Characterisation of zuclopenthixol metabolism by in vitro and therapeutic drug monitoring studies.

OBJECTIVE: Zuclopenthixol pharmacokinetics is incompletely characterised. We investigated potential interactions mediated through cytochrome P450 enzymes. METHOD: In vitro, we examined the impact of CYP2D6 and CYP3A4 inhibitors on zuclopenthixol metabolism in microsomes from six human livers. Subsequently, we compared dose-corrected serum zuclopenthixol concentrations in 923 samples from a therapeutic drug monitoring database from patients prescribed oral (n = 490) or injected (n = 423) zuclopenthixol alone or with fluoxetine, paroxetine, levomepromazine or carbamazepine. RESULTS: In vitro fluoxetine, paroxetine, ketoconazole and quinidine all significantly inhibited zuclopenthixol metabolism. Ketoconazole and quinidine together abolished zuclopenthixol disappearance. Clinically, dose-corrected oral zuclopenthixol serum concentrations increased significantly, after adjustment, by 93%, 78% and 46% during co-treatment with fluoxetine, paroxetine and levomepromazine and decreased 67% with carbamazepine. Carbamazepine caused dose-dependent reductions in the oral zuclopenthixol concentration-dose ratio (P < 0.001), fluoxetine (P < 0.001) and paroxetine (P = 0.011) dose-dependent increases and levomepromazine an increase related to its serum concentration (P < 0.001). Results for injected zuclopenthixol were similar but not all reached statistical significance. CONCLUSION: The In vitro study suggests zuclopenthixol is metabolised primarily by CYP2D6 and CYP3A4. The clinical study supports this, demonstrating the impact of co-prescribed inhibitors or inducers. Guidelines should incorporate these interactions noting the potential for zuclopenthixol-related toxicity or treatment failure.

Determination of a quantitative relationship between hepatic CYP3A5*1/*3 and CYP3A4 expression for use in the prediction of metabolic clearance in virtual populations.

The creation of virtual populations allows the estimation of pharmacokinetic parameters, such as metabolic clearance in extreme individuals rather than the 'average human'. Prediction of variability in metabolic clearance within genetically diverse populations relies on understanding the covariation in the expression of enzymes. A number of statistically significant positive correlations have been observed in the hepatic expression of cytochrome P450 drug metabolising enzymes. However, these rarely provided a quantitative description of the relationships which is required in creating virtual populations. Collation of data from 40 human liver microsomal samples in the current study indicated a significant positive relationship between hepatic microsomal CYP3A5*1/*3 and CYP3A4 content. Having developed a model describing the relationship between hepatic CYP3A4 and CYP3A5*1/*3, the Simcyp Population-based Simulator(®) was used to investigate the consequences of either incorporating or ignoring the relationship between the two enzymes on estimates of drug clearance. Simulations indicated that for a compound with greater metabolism by CYP3A5 than CYP3A4, such as tacrolimus, incorporation of the correlation between CYP3A4 and CYP3A5 does have an impact on the prediction of oral clearance. Failure to consider the relationship between CYP3A4 and CYP3A5 when creating the virtual population led to a 32% lower estimate of oral clearance in individuals possessing both the CYP3A5*1/*3 genotype and high basal concentrations of CYP3A4. Potential clinical implications may include an inadequate dose estimation during clinical study design, the consequences of which may include organ rejection in transplant recipients using immunosuppressants such as tacrolimus or toxicity due to elevated concentrations of circulating metabolites.

Determination by liquid chromatography-mass spectrometry of clomiphene isomers in the plasma of patients undergoing treatment for the induction of ovulation.

