The importance of both CYP2C19 and CYP2B6 germline variations in cyclophosphamide pharmacokinetics and clinical outcomes.

Cyclophosphamide is an alkylating agent used in the treatment of solid and haematological malignancies and as an immunosuppressive agent. As a prodrug, it is dependent on bioactivation to the active phosphoramide mustard metabolite to elicit its therapeutic effect. This focused review will highlight the evidence for the role of germline pharmacogenetic variation in both plasma pharmacokinetics and clinical outcomes. There is a substantial indication from 13 pharmacokinetic and 17 therapeutic outcome studies, in contexts as diverse as haematological malignancy, breast cancer, systemic lupus erythematosus and myeloablation, that pharmacogenetic variation in both CYP2C19 and CYP2B6 influence the bioactivation of cyclophosphamide. An additional role for pharmacogenetic variation in ALDH1A1 has also been reported. Future studies should comprehensively assess these 3 pharmacogenes and undertake appropriate statistical analysis of gene-gene interactions to confirm these findings and may allow personalised treatment regimens.

High CYP2C19 phenotypic variability in gastrointestinal cancer patients.

PURPOSE: CYP2C19 contributes to the metabolism of several chemotherapeutic agents. The CYP2C19 homozygous null function genotype strongly predicts activity phenotype in healthy populations. An additional acquired loss of function has been reported in up to one-third of cancer patients. It is not known whether this phenomenon also occurs in patients with earlier stage or in resected disease. METHODS: This study investigated whether acquired loss of CYP2C19 function was detectable in patients with stage III-IV or resected gastrointestinal cancer. CYP2C19 genotype was determined in 49 patients, and subjects were probed for CYP2C19 activity on three test occasions. RESULTS: An acquired loss of CYP2C19 activity was observed in 20% of stage III-IV and 17% of resected patients at the first test. Significant (p < 0.01) genotype-phenotype discordance was observed in both groups. There were no direct associations between this discordance and inflammatory markers, tumour burden or chemotherapeutic history. Notably, hepatic CYP2C19 function was not stable over time and phenotype conversion occurred in 23 patients over the period of testing. CONCLUSION: Reliance on germ-line genotype to infer a poor metaboliser status could substantially underestimate the number of patients with deficient CYP2C19 function. This could compromise the interpretation of genotype-based clinical association studies.

The preclinical pharmacokinetic disposition of a series of perforin-inhibitors as potential immunosuppressive agents.

The cytolytic protein perforin is a key component of the immune response and is implicated in a number of human pathologies and therapy-induced conditions. A novel series of small molecule inhibitors of perforin function have been developed as potential immunosuppressive agents. The pharmacokinetics and metabolic stability of a series of 16 inhibitors of perforin was evaluated in male CD1 mice following intravenous administration. The compounds were well tolerated 6 h after dosing. After intravenous administration at 5 mg/kg, maximum plasma concentrations ranged from 532 ± 200 to 10,061 ± 12 ng/mL across the series. Plasma concentrations were greater than the concentrations required for in vitro inhibitory activity for 11 of the compounds. Following an initial rapid distribution phase, the elimination half-life values for the series ranged from 0.82 ± 0.25 to 4.38 ± 4.48 h. All compounds in the series were susceptible to oxidative biotransformation. Following incubations with microsomal preparations, a tenfold range in in vitro half-life was observed across the series. The data suggests that oxidative biotransformation was not singularly responsible for clearance of the compounds and no direct relationship between microsomal clearance and plasma clearance was observed. Structural modifications however, do provide some information as to the relative microsomal stability of the compounds, which may be useful for further drug development.

CYP2C19 genotype-phenotype discordance in patients with multiple myeloma leads to an acquired loss of drug-metabolising activity.

