DNA adduct formation by alachlor metabolites

The extent of DNA adduct formation by alachlor [ArN(CH2OCH3)C(O)CH2Cl wherein Ar is 2,6-diethylphenyl] and its metabolites is used as a guide to deduce the causal agent(s) in the carcinogenicity of this major herbicide. [14C-phenyl]Alachlor is compared to its two metabolic cleavage products, [14C-phenyl]2-chloro-N-(2,6-diethylphenyl)acetamide (CDEPA) [ArNHC(O)CH2Cl] and [14C-phenyl]2,6-diethylaniline (DEA) (ArNH2), and to [14C-methoxy]alachlor in various in vitro and in vivo systems. Horseradish peroxidase and hydrogen peroxide activate DEA, but not CDEPA or alachlor, for formation of adducts with calf thymus DNA, which probably involves 2,6-diethylnitrosobenzene (ArNO) as an intermediate. Mouse liver microsomes and NADPH are both required to enhance the binding from each labeled preparation to calf thymus DNA; 4-fold higher labeling is observed from [14C-methoxy]- than from [14C-phenyl]alachlor. This 4-fold preferential DNA labeling from the 14C-methoxy compound is likewise found in the liver of mice treated intraperitoneally. Mouse liver protein and hemoglobin are also labeled, in vivo, with [14C-phenyl]alachlor, -CDEPA and -DEA, and, as with the DNA, the labeling of these proteins is 1.5- to 2-fold higher with [14C-methoxy]alachlor. Metabolic studies indicate that ArN(CH2OCH2OH)C(O)CH2Cl is an intermediate in forming CDEPA and presumably formaldehyde in the mouse liver microsomal mixed-function oxidase system and in yielding the O-glucuronide of ArN(CH2OH)C(O)CH2Cl in the urine of alachlor-treated mice. These findings point to the N-CH2OCH2OH metabolite or formaldehyde as a reactive intermediate in forming a DNA-adduct and as a candidate proximate carcinogen.     

Comparative cytotoxicity of alachlor, acetochlor, and metolachlor herbicides in isolated rat and cryopreserved human hepatocytes

Noncancerous adverse effects observed at the lowest dose for chloroacetanilide herbicides alachlor [2-chloro-2',6'-diethyl-N-(methoxymethyl)-acetanilide] and acetochlor [2-chloro-2'-methyl-6'-ethyl-N-(ethoxymethyl)acetanilide], but not metolachlor [2-chloro-2'-ethyl-6'-methyl-N-(1-methyl-2-methoxymethyl)acetanilide], are hepatotoxicity in rats and dogs. Liver microsomal N-dealkylation, a step in the putative activating pathway, of acetochlor exceeds that of alachlor and is negligible for metolachlor. In the present investigation, cytotoxicity of the three chloroacetanilides was ranked using isolated rat and cryopreserved human hepatocytes to correlate this endpoint with CYP3A-dependent metabolism. Chloroacetanilide cytotoxicity in rat hepatocyte suspensions was time dependent (e.g., LC(50 - alachlor/2 h) vs. LC(50 - alachlor/4 h) = 765 vs. 325 muM). Alachlor and acetochlor were more potent than metolachlor after 2 and 4 h, times when N-dealkylated alachlor product 2-chloro-N-(2,6-diethylphenyl)acetamide (CDEPA) formation was readily detectable. Alachlor and acetochlor potencies with cryopreserved human hepatocytes at 2 h were comparable to freshly isolated rat hepatocytes, and alachlor metabolism to CDEPA was likewise detectable. Unlike rat hepatocytes, metolachlor potency was equivalent to acetochlor and alachlor in human hepatocytes. Furthermore, chloroacetanilide cytotoxicity from two sources of human hepatocytes varied inversely with CYP3A4 activity. Collectively, while cytotoxicity in rat hepatocytes was consistent with chloroacetanilide activation by CYP3A, an activating role for CYP3A4 was not supported with human hepatocytes.     

