Effect of methamphetamine on cytochrome P450 activity.

Amphetamine-based drugs, including methamphetamine, are some of the most widely used illegal drugs in the world. Methamphetamine is metabolized by the cytochrome P450s, the latter also being involved in the metabolism of many drugs and other xenobiotics. The effect of methamphetamine pretreatment (10 mg kg-1, intraperitoneally once daily for 6 days) on the activity of the P450 enzymes was assessed both in the rat isolated perfused liver and in vivo. The rate of 4-hydroxydiclofenac production was significantly enhanced in vivo, indicating a possible stimulatory effect on P4502C6. Similarly, the kinetics of tolbutamide and dextromethorphan in isolated perfused rat liver indicate a significant increase in both P4502C6 and the P4502D subfamily. No significant changes in midazolam kinetic in the isolated perfused rat liver were observed. The potential for methamphetamine to cause drug interactions is of clinical relevance and, therefore, it warrants further investigation. Until further drug interaction experiments are accomplished, the co-administration of drugs with methamphetamine should be conducted with caution.

Metabolism of new-generation taxanes in human, pig, minipig and rat liver microsomes.

The novel taxanes SB-T-1102, SB-T-1214 and SB-T-1216 are up to 1000-fold more cytotoxic for resistant tumour cells than clinically used paclitaxel and docetaxel, and the current study has examined the metabolism of these new taxanes in human, rat, pig and minipig liver microsomes. Metabolites were characterized by high-performance liquid chromatography (HPLC)/tandem mass spectrometry (MS/MS) analysis. Metabolic pathways derived from their structures were confirmed by investigating subsequent metabolism of purified metabolites. SB-T-1102, SB-T-1214 and SB-T-1216 were metabolized to 14, 10 and 11 products, respectively. In contrast to docetaxel, side-chain hydroxylation did not occur at their tert-butyl group, but on the isobutyl (SB-T-1102) or isobutenyl (SB-T-1214 and SB-T-1216) chains. Species differences in their metabolism were observed. For example, human and untreated rat microsomes hydroxylated SB-T-1216 preferentially at the side-chain, whereas pig and minipig microsomes preferentially metabolized more at the taxane core. The increased formation of secondary and tertiary metabolites in rat microsomes with high expression of CYP3A1/2 compared with uninduced rats confirmed the role of CYP3A in taxane metabolism. All major products were formed by human cDNA-expressed CYP3A4 and none by CYP1A2, 1B1, 2A6, 2C9 and 2E1, indicating the principal role of CYP3A orthologues in SB-T metabolism. The knowledge of metabolic pathways of the examined agents and of their rates of formation is important due to possible metabolic inactivation of these three novel drugs with a great potential for the therapy of taxane-resistant tumours. The relatively slow metabolism of SB-T-1102 could be favourable for its antitumour efficiency in vivo.

Effect of methamphetamine on the pharmacokinetics of dextromethorphan and midazolam in rats.

Methamphetamine is the fourth most frequently reported compound associated with drug abuse on admission of patients to treatment centres after cocaine, heroin and marijuana. It is metabolized in the organism with a reaction that is catalyzed by cytochrome P450, mainly by the CYP2D and CYP3A subfamily, 4-hydroxyamphetamine and amphetamine being dominant metabolites. The present pharmacokinetic study was undertaken to investigate the possible influence of methamphetamine (10 mg/kg, i.p., once daily for six days) on the pharmacokinetics of dextromethorphane as a model substrate for rat cytochrome P-4502D2 and midazolam as a model substrate for CYP3A1/2. Animals received a single injection of dextromethorphane (10 mg/kg) or midazolam (5 mg/kg) in the tail vein 24 h after the last dose of methamphetamine or administration of placebo. The results of pharmacokinetic analysis showed a significantly increased rate of dextrorphane and 3-hydroxymorphinan formation, and a marked stimulatory effect of methamphetamine on CYP2D2 metabolic activity. Similarly, the kinetics of midazolam's metabolic conversion to hydroxy derivates of midazolam indicated a significant increase in CYP3A1/2 activity. The results showed that the administration of methamphetamine significantly stimulated the metabolic activity of CYP2D2 as well as that of CYP3A1/2. With regard to the high level of homology between human and rat CYP isoforms studied, the results may have a clinical impact on future pharmacotherapy for methamphetamine abuse.

Effect of St John's wort (Hypericum perforatum) on cytochrome P-450 activity in perfused rat liver.

