Identification of the human liver cytochrome P450 enzymes involved in the in vitro metabolism of a novel 5-lipoxygenase inhibitor

In vitro studies were conducted to identify the hepatic cytochrome P450 (CYP) forms involved in the oxidative metabolism of [14C]ABT-761 and its N-dehydroxylated metabolite, [14C]ABT-438, by human liver microsomes. The two compounds were metabolized by parallel pathways, to form the corresponding methylene bridge hydroxy metabolites. There was no evidence of sulfoxidation and/or ring hydroxylation. Over the ABT-761 and ABT-438 concentration ranges studied (1-300 microM), the rate of NADPH-dependent hydroxylation was linear with respect to substrate concentration ([S]) and did not conform to saturable Michaelis-Menten kinetics. Under these conditions ([S] < KM), the intrinsic clearance (Vmax/KM) of ABT-438 was 10-fold higher than that of ABT-761 (1.7 +/- 0.8 vs. 0.17 +/- 0.06 microl/min/mg, mean +/- SD, N = 3 livers). The hydroxylation of both compounds was shown to be highly correlated (r = 0.83, p < 0.01, N = 11 different human livers) with CYP3A-selective erythromycin N-demethylase activity, and the correlation between ABT-761 hydroxylation and tolbutamide hydroxylase (CYP2C9-selective) activity (r = 0.63, p < 0.05, N = 10) was also statistically significant. Ketoconazole (2.0 microM), a CYP3A-selective inhibitor, inhibited the hydroxylation of both compounds by 53-67%, and sulfaphenazole (CYP2C9-selective) decreased activity by 10-20%. By comparison, alpha-naphthoflavone, a known activator of CYP3A, stimulated the hydroxylation of ABT-761 (8-fold) and ABT-438 (4-fold). In addition, the abundance-normalized rates of cDNA-expressed CYP-dependent metabolism indicated that hydroxylation was largely mediated (66-86%) by CYP3A(4). Therefore, it is concluded that the hydroxylation of ABT-761 and ABT-438 (相似文献   

Identification of human liver cytochrome P450 isoforms involved in the in vitro metabolism of cyclobenzaprine

Cyclobenzaprine (Flexeril) is a muscle relaxant, possessing a tricyclic structure. Numerous therapeutic agents containing this structure are known to be metabolized by polymorphic cytochrome P4502D6. The aim of this study was to determine if cytochrome P4502D6 and other isoforms are involved in the metabolism of cyclobenzaprine in human liver microsomes. Selective cytochrome P450 inhibitors for CYP1A1/2 (furafylline and 7,8-benzoflavone) and CYP3A4 (troleandomycin, gestodene, and ketoconazole) inhibited the formation of desmethylcyclobenzaprine, a major metabolite of cyclobenzaprine, in human liver microsomes. Antibodies directed against CYP1A1/2 and CYP3A4 inhibited the demethylation reaction whereas anti-human CYP2C9/10, CYP2C19, and CYP2E1 antibodies did not show any inhibitory effects. When a panel of microsomes prepared from human B-lymphoblastoid cells that expressed specific human cytochrome P450 isoforms were used, only microsomes containing cytochromes P4501A2, 2D6, and 3A4 catalyzed N-demethylation. In addition, demethylation catalyzed by these recombinant cytochromes P450 can be completely inhibited with selective inhibitors at concentrations as low as 1 to 20 microM. Interestingly, cyclobenzaprine N-demethylation was significantly correlated with caffeine 3-demethylation (1A2) and testosterone 6 beta-hydroxylation (3A4) but not with dextromethorphan O-demethylation (2D6) in human liver microsomes. To further determine the involvement of cytochrome P4502D6 in cyclobenzaprine metabolism, liver microsomes from a human that lacked CYP2D6 enzyme activities was included in this study. The data showed that cyclobenzaprine N-demethylation still occurred in the incubation with this microsome. These results suggested that cytochrome P4502D6 plays only a minor role in cyclobenzaprine N-demethylation whereas 3A4 and 1A2 are primarily responsible for cyclobenzaprine metabolism in human liver microsomes. Due to the minimum involvement of CYP2D6 in the vitro metabolism of cyclobenzaprine, the polymorphism of cytochrome P4502D6 in man should not be of muci concern in the clinical use of cyclobenzaprine.     