A rapid, sensitive and selective LC-MS method is described for the simultaneous determination of zuclomiphene and enclomiphene in plasma from patients undergoing treatment with clomiphene citrate for the induction of ovulation. Samples spiked with N-didesmethyltamoxifen, the internal standard, were extracted into methyl tertiary butyl ether. The compounds were separated on a Luna C(18) analytical column, and a mobile phase of methanol-water (70:30 v/v) containing 0.05% trifluoroacetic acid at a flow rate of 1ml/min. The limits of determination were 35pg/ml and 7pg/ml for zu- and enclomiphene, respectively. Within-day coefficients of variation ranged from 2.1% to 7.2%.

A critical evaluation of the experimental design of studies of mechanism based enzyme inhibition, with implications for in vitro-in vivo extrapolation.

The published literature on mechanism based inhibition (MBI) of CYPs was evaluated with respect to experimental design, methodology and data analysis. Significant variation was apparent in the dilution factor, ratio of preincubation to incubation times and probe substrate concentrations used, and there were some anomalies in the estimation of associated kinetic parameters (k(inact), K(I), r). The impact of the application of inaccurate values of k(inact) and K(I) when extrapolating to the extent of inhibition in vivo is likely to be greatest for those compounds of intermediate inhibitory potency, but this also depends on the fraction of the net clearance of substrate subject to MBI and the pre-systemic and systemic exposure to the inhibitor. For potent inhibitors, the experimental procedure is unlikely to have a material influence on the maximum inhibition. Nevertheless, the bias in the values of the kinetic parameters may influence the time for recovery of enzyme activity following re-synthesis of the enzyme. Careful attention to the design of in vitro experiments to obtain accurate kinetic parameters is necessary for a reliable prediction of different aspects of the in vivo consequences of MBI. The review calls for experimental studies to quantify the impact of study design in studies of MBI, with a view to better harmonisation of protocols.

Beeturia and the biological fate of beetroot pigments.

Beeturia, the passage of pink or red urine after the ingestion of beetroot, is said to occur in 10-14% of the population, and is more common in iron deficiency and malabsorption. A specific HPLC assay for betacyanins, the red beetroot pigments, in biological fluids was developed to study the prevalence of this apparent polymorphism in humans, and to investigate its basis in rats. Two major peaks were observed in chromatograms of extracts of unpickled beetroot. They had identical UV absorption spectra (lambda max = 535 nm) by diode array analysis, and mass spectrometry indicated that one (betacyanin 1) was betanin or its epimer and the other (betacyanin 2) a disaccharide of betacyanin 1. In a population of 100 normal subjects the 0-8 h urinary recoveries after an oral dose of 60 mg beetroot extract were 0.06-0.54% for betacyanin 1 and 0.01-0.6% for betacyanin 2. The distributions of these data were skewed but not clearly bimodal by visual inspection or by kernel density analysis. Four subjects produced visibly red urine and had betacyanin recoveries at the upper end of the population range. Studies using in situ isolated perfused rat jejunum and liver preparations indicated a negligible absorption of the pigments after 1 h and no detectable metabolism or biliary secretion. Intact anaesthetized rats given i.v. bolus doses of beetroot extract cleared both betacyanins from plasma at the rate of 3.3 +/- 0.9 (SD) ml min-1 (n = 5). The total urinary recovery of both pigments amounted to 80% of the dose, and their renal clearances approached their plasma clearances. These data suggest that beeturia does not arise from deficiencies in hepatic metabolism or renal excretion of betacyanins. After oral administration of beetroot extract to rats the betacyanin content of the stomach decreased rapidly with time but neither the intestines nor the bile duct were stained visibly red. These findings together with those showing instability of the betacyanins in acid conditions suggest that variability in the biological fate of beetroot pigments may be determined largely by gastric pH and emptying rate.

Debrisoquine and metoprolol oxidation in Zambians: a population study.

