Metabolism of tamoxifen and its uterotrophic activity

Tamoxifen is an estrogen agonist in mouse uterus, a partial estrogen agonist/antagonist in rat uterus, and a pure estrogen antagonist in chicken oviduct. Tamoxifen metabolism was examined both in vitro and in vivo to determine if differences in the species response to this drug resulted from the differential formation of metabolites with estrogenic or antiestrogenic activity. Animals were given a subcutaneous injection of [3H]tamoxifen, and 4 or 24 hr later tamoxifen and its metabolites were extracted from tissues and separated by TLC. The profiles of metabolites extracted from the livers of these species were qualitatively similar; the principle metabolite was 4-hydroxytamoxifen, which comprised 27, 14, and 16% of the radioactivity from mouse, rat, and chicken livers, respectively, at 24 hr. Tamoxifen, however, was the principal compound extracted from all three livers. Metabolites extracted from mouse and rat uteri were the same ones obtained from liver, although their abundance (relative to tamoxifen) was much lower in uteri than in liver. Metabolite E and bisphenol, two tamoxifen derivatives that we believed might account for the uterotrophic effect of tamoxifen in the mouse, were found not to be formed in either liver or uterus. Tamoxifen metabolism was also studied in vitro using liver microsomes from these same species; The same metabolites were formed in vitro as in vivo, although their relative abundances were lower in vitro. No clear-cut differences in metabolism were seen that would account for the disparate pharmacological effects of tamoxifen in these species.     

Metabolism of loprazolam in rat- and dog-liver preparations

The metabolism of loprazolam by rat- and dog-liver preparations has been studied in aerobic and anaerobic conditions. Identification of unchanged loprazolam and metabolites was by comparison of chromatographic characteristics and mass spectra with those of authentic compounds. The piperazine-N-oxide was the sole metabolite formed under aerobic conditions in dog-liver slices and microsomes. In addition to this N-oxide, the N-desmethyl metabolite and the diazepine-hydroxy metabolite were formed in rat-liver microsomes. The principal metabolite in rat-liver slices was the glucuronide of the hydroxy compound. Under anaerobic conditions the nitro group of loprazolam is reduced to the amine by dog-liver slices and rat-liver microsomes.     

Reversible and irreversible inhibition of CYP3A enzymes by tamoxifen and metabolites

1. Preliminary studies have identified cytochrome P450 (CYP) 3A4 and CYP1B1 as the human CYPs inhibited by tamoxifen. To quantify the inhibitory potency of tamoxifen and its major metabolites, the metabolism of three substrates of CYP3A, midazolam, diltiazem and testosterone, and 7-ethoxyresorufin as a substrate of CYP1B1 were examined in catalytic assays carried out using human liver microsomes and cDNA-expression systems. 2. Tamoxifen, N-desmethyltamoxifen, 4-hydroxytamoxifen and 3-hydroxytamoxifen reversibly inhibited midazolam 1'-hydroxylation, diltiazem N-demethylation and testosterone 6beta-hydroxylation with K(i) ranging from 3 to 37 micro M in human liver microsomes. Tamoxifen, N-desmethyltamoxifen, 4-hydroxytamoxifen and 3-hydroxytamoxifen also reversibly inhibited the activity of cDNA-expressed CYP3A4, CYP3A5 and CYP1B1. 3. Tamoxifen and N-desmethyltamoxifen exhibited time-dependent inactivation of testosterone 6beta-hydroxylation by cDNA-expressed CYP3A4 (+ cytochrome b5) yielding k(inact) and K(i) of 0.04 min(-1) and 0.2 micro M for tamoxifen and 0.08 min(-1) and 2.6 micro M for N-desmethyltamoxifen. A metabolic intermediate complex (MIC) was also formed by tamoxifen and N-desmethyltamoxifen with CYP3A4 (+ cytochrome b5) and CYP3A4 but not with CYP3A5 or CYP3A7. Pre-incubation with 4-hydroxytamoxifen and 3-hydroxytamoxifen did not result in any CYP3A inactivation or detectable MIC formation. There was no detectable time-dependent inactivation or MIC formation with tamoxifen or metabolites with CYP1B1. 4. These data indicate that tamoxifen and its three major metabolites are effective inhibitors of CYP3A in vitro and that tamoxifen and N-desmethyltamoxifen are effective mechanism-based inhibitors. Thus, caution should be exercised when tamoxifen is coadministered with other CYP3A substrates.     