Determination of alachlor and its metabolites in rat plasma and urine by liquid chromatography-electrospray ionization mass spectrometry

A method based on liquid chromatography (LC) in combination with mass spectrometry (MS) for the analysis of alachlor (ALA) and its metabolites, 2-chloro-N-[2,6-diethylphenyl]acetamide (CDEPA) and 2,6-diethylaniline (DEA), in rat plasma and urine has been developed. 13C-labeled ALA was used as the internal standard for quantitation. The analyte in plasma or urine was isolated using a Waters Oasis HLB extraction plate. The mass spectrometer was operated in the ESI MS-SIM mode with a programming procedure. The retention times for ALA, CDEPA and DEA were 1.84, 3.11 and 4.12 min, respectively. The limits of quantification (LOQ) for ALA, CDEPA and DEA were 2.3, 0.8 and 0.8 ng per injection, respectively. The linear fit of analyte to mass response had an R2 of 0.99. Reproducibility of the sample handling and LC-MS analysis had a RSD of < or = 10%. The average recoveries for these analytes in rat plasma were better than 90%. Similar results were obtained with rat urine.     

An evaluation of the feasibility of using cytogenetic damage as a biomarker for alachlor exposure

Alachlor is a widely used herbicide for which there is significant human exposure, principally through groundwater contamination and inhalation. Because alachlor is purported to be carcinogenic and mutagenic, we initiated studies to determine if induced cytogenetic damage could be used as a biomarker for exposure to this herbicide. Both isolated and whole blood human lymphocytes were exposed to alachlor using several protocols. The lymphocytes were cultured for analysis of sister chromatid exchange (SCE), chromosome aberrations (CAs), micronuclei (MN) in cytochalasin B-induced binucleated cells, and proliferation kinetics using the replicative index (RI). In addition, CD rats were injected with either 10 or 50 mg kg-1 of alachlor, 2-chloro-N-(2,6-diethylphenyl) acetamide (CDEPA) or 2, 6-diethylanaline (DEA). After 24 h, the peripheral blood lymphocytes were removed and cultured for SCE and RI analysis. Alachlor did induce a concentration-related increase in SCE in vitro, but neither it nor its metabolites (CDEPA or DEA) induced a significant increase in SCEs or an alteration of RI in vivo. At the highest in vitro concentration tested, alachlor induced a statistically-significant increase in MN, but no concomitant increase in CAs was seen. From analyses of our data and the literature on alachlor clastogenicity and exposure levels, we concluded that cytogenetic damage may not be an adequately sensitive marker for evaluating human exposure to alachlor.     

In vitro metabolism of fipronil by human and rat cytochrome P450 and its interactions with testosterone and diazepam

Fipronil (5-amino-1-[2,6-dichloro-4-(trifluoromethyl)phenyl]-4-[(trifluoromethyl)sulfinyl]-1H-pyrazole-3-carbonitrile) is a highly active, broad spectrum insecticide from the phenyl pyrazole family, which targets the gamma-amino butyric acid (GABA) receptor. Although fipronil is presently widely used as an insecticide and acaricide, little information is available with respect to its metabolic fate and disposition in mammals. This study was designed to investigate the in vitro human metabolism of fipronil and to examine possible metabolic interactions that fipronil may have with other substrates. Fipronil was incubated with human liver microsomes (HLM) and several recombinant cytochrome P450 (CYP) isoforms obtained from BD Biosciences. HPLC was used for metabolite identification and quantification. Fipronil sulfone was the predominant metabolite via CYP oxidation. The K(m) and V(max) values for human liver microsomes are 27.2 microM and 0.11 nmol/mg proteinmin, respectively; for rat liver microsomes (RLM) the K(m) and V(max) are 19.9 microM and 0.39 nmol/mg proteinmin, respectively. CYP3A4 is the major isoform responsible for fipronil oxidation in humans while CYP2C19 is considerably less active. Other human CYP isoforms have minimal or no activity toward fipronil. Co-expression of cytochrome b(5) (b(5)) is essential for CYP3A4 to manifest high activity toward fipronil. Ketoconazole, a specific inhibitor of CYP3A4, inhibits 78% of the HLM activity toward fipronil at a concentration of 2 microM. Oxidative activity toward fipronil in 19 single-donor HLMs correlated well with their ability to oxidize testosterone. The interactions of fipronil and other CYP3A4 substrates, such as testosterone and diazepam, were also investigated. Fipronil metabolism was activated by testosterone in HLM but not in CYP3A4 Supersomes. Testosterone 6beta-hydroxylation in HLM was inhibited by fipronil. Fipronil inhibited diazepam demethylation but had little effect on diazepam hydroxylation. The results suggest that fipronil has the potential to interact with a wide range of xenobiotics or endogenous chemicals that are CYP3A4 substrates and that fipronil may be a useful substrate for the characterization of CYP3A4 in HLM.     