The 0-8 h urinary distributions of the metabolic ratios of debrisoquine (10 mg) and metoprolol (100 mg) were measured in 102 healthy, unrelated, black Zambian medical students. There was a statistically significant correlation (rs = 0.60, p < 0.001; n = 88) between the debrisoquine/4-hydroxydebrisoquine (D/HD) and metoprolol/alpha-hydroxymetoprolol (M/HM) ratios. Bimodality in the distribution of the log10D/HD ratio was not evident from visual inspection and following kernel density analysis of the data, although two subjects (ratios 20, 22) would be classified as phenotypic poor metabolizers (PMs) based on the antimode used for Caucasian populations. The distribution of the log10M/HM ratio was skewed and on the basis of kernel density analysis, bimodal. It was clear from visual inspection of the data that the very high M/HM value (> or = 302) of one individual had a profound influence on the population M/HM ratio distribution. No HM was detected in the urine of this subject but he was not one of the two PMs of debrisoquine (D/HD ratio 1.54). H117/04, the major metabolite of metoprolol was also not detected in this sample. Since H117/04 was shown to be present in all samples from previous population studies, the possibility that this subject did not comply with the protocol could not be excluded. All other subjects had M/HM ratios < or = 12.5. These findings suggest that there is a dissociation in the control of debrisoquine and metoprolol oxidation in Zambians as has been observed previously in Nigerians. Furthermore, clear evidence that the metabolism of these drugs exhibits genetic polymorphism in Zambians was not obtained.

Evidence for a dissociation in the control of sparteine, debrisoquine and metoprolol metabolism in Nigerians.

The 0-8 hour urinary distributions of the metabolic ratios of sparteine (100 mg), debrisoquine (10 mg) and metoprolol (100 mg) were measured in 165 healthy, unrelated, black Nigerian medical students. There was a weak correlation (rs = 0.51, p < 0.001; n = 82) between the metoprolol/alpha-hydroxymetoprolol (M/HM) and the sparteine/total (2- + 5-) dehydrosparteine (S/DHS) ratios. No significant correlations were found between the debrisoquine/4-hydroxydebrisoquine (D/HD) and M/HM ratios (rs = 0.16, n = 33) and between the D/HD and S/DHS ratios (rs = 0.31, n = 38). Both visual inspection and kernel density analysis of the data suggested the presence of two phenotypic groups for sparteine oxidation, with 4% of the population studied being putative poor metabolizers. In contrast biomodality was not apparent in the distribution of the log10M/HM and log10D/HD ratios. These findings provide evidence for a dissociation in the control of metoprolol, sparteine and debrisoquine oxidation in Nigerians and highlight the difficulties in the interpretation of data from pharmacogenetic studies in different ethnic groups.

Meta-analysis of studies of the CYP2D6 polymorphism in relation to lung cancer and Parkinson's disease.

Studies of associations between the CYP2D6 polymorphism and susceptibility to specific diseases, particularly lung cancer and Parkinsonism, have produced conflicting results with respect to an under or overrepresentation of poor metabolizers. Accordingly, we have re-evaluated this primary research (18 studies on lung cancer and 18 on Parkinsonism) using meta-analysis. For lung cancer, the median odds ratio (OR) was 0.69 (95% confidence interval (CI) 0.52-0.90), which differed significantly from unity (P < 0.007). A trail comprising 3000 patient and an equal number of control individuals would be required to demonstrate that this observation had arisen purely by chance (i.e. OR = 1). For Parkinson's disease, the analysis gave an OR of 1.32 (95% CI 0.98-1.78), which was of borderline statistical significance (P < 0.074). If the only individual study that was statistically significant was excluded, the P-value increased greatly to 0.489. A study of at least 500 patients and an equal number of control individuals giving the same value as the current mean OR of 1.32 would be required to make the overall analysis statistically significant. In summary, poor metabolizers with respect to CYP2D6 show a small decrease in susceptibility to lung cancer compared with extensive metabolizers and its is hard to justify further studies. The relationship between the CYP2D6 polymorphism and lung cancer, as a determinant of individual susceptibility, is not appreciable (OR = 0.69) compared with that between smoking and lung cancer (OR > 11). Nevertheless, the epidemiological impact on the number of poor metabolizers who are protected from lung cancer may be considerable. With regard to Parkinson's disease, additional well designed studies may allow a definitive conclusion, although any risk for poor metabolizers is likely to be small and therefore of questionable clinical significance. An important lesson from the current review of studies is that much time, effort, expense and patient inconvenience might have been avoid if more attention had been paid to appropriate study design particularly in the selection of control groups.