Identification of CYP4A11 as the major lauric acid omega-hydroxylase in human liver microsomes

Human liver microsomes are capable of oxidizing lauric acid (laurate), a model medium-chain fatty acid, at both the omega- and omega-1 positions to form 12- and 11-hydroxylaurate, respectively. These laurate hydroxylation reactions are apparently catalyzed by distinct P450 enzymes. While the P450 responsible for microsomal laurate omega-1 hydroxylation in human liver has been identified as CYP2E1, the enzyme catalyzing omega-hydroxylation remains poorly defined. To that end, we employed conventional purification and immunochemical techniques to characterize the major hepatic laurate omega-hydroxylase in humans. Western blotting with rat CYP4A1 antibodies was used to monitor a cross-reactive P450 protein (M(r) = 52 kDa) during its isolation from human liver microsomes. The purified enzyme (7.4 nmol P450/mg protein) had an NH2-terminal amino acid sequence identical to that predicted from the human CYP4A11 cDNA over the first 20 residues found. Upon reconstitution with P450 reductase and cytochrome b5, CYP4A11 proved to be a potent laurate omega-hydroxylase, exhibiting a turnover rate of 45.7 nmol 12-hydroxylaurate formed/min/nmol P450 (12-fold greater than intact microsomes), while catalyzing the omega-1 hydroxylation reaction at much lower rates (5.4 nmol 11-hydroxylaurate formed/min/nmol P450). Analysis of the laurate omega-hydroxylation reaction in human liver microsomes revealed kinetic parameters (a lone Km of 48.9 microM with a VMAX of 3.72 nmol 12-hydroxylaurate formed/min/nmol P450) consistent with catalysis by CYP4A11. In fact, incubation of human liver microsomes with antibodies raised to CYP4A11 resulted in nearly 85% inhibition of laurate omega-hydroxylase activity while omega-1 hydroxylase activity remained unaffected. Furthermore, a strong correlation (r = 0.89; P < 0.001) was found between immunochemically determined CYP4A11 content and laurate omega-hydroxylase activity in liver samples from 11 different subjects. From the foregoing, it appears that CYP4A11 is the principle laurate omega-hydroxylating enzyme expressed in human liver.     

A convenient method to discriminate between cytochrome P450 enzymes and flavin-containing monooxygenases in human liver microsomes

Liver microsomes are a frequently used probe to investigate the phase I metabolism of xenobiotics in vitro. Structures containing nucleophilic hetero-atoms are possible substrates for cytochrome P450 enzymes (P450) and flavin-containing monooxygenases (FMO). Both enzymes are located in the endoplasmatic reticulum of hepatocytes and both need oxygen and NADPH as cofactors. The common method to distinguish between the two enzyme systems is to use the thermal inactivation of FMO and to inhibit P450 completely with carbon monoxide, N-octylamine or N-benzylimidazole. In the literature no indication could be found that the heat inactivation of FMO does not affect any of the human P450 enzymes or that the overall P450 inhibitors inhibit the different human P450 enzymes sufficiently and do not affect the FMO. The effect of N-benzylimidazole and heat inactivation was tested on specific activities of seven P450 enzymes in human liver microsomes, 1A2, 2A6, 2C9, 2C19, 2D6, 3A4/5, and 2E1, using methoxyresorufin O-demethylation, coumarin 7-hydroxylation, (S)-warfarin 4-hydroxylation, (S)-(+)-mephenytoin 4-hydroxylation, dextrometorphan O-demethylation, oxidation of denitronifedipine, and chlorzoxazone 6-hydroxylation respectively. The sulfoxidation of methimazole (MMI) was used as a specific probe for the determination of FMO activity. Methimazole sulfoxidation was compared with the well known assay for FMO metabolism, the formation of N,N-dimethylaniline (DMA) N-oxide, to be confirmed as an exclusively FMO mediated reaction. The participation of P450 and FMO in the sulfoxidation of four sulfur containing peptides, ametryne; terbutryne, prometryne and methiocarb was investigated using human liver microsomes. All four reactions were demonstrated to be catalysed predominantly by cytochrome P450.     