Metabolites, pharmacodynamics, and pharmacokinetics of tamoxifen in rats and mice compared to the breast cancer patient.

The metabolism of tamoxifen was examined in the rat, mouse, and human breast cancer patient. Large oral doses of tamoxifen (200 mg/kg) in the immature ovariectomized rat and mature mouse produced circulating levels of the parent compound, N-desmethyltamoxifen, and 4-hydroxytamoxifen quantifiable by HPLC separation, UV activation, and fluorescence detection. N-Desmethyltamoxifen and 4-hydroxytamoxifen serum levels in the mature ovariectomized mouse paralleled tamoxifen levels throughout a 96-hr time course after a single dose of tamoxifen. On the other hand, N-desmethyltamoxifen was the predominant serum metabolite after an equivalent dose of tamoxifen to the immature rat, but there was little 4-hydroxytamoxifen. Peak levels of tamoxifen occurred 3-6 hr after oral administration of tamoxifen in both species, whereas peak levels of N-desmethyltamoxifen in the immature rat did not occur until 24-48 hr. AUCs for tamoxifen and N-desmethyltamoxifen were approximately 4 times greater in the rat (57.5 and 111 micrograms.hr/ml, respectively) than the mouse (15.9 and 26.3 micrograms.hr/ml, respectively) after equivalent doses of tamoxifen (200 mg/kg). AUC of 4-hydroxytamoxifen for the rat (8.9 micrograms.hr/ml), however, was similar to that for the mouse (13.9 micrograms.hr/ml). The rate of elimination from serum was similar for tamoxifen, N-desmethyltamoxifen, and 4-hydroxytamoxifen in both the rat (t1/2 = 10.3, 12.1, and 17.2 hr, respectively) and the mouse (t1/2 = 11.9, 9.6, and 6 hr, respectively). Administration of large oral doses of tamoxifen (200 mg/kg) every 24 hr to mature ovariectomized mice or immature ovariectomized rats resulted in accumulation for the first 4 days.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative studies of the in vitro metabolism and covalent binding of 14C-benzene by liver slices and microsomal fraction of mouse, rat, and human

Metabolism of benzene by the liver has been suggested to play an important role in the hepatotoxicity of benzene. The role of the different benzene metabolites and the causes of species differences in benzene hepatotoxicity are, however, not known. The metabolism and covalent binding of 14C-benzene by liver microsomal fractions and liver slices from rat, mouse, and human subjects have been studied. Rat microsomal fraction formed phenol at a rate of 0.32 nmol/min/mg of protein; mouse microsomal fraction formed phenol at 0.64 nmol/min/mg and hydroquinone at 0.03 nmol/min/mg; and human microsomal fraction formed phenol at 0.46 nmol/min/mg and hydroquinone at 0.07 nmol/min/mg. Covalent binding of 14C-benzene metabolites to rat, mouse, and human liver microsomal protein was 29, 113, and 169 pmol/min/mg of protein, respectively. The rates of metabolite formation from benzene by liver slices in nmol/min/g of tissue were: rat, phenol 0.15, hydroquinone 0.26, and phenylsulfate 1.22; mouse: phenol 0.13, hydroquinone 0.29, phenylsulfate 1.37, and phenylglucuronide 1.34; and human: phenol 0.16, hydroquinone 0.27, phenylsulfate 0.83, and phenylglucuronide 0.52. trans,trans-Muconic acid formation was not detected with liver slices of any species. Covalent binding of 14C-benzene metabolites to rat, mouse, and human liver slices was 8.2, 79.7, and 27.3 pmol/min/g liver, respectively. There was no correlation between ascorbic acid levels in the human liver slices and covalent binding of 14C-benzene metabolites. The results show that phenol and hydroquinone found in extrahepatic tissues, including bone marrow, of animals exposed to benzene could originate from the liver. There was no evidence for the release of highly reactive benzene metabolites such as trans,trans-muconaldehyde or p-benzoquinone from liver cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Aspects of metabolism of tamoxifen by rat liver microsomes. Identification of a new metabolite: E-1-[4-(2-dimethylaminoethoxy)-phenyl]-1, 2-diphenyl-1-buten-3-ol N-oxide

