamate (P4502E1), and troleandomycin (P4503A4). In most cases, these inhibitors were effective to varying degrees against the activity seen in horse, dog, and cat liver microsomes. However, even at high concentrations, furafylline did not inhibit phenacetin O-deethylase activity in cat and troleandomycin did not affect testosterone 6beta-hydroxylase activity in horse. Sulfaphenazole was not tested in dog and cat because of the low tolbutamide hydroxylase activity. Overall, these results show that there are also large interspecies differences in the way the selective P450 inhibitors affect the in vitro metabolism of the various substrates in horse, dog, and cat liver microsomes.

Dioxabicyclooctanyl naphthalenenitriles as nonredox 5-lipoxygenase inhibitors: structure-activity relationship study directed toward the improvement of metabolic stability.

Naphthalenic lignan lactone 3a (L-702,539), a potent and selective 5-lipoxygenase (5-LO) inhibitor, is extensively metabolized at two different sites: the tetrahydropyran and the lactone rings. Early knowledge of the metabolic pathways triggered and directed a structure-activity relationship study aimed toward the improvement of metabolic stability in this series. The best modifications discovered, i.e., replacement of the lactone ring by a nitrile group, replacement of the tetrahydropyran ring by a 6,8-dioxabicyclo[3.2.1]octanyl moiety, and replacement of the pendant phenyl ring by a 3-furyl ring, were incorporated in a single molecule to produce inhibitor 9ac (L-708,780). Compound 9ac inhibits the oxidation of arachidonic acid to 5-hydroperoxy-eicosatetraenoic acid by 5-LO (IC50 = 190 nM) and the formation of leukotriene B4 in human polymorphonuclear leukocytes (IC50 = 3 nM) as well as in human whole blood (IC50 = 150 nM). The good inhibitory profile shown by naphthalenenitrile 9ac is accompanied by an improved resistance to oxidative metabolism. In addition, 9ac is orally active in the functional model of antigen-induced bronchoconstriction in allergic squirrel monkeys (95% inhibition at 0.1 mg/kg).

Microsomal metabolism of the 5-lipoxygenase inhibitors L-746,530 and L-739,010 to reactive intermediates that covalently bind to protein: the role of the 6,8-dioxabicyclo[3.2.1]octanyl moiety.

Hepatic microsomes from different species were used to study the oxidative metabolism of L-746,530 and L-739,010, two potent and specific 5-lipoxygenase inhibitors. HPLC analysis of the incubates obtained from the microsomal incubations of L-739,010 and L-746,530 showed only traces of metabolites. However, recovery of the starting material in the supernatant was less than quantitative in all of the species studied (approximately 90% in rat, approximately 70% in the dexamethasone-induced rat, approximately 70-90% in humans, and approximately 60% in the rhesus monkey for both compounds). The recovery of the starting material was found to be time- and NADPH-dependent, suggesting that metabolite(s) were formed and reacting with the microsomal proteins. Evidence that the cytochrome P4503A (CYP3A) contributed to the formation of the reactive metabolite(s) was shown by the low recovery of material that was observed upon incubation with microsomes obtained from dexamethasone-treated rats (a CYP3A inducer), compared with microsomes obtained from untreated rats. Also, the recovery of material was improved when troleandomycin, a CYP3A inhibitor, was added to rhesus monkey microsomal incubations (25% more parent compound detected in the supernatant with 100 microM of troleandomycin). Using radiolabeled L-746,530 and gel electrophoresis analysis, it was confirmed that radiolabeled material was covalently bound to the microsomal protein. Incubations of L-739,010 and L-746,530 in the presence of semicarbazide resulted, in both cases, in the formation of two adducts. Using a combination of NMR, liquid secondary-ion MS, and UV techniques, these adducts were identified as isomers of an oxidized metabolite that had been trapped by semicarbazide. The site of oxidation was determined to be on the dioxabicyclo moiety. The importance of this moiety in the formation of reactive metabolite(s) was verified by incubating analogs of the 5-lipoxygenase inhibitors that contained blocking methyl groups at the proposed site of oxidation on the bicyclo moiety. Incubations of these gemdimethyl analogs of L-746,530 and L-739,010 with microsomes from different species resulted in significantly improved recovery of the starting material (approximately 94% in the rat, 85% in the dexamethasone-induced rat, 95% in humans, and 85% in the rhesus monkey for both compounds) and significantly less radioactive binding to the microsomal protein.

Verlukast (MK-0679) conjugation with glutathione by rat liver and kidney cytosols and excretion in the bile.

Verlukast (MK-0679) is a potent leukotriene D4 antagonist that was under development for the treatment of bronchial asthma. A previously uncharacterized metabolite of verlukast was formed in incubations using rat liver cytosol fortified with glutathione (GSH). The metabolite was detected by HPLC and characterized by UV spectroscopy (photodiode array detection after HPLC) and capillary HPLC continuous flow-liquid secondary-ion mass spectrometry. After a large-scale incubation and isolation, it was further characterized by 500 MHz proton NMR. The metabolite is a 1,4-Michael addition product in which GSH has added to position 12 of the styryl quinoline double bond of verlukast. There is no apparent stereoselectivity because a mixture of the two possible isomers, in equal amounts, was observed by NMR. Although there was spontaneous chemical addition of GSH to verlukast (0.18 nmol/min), the reaction was shown to be enzyme-catalyzed in studies using three different preparations of rat liver cytosol at pH 7.4. Using Lineweaver-Burk analysis of experiments in which the effect of verlukast concentration on the rate of conjugation was studied, the apparent KM and Vmax were determined to be 107 +/- 22 microM (SD, N=3) and 0.66 +/- 0.21 nmol/min/mg protein, respectively. In similar studies with GSH as the variable substrate, the apparent KM and Vmax were 2.32 +/- 0.68 mM and 0.69 +/- 0.14 nmol/min/mg protein, respectively. Incubations with kidney cytosol produced the GSH, cysteinylglycine, and cysteine conjugates of verlukast. In bile collected from rats dosed intravenously with 50 mg/kg of verlukast, approximately 80% of the dose was recovered up to 4 hr postdose. The GSH conjugate accounted for 16.5% of the dose. The cysteinylglycine, cysteine, and N-acetylcysteine conjugates were observed and together accounted for 7.5%. Verlukast accounted for 14.5%, and the remainder of the metabolites (40.5%) were oxidation or acyl glucuronide metabolites.

Integrated application of capillary HPLC/continuous-flow liquid secondary ion mass spectrometry to discovery stage metabolism studies.

The application of capillary HPLC/continuous-flow liquid secondary ion mass spectrometry (CF-LSIMS) as part of an integrated approach for characterizing discovery stage in vitro metabolites, using a specific inhibitor for 5-lipoxygenase as a model compound, was investigated. CF-LSIMS demonstrated excellent sensitivity in detecting the metabolites in both the positive and the negative ion modes, with a good full-scan mass spectrum obtained when 5 pmol of metabolite was injected onto the capillary column. Strong pseudomolecular ions and key fragment ions were observed in the primary spectra of the parent drug and its three oxidative in vitro metabolites, allowing the site of metabolism to be pinpointed to particular substructures. This technique demonstrated versatility and offered a very rapid screening procedure for metabolite identification.