A convenient assay for mephenytoin 4-hydroxylase activity of human liver microsomal cytochrome P-450

A simple and rapid method for the determination of (S)-mephenytoin 4-hydroxylase activity by human liver microsomal cytochrome P-450 has been developed. [Methyl-14C] mephenytoin was synthesized by alkylation of S-nirvanol with 14CH3I and used as a substrate. After incubation of [methyl-14C]mephenytoin with human liver microsomes or a reconstituted monooxygenase system containing partially purified human liver cytochrome P-450, the 4-hydroxylated metabolite of mephenytoin was separated by thin-layer chromatography and quantified. The formation of the metabolite depended on the incubation time, substrate concentration, and cytochrome P-450 concentration and was found to be optimal at pH 7.4. The Km and Vmax rates obtained with a human liver microsomal preparation were 0.1 mM and 0.23 nmol 4-hydroxymephenytoin formed/min/nmol cytochrome P-450, respectively. The hydroxylation activity showed absolute requirements for cytochrome P-450, NADPH-cytochrome P-450 reductase, and NADPH in a reconstituted monooxygenase system. Activities varied from 5.6 to 156 pmol 4-hydroxymephenytoin formed/min/nmol cytochrome P-450 in 11 human liver microsomal preparations. The basic system utilized for the analysis of mephenytoin 4-hydroxylation can also be applied to the estimation of other enzyme activities in which phenol formation occurs.     

Biotransformation of (-)-menthone by human liver microsomes

The aim of the current study was to investigate the metabolism of (-)-menthone by liver microsomes of humans. (-)-Menthone (1) was metabolized to (+)-neomenthol (2) (3-reduction) and 7-hydroxymenthone (3) by human liver microsomes. The metabolites formed were analyzed on GC and GC-MS. Kinetic analysis showed that K(m) and V(max) values for the metabolized (-)-menthone to respective (+)-neomenthol and 7-hydroxymenthone by liver microsomes of human sample HG70 were 0.37 mM and 4.91 nmol/min/mg protein and 0.07 mM and 0.71 nmol/min/mg protein.     

Acetaminophen activation by human liver cytochromes P450IIE1 and P450IA2

Acetaminophen (APAP), a widely used over-the-counter analgesic, is known to cause hepatotoxicity when ingested in large quantities in both animals and man, especially when administered after chronic ethanol consumption. Hepatotoxicity stems from APAP activation by microsomal P450 monooxygenases to a reactive metabolite that binds to tissue macromolecules, thereby initiating cellular necrosis. Alcohol consumption also causes the induction of P450IIE1, a liver microsomal enzyme that in reconstitution studies has proven to be an effective catalyst of APAP oxidation. Thus, elevated microsomal P450IIE1 levels could explain not only the known increase in APAP bioactivating activity of liver microsomes after prolonged ethanol ingestion but also the enhanced susceptibility to APAP toxicity. We therefore examined the role of P450IIE1 in human liver microsomal APAP activation. Liver microsomes from seven non-alcoholic subjects were found to convert 1 mM APAP to a reactive intermediate (detected as an APAP-cysteine conjugate by high-pressure liquid chromatography) at a rate of 0.25 +/- 0.1 nmol conjugate formed/min/nmol microsomal P450 (mean +/- SD), whereas at 10 mM, this rate increased to 0.73 +/- 0.2 nmol product/min/nmol P450. In a reconstituted system, purified human liver P450IIE1 catalyzed APAP activation at rates threefold higher than those obtained with microsomes whereas two other human P450s, P450IIC8 and P450IIC9, exhibited negligible APAP-oxidizing activity. Monospecific antibodies (IgG) directed against human P450IIE1 inhibited APAP activation in each of the human samples, with anti-P450IIE1 IgG-mediated inhibition averaging 52% (range = 30-78%) of the rates determined in the presence of control IgG. The ability of anti-P450IIE1 IgG to inhibit only one-half of the total APAP activation by microsomes suggests, however, that other P450 isozymes besides P450IIE1 contribute to bioactivation of this compound in human liver. Of the other purified P450 isozymes examined, a beta-naphthoflavone (BNF)-inducible hamster liver P450 promoted APAP activation at rates even higher than those obtained with human P450IIE1. The extensive APAP-oxidizing capacity of this hamster P450, designated P450IA2 based upon its similarity to rat P450d and rabbit form 4 in terms of NH2-terminal amino acid sequence, spectral characteristics, immunochemical properties, and inducibility by BNF, agrees with previous reports concerning the APAP substrate specificity of the rat and rabbit P450IA2 proteins.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Characterization of a phenobarbital-inducible dog liver cytochrome P450 structurally related to rat and human enzymes of the P450IIIA (steroid-inducible) gene subfamily