PURPOSE: Previous reports indicate that discordance between CYP2C19 genotype and enzyme function occurs in up to 37 % of cancer patients with a range of solid tumours. The aim of this study was to determine whether this acquired loss of function in hepatic CYP2C19 activity also occurs in patients with haematological malignancy. METHODS: CYP2C19 genotype was determined in 25 patients with multiple myeloma using PCR-RFLP analysis for the common allelic variants (*2, 681G>A, rs4244285; *3, 636G>A, rs49486893, and *17, -806C>T, rs12248560). The activity of the enzyme was evaluated using the CYP2C19 probe drug proguanil, and a metabolic ratio used to categorise subjects as extensive or poor metabolisers (PM). RESULTS: No genotypic PM (homozygous null) were detected in this patient cohort. However, CYP2C19 activity was severely compromised in some multiple myeloma patients, resulting in a PM status in 28 % of subjects. Hence, there was significant (p < 0.0001) discordance between the CYP2C19 activity predicted by genotype and the measured phenotype. Discordant CYP2C19 activity did not correlate with any of the pro-inflammatory markers studied. CONCLUSIONS: Acquired loss of CYP2C19 activity occurs in a substantial proportion of patients with multiple myeloma. This indicates that the previously reported phenomenon is not limited to patients with solid tumours. Thus, measurement of CYP2C19 activity rather than CYP2C19 genotype may be more clinically relevant for the determination of whether loss of CYP2C19 function adversely influences the toxicity and efficacy of certain drugs used in medical oncology.

Comparative bioactivation of the novel anti-tuberculosis agent PA-824 in Mycobacteria and a subcellular fraction of human liver.

BACKGROUND AND PURPOSE: PA-824 is a 2-nitroimidazooxazine prodrug currently in Phase II clinical trial for tuberculosis therapy. It is bioactivated by a deazaflavin (F(420) )-dependent nitroreductase (Ddn) isolated from Mycobacterium tuberculosis to form a des-nitro metabolite. This releases toxic reactive nitrogen species which may be responsible for its anti-mycobacterial activity. There are no published reports of mammalian enzymes bioactivating this prodrug. We have investigated the metabolism of PA-824 following incubation with a subcellular fraction of human liver, in comparison with purified Ddn, M. tuberculosis and Mycobacterium smegmatis. EXPERIMENTAL APPROACH: PA-824 (250 µM) was incubated with the 9000 × g supernatant (S9) of human liver homogenates, purified Ddn, M. tuberculosis and M. smegmatis for metabolite identification by liquid chromatography mass spectrometry analysis. KEY RESULTS: PA-824 was metabolized to seven products by Ddn and M. tuberculosis, with the major metabolite being the des-nitro product. Six of these products, but not the des-nitro metabolite, were also detected in M. smegmatis. In contrast, only four of these metabolites were observed in human liver S9; M3, a reduction product previously proposed as an intermediate in the Ddn-catalyzed des-nitrification and radiolytic reduction of PA-824; two unidentified metabolites, M1 and M4, which were products of M3; and a haem-catalyzed product of imidazole ring hydration (M2). CONCLUSIONS AND IMPLICATIONS: PA-824 was metabolized by des-nitrification in Ddn and M. tuberculosis, but this does not occur in human liver S9 and M. smegmatis. Thus, PA-824 was selectively bioactivated in M. tuberculosis and there was no evidence for 'cross-activation' by human enzymes.

Do 5-fluorouracil therapies alter CYP2C19 metaboliser status?

PURPOSE: To report a case of altered CYP2C19 metaboliser status following 5-fluorouracil treatment. METHODS: A 78-year-old male with stage III colorectal adenocarcinoma was prescribed with weekly iv 5-fluorouracil and folinic acid (FU/FA). Fourteen weeks after starting FU/FA, the patient was enrolled in a clinical study to investigate the role of tumour burden on drug metabolising enzyme activity. CYP2C19 genotype was determined and the activity of CYP2C19 was measured using proguanil (PG) as a probe substrate. A metabolic ratio (PG/CG) for CYP2C19 activity was determined on three separate occasions, 7 days apart. RESULTS: The patient was homozygous wild type (CYP2C19*1/*1), and on the first test, the metabolic ratio was concordant with the extensive metaboliser genotype. However, at day 14 and day 21, the metabolic capacity of this enzyme had decreased, and the subject had become a poor metaboliser (PG/CG > 30). The patient developed grade III hand and foot syndrome at day 10 of the study during the period of null CYP2C19 activity. CONCLUSIONS: Although 5FU is not a substrate for hepatic drug metabolising CYP enzymes, it may interfere with the synthesis of CYP2C19. Decreased activity of a related enzyme, CYP2C9, following 5FU has been reported previously. Down regulation of CYP2C9 and CYP2C19 synthesis by 5FU therapies may explain the adverse effect of 5FU on the clinical disposition of warfarin and phenytoin.

CYP2C19 pharmacogenetics in advanced cancer: compromised function independent of genotype.