St. John's wort (Hypericum perforatum) is a popular over-the-counter dietary supplement and a herbal antidepressant that has been implicated in drug interactions with substrates of several cytochrome P-450 (CYP) isozymes. The effects of the St. John's wort extract (100 mg/kg, i.p., once daily for 10 days) on metabolic activity of CYP450 were assessed in the system of isolated perfused rat liver. The substrates used in this study were tolbutamide (CYP2C6), dextromethorphan (CYP2D2) and midazolam (CYP3A2). Validated HPLC method was used to quantify all compounds of interest. St. John's wort administration affected CYP activity, causing a significant decline in AUC of dextromethorphan [F(4,31)=1511, p<0.001; PLSD, p<0.001] and AUC of midazolam [F(3,25)=221, p<0.001; PLSD, p=0.035] and a significant increase in AUC of tolbutamide [F(3,26)=200, p<0.001; PLSD, p<0.001]. St. John's wort administration resulted in a significant induction of CYP2D2 and CYP3A2, and in a significant inhibition of CYP2C6 metabolic activities.

Stereochemistry of styrene biotransformation.

Metabolism of styrene, an important industrial monomer, is reviewed. Attention is focused on the stereoselectivity of its oxidation to 7,8-styrene oxide as well as on further stereoselective biotransformation by hydrolytic and mercapturic acid pathway. Toxic effects such as mutagenicity, genotoxicity, hepatotoxicity, and pneumotoxicity may be related to the ratio of styrene oxide enantiomers at the target site. In rats formation of the less mutagenic (S)-styrene oxide and a faster detoxication of the (R)-enantiomer is favored. In mice metabolic activation of styrene favors the formation of (R)-styrene oxide but this more toxic enantiomer is detoxified faster, so that a nearly racemic styrene oxide results. Stereochemistry of biotransformation can contribute to the species differences in toxicity but can hardly be interpreted as a crucial factor. Due to lack of relevant data the stereochemistry of human metabolism cannot be interpreted in relation to the toxic effects.

Biotransformation of styrene in mice. Stereochemical aspects.

Biotransformation of styrene and its toxic metabolite, phenyloxirane (1), in mice in vivo was studied. Mice were treated with single intraperitoneal doses of styrene (400 mg/kg of body weight), and with (R)-, (S)-, or racemic styrene oxide (150 mg/kg of body weight). Profiles of neutral and acidic metabolites were determined by GC/MS. Mandelic acid (3) and two mercapturic acids, N-acetyl-S-(2-hydroxy-2-phenylethyl)cysteine (5) and N-acetyl-S-(2-hydroxy-1-phenylethyl)cysteine (6), were found to be major urinary metabolites of both styrene and phenyloxirane. 1-Phenylethane-1,2-diol (2) was the main neutral metabolite. The rate of excretion of this metabolite, as determined by GC, was 5-10 times lower than that of mandelic acid. Several minor acidic metabolites were also identified. Among them, novel phenolic metabolites, namely, 2-(4-hydroxyphenyl)ethanol (7), (4-hydroxyphenyl)acetic acid (11), and two isomeric hydroxymandelic acids (12), are of toxicological significance. Main stereogenic metabolites were isolated as methyl esters from extracts of pooled acidified urine treated with diazomethane. The mandelic acid that was obtained was converted to diastereomeric Mosher's derivatives prior to analysis by NMR. Mercapturic acids were analyzed directly by (13)C NMR. Pure enantiomers of 1 were metabolized predominantly but not exclusively to corresponding enantiomers of 3. Styrene yielded predominantly (S)-mandelic acid. Fractions of mercapturic acids 5 and 6 isolated from urine amounted to 12-15% of the dose for all compounds that were administered. Conversion to mercapturic acids was highly regio- and stereoselective, yielding predominantly regioisomer 5. Styrene, as compared to racemic phenyloxirane, yielded slightly more diastereomers arising from (S)-1 than from (R)-1. These data can be explained by formation of a moderate excess of the less mutagenic (S)-1 in the metabolic activation of styrene in mice in vivo.

Stereochemical aspects of styrene biotransformation.

Urine of rats dosed with styrene (240 mg/kg), R-, S- and racemic styrene oxide (150 mg/kg) was analysed for mandelic acid enantiomers and for regioisomers and diastereomers of mercapturic acids by NMR spectrometry. Enantiomers of mandelic acid were converted to diastereomeric Mosher's derivatives prior to analysis. R- and S-styrene oxide yielded predominantly R- and S-mandelic acid, respectively, racemic styrene oxide gave predominantly the R-enantiomer whereas styrene yielded almost racemic mandelate. The regioselectivity of mercapturic acid formation was very similar for styrene, R- and S-styrene oxide. These three species yielded a 2:1 mixture of N-acetyl-S-(1-phenyl-2-hydroxyethyl)cysteine (MA1) and N-acetyl-S-(2-phenyl-2-hydroxyethyl)cysteine (MA2). R-Styrene oxide gave higher conversion to mercapturic acids (28%) than the S-isomer (19% of the dose). However, R-styrene oxide yielded stereospecifically S,R-MA1 and R,R-MA2 whereas S-styrene oxide gave R,R-MA1 and S,R-MA2. Styrene yielded a mixture of diastereomeric mercapturic acids. The ratios of R,R-/S,R-isomers were 80:20 and 15:85 for MA1 and MA2, respectively. These data suggest that styrene is metabolised stereoselectively to S-styrene oxide as a major enantiomer in rat in vivo. This enantiomer has been reported to be less mutagenic than R-styrene oxide in vitro.