A cytochrome P450 called PBD-1 isolated from liver microsomes of an adult male Beagle dog treated with phenobarbital (PB) is structurally and functionally similar to members of the P450IIIA gene subfamily in rat and human liver microsomes. The sequence of the first 28 amino-terminal residues of PBD-1 is identical in 15 and 20 positions, respectively, to the P450IIIA forms P450p from rat and P450NF (and HLp) from human. Upon immunoblot analysis, anti-PBD-1 IgG recognizes PCNa (P450p) and PCNb (PB/PCN-E) from rat, P450NF from human, and two proteins in liver microsomes from both untreated and PB-treated dogs. Similarly, anti-PCNb IgG cross-reacts with PBD-1 and with at least one protein in microsomes from untreated dogs and two proteins in microsomes from PB-treated dogs. P450IIIA-form marker steroid 6 beta-hydroxylase activities increase 2.5-fold upon PB-treatment of dogs and are selectively inhibited by anti-PBD-1 IgG. NADPH-dependent triacetyloleandomycin (TAO) complex formation and erythromycin demethylase, also marker activities for P450IIIA forms from rats and humans, increase 4- and 5-fold in dog liver microsomes upon PB treatment, whereas immunochemically reactive PBD-1 is induced 3-fold. In microsomes from PB-treated dogs, 5 mg anti-PBD-1 IgG/nmol P450 inhibits greater than 75 and 50% of TAO complex formation and erythromycin demethylase activity, respectively. TAO complex formation is not inhibited by chloramphenicol, a selective inhibitor of the major PB-inducible dog liver cytochrome P450, PBD-2. These data suggest that PBD-1 or another immunochemically related form is responsible for a major portion of macrolide antibiotic metabolism by microsomes from PB-treated dogs and for steroid 6 beta-hydroxylation by microsomes from both untreated and PB-treated dogs. Major species differences were noted, however, in the apparent Km for 6 beta-hydroxylation of androstenedione by liver microsomes from untreated rats (24 microM), humans (380 microM), and untreated dogs (4700 microM).     

Metabolic activation of alpha-naphthoflavone by 2,3,7,8-tetrachlorodibenzodioxin-induced rat liver microsomes

Previous studies in our laboratory had demonstrated that addition of alpha-naphthoflavone (ANF) to lymphocytes from smokers or polychlorinated biphenyls (PCB)s-exposed individuals caused an increase in sister chromatid exchange (SCE) frequency whereas lymphocytes from controls were relatively unaffected. In order to investigate the mechanism responsible, metabolism of ANF by uninduced and 2,3,7,8-tetrachlorodibenzodioxin (TCDD)-induced microsomes was studied as a function of microsomal protein concentration and incubation time. Nonpolar metabolites were analyzed and the amount of conjugated (polar) and protein-bound metabolites determined. The initial ANF-metabolism rate was 10-fold higher in TCDD-induced microsomes (4.9 +/- 0.6 nmol/min per mg TCDD-induced microsomal protein vs. 0.5 +/- 0.2 nmol/min per mg uninduced microsomal protein) than in uninduced microsomes. Moreover, uninduced microsomes no longer metabolize ANF after 30-40 min while TCDD-induced microsomes metabolize ANF for longer than 2 h or until all the ANF is gone. In addition to the metabolites formed by uninduced microsomes [7,8-dihydro-7,8-dihydroxy-ANF (7,8-dihydrodiol); 5,6-dihydro-5,6-dihydroxy-ANF (5,6-dihydrodiol); 5,6-oxide-ANF and 6-hydroxy-ANF], TCDD-induced microsomes from unidentified metabolites. When TCDD-induced microsomes and 40 microM ANF were added to Chinese hamster ovary (CHO) cells, we found a correlation between the concentration of 5,6-oxide-ANF and clastogenicity to CHO cells. However, purified 5,6-oxide-ANF did not induce SCEs in CHO cells in the absence or presence of TCDD-induced microsomes. However, a minor metabolite (identified as the 9,10-dihydro-9,10-dihydroxy-ANF by acid dehydration) formed with TCDD-induced microsomes produces clastogenicity in CHO cells. These data indicate that a minor metabolite of ANF is a potent clastogen which suggests that this metabolite may be responsible for the ANF-mediated increases in SCE frequency in lymphocytes from smokers or PCB-exposed individuals.     