CYP2C19 is a drug-metabolising enzyme involved in the metabolism of a number of chemotherapeutic agents including cyclophosphamide. Variants of the CYP2C19 gene result in a loss of function polymorphism, which affects approximately 3% of the Caucasian population. These individuals are poor metabolisers (PM) of a wide range of medications including omeprazole (OMP). In healthy subjects PM can be identified through homozygous variant genotype. However, a discordance between CYP2C19 genotype and phenotype has been reported previously in a small study of cancer patients. To investigate whether CYP2C19 activity was decreased in patients with advanced cancer, CYP2C19 genotype was determined in 33 advanced cancer patients using PCR-RFLP analysis for the two important allelic variants (*2,681G>A and *3,636G>A) and the activity of the enzyme was evaluated using the CYP2C19 probe drug OMP. The activity of the drug-metabolising enzyme CYP2C19 was severely compromised in advanced cancer patients, resulting in a PM status in 37% of the patients who had normal genotype. This is significantly (P<0.0005) higher than that would be predicted from the genotypic status of these patients. There was no evidence of a correlation between compromised CYP2C19 activity and any of the proinflammatory cytokines or acute phase response proteins studied. However, there was preliminary evidence of an association between PM status and low body mass (P=0.03). There is increasing interest in using pharmacogenetics to 'individualise medicine', however, the results of this study indicate that in a cancer population genotyping for CYP2C19 would significantly underestimate the number of phenotypic PM of drugs, such as cyclophosphamide, which may be metabolised by this enzyme.

Can in vitro drug metabolism studies with human tissue replace in vivo animal studies?

Animals provide a physiologically relevant system for evaluation of drug metabolism, but marked inter-species differences limit extrapolation to humans. Liver microsomes are used extensively as an in vitro human drug metabolising system, and with appropriate selection of parameters, such as substrate and enzyme concentrations, may predict both routes and rate of metabolism. However, variable enzyme expression between donors and overlapping substrate specificity influence reproducibility, hence recombinant human CYP enzymes expressed in human, yeast or insect cells have been developed. For complex metabolic profiles involving sequential or competing pathways, isolated hepatocytes and liver slices are of value. Altered enzyme activity and restricted availability constrain their use. Cryopreservation or culture increase availability, but changes in enzyme activity remain a constraint. To date, human in vitro systems do not predict all aspects of drug metabolism, thus a combination of in vivo animal and in vitro human studies will be required for the foreseeable future.

2-Amino metabolites are key mediators of CB 1954 and SN 23862 bystander effects in nitroreductase GDEPT.

An important feature of gene-directed enzyme-prodrug therapy is that prodrug activation can provide diffusible cytotoxic metabolites capable of generating a local bystander effect in tumours. Activation of the aziridinyl dinitrobenzamide CB 1954 by E. coli nitroreductase (NTR) provides a bystander effect assumed to be due to the potently cytotoxic 4-hydroxylamine metabolite. We show that there are four cytotoxic extracellular metabolites of CB 1954 in cultures of NTR-expressing tumour cells (the 2- and 4-hydroxylamines and their corresponding amines). The 4-hydroxylamine is the most cytotoxic in DNA crosslink repair defective cells, but the 2-amino derivative (CB 10-236) is of similar potency to the 4-hydroxylamine in human tumour cell lines. Importantly, CB 10-236 has much superior diffusion properties to the 4-hydroxylamine in multicellular layers grown from the SiHa human cervical carcinoma cell line. These results suggest that the 2-amine, not the 4-hydroxylamine, is the major bystander metabolite when CB 1954 is activated by NTR in tumours. The corresponding dinitrobenzamide nitrogen mustard SN 23862 is reduced by NTR to form a single extracellular metabolite (also the 2-amine), which has superior cytotoxic potency and diffusion properties to the CB 1954 metabolites. These results are consistent with the reported high bystander efficiency of SN 23862 as an NTR prodrug in multicellular layers and tumour xenografts.

Antimutagenic effects of wheat bran diet through modification of xenobiotic metabolising enzymes.