Metoprolol and debrisoquin metabolism in Nigerians: lack of evidence for polymorphic oxidation.

The role of genetic polymorphism in the oxidative metabolism of metoprolol and debrisoquin was investigated in a population of 138 unrelated Nigerians. The debrisoquin/4-hydroxydebrisoquin 0-8 hour urinary ratio (D/HD) correlated significantly with the metoprolol/alpha-hydroxymetoprolol 0-8 hour urinary ratio (M/HM) (rs = 0.54; P less than 0.001), the metoprolol/H117-04 [4-(2-hydroxy-3-isopropylaminopropoxy)-phenylacetic acid] 0-8 hour urinary ratio (M/H117-04) (rs = 0.42; P less than 0.001), and the plasma metoprolol concentration at 3 hours (rs = 0.48; P less than 0.01). Both the median D/HD and M/HM ratios were significantly higher in this population than in a previously studied population of white British subjects. According to criteria established in studies of white populations, only one subject, later identified as an Indian, would be classified unequivocally as a poor metabolizer of both metoprolol and debrisoquin. All the other subjects were black Africans. Bimodality in the frequency distribution of both the log10 M/HM and D/HD ratios was not apparent. The poor hydroxylation trait may, therefore, be present at a lower frequency than in whites, absent altogether, or obscured by other factors. In ethnic studies of drug metabolism each racial group should be examined separately for evidence of polymorphic metabolism and antimodes should not be extrapolated from one population to another.

Differential stereoselective metabolism of metoprolol in extensive and poor debrisoquin metabolizers.

The hypothesis that variability in metoprolol metabolism stereoselectivity is related to debrisoquin oxidation phenotype was tested in six extensive (EM) and six poor (PM) debrisoquin metabolizers. In EM, plasma AUCs for (S)-metoprolol were 35% higher than for (R)-metoprolol, whereas in PM, AUCs for (S)-metoprolol were lower than for (R)-metoprolol. AUCs for total metoprolol correlated with the ratio of (S)- to (R)-metoprolol AUC. The renal clearance of metoprolol was also stereoselective but to the same extent in both EM and PM. Findings suggest that the enzyme system responsible for polymorphic oxidation of the debrisoquin-type is stereoselective. The relation between log total metoprolol plasma concentration and response (beta-blockade) was shifted to the right in PM relative to EM, which is compatible with a difference in pharmacologic activity of metoprolol enantiomers. Kinetic predictions based on total drug measurements will tend to overestimate dynamic differences between EM and PM, but the magnitude of the error is relatively small, and, in absolute terms, there is a large difference in pharmacologic activity between the phenotypes (beta-blockade at 24 hr: EM = 5.3 +/- 5.6%; PM = 18.9 +/- 3.8%).

The polymorphic oxidation of beta-adrenoceptor antagonists. Clinical pharmacokinetic considerations.