The stereoselective metabolism of halofantrine to desbutylhalofantrine in the rat: evidence of tissue-specific enantioselectivity in microsomal metabolism

The pharmacokinetics of the antimalarial drug (+/-)-halofantrine are stereoselective in humans and rats. To better understand the stereoselective metabolism of the drug to its primary metabolite, desbutylhalofantrine (DHF), a series of in vitro and in vivo experiments were undertaken in the rat. Formation of (-)-DHF exceeded that of (+)-DHF in liver microsomes [(-):(+) ratio of intrinsic formation clearances = 1.4]. In contrast, in intestinal microsomes no significant stereoselectivity was noted in the formation of the DHF enantiomers. Intestinal microsomes were also less efficient at producing the DHF enantiomers than were liver microsomes. Based on kinetic analysis of the DHF formation, there appeared to be more than one enzyme involved in the biotransformation. (+/-)-Ketoconazole (KTZ) effectively inhibited the formation of both DHF enantiomers by both liver and intestinal microsomes, although the reduction was more marked in liver microsomes. Through a combination of the use of CYP antibodies and recombinant CYP isoenzymes, the involvement of CYP 2B1/2, 3A1, 3A2, 1A1, 2C11, 2C6, 2D1, and 2D2 were implicated in the metabolism of halofantrine to DHF. Of these, CYP3A1/2 and CYP2C11 appeared to be the primary isoenzymes involved, although CYP2C11 showed greater (+)-DHF than (-)-DHF formation, whereas for CYP3A1 it was similar to the isolated rat liver microsomes. In vivo, oral (+/-)-KTZ caused significant increases in plasma halofantrine and decreases in DHF enantiomer plasma concentrations.     

Cocaine metabolism in human fetal and adult liver microsomes is related to cytochrome P450 3A expression

Cocaine N-demethylation to norcocaine was studied in human liver microsomes of different ages. Norcocaine was formed at a considerable rate in fetal (45.4+/-18.2 nmol/mg x hour, n = 8) and adult specimens (82.0+/-46.6 nmol/mg x hour, n = 15), p = 0.04 (Mann-Whitney). Furthermore, the apparent Km values in fetal specimens (0.57 and 0.48 mM, n = 2) showed a higher affinity compared with those of adults (mean value 2.7 (1.8-4.25) mM, n = 4). Estimated enzyme metabolic clearance with respect to P450 total content was higher in fetal than in adult liver microsomes (2.22 ml/nmol P450 x hour, and 0.18 (0.14-0.23) ml/nmol P450 x hour, respectively). Several drugs, known to be CYP3A substrates, were used as potential inhibitors of cocaine metabolism. Midazolam, ergotamine and erythromycin showed strong inhibition (approx. 70 %) when used at concentrations of 500 microM (midazolam, erythromycin) or 200 microM (ergotamine). The metabolism of 1 mM cocaine correlated strongly with immunodetected CYP3A protein determined by Western blotting in both fetal (r = 0.89, p = 0.19) and adult specimens (r = 0.82, p < 0.01) . These findings further support CYP3A as a major catalyst of norcocaine formation in human liver microsomes. These results are important given the potential risk of toxicity to the foetus of maternal cocaine abuse during pregnancy. Although the high Km values found in adult livers reduce the importance of this enzyme pathway in cocaine detoxication, this pathway would emerge as significant in circumstances of CYP3A induction and/or drug interactions leading to potential liver toxicity in chronic cocaine abusers.     