Diets containing wheat bran (WB) protect against cancers of the colon or breast in rats, and may be beneficial in humans. In a previous study of rats treated with the carcinogen 2-amino-3-methylimidazo[4,5-f]quinoline (IQ), inclusion of 10% wheat bran in the diet led to an apparent reduction in IQ metabolites but not of intact IQ in plasma. In the present study, male Wistar rats were fed diets containing 0, 10 or 20% wheat bran, and effects on xenobiotic metabolising enzymes compared. Wheat bran-supplementation showed differential effects on phase I enzymes, significantly increasing the activity of hepatic cytochrome P450 isozyme CYP3A2, but slightly reducing the activity of CYP1A1/2. The activities of both hepatic phase II detoxification enzymes glutathione-S-transferase and glucuronosyl transferase were also reduced. Western blotting revealed similar effects on expression of the proteins. Interestingly, the expression of xenobiotic metabolising enzymes (XME) in the colon appeared to be modulated independently of hepatic XME. Although the wheat bran-supplemented diet still led to an increased expression of CYP3A, it now slightly increased CYP1A in the colon. However, 20% wheat bran significantly increased the expression of both glutathione transferase isozymes, GST A1 & A2, in the colon. Natures Gold (NG) is a commercial wheat bran derivative which is lower than wheat bran in dietary fibre, but enriched in vitamins, minerals and various phytochemicals. Dietary supplementation with 20% Natures Gold led to similar trends as seen in wheat bran-fed rats, but more potent effects in both hepatic and colonic enzymes. The significance of these changes for activation of carcinogens to mutagenic metabolites was investigated using the Salmonella/mammalian microsome mutagenicity test. The activation of IQ and benzo[a]pyrene, but not cyclophosphamide, to a mutagen by hepatic S9 from wheat bran-fed or Natures Gold-fed rats was significantly reduced compared with S9 from animals on a diet lacking wheat bran. We suggest that modulation of xenobiotic metabolising enzymes may be an important component of cancer protection by wheat bran, and this effect may relate to micronutrients or cancer-protective non-nutrient phytochemicals rather more than to dietary fibre.

Interleukin-4 differentially regulates prostaglandin production in amnion-derived WISH cells stimulated with pro-inflammatory cytokines and epidermal growth factor.

Cytokines and growth factors have been proposed to act as in vivo modulators of amnion prostaglandin production at parturition. To characterize the effects of the 'anti-inflammatory' cytokine interleukin (IL)-4 on amnion prostaglandin production, amnion epithelium-derived WISH cells were treated with IL-4 in the presence/absence of IL-1beta, tumour necrosis factor-alpha (TNF-alpha) or epidermal growth factor (EGF). IL-4 (0.08-10 ng/ml) potently inhibited cytokine-stimulated PGE2 production over 16 h (maximal inhibition approximately 66% at 2.0 ng/ml IL-4). Delaying addition of IL-4 (1 ng/ml) by up to 8 h after IL-1beta addition only slightly attenuated its inhibitory effects, from approximately 65% to approximately 50%. EGF-stimulated PGE2 production was either not inhibited or slightly stimulated by IL-4. Immunoblotting studies revealed that IL-4 (10 ng/ml) significantly suppressed prostaglandin-H synthase-2 (PGHS-2) levels in cells stimulated with IL-1beta and TNF-alpha over 16 h, but had no consistent effects on cytosolic phospholipase A2 (cPLA2) levels under any condition. In the presence of arachidonic acid (10 microM), IL-4 again inhibited cytokine-stimulated, but not EGF-stimulated, PGE2 production. The presence of IL-4 also failed to alter the amount of arachidonic acid released in response to EGF. These findings suggest a role and potential therapeutic application for IL-4 in inhibiting amnion PGHS-2 expression and hence prostaglandin production in infection-driven preterm labour, but not labour in the absence of inflammatory initiators.

Inhibition of mouse and human CYP 1A- and 2E1-dependent substrate metabolism by the isoflavonoids genistein and equol.

The inhibitory effect of the isoflavonoids genistein and equol on cytochrome P450 activities has been investigated. Genistein and equol inhibited the high capacity component of p-nitrophenol (CYP2E1 substrate) metabolism in liver microsomes from acetone-induced mice with IC50 values of approximately 10 mM and 560 microM, respectively (cf. diethyldithiocarbamate, IC50, 69 microM). Using human CYP2E1 from a specific expression system (which overcame multienzyme involvement in the rodent system), non-competitive inhibition was also seen with both isoflavonoids. Genistein and equol also inhibited the high capacity component of ethoxyresorufin (CYP1A substrate) metabolism in liver microsomes from beta-naphthoflavone-induced mice with IC50 values of 5.6 mM and 1.7 mM, respectively (cf. alpha-naphthoflavone, IC50 0.8 microM). Using human CYPIA2 from a specific expression system, noncompetitive inhibition was seen with both isoflavonoids. CYP1A1 inhibition offers a possible explanation for the chemopreventative effect of genistein against, for example, dimethylbenz[a]anthracene genotoxicity reported in animals but the IC50 values negate the relevance of this specific chemopreventative action at the levels likely to be achieved from the human diet.

