Butylbenzyl phthalate hydrolysis in liver microsomes of humans, monkeys, dogs, rats and mice.

Butylbenzyl phthalate (BBzP) is used as a plasticizer to import flexibility to polyvinylchloride plastics. In this study, hydrolysis of BBzP to monobutyl phthalate (MBP) and monobenzyl phthalate (MBzP) in liver microsomes of humans, monkeys, dogs, rats and mice was examined. The kinetics for MBP formation by human, dog and mouse liver microsomes followed the Michaelis-Menten model, whereas the kinetics by monkey and rat liver microsomes fitted the Hill model. The kinetics for MBzP formation fitted the Hill model for all liver microsomes. The Vmax and in vitro clearance (CLint or CLmax) ratios of MBP/MBzP formation varied among animal species, although the Km for MBP and MBzP formation in each liver microsomes were generally comparable. The hydrolysis of BBzP to monoester phthalates in mammalian liver microsomes could be classified into two types: MBzP>MBP type for humans and dogs, and MBP>MBzP type for monkeys, rats and mice. These findings suggest that the formation profile of MBzP and MBP from BBzP by liver microsomes differs extensively among animal species.

Functional characterization of cynomolgus monkey UDP-glucuronosyltransferase 1A9.

UDP-glucuronosyltransferase 1A9 (UGT1A9) contributes to the glucuronidation of numerous drugs. Cynomolgus monkeys are regarded as experimental animals similar to humans in studies on safety evaluation and biotransformation for drug development. In this study, the similarities and differences in the enzymatic properties of UGT1A9 between humans and cynomolgus monkeys were precisely identified. UGT1A9 cDNAs of humans (humUGT1A9) and cynomolgus monkeys (monUGT1A9) were cloned, and the corresponding proteins were heterologously expressed in Sf9 cells. The enzymatic properties of UGT1A9s were characterized by kinetic analysis of propofol glucuronidation. The amino acid homology between humUGT1A9 and monUGT1A9 was 93.2 %. Propofol glucuronidation by recombinant humUGT1A9 and monUGT1A9 exhibited substrate inhibition and monophasic Michaelis-Menten kinetics, respectively. The K m, V max and CL int values of humUGT1A9 were 15.0 µM, 1.56 nmon/min/mg protein and 107 µL/min/mg protein, respectively. The K m value of monUGT1A9 was 8.8-fold higher than humUGT1A9, and the V max and CL int values of monUGT1A9 were 15 and 2 % of humUGT1A9, respectively. These findings suggest that the enzymatic properties of UGT1A9 are considerably different between humans and cynomolgus monkeys, although humUGT1A9 and monUGT1A9 were highly conserved at the amino acid level. The information on species differences in UGT1A9 function gained in this study should help with the in vivo extrapolation of drug metabolism.

Metabonomic study on the biochemical response of spontaneously hypertensive rats to chronic taurine supplementation using (1)H NMR spectroscopic urinalysis.

There is a wealth of experimental information and some clinical evidence available in the literature suggesting that taurine exerts preventive effects on cardiovascular diseases. In particular, taurine has been shown to reduce blood pressure in not only hypertensive patients but also in a number of hypertensive rodent models such as spontaneously hypertensive rats (SHR). However, the molecular basis of the efficacy and toxicity of the compound has not been fully characterized. We have investigated the effects of taurine supplementation to urinary low-molecular-weight endogenous metabolites in SHR using a (1)H NMR-based urinary metabonomic approach. The SHR were chronically treated with 3% taurine in drinking water from four to 14 weeks of age, and 24-h urine samples were analyzed using (1)H NMR spectroscopy. Metabolic information was extracted from the NMR data by principal components analysis as well as visual inspection. Consequently, the metabolite profile started to change with considerable interindividual variation from six weeks of age. The extent of change became increasingly remarkable with the duration of treatment, with the concurrent observation of the hypotensive effect. The metabolic changes included a decreased urinary output of tricarboxylic acid cycle intermediates (citrate, α-ketoglutarate, and succinate) and an increased output of phenylacetylglycine and p-cresol sulfate. The results suggest that chronic taurine supplementation to the SHR resulted in an acceleration of metabolic acidosis with perturbation in the tricarboxylic acid cycle and the modulation of the intestinal microbial metabolism.