Metabolism of 1,8-cineole by human cytochrome P450 enzymes: identification of a new hydroxylated metabolite

Human metabolism of the monoterpene cyclic ether 1,8-cineole was investigated in vitro and in vivo. In vitro, the biotransformation of 1,8-cineole was investigated by human liver microsomes and by recombinant cytochrome P450 enzymes coexpressed with human CYP-reductase in Escherichia coli cells. Besides the already described metabolite 2alpha-hydroxy-1,8-cineole we found another metabolite produced at high rates. The structure was identified by a comparison of its mass spectrum and retention time with the reference compounds as 3alpha-hydroxy-1,8-cineole. There was a clear correlation between the concentration of the metabolites, incubation time and enzyme content, respectively. CYP3A4/5 antibody significantly inhibited the 2alpha- and 3alpha-hydroxylation catalyzed by pooled human liver microsomes. Further kinetic analysis revealed that the Michaelis-Menten K(m) and V(max) for oxidation of 1,8-cineole in position three were 19 microM and 64.5 nmol/min/nmol P450 for cytochrome P450 3A4, and 141 microM and 10.9 nmol/min/nmol P450 for cytochrome P450 3A5, respectively. To our knowledge, this is the first time that 3alpha-hydroxy-1,8-cineole is described as a human metabolite of 1,8-cineole. We confirmed these in vitro results by the investigation of human urine after the oral administration of cold medication containing 1,8-cineole. In human urine we found by GC-MS analysis the described metabolites, 2alpha-hydroxy-1,8-cineole and 3alpha-hydroxy-1,8-cineole.     

Metabolism of retinol and retinoic acid by human liver cytochrome P450IIC8

Liver microsomes obtained from nine subjects were found to metabolize retinol to polar metabolites, including 4-hydroxyretinol. In a reconstituted monooxygenase system containing human liver P450IIC8, retinol was converted to 4-hydroxyretinol and other polar metabolites, with a Km of 0.071 mM and a Vmax of 1.73 nmol/min/nmol P450. Neither P450IIC9 nor P450IIE1, two other purified human P450s, displayed significant retinol hydroxylase activity. Immunoblots performed with a monospecific antibody directed against human P450IIC8 revealed that appreciable amounts of this enzyme were present in human liver microsomes. The same antibody significantly inhibited retinol metabolism in liver microsomes and in the system reconstituted with P450IIC8. The system reconstituted with P450IIC8 also converted retinoic acid to polar metabolites. Thus, this study shows, for the first time, metabolism of two physiologic substrates by a human liver cytochrome P450 related to a group of "constitutive" rodent P450s believed to participate in the metabolism of endogenous compounds. Through its involvement in vitamin A metabolism, P450IIC8 may participate in maintaining the balance between those vitamin A concentrations that promote cellular integrity (and oppose the development of cancer) and those concentrations that cause cellular toxicity.     

Characterization of the human hepatic cytochromes P450 involved in the in vitro oxidation of clozapine.

It was aimed to identify the cytochrome(s) P450 (CYPs) involved in the N-demethylation and N-oxidation of clozapine (CLZ) by various approaches using human liver microsomes or microsomes from human B-lymphoblastoid cell lines. The maximum rates of formation were measured in the microsomal fraction of human livers and the Michaelis-Menten kinetics one enzyme model was found to best fit the data with mean K(M) for CLZ N-oxide and N-desmethyl-CLZ of 336 and 120 microM, respectively. Significant correlations were observed between the maximum rates of formation (Vmax) for CLZ N-oxide and N-desmethyl-CLZ with the microsomal immunoreactive contents of CYP1A2 (r = 0.92, P < 0.009 and r = 0.77, P < 0.077; respectively) and CYP3A (r = 0.89, P < 0.02 and r = 0.82, P < 0.05; respectively). Antibodies directed against CYP1A2 and CYP3A inhibited formation of CLZ N-oxide in human liver microsomes by 10.7+/-6.1%) and 37.2+/-6.9% of control, respectively, whereas CLZ N-demethylation was inhibited by 32.2+/-15.4% and 33.6+/-7.4%, respectively. Troleandomycin (CYP3A inhibitor) and furafylline (CYP1A2 inhibitor) inhibited CLZ N-oxidation in human liver microsomes by 23.2+/-12.1% and 7.8+4.3%, respectively, whereas CLZ N-demethylation was inhibited by 17.5+/-13.9% and 25.6+/-16.5%, respectively. While ketoconazole did not inhibit N-oxidation of CLZ, the N-demethylation pathway was inhibited by 34.1+/-10.0%. Formation in stable expressed enzymes indicated involvement of CYP3A and CYP1A2 in CLZ N-oxide formation and CYP2D6, CYP1A2 and CYP3A4 in CLZ N-demethylation. This apparent involvement of CYP2D6 in the N-demethylation of CLZ did not corroborate with the findings of other experiments. In conclusion, these data indicate that while both CYP isoforms readily catalyze both metabolic routes in vitro, CYP1A2 and CYP3A4 are more important in N-demethylation and N-oxidation, respectively.     