Metabolism of tamoxifen N-oxide by phenobarbitone-induced rat liver microsomes gave a major metabolite which was identified as E-1-[4-(2-dimethylaminoethoxy)phenyl]-1, 2-diphenyl-1-buten-3-ol N-oxide (alpha-hydroxytamoxifen N-oxide) by comparison of mass spectral properties with synthetic material. This new metabolite was also formed from tamoxifen. Tamoxifen epoxide was synthesised; its microsomal metabolism gave the corresponding N-oxide. Neither tamoxifen epoxide nor its N-oxide was detected as a product of tamoxifen metabolism.     

Reversible and irreversible inhibition of CYP3A enzymes by tamoxifen and metabolites

1. Preliminary studies have identified cytochrome P450 (CYP) 3A4 and CYP1B1 as the human CYPs inhibited by tamoxifen. To quantify the inhibitory potency of tamoxifen and its major metabolites, the metabolism of three substrates of CYP3A, midazolam, diltiazem and testosterone, and 7-ethoxyresorufin as a substrate of CYP1B1 were examined in catalytic assays carried out using human liver microsomes and cDNA-expression systems. 2. Tamoxifen, N-desmethyltamoxifen, 4-hydroxytamoxifen and 3-hydroxytamoxifen reversibly inhibited midazolam 1'-hydroxylation, diltiazem N-demethylation and testosterone 6 β -hydroxylation with K_i ranging from 3 to 37 µM in human liver microsomes. Tamoxifen, N-desmethyltamoxifen, 4-hydroxytamoxifen and 3-hydroxytamoxifen also reversibly inhibited the activity of cDNA-expressed CYP3A4, CYP3A5 and CYP1B1. 3. Tamoxifen and N-desmethyltamoxifen exhibited time-dependent inactivation of testosterone 6 β -hydroxylation by cDNA-expressed CYP3A4 (⁺cytochrome b5) yielding k inact and K i of 0.04?min -1 and 0.2 µM for tamoxifen and 0.08?min -1 and 2.6 µM for N-desmethyltamoxifen. A metabolic intermediate complex (MIC) was also formed by tamoxifen and N -desmethyltamoxifen with CYP3A4 (+ cytochrome b5) and CYP3A4 but not with CYP3A5 or CYP3A7. Pre-incubation with 4-hydroxytamoxifen and 3-hydroxytamoxifen did not result in any CYP3A inactivation or detectable MIC formation. There was no detectable time-dependent inactivation or MIC formation with tamoxifen or metabolites with CYP1B1. 4. These data indicate that tamoxifen and its three major metabolites are effective inhibitors of CYP3A in vitro and that tamoxifen and N-desmethyltamoxifen are effective mechanism-based inhibitors. Thus, caution should be exercised when tamoxifen is coadministered with other CYP3A substrates.     