Hepatic cytochrome P450 CYP2C activity in psoriasis: studies using proguanil as a probe compound.

Retinol and proguanil are metabolised by the same family of hepatic cytochrome P450, i.e. CYP2C. We used proguanil as a probe to study CYP2C activity, and by implication retinol metabolism, in psoriasis. In vitro studies showed that retinol competitively inhibited the hepatic metabolism of proguanil to cycloguanil. Proguanil metabolism was assessed in 82 patients with chronic plaque psoriasis. Following proguanil orally (200 mg), urine was analysed for proguanil and cycloguanil. A proguanil to cycloguanil ratio < 1 signified extensive metabolism and a ratio > 10 poor metabolism. A wider range of ratios was observed in psoriasis than previously reported for normal subjects. The proguanil to cycloguanil ratio was assessed in 10 cases each of know severe and mild psoriasis. Low CYP2C activity was associated with severe psoriasis, poor metaboliser status occurring in 50% of the severe group, but in none of the mild cases, p < 0.01. These findings may indicate differences in retinoid metabolism in psoriasis.

The isoflavones equol and genistein do not induce xenobiotic-metabolizing enzymes in mouse and in human cells.

1. In view of the anticarcinogenic effects of the isoflavonoid genistein and the known ability of various flavonoids to induce carcinogen-metabolizing enzymes, the ability of the isoflavonoids genistein and equol to induce these enzymes was studied in mouse. 2. In comparison with induction by the positive control beta-naphthoflavone (40 mg/kg i.p. 4 days) neither genistein or equol (0.4-40 mg/kg i.p. 4 days) gave a significant induction of ethoxyresorufin O-deethylase, p-nitrophenol oxidase or immunoreactive CYP1A2 or CYP2E1. There was also no induction of erythromycin-N-demethylase or elevation of immunoreactive CYP3A1. 3. In contrast with the induction by beta-naphthoflavone of glutathione S-transferase protein and activity towards 1-chloro-2,4-dinitrobenzene, neither isoflavone exhibited such induction. 4. Response elements for human CYP1A1, glutathione S-transferase lambda a and the xenobiotic response element (XRE) in HepG2 cells were activated by beta-naphthoflavone but not by genistein or equol. 5. The isoflavones have been found not to induce a range of enzymes involved in carcinogen metabolism. The lack of enzyme induction differs from the characteristics of many other flavonoids. The results do not support the monofunctional induction of GST as a basis of anticarcinogenicity.

The role of S-mephenytoin hydroxylase (CYP2C19) in the metabolism of the antimalarial biguanides.

The effects of the CYP2C19 substrates, mephenytoin, methsuximide and mephobarbitone on the metabolism of proguanil and chlorproguanil by human liver microsomes were studied. All of the CYP2C19 substrates significantly inhibited (P < 0.05) the formation of both cycloguanil and chlorcycloguanil from their parent compounds. In the presence of mephenytoin (50 and 100 microM) the extent of proguanil cyclisation was decreased by 66% and 67% whilst the cyclisation of chlorproguanil was decreased by 51% and 70%, respectively. Methsuximide (50 and 100 microM) inhibited cycloguanil formation by 68% and 77% and chlorcycloguanil formation by 43% and 58%, respectively. In the presence of mephobarbitone (50 and 100 microM) the cyclisation of proguanil and chlorproguanil to their active metabolites was reduced by 24% and 42% and 48% and 63%, respectively. In addition, proguanil and chlorproguanil were shown to be mutual competitive inhibitors of metabolism to their triazine metabolites. In the presence of proguanil (50 and 100 microM) the Km value for chlorcycloguanil production was increased by 118% and 200%, respectively, with little change in Vmax. Similarly, chorproguanil (50 microM) increased the Km for the in vitro cyclisation of proguanil by 50% with no alteration in Vmax. These data suggest that both chlorproguanil and proguanil are metabolised in vitro by mephenytoin hydroxylase, CYP2C19.

The multiple dose pharmacokinetics of proguanil.