Studies on cytochrome P450 responsible for oxidative metabolism of imipramine in human liver microsomes

The activity of imipramine 2-hydroxylase highly correlated with that of desipramine 2-hydroxylase but not with that of desipramine N-demethylase. The correlation was also found between N-demethylation and 2-hydroxylation when imipramine was used as a substrate, whereas no correlation was observed between them when desipramine was used in place of imipramine. Both activities of desipramine and imipramine 2-hydroxylase were markedly inhibited by quinidine but not by quinine. Although the activity of imipramine N-demethylase was slightly inhibited by both quinidine and quinine, the activity of desipramine N-demethylase was unaffected under the same conditions. The activity of imipramine N-demethylase was roughly correlated with the amounts of P450 3A4 immunochemically determined and the activities of testosterone 6 beta-hydroxylase in human liver microsomes. The P450 3A4 catalyzed imipramine N-demethylation much more efficiently than 2-hydroxylation in a reconstituted system, whereas neither N-demethylation nor 2-hydroxylation of desipramine was catalyzed by P450 3A4. The activity of imipramine N-demethylase was inhibited, to various extents, by anti-P450 3A4 antibodies in human liver microsomes. Taking together these and other results, it is suggested that P450 3A4, other than P450 2Cmp, also partly contributes to N-demethylation of imipramine, depending on human liver microsomes.     

Changes in rat liver cytochrome P450 enzymes by atrazine and simazine treatment

1. We examined the effect of two chloro-s-triazines (atrazine and simazine) on hepatic microsomal cytochrome P450 enzymes in rat. Rats were treated intraperitoneally with atrazine or simazine daily for 3 days with 100, 200 and 400 mumol/kg. 2. Among the P450-dependent monooxygenase activities, testosterone 2 alpha-hydroxylase (T2AH) activity in rat, which is associated with CYP2C11, was significantly decreased at all doses of atrazine and simazine. The levels relative to control activities were 59-46 and 60-32% respectively. Similarly, oestradiol 2-hydroxylase (ED2H) activity was also significantly decreased by 28-51% by atrazine and simazine at all doses. However, no change in CYP2C11 protein level by either chloro-s-triazine was observed. K(m) for T2AH was significantly increased only by simazine (200 mumol/kg), whereas the Vmax and Cl(int) for T2AH were significantly decreased by atrazine and simazine at all doses. 3. 7-Ethoxyresorufin O-deethylase (EROD), 7-methoxyresorufin O-demethylase (MROD) and 7-pentoxyresorufin O-depentylase (PROD) activities were significantly increased by 1.4-1.6-, 1.7-3.2- and 1.5-2.2-fold respectively, by both chloro-s-triazines at 200 or 400 mumol/kg. Lauric acid omega-hydroxylase (LAOH) was also increased by 1.4-fold by simazine at 200 and 400 mumol/kg. Immunoblotting showed that only simazine induces CYP1A2 and CYP4A1/2 protein expression. 4. The activities of 7-ethoxycoumarin O-deethylase (ECOD), bufuralol 1'-hydroxylase (BF1'H), chlorzoxazone 6-hydroxylase (CZ6H), testosterone 6 beta-hydroxylase (T6BH) and testosterone 7 alpha-hydroxylase (T7AH) were not affected by either chloro-s-triazine. 5. These results suggest that the pattern of changes in P450 isoforms by chloro-s-triazines differs between atrazine and simazine, that these herbicides change the constitutive and/or male specific P450 isoform(s) in rat liver, and that these changes closely relate to the toxicity of chloro-s-triazines.     

Identification of human cytochrome P450 isoforms involved in the 3-hydroxylation of quinine by human live microsomes and nine recombinant human cytochromes P450