Metabolism of [4-14C]estrone in hamster and rat hepatic and renal microsomes: species-, sex- and age-specific differences.

The metabolism of [4-14C]estrone (E1) was examined in liver and kidney microsomes of adult castrated male and ovariectomized female hamsters and rats and in neonatal and immature hamster renal microsomes. In castrated male hamster liver microsomes, E1 was metabolized extensively to six major metabolites; 15 beta-hydroxyestrone, 7 alpha-hydroxyestrone, 6 alpha-hydroxyestrone, 6 beta-hydroxyestrone, 2-hydroxyestrone, and delta(9,11)-dehydroestrone, and a nonpolar fraction. Six minor metabolites of E1 were also detected. In contrast, kidney microsomes derived from castrated male hamsters metabolized E1 to mainly 17 beta-estradiol, 2- and 4-hydroxyestrone, 6 alpha-hydroxyestrone, 6 beta-hydroxyestrone and one monohydroxyestradiol metabolite. However, 16 alpha-hydroxyestrone was not detected. A variable, but low amount of estriol was also found. Interestingly, the quantity of 2-hydroxyestrone found in kidney microsomes of the hamster represented 26% of the total amount of metabolites formed, whereas in liver microsomes, only 9% of the overall metabolism resulted in the formation of 2-hydroxyestrone. The ability of kidney microsomes of female ovariectomized hamsters and two different rat strains to metabolize E1 was 5.9- and 9.4-fold lower, respectively, compared to renal microsomes of male castrated hamsters. The onset of oxidative metabolism in newborn hamster kidneys during development was also assessed. The results indicate that the oxidative metabolism of [14C]E1 in renal microsomes of newborn hamsters was 20-fold less than in kidney microsomes of adult hamsters. While catechol E1 metabolites were essentially negligible in hamster kidneys of these ages, it was evident that the conversion of E1 to estradiol via 17 beta-hydroxysteroid dehydrogenase resembles levels seen in the adult animals. Between the age of one and two months, the male hamster kidney exhibited the capacity to metabolize E1 at levels seen in fully mature adult hamsters.     

6alpha-hydroxylation of taurochenodeoxycholic acid and lithocholic acid by CYP3A4 in human liver microsomes

The aim of the present study was to identify the enzymes in human liver catalyzing hydroxylations of bile acids. Fourteen recombinant expressed cytochrome P450 (CYP) enzymes, human liver microsomes from different donors, and selective cytochrome P450 inhibitors were used to study the hydroxylation of taurochenodeoxycholic acid and lithocholic acid. Recombinant expressed CYP3A4 was the only enzyme that was active towards these bile acids and the enzyme catalyzed an efficient 6alpha-hydroxylation of both taurochenodeoxycholic acid and lithocholic acid. The Vmax for 6alpha-hydroxylation of taurochenodeoxycholic acid by CYP3A4 was 18.2 nmol/nmol P450/min and the apparent Km was 90 microM. Cytochrome b5 was required for maximal activity. Human liver microsomes from 10 different donors, in which different P450 marker activities had been determined, were separately incubated with taurochenodeoxycholic acid and lithocholic acid. A strong correlation was found between 6alpha-hydroxylation of taurochenodeoxycholic acid, CYP3A levels (r2=0.97) and testosterone 6beta-hydroxylation (r2=0.9). There was also a strong correlation between 6alpha-hydroxylation of lithocholic acid, CYP3A levels and testosterone 6beta-hydroxylation (r2=0.7). Troleandomycin, a selective inhibitor of CYP3A enzymes, inhibited 6alpha-hydroxylation of taurochenodeoxycholic acid almost completely at a 10 microM concentration. Other inhibitors, such as alpha-naphthoflavone, sulfaphenazole and tranylcypromine had very little or no effect on the activity. The apparent Km for 6alpha-hydroxylation of taurochenodeoxycholic by human liver microsomes was high (716 microM). This might give an explanation for the limited formation of 6alpha-hydroxylated bile acids in healthy humans. From the present results, it can be concluded that CYP3A4 is active in the 6alpha-hydroxylation of both taurochenodeoxycholic acid and lithocholic acid in human liver.     