Wide variability in response to some drugs such as debrisoquine can be attributed largely to genetic polymorphism of their oxidative metabolism. Most beta-blockers undergo extensive oxidation. Anecdotal reports of high plasma concentrations of certain beta-blockers in poor metabolisers (PMs) of debrisoquine have claimed that the oxidation of these drugs is under polymorphic control. Subsequently, controlled studies have shown that debrisoquine oxidation phenotype is a major determinant of the metabolism, pharmacokinetics and some of the pharmacological actions of metoprolol, bufuralol, timolol and bopindolol. The poor metaboliser phenotype is associated with increased plasma drug concentrations, a prolongation of elimination half-life and more intense and sustained beta-blockade. Phenotypic differences have also been observed in the pharmacokinetics of the enantiomers of metoprolol and bufuralol. In vivo and in vitro studies have identified some of the metabolic pathways which are subject to the defect, viz. alpha-hydroxylation and O-demethylation of metoprolol and 1'- and possibly 4- and 6-hydroxylation of bufuralol. In contrast, the overall pharmacokinetics and pharmacodynamics of propranolol, which is also extensively oxidised, are not related to debrisoquine polymorphism, although 4'-hydroxypropranolol formation is lower in poor metabolisers. As anticipated, the disposition of atenolol which is eliminated predominantly unchanged by the kidney and in the faeces, is unrelated to debrisoquine phenotype. The clinical significance of impaired elimination of beta-blockers is not clear. If standard doses of beta-blockers are used in poor metabolisers, these subjects may be susceptible to concentration-related adverse reactions and they may also require less frequent dosing for control of angina pectoris.

Droloxifene (3-hydroxytamoxifen) has membrane antioxidant ability: potential relevance to its mechanism of therapeutic action in breast cancer.

Droloxifene (3-hydroxytamoxifen), is a triphenylethylene derivative recently developed for the treatment of breast cancer. Droloxifene was found to exhibit a membrane antioxidant ability in that it inhibited Fe(III)-ascorbate dependent lipid peroxidation in rat liver microsomes and ox-brain phospholipid liposomes. It also inhibited microsomal lipid peroxidation induced by Fe(III)-ADP/NADPH. Droloxifene was a better inhibitor of lipid peroxidation than tamoxifen, but was less effective than 17 beta-oestradiol in the two microsomal systems and in the preformed liposomal system. When introduced into ox-brain phospholipid liposomes, droloxifene inhibited Fe(III)-ascorbate induced lipid peroxidation to approximately the same extent as similarly introduced cholesterol and tamoxifen, although to a lesser extent than 17 beta-oestradiol. This inhibition of lipid peroxidation by droloxifene may result from a membrane stabilization that could be associated in cancer cells with decreased plasma membrane fluidity. This mechanism may be related to the clinically important antiproliferative action of droloxifene on cancer cells.

An evaluation of cytochrome P450 isoform activities in the female dark agouti (DA) rat: relevance to its use as a model of the CYP2D6 poor metaboliser phenotype.

The female dark agouti (DA) rat lacks CYP2D1, the equivalent enzyme in the rat to human CYP2D6 (debrisoquine hydroxylase), and shows impaired metabolism of a number of CYP2D6 substrates. However, from the data available in the literature it is not entirely clear whether the enzyme deficiency in the DA rat is restricted to CYP2D1, and whether factors such as age and substrate concentration are important determinants of interstrain differences in the activity of this enzyme. Given that the female DA rat is used as a model of the human CYP2D6 poor metaboliser phenotype, there is a need for a systematic evaluation of the P450 activities in the DA rat, and of its suitability as a model of the PM phenotype. In the present study metoprolol was used as a probe substrate to investigate CYP2D1 activity since both the alpha-hydroxylation and O-demethylation of this drug are catalysed by CYP2D6 in man. Formation of alpha-hydroxymetoprolol (AHM) and O-demethylmetoprolol (ODM) was 10- and 2.5-fold lower in liver microsomes from female DA rats compared with microsomes from age-matched female Wistar rats, the latter representing the extensive metaboliser strain. Kinetic analysis suggested that in both strains of rat both the alpha-hydroxylation and O-demethylation of metoprolol were catalysed by more than one enzyme. By using quinine as a specific inhibitor of the enzyme, CYP2D1 was identified as an intermediate affinity site in the Wistar strain and was shown to have impaired activity in the DA strain. The activities of lower and higher affinity sites were similar in the two strains. Thus, the only difference between the two strains with respect to both routes of metoprolol metabolism appeared to be in the activity of CYP2D1. Interstrain differences were found to be highly dependent on the choice of substrate concentration, being more marked at lower concentrations. We have also investigated the metabolism of a number of probe compounds for some of the other P450 isoforms commonly involved in drug metabolism to determine the selectivity of the deficiency in the DA strain. p-Nitrophenol hydroxylation and erythromycin N-demethylation were catalysed at higher rates by DA than by Wistar liver microsomes, indicating higher levels of activity of CYP2E1 and CYP3A in the former strain. Felodipine oxidation, tolbutamide hydroxylation and both the hydroxylation and N-demethylation of S-mephenytoin were catalysed at similar rates by microsomes from the two strains, indicating similar activities of enzymes in the CYP2C and CYP3A families.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of metronidazole metabolism by human liver microsomes.