Proguanil, a prophylactic antimalarial agent, is metabolised by the polymorphic isoenzyme CYP2Cmep in man. In this study the multiple dose pharmacokinetics of proguanil were investigated in subjects who were phenotyped previously as extensive (n = 6) or poor (n = 2) metabolisers of the drug. Steady-state plasma concentrations of proguanil were achieved within 48 h in extensive metaboliser subjects and chronic administration of the drug did not appear to alter the disposition of proguanil or that of its active metabolite, cycloguanil. The currently recommended dosage regimen appears to be appropriate for extensive metabolisers of proguanil. Poor metabolisers of proguanil had significantly lower plasma concentrations of the active metabolite cycloguanil compared with extensive metabolisers. Thus, even on multiple dose administration these subjects may not achieve adequate plasma concentrations of cycloguanil. Deficient metabolism of proguanil to cycloguanil leads to an increased appearance of the N-dealkylated metabolite p-chlorphenylbiguanide in the urine of poor metabolisers.

The activation of the biguanide antimalarial proguanil co-segregates with the mephenytoin oxidation polymorphism--a panel study.

The activation of the antimalarial drug proguanil (PG) to the active metabolite cycloguanil (CG) has been evaluated in a panel of 18 subjects. These subjects had previously been screened and classified as mephenytoin poor (PMm) or extensive metabolisers (EMm) and sparteine poor (PMs) or extensive metabolisers (EMs). Five subjects had the phenotype PMm/EMs, one was PMm/PMs, six subjects were EMm/PMs and six were EMm/EMs. The PG/CG ratio in urine (8 h) was significantly higher in PMm than in EMm (P = 0.0013). This study shows that the P450-isozyme involved in the polymorphic oxidation of mephenytoin is of critical importance in the activation of PG to CG and this may explain the large intersubject variability in CG concentrations in man. PMm make up about 3% of Caucasians, but up to about 20% of Orientals. From the present study, it may be anticipated that the antimalarial effect of PG is absent or impaired in this phenotype. The sparteine polymorphism appeared not to influence the activation of PG to CG significantly.

Inter-individual variation in the metabolic activation of the antimalarial biguanides.

The aryl-biguanides proguanil and chlorproguanil were developed as part of a collaborative programme between ICI and the Liverpool School of Tropical Medicine during the 1940s. The compounds were characterized by their absence of host toxicity. However, the rapid development of parasite resistance to the actions of these drugs and the development of the 4-aminoquinoline, chloroquine, severely limited their use. The subsequent widespread development of parasite resistance to chloroquine, together with the observations that the magnitude of dihydrofolate reductase inhibitor resistance (the site of action of the biguanides) developed to pyrimethamine is not directly correlated with biguanide resistance(1,2). has resulted in renewed interest in these drugs. In particular, proguanil is now the drug of choice for malaria prophylaxis, in combination with chloroquine; used in combination with a suitable sulphonamide, it may be of value in malaria therapy.

The pharmacokinetics and activation of proguanil in man: consequences of variability in drug metabolism.

1. Based on the ratio of drug to active metabolite excreted in urine approximately 3% of a healthy Caucasian population showed a reduced ability to convert proguanil to cycloguanil. 2. Pharmacokinetic analysis showed that this observation resulted from a reduced oral clearance of proguanil in these individuals (245, 534 and 552 ml min-1) compared with the rest of the population (858 +/- 482 ml min-1). 3. Peak plasma concentrations of active metabolite were significantly lower in these subjects (54.2, 26.8 and 51.7 ng ml-1) compared with the rest of the population (141 +/- 45.2 ng ml-1). 4. The observed variability may result from the polymorphic metabolism of proguanil in man.

In vitro metabolism of the biguanide antimalarials in human liver microsomes: evidence for a role of the mephenytoin hydroxylase (P450 MP) enzyme.

The metabolic activation of the arylbiguanide antimalarials proguanil (PG) and chlorproguanil (CPG) has been investigated in liver microsomes from three human livers. All three microsomal preparations activated the biguanides. The kinetic parameters for PG metabolism to cycloguanil (CG) were Km 21.8, 29.6 and 26.4 microM and Vmax 1.5, 5.9, and 8.2 pmol min-1 mg-1. The values for CPG conversion to chlorcycloguanil (CCG) were Km 12.9, 19.7 and 26.1 microM and Vmax 5.7, 4.8 and 3.6 pmol min-1 mg-1. The metabolic activation of both biguanides was competitively inhibited by the anticonvulsant mephenytoin. Sparteine and tolbutamide had no effect on biguanide metabolism. These data suggest an involvement of the mephenytoin hydroxylase enzyme, which exhibits a genetic polymorphism in man, in the metabolic activation of the biguanide antimalarials.