Sample preparation method to minimize chemical shift variability for NMR-based urinary metabonomics of genetically hypertensive rats.

Urinary metabonomics based on proton nuclear magnetic resonance ((1)H NMR) has been widely employed to study metabolic differences associated with gene function and pathophysiological and toxicological stimuli. However, the chemical shift variability of (1)H NMR signals, which is due to differences in pH and ionic strength among urine samples, remains an outstanding problem for efficient data mining. Thus, we have proposed an improved sample preparation method where urine samples are lyophilized and reconstituted in a buffer solution (pH 7.40) so that the extent of urine concentration becomes constant based on creatinine concentration. In order to examine the usefulness of the proposed method, urine samples taken from spontaneously hypertensive rats (SHR) and stroke-prone SHR (SHRSP) were treated not only by the proposed method but also by the usual method where urine with various concentrations is mixed with an equivalent volume of buffer solution (pH 7.40). Consequently, the pH of the urine samples prepared by the proposed method was precisely controlled to 6.89-7.01, whereas the pH of samples by the usual method was in the range of 6.81-7.18. The chemical shift variations of various metabolites having ionizable groups such as succinate, α-ketoglutarate, cis-aconitate, taurine, and glycine were significantly reduced with decreases in pH variability. A preliminary multivariate statistical analysis was carried out for the (1)H NMR spectral data obtained by the proposed method, where the metabolic profiles were distinguished between the SHR and SHRSP. The proposed sample preparation method will be particularly useful to closely inspect NMR-based urinary metabonomic data for the exploration of metabolic changes.

Catalytic roles of CYP2D6.10 and CYP2D6.36 enzymes in mexiletine metabolism: in vitro functional analysis of recombinant proteins expressed in Saccharomyces cerevisiae.

Cytochrome P450 2D6 (CYP2D6) metabolizes approximately one-third of the medicines in current clinical use and exhibits genetic polymorphism with interindividual differences in metabolic activity. To precisely investigate the effect of CYP2D6*10B and CYP2D6*36 frequently found in Oriental populations on mexiletine metabolism in vitro, CYP2D6 proteins of wild-type (CYP2D6.1) and variants (CYP2D6.10 and CYP2D6.36) were heterologously expressed in yeast cells and their mexiletine p- and 2-methyl hydroxylation activities were determined. Both variant CYP2D6 enzymes showed a drastic reduction of CYP2D6 holo- and apoproteins compared with those of CYP2D6.1. Mexiletine p- and 2-methyl hydroxylation activities on the basis of the microsomal protein level at the single substrate concentration (100 microM) of variant CYP2D6s were less than 6% for CYP2D6.10 and 1% for CYP2D6.36 of those of CYP2D6.1. Kinetic analysis for mexiletine hydroxylation revealed that the affinity toward mexiletine of CYP2D6.10 and CYP2D6.36 was reduced by amino acid substitutions. The Vmax and Vmax/Km values of CYP2D6.10 on the basis of the microsomal protein level were reduced to less than 10% of those of CYP2D6.1, whereas the values on the basis of functional CYP2D6 level were comparable to those of CYP2D6.1. Although it was impossible to estimate the kinetic parameters for the mexiletine hydroxylation of CYP2D6.36, the metabolic ability toward mexiletine was considered to be poorer not only than that of CYP2D6.1 but also than that of CYP2D6.10. The same tendency was also observed in kinetic analysis for bufuralol 1''-hydroxylation as a representative CYP2D6 probe. These findings suggest that CYP2D6*36 has a more drastic impact on mexiletine metabolism than CYP2D6*10.

Different effects of desipramine on bufuralol 1''-hydroxylation by rat and human CYP2D enzymes.