4-Hydroxytamoxifen gives DNA adducts by chemical activation, but not in rat liver cells

The drug tamoxifen shows evidence of genotoxicity, and induces liver tumors in rats. Covalent DNA adducts have been detected in the liver of rats treated with tamoxifen, and in rat hepatocytes in culture. These arise primarily from its metabolite alpha-hydroxytamoxifen, and may also arise, in part, from another metabolite, 4-hydroxytamoxifen. We have prepared two model compounds for the potential reactive metabolite formed from 4-hydroxytamoxifen in rat liver. One of these was its alpha-acetoxy ester. This was much more reactive than that from tamoxifen, and could not be isolated in pure form. It reacted with DNA in the same way that alpha-acetoxytamoxifen did, to give adducts which were isolated by hydrolysis and chromatography, and identified as alkyldeoxyguanosines. The second derivative was alpha, beta-dehydro-4-hydroxytamoxifen. This also reacts with DNA in vitro, to give the same products as those from alpha-acetoxy-4-hydroxytamoxifen. Reaction probably proceeds through the same resonance-stabilized carbocation in either case. However, when primary cultures of rat hepatocytes were treated with either 4-hydroxytamoxifen, 4,alpha-dihydroxytamoxifen, or alpha, beta-dehydro-4-hydroxytamoxifen at a concentration of 10 microM, no adducts could be detected in their DNA by the 32P-postlabeling technique. Similarly, no adducts could be found in the liver DNA of female Fischer F344 rats treated orally (at 0.12 mmol kg-1) with the same substances. If 4-hydroxytamoxifen is metabolized to 4, alpha-dihydroxytamoxifen in rat liver, then either this substance is not converted to reactive esters or they are rapidly detoxified.     

Determination of the human cytochrome P450 isoforms involved in the metabolism of zolmitriptan.

1. Zolmitriptan was extensively metabolized by freshly isolated human hepatocytes to a number of components including the three main metabolites observed in vivo (N-desmethyl-zolmitriptan, zolmitriptan N-oxide and the indole acetic acid derivative). In contrast, metabolism of zolmitriptan by human hepatic microsomes was extremely limited with only small amounts of the N-desmethyl and indole ethyl alcohol metabolites being produced. 2. Furafylline, a selective inhibitor of CYP1A2, almost completely abolished the hepatocellular metabolism of zolmitriptan and markedly inhibited formation of the N-desmethyl metabolite in microsomes. Chemical inhibitors, selective against other major human cytochrome P450 (CYP2C9, 2C19, 2D6 and 3A4), had no obvious effects. In addition, expressed human CYP1A2 was the only cytochrome P450 to form the N-desmethyl metabolite. 3. N-desmethyl-zolmitriptan was extensively metabolized by both human hepatocytes and microsomes. The indole acetic acid and ethyl alcohol derivatives were the major metabolites formed by hepatocytes, whereas only the indole ethyl alcohol derivative was produced by microsomes. Metabolism of N-desmethyl-zolmitriptan was not inhibited by cytochrome P450-selective chemical inhibitors nor was it observed following incubation with expressed human cytochrome P450. Clorgyline, a selective inhibitor of monoamine oxidase A (MAO-A), markedly inhibited the microsomal formation of the indole ethyl alcohol derivative. 4. Primary metabolism of zolmitriptan is dependent mainly on CYP1A2, whereas MAO-A is responsible for further metabolism of N-desmethyl-zolmitriptan, the active metabolite. Since the in vivo clearance of zolmitriptan is primarily dependent on metabolism, interactions with drugs that induce or inhibit CYP1A2 or MAO-A may be anticipated.     