Studies using human liver microsomes and nine recombinant human cytochrome P450 (CYP) isoforms (CYP1A1, 1A2, 2A6, 2B6, 2C9, 2C19, 2D6, 2E1 and 3A4) were performed to identify the CYP isoform(s) involved in the major metabolic pathway (3-hydroxylation) of quinine in humans. Eadie-Hofstee plots for the formation of 3-hydroxyquinine exhibited apparently monophasic behavior for all of the 10 different microsomal samples studies. There was interindividual variability in the kinetic parameters, as follows: 1.8-, 3.2- and 3.5-fold for K(m) Vmax and Vmax/K(m), respectively. The mean +/- S.D. values for K(m), Vmax and Vmax/K(m) were 106.1 +/- 19.3 microM, 1.33 +/- 0.48 nmol/mg protein/min and 12.8 +/- 5.1 microliters/mg protein/min, respectively. With 10 different human liver microsomes, the relationships between the 3-hydroxylation of quinine and the metabolic activities for substrates of the respective CYP isoforms were evaluated. The 3-hydroxylation of quinine showed an excellent correlation (r = 0.986, P < .001) with 6 beta-hydroxylation of testosterone, a marker substrate for CYP3A4. A significant correlation (r = 0.768, P < .01) between the quinine 3-hydroxylase and S-mephenytoin 4'-hydroxylase activities was also observed. However, no significant correlation existed between the 3-hydroxylation of quinine and the oxidative activities for substrates for CYP1A2 (phenacetin), 2C9 (diclofenac), 2D6 (desipramine) and 2E1 (chlorzoxazone). Ketoconazole and troleandomycin (inhibitors of CYP3A4) inhibited the 3-hydroxylation of quinine by human liver microsomes with respective mean IC50 values of 0.026 microM and 28.9 microM. Anti-CYP3A antibodies strongly inhibited quinine 3-hydroxylation, whereas weak inhibition was observed in the presence of S-mephenytoin or anti-CYP2C antibodies. Among the nine recombinant human CYP isoforms, CYP3A4 exhibited the highest catalytic activity with respect to the 3-hydroxylation of quinine, compared with the minor activity of CYP2C19 and little discernible or no effect of other CYP isoforms. Collectively, these data suggest that the 3-hydroxylation of quinine is mediated mainly by CYP3A4 and to a minor extent by CYP2C19. Other CYP isoforms used herein appear to be of negligible importance in this major pathway of quinine in humans.     

Hormonal regulation of hepatic enzymes involved in foreign compound metabolism

The regulation of hepatic P450s has been the focus of numerous studies because of the importance of these proteins in endocrinology, oncology, and toxicology, as well as drug development. Considerable evidence exists demonstrating that many hepatic P450s are regulated by developmental, sex, or hormonal factors in addition to receptors that interact with foreign chemicals. The focus of work in our laboratory has been on the effects of steroid hormones, especially glucocorticoids, on expression of genes regulated by the Ah receptor. We have shown that most rat hepatic genes of the Ah receptor gene battery are regulated by glucocorticoids. We have used glucocorticoid-deficient animal models to demonstrate that these steroids do modulate the expression (basal and inducible) of these genes in vivo. Using cultured rat hepatocytes, we have demonstrated that polycyclic aromatic hydrocarbon (PAH) induction of cytochrome P4501A1, glutathione S-transferase Ya1, and UDP-glucuronosyltransferase 1*6 are apparently potentiated two- to fourfold upon inclusion of glucocorticoids in the media to activate the glucocorticoid receptor and further, that the receptor antagonist RU 38486 reverses these phenomenon. NAD(P)H:quinone oxidoreductase and aldehyde dehydrogenase 3 gene expression were repressed 70-80% by glucocorticoids in cultured hepatocytes through a glucocorticoid receptor-mediated process as well. The effect of glucocorticoid concentration on PAH induction of glutathione S-transferase Ya1 subunit for glucocorticoids was biphasic, but at physiological concentrations gene expression was repressed to approximately 20-40% of control. At supraphysiological concentrations, glucocorticoids alone induced expression two- to threefold and potentiated the PAH-inducible expression of the Ya1 subunit gene. Subsequent work in our laboratory has focused on defining the molecular basis of this hormonal regulation, specifically elucidating responsive elements responsible for the action of the glucocorticoid receptor and the mechanisms by which some of these genes are positively regulated and others are negatively regulated.     