Inhibitory effects of desipramine (DMI) on rat and human CYP2D enzymes were studied using bufuralol (BF) 1''-hydroxylation as an index. Inhibition was examined under the following two conditions: 1) DMI was co-incubated with BF and NADPH in the reaction mixture containing rat or human liver microsomes or yeast cell microsomes expressing rat CYP2D1, CYP2D2 or human CYP2D6 (co-incubation); 2) DMI was preincubated with NADPH and the same enzyme sources prior to adding the substrate (preincubation). When either rat liver microsomes or recombinant CYP2D2 was employed, the preincubation with DMI (0.3 microM) caused a greater inhibition of BF 1''-hydroxylation than the co-incubation did, whereas BF 1''-hydroxylation by rat CYP2D1 was not markedly affected under the same conditions. The inhibitory effect of DMI on BF 1''-hydroxylation by human liver microsomal fractions or recombinant CYP2D6 was much lower than that on the hydroxylation by rat liver microsomes or CYP2D2. Kinetic studies demonstrated that the inhibition-type changed from competitive for the co-incubation to noncompetitive for the preincubation in the case of CYP2D2, whereas the inhibition-type was competitive for both the co-incubation and the preincubation in the case of CYP2D6. Furthermore, the loss of activity of rat CYP2D2 under the preincubation conditions followed pseudo-first-order kinetics. Binding experiments employing the recombinant enzymes and [(3)H]-DMI revealed that CYP2D2 and CYP2D6 were the only prominent proteins to which considerable radioactive DMI metabolite(s) bound. These results indicate that rat CYP2D2 biotransforms DMI into reactive metabolite(s), which covalently bind to CYP2D2, resulting in inactivation of the enzyme. In contrast, human CYP2D6 may also biotransform DMI into some metabolite(s) that covalently bind to CYP2D6, but that do not inactivate the enzyme.

Molecular cloning and functional analysis of cytochrome P450 1A2 from Japanese monkey liver: comparison with marmoset cytochrome P450 1A2.

A cDNA encoding a novel cytochrome P450 1A2 (CYP1A2) was cloned from the liver of an adult female Japanese monkey. The CYP1A2 protein was expressed in yeast cells and its enzymatic properties were compared with those of marmoset CYP1A2 using ethoxyresorufin (ER) and phenacetin (PN) as substrates. The nucleotide sequence of Japanese monkey CYP1A2 revealed 94.7, 99.5 and 93.5% identities to those of human, cynomolgus monkey and marmoset monkey CYP1A2, respectively. Multiple amino acid sequence alignment of Japanese monkey CYP1A2 with CYP1A2 of humans, cynomolgus monkeys and marmosets showed that Japanese monkey CYP1A2 had 92.4, 99.0 and 91.9% identities to the human, cynomolgus monkey and marmoset enzymes, respectively. Kinetic studies demonstrated that the enzymatic properties as ER and PN O-deethylases were considerably different between the Japanese monkey and the marmoset CYP1A2. Furthermore, both of these reactions in liver microsomal fractions from the Japanese monkey and marmoset showed biphasic kinetics. On the basis of the kinetic parameters, it is suggested that Japanese monkey CYP1A2 is a high-K(m) enzyme in both ER and PN O-deethylations, whereas marmoset CYP1A2 is a high-K(m) and low-K(m) enzyme in ER and PN O-deethylations, respectively. alpha-Naphthoflavone, an inhibitor of human CYP1A1 and CYP1A2, did not completely inhibit the liver microsomal oxidations of ER and PN even at the highest concentration (50muM), supporting the notion that CYP1A2 enzymes are not the sole ER or PN O-deethylase in Japanese monkey and marmoset liver microsomes. Inhibitory effects of furafylline, an inhibitor of human CYP1A2, on ER O-deethylation by recombinant CYP1A2 enzymes were much lower than those of alpha-naphthoflavone, but marmoset CYP1A2 was more sensitive to furafylline than Japanese monkey CYP1A2. These results indicate that the properties of Japanese monkey CYP1A2 are considerably different from those of marmoset CYP1A2.

Functional characterization of five novel CYP2C8 variants, G171S, R186X, R186G, K247R, and K383N, found in a Japanese population.