Determination of the human cytochrome P450 isoforms involved in the metabolism of zolmitriptan

1. Zolmitriptan was extensively metabolized by freshly isolated human hepatocytes to a number of components including the three main metabolites observed in vivo (N-desmethyl-zolmitriptan, zolmitriptan N-oxide and the indole acetic acid derivative). In contrast, metabolism of zolmitriptan by human hepatic microsomes was extremely limited with only small amounts of the N-desmethyl and indole ethyl alcohol metabolites being produced. 2. Furafylline, a selective inhibitor of CYP1A2, almost completely abolished the hepatocellular metabolism of zolmitriptan and markedly inhibited formation of the N-desmethyl metabolite in microsomes. Chemical inhibitors, selective against other major human cytochrome P450 (CYP2C9, 2C19, 2D6 and 3A4), had no obvious effects. In addition, expressed human CYP1A2 was the only cytochrome P450 to form the N-desmethyl metabolite. 3. N-desmethyl-zolmitriptan was extensively metabolized by both human hepatocytes and microsomes. The indole acetic acid and ethyl alcohol derivatives were the major metabolites formed by hepatocytes, whereas only the indole ethyl alcohol derivative was produced by microsomes. Metabolism of N-desmethyl-zolmitriptan was not inhibited by cytochrome P450-selective chemical inhibitors nor was it observed following incubation with expressed human cytochrome P450. Clorgyline, a selective inhibitor of monoamine oxidase A (MAO-A), markedly inhibited the microsomal formation of the indole ethyl alcohol derivative. 4. Primary metabolism of zolmitriptan is dependent mainly on CYP1A2, whereas MAO-A is responsible for further metabolism of N-desmethyl-zolmitriptan, the active metabolite. Since the in vivo clearance of zolmitriptan is primarily dependent on metabolism, interactions with drugs that induce or inhibit CYP1A2 or MAO-A may be anticipated.     

The metabolism of chlorpromazine N-oxide in man and dog

1. The metabolism of chlorpromazine N-oxide was studied in female dogs and adult male humans after a single oral dose. 2. There was extensive metabolism in both species in that between four and seven metabolites were separately identified in urine and faeces. Apart from chlorpromazine N-oxide, chlorpromazine N,S-dioxide was the only isolated metabolite which retained the N-oxide group. The other identified metabolites were chlorpromazine and its 7-hydroxy, sulphoxide, N-desmethyl, 7-hydroxy-N-desmethyl and N-desmethylsulphoxide derivatives. 3. With dog samples, metabolites were separated by h.p.l.c. and individually collected prior to mass spectrometric analysis. With human samples, metabolites were directly subjected to h.p.l.c.-mass spectrometric determination. With all metabolites their structures were confirmed by direct comparison of their mass spectra and chromatographic behaviours with those of authentic samples. 4. The metabolites identified in urine and faeces were for the most part the same in both species, with the exceptions that chlorpromazine N-oxide was identified in the faeces of dog only and 7-hydroxy-N-desmethylchlorpromazine was identified in the urine of man only. 5. The observation of N-oxide compounds in the excreta of both man and dog contrasted with that for the previously studied rat, where no such compounds were detected.     

Inter-species comparison of microsomal reductive transformation of biologically active benfluron N-oxide

Benfluron N-oxide is an anti-neoplastic active metabolite of benfluron (B) /1/. It is generated by flavine-monooxygenase-catalysed reactions /2/ and immediately undergoes subsequent metabolic transformations, the most important of which are reductive reactions /3/. The products of reductive pathways catalysed by two different microsomal enzymatic systems are the tertiary amine benfluron (i.e. the original parent compound) and/or 7-dihydrobenfluron N-oxide. Our studies on the reductive transformation of B N-oxide in rat, mouse, guinea-pig, rabbit, mini-pig and human microsomes have revealed significant species differences both in the yields of respective reduced metabolites and in the conditions essential for the activity of the reductases involved. While B, the original tertiary amine, is the main product of aerobic incubation of B N-oxide with NADPH in rat, mouse and mini-pig, significantly higher activities of the enzymes catalysing the formation of 7-dihydro-B N-oxide have been detected in rabbit and human microsomes. In rat, mouse and mini-pig, NADPH rather than NADH is the preferred coenzyme for B formation, and NADPH is also the preferred coenzyme for the formation of 7-dihydro-B N-oxide in most of the species used. The yield of tertiary amine B is higher in anaerobic rather than aerobic conditions in most experimental species studied. Aerobic or anaerobic incubating conditions have an insignificant effect on the formation of 7-dihydro-B N-oxide. Based on the inhibitory effect of CO on the reductive transformation of B N-oxide, cytochromes P450 can be assumed to participate in the formation of B both in rat and mini-pig, and, in mini-pig only, also in the formation of 7-dihydro-B N-oxide. Inter-species comparison of the properties of the reductases participating in the transformation of B N-oxide shows that the rabbit is a suitable model to study reductive transformation of B N-oxide in man.     