In vitro metabolism of clenbuterol and bromobuterol by pig liver microsomes

1. Clenbuterol (CBL) and bromobuterol (BBL) were both extensively metabolized by hepatic microsomes of swine to only one polar metabolite which was separated by hplc and purified to perform mass analysis. 2. LC-MIS analysis by direct infusion into an ion trap system and after reverse-phase chromatograpy into a triple quadrupole system showed that the metabolites were the hydroxylamine-derivatives of CBL and BBL. GC-MS analysis by the CI and EI modes confirmed that the hydroxyl group was bound to the aniline nitrogen. The chemical instability of those metabolites probably as a consequence of spontaneous oxidation and reduction gave rise during the analysis to the corresponding nitroso and nitro derivatives, together with the original compound. 3. Thermal inactivation and CO complex formation were used selectively to inactivate flavin monooxygenase and cytochrome P450, respectively. Both inactivation procedures significantly reduced the formation of the hydroxyl metabolite.     

Elucidation of individual cytochrome P450 enzymes involved in the metabolism of clozapine

The three-dimensional structures of E. coli inorganic pyrophosphatase (PPase) and its complexes with Mn2+ in a high affinity site and with Mg2+ in high and low affinity sites determined by authors in 1994-1996 at 1.9-2.2 A resolution are compared. Metal ion binding initiates the shifts of alpha-carbon atoms and of functional groups and rearrangement of non-covalent interaction system of hexameric enzyme molecule. As a result, the apoPPase with six equal subunits turns after Mg2+ binding into the structure with three types of subunits distinguished by structure and occupance of the low affinity Mg2+ site. Induced asymmetry reflects the subunit interactions and cooperativity between Mg2+ binding sites. These molecular rearrangements are structural basis to account for special features of the enzyme behavior and to propose one of the pathways for enzymatic activity regulation of constitutive PPases in vivo.     

Metabolic deesterification of tazarotene in human blood and rat and human liver microsomes

Tazarotene is a novel acetylenic retinoid for the treatment of psoriasis and acne. We examined (1) the hydrolysis of tazarotene in blood from Japanese-American and Caucasian subjects, (2) the esterases responsible for this hydrolysis in human blood, and (3) tazarotene hydrolysis in rat and human liver microsomes. Tazarotene hydrolysis and enzyme inhibition were assessed by monitoring the disappearance of tazarotene and the appearance of its primary metabolite tazarotenic acid by HPLC. In blood, tazarotene was converted mainly to tazarotenic acid via first-order kinetics, and there was no statistically significant difference in the hydrolytic (metabolic) rate of tazarotene in uninhibited Japanese-American and Caucasian blood. Physostigmine (a cholinesterase inhibitor), bis(p-nitrophenyl) phosphate (a carboxylesterase inhibitor), and EDTA (an aromatic esterase inhibitor) did not significantly affect tazarotene hydrolysis in blood. Paraoxon, an inhibitor of all serine esterases including cholinesterase and carboxylesterase, decreased the hydrolysis of tazarotene to tazarotenic acid by 95% in both blood and liver microsomes. In conclusion, blood and liver esterases play a significant role in the hydrolysis of tazarotene to tazarotenic acid, and paraoxon-inhibitable forms of esterases are involved in this hydrolysis in humans.     

In vitro biotransformation of atrazine by rat liver microsomal cytochrome P450 enzymes