Cytochrome P450 2C8 is one of the primary enzymes responsible for the metabolism of a wide range of drugs such as paclitaxel, cerivastatin, and amiodarone. We have sequenced the CYP2C8 gene from 201 Japanese subjects and found five novel nonsynonymous single nucleotide polymorphisms (SNPs): 511G>A (G171S), 556C>T (R186X; X represents the translational stop codon), 556C>G (R186G), 740A>G (K247R), and 1149G>T (K383N), with the allele frequency of 0.0025. The CYP2C8 variants were heterologously expressed in COS-1 cells and functionally characterized in terms of expression level, paclitaxel 6alpha-hydroxylase activity, and intracellular localization. The prematurely terminated R186X variant was undetectable by Western blotting and inactive toward paclitaxel 6alpha-hydroxylation. The G171S, K247R, and K383N variants exhibited properties similar to those of the wild-type CYP2C8. Paclitaxel 6alpha-hydroxylase activity of the R186G transfectant was only 10 to 20% that of wild-type CYP2C8. Furthermore, the R186G variant displayed a lower level of protein expression in comparison to the wild type, which was restored by the addition of a proteasome inhibitor (MG-132; Z-Leu-Leu-Leu-aldehyde). The reduced CO-difference spectral analysis using recombinant proteins from an insect cell/baculovirus system revealed that the R186G variant has a minor peak at 420 nm in addition to the characteristic Soret peak at 450 nm, suggesting the existence of improperly folded protein. These results indicate that the novel CYP2C8 SNPs, 556C>T (R186X) and 556C>G (R186G), could influence the metabolism of CYP2C8 substrates such as paclitaxel and cerivastatin.

Change in enantioselectivity in bufuralol 1''-hydroxylation by the substitution of phenylalanine-120 by alanine in cytochrome P450 2D6.

The functional roles of phenylalanine at position 120 in drug oxidation by cytochrome P450 2D6 (CYP2D6) were examined using a yeast cell expression system and bufuralol (BF) enantiomers as a chiral substrate. Two mutated cDNAs, one encoding a CYP2D6 mutant having alanine instead of Phe-120 (F120A) and another encoding a mutant having alanine instead of Glu-222 (E222A), were prepared by site-directed mutagenesis and transformed into yeast cells via pGYRI vectors. The enantiomeric BF 1''-hydroxylase activities of the mutants were compared with those of the wild type. When enantiomeric BF 1''-hydroxylase activities at a substrate concentration of 100 microM were compared, the CYP2D6 wild type showed substrate enantioselectivity of (R-BF >> S-BF) and the F120A mutant exhibited substrate enantioselectivity of (R-BF < or = S-BF), whereas the product diastereoselectivity of (1''R-OH-BF << 1''-S-OH-BF) was similar between the wild type and the mutant. The activities of the other mutant (E222A) were much lower than those of the wild type and the F120A mutant, while its substrate enantioselectivity and product diastereoselectivity were the same as those of the wild type. The kinetics demonstrated that apparent K(m) values were similar among the recombinant enzymes, and V(max) values clearly reflected the selectivity described above. These results indicate that Phe-120 has a key role in the enantioselective BF 1''-hydroxylation by CYP2D6.

Seven novel single nucleotide polymorphisms in the human SLC22A1 gene encoding organic cation transporter 1 (OCT1).

Twenty genetic variations, including seven novel ones, were found in the human SLC22A1 gene, which encodes organic cation transporter 1, from 116 Japanese individuals. The novel variations were as follows: -94C>A in the 5'-untranslated region (A of the translation start codon is numbered +1 in the cDNA sequence; MPJ6_OC1001), 350C>T (MPJ6_OC1004), IVS1-35T>C (MPJ6_OC1006), 561G>A (MPJ6_OC1010), IVS6+75C>G (MPJ6_OC1014), IVS8+108A>G (MPJ6_OC1017), and 1671_1673delATG (MPJ6_OC1020). The frequencies were 0.082 for IVS1-35T>C, 0.022 for IVS6+75C>G, 0.009 for 561G>A, and 0.004 for the other 4 variations. Among them, 350C>T resulted in the amino acid substitution Pro117Leu, which is located in the large extracellular loop between transmembrane domains 1 and 2. Also, we detected the four previously reported nonsynonymous variations, 123C>G (Phe41Leu), 480C>G (Phe160Leu), 1022C>T (Pro341Leu), and 1222A>G (Met408Val) with frequencies of 0.004, 0.086, 0.168, and 0.810, respectively.

The roles of amino acid residues at positions 43 and 45 in microsomal contents and enzymatic functions of rat CYP2D1 and CYP2D2.