The metabolism of metronidazole was studied in microsomes isolated from livers of human kidney donors. The formation of the major in vivo metabolite, hydroxymetronidazole, proceeded according to biphasic kinetics, suggesting the involvement of at least two enzymatic sites. The affinity constant (Km) of the high affinity site ranged from 140 to 320 microM and metabolism at this site contributed more than 75% of the intrinsic clearance. Thus, at therapeutic doses of metronidazole most of the hydroxylation in vivo should be associated with this site. Antipyrine, cimetidine, alpha-naphthoflavone, caffeine, theophylline, mephenytoin, tolbutamide, quinidine, acetone and nifedipine were poor inhibitors of the formation of hydroxymetronidazole by human liver microsomes. Propranolol (500 microM) inhibited the hydroxylation rate by 70%. Phenacetin inhibited metronidazole hydroxylation with a competitive inhibition constant (Ki) of 4-5 microM. However, metronidazole did not inhibit the O-deethylation of phenacetin. It is concluded that cytochromes P450 IA2, IIC9, IIC10, IID6, IIE1 and IIIA3 do not contribute significantly to the high affinity hydroxylation of metronidazole in man.

Metoprolol oxidation by rat liver microsomes. Inhibition by debrisoquine and other drugs.

The oxidative metabolism of metoprolol has been shown to display genetic polymorphism of the debrisoquine-type. The use of in vitro inhibition studies has been proposed as a means of defining whether one or more forms of cytochrome P-450 are involved in the monogenically-controlled metabolism of two substrates. We have, therefore, tested the ability of debrisoquine and other substrates to inhibit the oxidation of metoprolol by rat liver microsomes. Debrisoquine and guanoxan were potent competitive inhibitors of the alpha-hydroxylation and O-desmethylation of metoprolol as well as its metabolism by all routes (measured by substrate disappearance). Cimetidine and ranitidine, drugs which are known to impair the clearance of metoprolol in man, showed an inhibitory action comparable to that of debrisoquine in rat liver microsomes. Antipyrine, a compound whose metabolism is not impaired in poor metabolisers of debrisoquine, was found to be only a weak inhibitor of the metabolism of metoprolol. These findings suggest that the oxidation of metoprolol is linked closely to that of debrisoquine, cimetidine and ranitidine but not to that of antipyrine in the rat.

Irreversible binding and metabolism of propranolol by human liver microsomes--relationship to polymorphic oxidation.

Studies were performed to investigate the irreversible binding and oxidative metabolism of propranolol in human liver microsomes and the relationship of binding and metabolism to the polymorphic oxidation of debrisoquine. Incubation of microsomes with 14C-labelled propranolol in the presence of a NADPH-generating system gave rise to irreversible binding which increased linearly with time and became saturated at high substrate concentrations. The extent of binding was decreased by the exclusion of cofactors, boiling, anaerobic conditions, and the addition of reduced glutathione and SKF-525A. Trichloropropene oxide had a negligible effect on cofactor-dependent binding. However, debrisoquine, antipyrine and phenacetin decreased binding to a considerable extent. The latter compound abolished cofactor-dependent binding completely at the concentration used (1 mM). Electrophoresis of microsomes which had been incubated with tritiated propranolol revealed that binding was probably occurring to a large number of proteins particularly in the 40,000-90,000 molecular weight range. Glutathione, debrisoquine and antipyrine did not inhibit the 4'-hydroxylation and N-deisopropylation of propranolol. In contrast, phenacetin exerted a very potent inhibitory action on both routes of metabolism. It is concluded that a product or products of propranolol oxidation bind irreversibly but non-selectively to human liver microsomal protein, the enzyme system responsible for the activation of propranolol appears to be related more closely to the cytochrome P-450 system which metabolizes phenacetin than to that metabolising debrisoquine, and radiolabelled propranolol is not a sufficiently specific probe for studying these cytochrome P-450 systems.