三七提取物对大鼠体内他莫昔芬及其代谢物的药动学的影响

目的:研究三七提取物对大鼠体内他莫昔芬及其代谢物的药动学的影响。方法:口服给予大鼠三七提取物10 d后再分别予口服、静注他莫昔芬,采用LC-MS/MS方法,测定他莫昔芬和4-羟基他莫昔芬在血浆和胆汁中的浓度,比较药动学行为的改变情况。结果:三七提取物未改变他莫昔芬及其代谢物的血浆药动学参数,但能明显影响他莫昔芬及其代谢物的口服吸收和胆汁排泄。结论:三七提取物对大鼠体内他莫昔芬及其代谢物的口服吸收和胆汁排泄存在影响,临床上二者合用时应注意潜在的药物相互作用。     

Interactions of tamoxifen, N-desmethyltamoxifen and 4-hydroxytamoxifen with P-glycoprotein and CYP3A

The effects of tamoxifen, N-desmethyltamoxifen and 4-hydroxytamoxifen on transport attributable to P-glycoprotein were studied using Caco-2 cell monolayers in a transwell system, with rhodamine-123 as an index substrate for inhibition studies. The three compounds did not demonstrate differential flux between basal-apical and apical-basal directions in Caco-2 monolayers. The mean IC50 values for inhibition of rhodamine-123 transport were: 29 microM for tamoxifen; 26 microM for N-desmethyltamoxifen; and 7.4 microM for 4-hydroxytamoxifen. The three compounds were also evaluated as potential inhibitors of human CYP3A based on an in vitro model using triazolam hydroxylation by human liver microsomes as an index reaction. Mean (+/-SE) IC50 values versus formation of alpha-hydroxy-triazolam and 4-hydroxy-triazolam in human liver microsomes were, respectively: 23.5 (+/-3.9) and 18.4 (+/-5.3) microM for tamoxifen; 10.2 (+/-1.7) and 9.2 (+/-1.5) microM for N-desmethyltamoxifen; and 2.6 (+/-0.5) and 2.7 (+/-0.3) microM for 4-hydroxytamoxifen. Thus, tamoxifen, N-desmethyltamoxifen and 4-hydroxytamoxifen, do not appear to be substrates for transport by P-glycoprotein. However, tamoxifen has the potential to inhibit transport mediated by P-glycoprotein as well as CYP3A-mediated metabolism. Inhibitory effects of the principal metabolites, N-desmethyltamoxifen and 4-hydroxytamoxifen, may exceed those of the parent drug. Tamoxifen, and possibly its metabolites, may have the potential to cause drug interactions by inhibiting both drug transport and metabolism. This possibility requires further evaluation in clinical studies.     

Metabolic N- and S-oxygenation of dokloxytepin in vitro]

Dokloxytepin in the medium of the induced monooxygenase system of the microsomal fraction of the liver of the rat, rabbit and mice is metabolized into three metabolites: two identical, i.e., N-oxide and 5-sulfoxide, and a third different one. In the rat and rabbit it is the hitherto unknown metabolite M1, and in the mouse S,N-dioxide of dokloxytepin. The metabolites were identified by thin-layer chromatography by comparing with synthetic standards.     