The effects of the substitution of amino acid residues at positions 43 and 45 of rat CYP2D1 and CYP2D2 on their microsomal contents and enzymatic functions were examined. The substitution of Val-45 of CYP2D1 by glycine decreased the microsomal content, whereas the substitution of Gly-45 of CYP2D2 by valine increased. The substitution of Leu-43 of CYP2D2 by tryptophan also increased the microsomal protein content. In reduced CO-difference spectra, CYP2D2 showed a P420 peak as well as a P450 peak, whereas CYP2D1 gave only a P450 peak. The substitution of Leu-43 and Gly-45 of CYP2D2 by valine and tryptophan, respectively, markedly decreased the P420 peak in parallel with an increase in P450 content. These substitutions did not cause remarkable changes in drug oxidation capacities (bufuralol 1''-hydroxylation and debrisoquine 4-hydroxylation) of the recombinant enzymes in terms of nmol/min/nmol CYP. The results indicate that amino acid residues at positions 43 and 45 are important for anchoring of the rat CYP2D proteins and their stabilities in the endoplasmic reticulum membrane.

Cloning and functional expression of a novel marmoset cytochrome P450 2D enzyme, CYP2D30: comparison with the known marmoset CYP2D19.

Using a primer set designed on the cDNA encoding the known marmoset cytochrome P450 2D19 (CYP2D19), a cDNA encoding a novel CYP2D enzyme (CYP2D30) was cloned from the liver of a female marmoset bred at Kyoto University (KYU). In addition, a cDNA encoding CYP2D19 was cloned from the liver of a female marmoset bred at Kagoshima University (KAU). CYP2D30 and CYP2D19 showed homologies of 93.6 and 93.4% in their nucleotide and amino acid sequences, respectively. Reverse transcription polymerase chain reaction (RT-PCR) and digestion with NdeI demonstrated that the KYU-marmoset liver contained mainly mRNA for CYP2D30, while the KAU-marmoset liver contained mainly mRNA for CYP2D19. Marmoset CYP2D30, like human CYP2D6, exhibited high debrisoquine (DB) 4-hydroxylase activity and relatively low DB 5-, 6-, 7- and 8-hydroxylase activities, whereas CYP2D19 lacked DB 4-hydroxylase but exhibited marked 5-, 6-, 7- and 8-hydroxylase activities. The two marmoset recombinant enzymes showed enantioselective bufuralol (BF) 1"-hydroxylase activities, similar to CYP2D6. BF 1"-hydroxylation by CYP2D30 exhibited product-enantioselectivity of (1"R-OH-BF << 1"S-OH-BF), similar to that observed with human CYP2D6, whereas CYP2D19 showed a reversed selectivity of (1"R-OH-BF > or = 1"S-OH-BF). BF 1"-hydroxylation in marmoset liver microsomes from both sources was inhibited by antibodies raised against rat CYP2D1 in a concentration-dependent manner. A known inhibitor of CYP2D6, quinidine, effectively inhibited the BF 1"-hydroxylation activities in liver microsomal fractions prepared from KYU- and KAU-marmosets. These results suggest that CYP2D19 and CYP2D30 proteins can be expressed as functional enzymes in marmoset livers, although it is unresolved whether both enzymes coexist in the same marmoset liver.

Stereoselectivity in the oxidation of bufuralol, a chiral substrate, by human cytochrome P450s.

Bufuralol (BF), a nonselective beta-adrenoceptor blocking agent, has a chiral center in its molecule, yielding the enantiomers 1'R-BF and 1'S-BF. beta-Adrenoceptor blocking potency is much higher in 1'S-BF than in 1'R-BF. One of the metabolic pathways of BF is 1"-hydroxylation of an ethyl group attached at the aromatic 7-position forming a carbinol metabolite (1"-hydroxybufuralol, 1"-OH-BF), and further oxidation (or dehydrogenation) produces a ketone metabolite (1-oxobufuralol, 1"-Oxo-BF). Both 1"-OH-BF and 1"-Oxo-BF are known to have beta-adrenoceptor blocking activities comparable to or higher than those of the parent drug. The 1"-hydroxylation introduces another chiral center into the BF molecule and four 1"-OH-BF diastereomers are formed from BF racemate in mammals, including humans, making elucidation of the metabolic profiles complicated. HPLC methods employing derivatization, reversed phase, or chiral columns have been developed to efficiently separate the four 1"-OH-BF diastereomers formed from BF enantiomers or racemate. Accumulated in vitro experimental results revealed that 1'R-BF is a much more preferential substrate than 1'S-BR for BF 1"-hydroxylation in human liver microsomes. Kinetic studies using recombinant human cytochrome P450 (CYP) enzymes indicate that CYP2D6 serves as a major BF 1"-hydroxylase and that CYP1A2 and CYP2C19 also contribute to BF 1"-hydroxylation in human livers. This mini-review summarizes the knowledge reported so far on the pharmacology of BF and its metabolites and the profiles of BF metabolism, especially focusing on the stereoselectivity in the oxidation of BF mainly in human livers and recombinant CYP enzymes.