Variable contribution of cytochromes P450 2D6, 2C9 and 3A4 to the 4-hydroxylation of tamoxifen by human liver microsomes.

4-Hydroxylation is an important pathway of tamoxifen metabolism because the product of this reaction is intrinsically 100 times more potent as an oestrogen receptor antagonist than is the parent drug. Although tamoxifen 4-hydroxylation is catalysed by human cytochrome P450 (CYP), data conflict on the specific isoforms responsible. The aim of this study was to define unequivocally the role of individual CYPs in the 4-hydroxylation of tamoxifen by human liver microsomes. Microsomes from each of 10 human livers catalysed the reaction [range = 0.6-2.9 pmol/mg protein/min (1 microM substrate concentration) and 6-25 pmol/mg protein/min (18 microM)]. Three of the livers with the lowest tamoxifen 4-hydroxylation activity were from genetically poor metabolisers with respect to CYP2D6. Inhibition of activity by quinidine (1 microM), sulphaphenazole (20 microM) and ketoconazole (2 microM), selective inhibitors of CYPs 2D6, 2C9 and 3A4, respectively, was 0-80%, 0-80% and 12-57%. The proportion of activity inhibited by quinidine correlated positively with total microsomal tamoxifen 4-hydroxylation activity (rs = 0.89, P < 0.01), indicating a major involvement of CYP2D6 in this reaction. Recombinant human CYPs 2D6, 2C9 and 3A4 but not CYPs 1A1, 1A2, 2C19 and 2E1 displayed significant 4-hydroxylation activity. Similar inhibition and correlation experiments confirmed that tamoxifen N-demethylation is catalysed predominantly by CYP3A4. These findings indicate that the 4-hydroxylation of tamoxifen is catalysed almost exclusively by CYPs 2D6, 2C9 and 3A4 in human liver microsomes. However, the marked between-subject variation in the contribution of these isoforms underlines the need to study metabolic reactions in a sufficient number of livers that are characterised with respect to a range of cytochrome P450 activities.

Enantioselective and diastereoselective aspects of the oxidative metabolism of metoprolol.

Enantio- and diastereoselective aspects of oxidative metabolism of metoprolol (1) were examined in the presence of rat liver and human liver microsomes using a pseudoracemate of 1, made up of equal molar (2R)-1-d0 and (2S)-1-d2, as substrate. Both O-demethylation and alpha-hydroxylation showed only slight enantioselectivity, 2R/2S ratios being 1.18 and 0.93 for these pathways in rat liver microsomes and 1.09 and 0.92 in human liver microsomes. In the presence of the rat liver microsomal fraction, alpha-hydroxylation yielded predominantly the 1'R-hydroxy product, 1'R/1'S ratio greater than 12, regardless of the stereochemistry of the side chain. In humans (extensive metabolizers) administered a single 50 mg oral dose of pseudoracemic metoprolol tartrate, urinary alpha-hydroxymetoprolol (2) accounted for 9.3 +/- 2.4% of the dose, 2R/2S ratio 0.85 +/- 0.14, and the carboxylic acid metabolite 4, accounted for 52.7 +/- 6.8% of the dose, 2R/2S ratio 1.15 +/- 0.09. The data suggested that preferential O-demethylation of the (2R)-enantiomer of 1 could contribute to the 2S greater than 2R plasma ratio of metoprolol enantiomers observed in this population.