We studied atrazine (ATZ) metabolism in male and female rat liver microsomes in vitro, and the major metabolite was deisopropylatrazine (DeiPr-ATZ) with deethylatrazine (DeEt-ATZ) and 1-hydroxyisopropylatrazine (iPrOH-ATZ) as minor metabolites in both sexes. The enzyme kinetics of ATZ biotransformation were examined by means of Eadie-Hofstee analyses. Although no remarkable sex difference of Michaelis Menten values for each pathway was observed, Cl(int)S (Vmax/Km) for DeiPr-ATZ, DeEt-ATZ and iPrOH-ATZ were slightly higher in female than in male rats. The formation of DeiPr-ATZ, DeEt-ATZ and iPrOH-ATZ from ATZ was substantially inhibited by SKF-525A, metyrapone, diallyl sulfide, 7-ethoxycoumarin, benzphetamine, nicotine, testosterone and lauric acid in both sexes. Cimetidine effectively inhibited the formation of all metabolites in male rats. On the other hand, the inhibition rates of the formation of DeiPr-ATZ and iPrOH-ATZ by cimetidine in female rats were lower than those in male rats, and DeEt-ATZ was hardly affected by the chemicals. In contrast with the results for cimetidine, the inhibition of ATZ biotransformation by bufuralol was more effective in female than in male rats. Anti-rat CYP2B1 and CYP2E1 antibodies effectively inhibited DeiPr-ATZ, DeEt-ATZ and iPrOH-ATZ formations in both sexes. Anti-rat CYP2C11 antibody also inhibited the three metabolites in both sexes, with the inhibition rates higher in male than in female rats, similar to cimetidine. In the case of anti-rat CYP2D1 antibody, the inhibitory effect on ATZ biotransformation in male rats was less than that in female rats. On the other hand, anti-rat CYP1A2, CYP3A2 and CYP4A1 antibodies did not affect the ATZ biotransformation in either sex. There was no significant correlation between the formation rate of ATZ metabolites and P450 isoform levels in either sex. These results may mean that CYP2B2, CYP2C11, CYP2D1 (only iPrOH-ATZ formation) and CYP2E1 in male rats, and CYP2B2, CYP2D1 and CYP2E1 in female rats are involved ATZ metabolism in liver, and that the substrate specificity of P450 isoforms for ATZ is broad.     

Amiodarone N-deethylation in human liver microsomes: involvement of cytochrome P450 3A enzymes (first report)

Experiments were conducted on three different human liver samples to identify the cytochrome P450 isozyme which is involved in the biotransformation of the class III antiarrhythmic agent, amiodarone, into its major metabolite, desethylamiodarone (DEA). The classic P450 inhibitors, SKF 525A, metyrapone, and carbon monoxide provided a significant reduction in the in vitro formation of DEA by human hepatic microsomes. Amiodarone N-deethylase activities expressed by intrinsic clearance values were similar in all the livers used, although two livers were genotyped as extensive and one as a poor metabolizer for the cytochrome P450 CYP2D6 gene. DEA production was strongly inhibited (more than 80%) by the anti-P450 3A4 antibody, but not by anti-LKM1-positive serum. It seems therefore that the P450 3A subfamily is certainly implicated in human hepatic amiodarone N-deethylation.     

Cytochrome P450-mediated metabolism of the HIV-1 protease inhibitor ritonavir (ABT-538) in human liver microsomes

The HIV-1 protease inhibitor ritonavir (ABT-538) undergoes cytochrome P450-mediated biotransformation in human liver microsomes to three major metabolites, Ml, M2 and M11, with wide interindividual variation in the rates of metabolite formation. The structures of these metabolites were determined with the use of electrospray ionization mass spectrometry. Chemical inhibition, metabolic correlation, immunoinhibition and metabolism by microsomes derived from specific CYP cDNA-transfected B-lymphoblastoid cell lines indicated that the CYP3A subfamily of enzymes was the major contributor to the formation of M1 and M11, whereas both CYP3A and CYP2D6 contributed to the formation of M2. None of the typical CYP3A substrates/inhibitors (e.g., ketoconazole, troleandomycin) were able to completely inhibit ritonavir metabolism, even at high concentrations. Ritonavir was found to be a potent inhibitor of CYP3A-mediated biotransformations (nifedipine oxidation, IC50) = 0.07 microM; 17alpha-ethynylestradiol 2-hydroxylation, IC50 = 2 microM; terfenadine hydroxylation, IC50 = 0.14 microM). Ritonavir was also found to be an inhibitor of the reactions mediated by CYP2D6 (IC50 = 2.5 microM) and CYP2C9/10 (IC50 = 8.0 microM). The results of this study indicate the potential for in vivo inhibition of the metabolism by ritonavir of drugs that are CYP3A, CYP2D6 and, to a lesser extent, CYP2C9/10 substrates.     