Metabolism of roquinimex in mouse and rat: an in vitro/in vivo comparison

1. In vitro studies with roquinimex, an immuno-modulator, in liver microsomes from mouse and rat were conducted to evaluate the primary metabolism and compare the metabolite pattern as well as the rate of metabolism with the in vivo pharmacokinetics of the compound in these two species. 2. In the presence of NADPH, roquinimex was metabolized to six primary metabolites (R1-6) by liver microsomes from mouse and rat. The formation of these metabolites was qualitatively similar in both species, and was greatly enhanced by pretreatment with PCN, an inducer of cytochrome P4503A. 3. The identification of the R1-6 demonstrated that roquinimex had been hydroxylated and demethylated. Hydroxylation at different sites of the quinoline moiety was the dominating reaction in both species. 4. Comparison of the resulting microsomal intrinsic clearance of 0.3 micromol mg(-1) protein min(-1) in mouse liver microsomes, versus 0.03 micromol mg(-1) protein min(-1) in rat liver microsomes demonstrated that the mouse possesses about a 10-fold greater metabolic capacity for roquinimex than the rat. 5. The in vivo pharmacokinetics of roquinimex demonstrated a 7-fold higher clearance in mouse than in the rat (82 ml h(-1) kg(-1) in mouse, 10.6 ml h(-1) kg(-1) in rat), which is in concordance with the in vitro findings.     

Metabolism of coumarin and 7-ethoxycoumarin by rat,mouse, guinea pig,Cynomolgus monkey and human precision-cut liver slices

1. The metabolism of 50 μM 7-ethoxycoumarin and 50 μM [3-¹⁴C]coumarin has been studied in precision-cut liver slices from the male Sprague-Dawley rat, female DBA/2 mouse, male Dunkin-Hartley guinea pig, male Cynomolgus monkey and man.

2. In liver slices from all five species 7-ethoxycoumarin was metabolized to 7-hydroxycoumarin (7-HC), which was extensively conjugated with D-glucuronic acid and sulphate. In rat and mouse, 7-HC was preferentially conjugated with sulphate, whereas rates of glucuronidation and sulphation were similar in the other three species.

3. [3-¹⁴C]coumarin was metabolized by liver slices from all five species to various polar products and to metabolite(s) that bound covalently to liver slice proteins. In Cynomolgus monkey and both human subjects studied, 7-HC was the major metabolite that was conjugated with D-glucuronic acid and sulphate, whereas in rat the major metabolites were products of the 3-hydroxylation pathway and unknown metabolites. Major metabolites in mouse liver slices were 7-HC, 3-hydroxylation pathway products and unknown metabolites, and in guinea pig liver slices, 7-HC and unknown metabolites.

4. The metabolism of 7-ethoxycoumarin to free and conjugated 7-HC and [3-¹⁴C] coumarin to total polar products was greater in liver slices from mouse and Cynomolgus monkey than the other three species.

5. With liver slices from all five species there appeared to be little difference in the extent of metabolism of 7-ethoxycoumarin and [3-¹⁴C]coumarin to various products in either a complex tissue culture medium (RPMI 1640 plus foetal calf serum) or a simple balanced salt solution (Earle's balanced salt solution).

6. These results demonstrate that precision-cut liver slices are avaluable in vitro model system for investigating species differences in xenobiotic metabolism. Generally, the observed species differences in coumarin metabolism in vitro agree well with available in vivo data.     

Identification and structure characterization of S-containing metabolites of 3-tert-butyl-4-hydroxyanisole in rat urine and liver microsomes.