The expression of human cytochrome P450IA1 in the yeast Saccharomyces cerevisiae.

Data from animal studies suggest that cytochrome P450IA1 catalyses the metabolic activation of several procarcinogenic compounds. In the present study, we have expressed human cytochrome P450IA1 in yeast cells. A 1.70 kb BclI/BamHI fragment containing a full-length human cytochrome P450IA1 cDNA was inserted into the BglII expression site of the yeast expression plasmid pMA91 thereby allowing the ATG initiation codon to be located adjacent to the PGK (phosphoglycerate kinase) promoter. The resulting recombinant plasmid, pCK-1, was introduced into Saccharomyces cerevisiae strains ATCC 44773 and AH22. Microsomes prepared from yeast transformatants of strain ATCC 44773 contained undetectable levels of cytochrome P450. In contrast, microsomes from strain AH22 contained cytochrome P450 with a specific content of 33.3 +/- 10.8 pmol/mg of microsomal protein and showed a reduced carbon monoxide difference spectrum with a peak at 448 nm. Control yeast cells transformed with pMA91 showed no cytochrome P450. Western blots were carried out using an antibody that reacts against rat cytochrome P450IA1 and an antibody that reacts against a synthetic peptide representing a short sequence of human cytochrome P450IA1. A band with a molecular weight of 54 kD was observed in microsomes of yeast transformed with pCK-1, but not with pMA91. When microsomes from yeast transformed with pCK-1 were incubated with benzo(a)pyrene (10 min, 10-160 microM), an estimated Km value of 7 microM was obtained. The availability of yeast cells with functionally active human cytochrome P450IA1 will facilitate molecular structure-activity studies of procarcinogen and drug metabolism by this enzyme in man.

Catalytic activities of human debrisoquine 4-hydroxylase cytochrome P450 (CYP2D6) expressed in yeast.

A 1.57kb BamH1 fragment containing a full-length human debrisoquine 4-hydroxylase cytochrome P450 (CYP2D6) cDNA was inserted into the BglII site of the yeast expression plasmid pMA91 and the resulting recombinant plasmid, PELT1, introduced into Saccharomyces cerevisiae strain AH22. Microsomes prepared from AH22/pELT1 cells gave an absorption maximum at 448 nm and a P450 content of 67 +/- 31 pmol/mg of microsomal protein. No P450 was detectable in microsomes prepared from AH22/pMA91 control cells. A western blot of microsomes prepared from yeast transformed with pELT1 were probed with a monoclonal antibody to CYP2D6 and revealed a strong band with a molecular mass consistent with that of CYP2D6 from human liver microsomes. No corresponding band was observed with microsomes from control yeast transformed with pMA91 alone. Microsomes from AH22/pELT cells showed catalytic activity towards metoprolol (alpha-hydroxylation and O-demethylation, 0.17 and 0.78 nmol/mg protein/h, respectively); and towards sparteine (2- and 5-dehydrogenation, 1.82 and 0.59 nmol/mg protein/h, respectively). The inhibition of metoprolol metabolism by quinidine (Qd) was 200 times more potent than that of quinine (Qn), both for alpha-hydroxylation (Qd IC50 = 0.05 microM; Qn IC50 = 4 microM) and O-demethylation (Qd IC50 = 0.05 microM; Qn IC50 = 4 microM). Negligible metabolism of tolbutamide and S-mephenytoin, substrates of the 2C sub-family, and of p-nitrophenol, a substrate of CYP2E1, was detected, although a trace of the N-deethylated metabolite of lignocaine, thought to be metabolised by CYP3A4, was detected with microsomes from CYP2D6-expressing yeast cells. The results indicate that yeast cells containing human CYP2D6 cDNA express a functionally active form of the enzyme, the immunochemical and catalytic properties of which are consistent with those of human liver.