Alteration in catalytic properties of human CYP2D6 caused by substitution of glycine-42 with arginine, lysine and glutamic acid.

The effects of the substitution of glycine at position 42 with various other amino acid residues on the functions of CYP2D6 were studied using debrisoquine (DB) and bunitrolol (BTL) 4-hydroxylations as indices of drug-metabolizing enzymes. The substitution with hydrophobic amino acid residues such as valine and phenylalanine did not affect the enzymatic properties such as reduced CO-difference spectra, microsomal CYP contents and oxidation activities towards DB and BTL. The substitution of glycine-42 with a polar but noncharged amino acid residue (serine) exhibited a similar reduced CO-different spectrum, but the substitution with a charged basic (lysine and arginine) or acidic (glutamic acid) amino acid residue commonly produced a peak at 420 nm in addition to a Soret peak at 450 nm. Cytochrome P450 contents and microsomal contents of G42S, G42K, G42R and G42E estimated spectrophotometrically and estimated by Western blot analysis, respectively, were lower than those of the wild-type. Kinetic analysis revealed that the substitution of glycine-42 with charged amino acid residues such as lysine, arginine and glutamic acid markedly increased the apparent K(m) values for DB and BTL oxidations without remarkable changes in the V(max) values. The subsitution with noncharged amino acid residues such as serine, valine and phenylalanine did not cause such a marked change in the K(m) values. Efficiencies (V(max)/K(m)) as DB and BTL 4-hydroxylases of CYP2D6 mutant proteins having charged amino acid residues were found to be decreased mainly by increasing their K(m) values. These results indicate that the properties of amino acid residues at position 42 affect the behavior of CYP2D6 proteins such as anchoring into ER membranes, conversion of P450 to P420 and incorporation of heme into apoproteins.

Complementary DNA cloning and characterization of cytochrome P450 2D29 from Japanese monkey liver.

A cDNA was cloned from Japanese monkey liver mRNA by reverse transcriptase-polymerase chain reaction (RT-PCR) using oligonucleotide primers based on the marmoset cytochrome P450 2D19 (CYP2D19) nucleotide sequence. The full-length cDNA encoded a 497 amino acid protein (designated CYP2D29) that is 96, 91, and 88% homologous to human CYP2D6, cynomolgus monkey CYP2D17, and marmoset monkey CYP2D19, respectively. Yeast cells (Saccharomyces cerevisiae AH-22 strain) transfected with pGYR1 vectors containing the CYP2D29 cDNA were cultured, and microsomal fractions were obtained. Reduced carbon monoxide-difference spectra and western blot analysis using polyclonal antibodies raised against rat CYP2D2 demonstrated that in yeast cell microsomal fractions, the level of CYP2D29 holoenzyme was similar to that of CYP2D6 holoenzyme. However, western blot analysis indicated that the level of CYP2D29 in Japanese monkey liver microsomes might be much higher than that of CYP2D6 in human liver microsomes. Japanese monkey liver microsomes exhibited much higher activities than did human liver microsomes, expressed as nmol/min/mg protein, for debrisoquine (DB) 4-hydroxylation and bufuralol (BF) 1"-hydroxylation (typical reactions catalyzed by CYP2D6), whereas recombinant CYP2D29 activity, expressed as nmol/min/nmol CYP, was similar to that of CYP2D6 for DB and BF hydroxylation. In kinetic analyses, the K(m) value of CYP2D29 for DB 4-hydroxylation was much lower than that of Japanese monkey liver microsomes, whereas the K(m) value of CYP2D6 for DB 4-hydroxylation was similar to that of human liver microsomes. In contrast, K(m) values for BF 1"-hydroxylation were similar for Japanese monkey and human liver microsomes and yeast cell microsomal fractions expressing recombinant CYP2D29 or CYP2D6. These results suggest that the properties of Japanese monkey CYP2D29 are similar to those of human CYP2D6, but their populations and/or some other factors in liver microsomes may cause the difference in microsomal DB 4-hydroxylase activities between Japanese monkeys and humans.