After ip administration of 3-tert-butyl-4-hydroxyanisole (3-BHA) to rats, two previously undocumented metabolites 2-tert-butyl-5-methylthiohydroquinone (TBHQ-5-SMe) and 2-tert-butyl-6-methylthiohydroquinone (TBHQ-6-SMe) were identified in the urine by comparison with the authentic samples by GC/MS. In addition to these metabolites, 3-tert-butyl-4,5-dihydroxyanisole was also detected in the urine hydrolyzed by beta-glucuronidase/sulfatase. Administration of tert-butylhydroquinone (TBHQ), an O-demethylated metabolite of 3-BHA, also resulted in the formation of the S-containing metabolites, TBHQ-5-SMe and TBHQ-6-SMe. After incubation of TBHQ with rat liver microsomes in the presence of glutathione (GSH), two metabolites were isolated and purified by HPLC. The metabolites were identified as 2-tert-butyl-5-(glutathion-S-yl)hydroquinone and 2-tert-butyl-6-(glutathion-S-yl)hydroquinone by 1H- and 13C-NMR spectrometry and by fast atom bombardment-mass spectrometry. The formation of TBHQ-GSH conjugates required NADPH, molecular oxygen, and GSH. Cytochrome P-450 inhibitors such as SKF 525-A and metyrapone markedly inhibited the formation of TBHQ-GSH conjugates in vitro. These results suggest that TBHQ is converted by cytochrome P-450-mediated monooxygenases to a reactive metabolite, 2-tert-butyl-p-benzoquinone (TBQ), which then conjugates with GSH to form TBHQ-GSH conjugates. GSH S-transferase activities do not seem to play a role in GSH conjugation reaction to TBQ because cytosol fraction from rat liver homogenates did not enhance the microsome-mediated production of TBHQ-GSH conjugates.     

Metabolism of the styrene metabolite 4-vinylphenol by rat and mouse liver and lung

Styrene is a widely used chemical in the reinforced plastics industry and in polystyrene production. Its primary metabolic pathway to styrene oxide and then to styrene glycol, which is further metabolized to mandelic acid and phenylglyoxylic acid, has been well studied. However, a few studies have reported finding a minor metabolite, 4-vinylphenol (4-VP), in rat and human urine. The present studies sought to determine if the formation and metabolism of 4-VP in rat and mouse liver and lung preparations could be measured. When styrene was incubated with hepatic and pulmonary microsomal preparations, 4-VP formation could not be measured in these preparations. However, considerable 4-VP metabolizing activity, as determined by the loss of 4-VP, was observed in both mouse and rat liver and lung microsomal preparations. 4-Vinylphenol metabolizing activity in mouse liver microsomes was three times greater than that in rat liver microsomes, and activity in mouse lung microsomes was eight times greater than that in rat lung microsomes. This activity was completely absent in the absence of NADPH. Studies with cytochrome P-450 inhibitors indicated the involvement of CYP2E1 and CYP2F2. Induction of CYP2E1 by pyridine resulted in an increase in 4-VP metabolism by mouse hepatic microsomes but not by pulmonary microsomes. The metabolite(s) formed as a result of this oxidative pathway remain to be identified. In additional studies, glutathione conjugation appeared to be involved in 4-VP metabolism with the highest activity being in mouse lung, with or without the addition of NADPH.     

Stereoselective N-oxygenation of zimeldine and homozimeldine by the flavin-containing monooxygenase

The metabolism of (Z)- and (E)-zimeldine and (Z)- and (E)-homozimeldine in hepatic rat and hog microsomes is described. The major metabolite observed in all cases examined was the tertiary amine N-oxide and it was formed at a rate 7-20 times that of norzimeldine or homonorzimeldine. N-Oxygenation requires NADPH and is stimulated by n-octylamine. Thiobenzamide and methimazole significantly inhibit N-oxide formation whereas heat pretreatment of microsomes completely abolishes N-oxide formation, strongly suggesting that zimeldine N-oxygenation if solely dependent on the flavin-containing monooxygenase. Hog liver microsomes N-oxygenate the Z-allylic and homoallylic tertiary amines in marked preference to the E-isomers, whereas rat liver microsomes N-oxygenate E-isomers to a greater extent than Z-isomers. Thus, opposite stereoselectivity for zimeldine N-oxygenation occurs in rat liver and hog liver microsomes.