Metabolism of carbamazepine by CYP3A6: a model for in vitro drug interactions studies

Carbamazepine (CBZ) is widely used in the treatment of epilepsy. The drug is principally metabolized by CYPs to 10, 11-epoxy carbamazepine (CBZ-E) but this metabolite more toxic than the parent drug, does possess anticonvulsant properties. In humans, CYP3A4, CYP2C8 and CYP1A2 have been shown to be implicated in CBZ biotransformation. Our purpose was to establish an experimental model to determine the interaction of CBZ with other antiepileptic drugs. We first identified the CYP isoforms that metabolized CBZ in rabbit. We used liver microsomes from rabbit treated with various compounds known to induce principally some CYPs subfamilies. Having tested all the compounds we demonstrated that only the animals treated with CYP3A inducers were able to metabolize CBZ strongly. The CBZ biotransformation was inhibited by anti CYP3A antibodies. All the CYP3A subfamily substrates specifically decrease CBZ-E formation. In our experiment we did not observe any inhibition with CYP2C substrate. These data provide evidence that in rabbit the CYP3A subfamily is primarily involved in CBZ metabolism. Using this model we investigated the interaction of CBZ with phenobarbital, phenytoin, ethosuccimide, primidone, progabide, vigabatrin and lamotrigine.     

Functional characterization of human and cynomolgus monkey UDP-glucuronosyltransferase 1A6 enzymes

UDP-glucuronosyltransferase 1A6 (UGT1A6) is a major isoform in the human liver that glucuronidates numerous drugs, environmental chemicals and endogenous substrates. In this study, human and cynomolgus monkey UGT1A6 cDNAs (humUGT1A6 and monUGT1A6, respectively) were cloned, and the corresponding proteins were heterologously expressed in yeast cells to identify the functions of primate UGT1A6s. The enzymatic properties of UGT1A6 proteins were characterized by the kinetic analysis of serotonin (5-hydroxytryptamine, 5-HT) and 4-methylumbelliferone (4-MU) glucuronidation. humUGT1A6 and monUGT1A6 showed 96% identity in their nucleotide and amino acid sequences. Immunoblotting analysis using an antibody raised against human UGT1A6 showed that protein staining intensities were different between human and cynomolgus monkey UGT1A6 enzymes in microsomal fractions from livers and yeast cells, although both enzymes were detectable. The apparent K(m) value (15 mM) for 5-HT glucuronidation of cynomolgus monkey liver microsomes was significantly higher than that (8.6mM) of human liver microsomes, whereas V(max) values were lower in cynomolgus monkeys (2.8 nmol/min/mg protein) than in humans (8.6 nmol/min/mg protein). No significant species difference was observed in K(m) (approximately 90 microM) or V(max) (approximately 25 nmol/min/mg protein) values for liver microsomal 4-MU glucuronidation. In yeast cell microsomes, K(m) values (approximately 6mM) for 5-HT glucuronidation by recombinant UGT1A6s were similar, while a V(max) value (0.1nmol/min/mg protein) of monUGT1A6 was significantly lower than that (0.7 nmol/min/mg protein) of humUGT1A6. In 4-MU glucuronidation, both K(m) (210 microM) and V(max) (3.5 nmol/min/mg protein) values of monUGT1A6 were significantly higher than those of humUGT1A6 (K(m), 110 microM; V(max), 1.5nmol/min/mg protein). These findings suggest that the enzymatic properties of UGT1A6 were extensively different between humans and cynomolgus monkeys, although humUGT1A6 and monUGT1A6 showed high homology at the amino acid level. The information gained in this study should help with in vivo extrapolation and to assess the toxicity of xenobiotics.