Glucuronidation of dihydrocodeine by human liver microsomes and the effect of inhibitors

1. Glucuronidation is the major route of metabolism of dihydrocodeine (DHC) and accounts for 25-30% of an oral dose in urine. The kinetics of DHC-6-glucuronide formation in liver microsomes from five human donors and the effect of a number of potential inhibitor drugs were examined using a newly developed and validated HPLC assay. 2. The formation of DHC-6-glucuronide exhibited atypical kinetics that conformed to the Hill equation. The mean intrinsic dissociation constant (Ks) and maximum velocity (Vmax) values were 1566 micromol/L and 0.043 micromol/min per g, respectively. The Ks and Vmax values varied 1.5- and 3.5-fold, respectively. 3. Seven drugs were tested for inhibitory effects on DHC glucuronidation at low (50 micromol/L) and high (500 micromol/L) concentrations. At 50 micromol/L, only diclofenac produced greater than 50% inhibition, while at concentrations of 500 micromol/L inhibition was greater than 35% for diclofenac, amitriptyline, oxazepam, naproxen, chloramphenicol and probenecid, but not paracetamol. 4. The present study found little interindividual variation in the activity of human liver microsomes for glucuronidation of DHC. Comparison of the results from the inhibition studies with those reported previously for codeine and morphine suggest that the UDP-glucuronosyltransferase isoform UGT2B7 is involved in the glucuronidation of DHC.     

Metabolic interactions of putative cytochrome P4503A substrates with alternative pathways of dapsone metabolism in human liver microsomes

The cytochrome P4503A (CYP3A) subfamily of enzymes are responsible for the metabolism of a large number of endogenous and exogenous compounds, and activation of some procarcinogens; but the activity is not well understood. N-Hydroxylation of dapsone in human liver microsomes has been shown to be mediated largely by CYP3A4. We have also observed the formation of an as yet unidentified metabolite of dapsone, whose formation is inhibited by antibody to CYP3A4, by these microsomes. This study investigated the influence of various (22) CYP3A putative substrates on the formation of both metabolites of dapsone in human liver microsomes. The compounds fall into four different categories on the basis of the pattern of their inhibitory interaction with the formation of both metabolites: those that inhibited both metabolites; those that inhibited N-hydroxylamine alone; those that inhibited the unidentified metabolite alone; and those with no significant effect on either metabolite. Some others were stimulatory. These results are consistent with two alternative but not mutually exclusive hypotheses: 1) different isoforms of CYP3A are involved in the formation of the alternative metabolites and the pattern of interaction observed was caused by the particular isoform(s) that each compound interacted with; or 2) formation of the alternative metabolites is a result of dapsone's interaction with and orientation at the enzyme's active site and the pattern of interaction observed is a consequence of changes in orientation caused by these compounds. This study provides relevant observations that must be considered in understanding mechanisms of CYP3A-mediated metabolism.     

In vivo disposition and metabolism by liver and enterocyte microsomes of the antitubercular drug rifabutin in rats

The in vivo disposition and in vitro metabolism of rifabutin, a new spiropiperidylrifamycin, were studied in rats and in microsomes from rat liver and enterocytes, respectively. After i.v. doses of 1,5, 10 and 25 mg/kg the systemic clearance was 0.7 to 1.0 liters/hr/kg; the volume of distribution was 4.4 liters/kg for the 1 mg/kg dose and 7.4 to 7.7 liters/kg for the 5 to 25 mg/kg doses, and the half-life ranged from 4.4 to 9.1 hr. Urinary and fecal excretion over 0 to 96 hr after i.v. administration of 25 mg/kg [14C]rifabutin accounted for 40.1 and 52.2% of the dose, respectively. Exteriorization of the bile duct showed that approximately 24% of the dose was eliminated in bile, > or = 98% as metabolites. Bioavailability after oral administration of 25 and 1 mg/kg rifabutin was > 90% and 44%, respectively, suggesting significant first-pass metabolism of the lower dose. Concentrations of rifabutin in gastric juice were 10 to 17 times higher than in blood, indicating extensive secretion into the stomach. Experiments with the isolated small intestinal loop demonstrated direct exsorption of the drug into the lumen. The rate of rifabutin metabolism by enterocyte microsomes was > 10 times higher than that by liver microsomes, i.e., 84 and 8 pmol/min/mg protein, respectively. Biotransformation of rifabutin in vivo and in vitro was markedly induced by dexamethasone and inhibited by erythromycin, suggesting that CYP3A is involved in the metabolism of rifabutin. Several metabolites, including 20-OH-rifabutin and 27-O-demethyl-rifabutin, isolated from urine and microsomes were identified by mass spectrometry and nuclear magnetic resonance spectroscopy.