The evidence for conjugated mandelic and phenylglyoxylic acids in the urine of rats dosed with styrene.

Male Wistar rats were dosed intraperitoneally with styrene (400 mg/kg). Urine samples were collected over phosphate buffer, pH 6.5 for 24 h. Excretion of mandelic (MA) and phenylglyoxylic acid (PGA) amounted to 1.66 +/- 0.62 and 5.21 +/- 2.44% of dose, respectively, as determined by ion-pair HPLC. After acidic hydrolysis, the amount of MA and PGA found in urine increased to 2.10 +/- 0.84 and 6.81 +/- 3.20% (mean +/- S.D.; n = 7), respectively. A similar increase was observed after alkaline hydrolysis of urine samples. Differences between hydrolysed and non-hydrolysed samples were significant in the paired t-test (P < 0.05). Further, urine samples were fractionated by HPLC. Fractions were subjected to acidic hydrolysis and analysed by HPLC and GC/MS. Both MA and PGA were detected in the fraction which did not contain any of these metabolites before hydrolytic treatment. Thus, MA and PGA, which are used as biomarkers of exposure to styrene, form hydrolysable conjugates in the rat. At least a minor part of the total urinary MA and PGA is bound in these conjugates.

Biotransformation of diethenylbenzenes, V. Identification of urinary metabolites of 1,2-diethenylbenzene in the rat.

1. Biotransformation of 1,2-diethenylbenzene (1) in rat was studied. Five urinary metabolites were isolated by extraction of acid hydrolysed urine and identified by nmr and mass spectroscopy, namely, 1-(2-ethenylphenyl)ethane-1,2-diol (2) 2-ethenylmandelic acid (3), 2-ethenylphenylglyoxylic acid (4), 2-ethenylphenylacetylglycine (5) N-acetyl-S-[1-(2-ethenylphenyl)-2-hydroxyethyl]cysteine (6) and N-acetyl-S-[2-(2-ethenylphenyl)-2-hydroxy-ethyl]cysteine (7). 2. In addition, minor metabolites, namely, 2-ethenylbenzoic acid (8) and 2-ethenylphenyl-acetic acid (9) were identified by glc-mass spectral analysis of the hydrolysed urine extract treated subsequently with diazomethane, hydroxylamine and a trimethyl-silylating reagent. Several compounds, which could arise from biotransformation of both ethenyl groups in the molecule of 1, were detected but not identified unequivocally. 3. A glucuronide was detected by tlc analysis of urine as a blue spot after spraying with naphthoresorcinol. Compounds showing molecular fragments indicating the glucuronide moiety were also detected by glc-mass spectroscopy in non-hydrolysed urine samples. 4. The total thioether excretion amounted to 5.3 +/- 2.4, 5.1 +/- 3.4 and 5.0 +/- 1.9% of the dose at 500, 300 and 100 mg/kg, respectively (mean +/- SD; n = 5). 5. Like styrene and other diethenylbenzene isomers, 1,2-diethenylbenzene is metabolically activated to a reactive epoxide intermediate, 2-ethenylphenyloxirane (10), which is further converted to the urinary metabolites mentioned above. The main detoxification pathways are hydrolysis to the glycol 2 followed by several oxidation steps, and conjugation with glutathione. The latter reaction is both regioselective and stereoselective. 6. The ratio of mercapturic acids 6:7 was 83:17. Each regioisomer consists of two diastereomers which show distinct resonance signals in the 13C-nmr. The diastereomer ratio was 82:28 and 79:21 for 6 and 7 respectively.

Biotransformation of acrolein in rat: excretion of mercapturic acids after inhalation and intraperitoneal injection.

Biotransformation of acrolein (ACR) was studied in vivo in the rat following inhalation and ip administration. The major and minor urinary metabolites were 3-hydroxypropylmercapturic acid (HPMA) and 2-carboxyethylmercapturic acid (CEMA), respectively. Male Wistar rats were exposed to ACR, 23, 42, 77 and 126 mg/m3, for 1 hr. The sum of mercapturic acids HPMA and CEMA excreted within 24 hr after the exposure amounted to 0.87 +/- 0.12, 1.34 +/- 0.5, 2.81 +/- 1.15, and 7.13 +/- 1.56 mumol/kg, i.e., 10.9 +/- 1.5, 13.3 +/- 5.0, 16.7 +/- 6.9, and 21.5 +/- 4.8% of the estimated absorbed dose, respectively. The dose estimate was based on reported values of minute respiratory volume and respiratory tract retention and was corrected for the ACR-induced changes in minute respiratory volume. In the relevant dose range (8.9 to 35.7 mumol/kg) the portion of mercapturic acids excreted was nearly constant for ip exposed rats. The sum of HPMA and CEMA amounted to 29.1 +/- 6.5% of the dose. These results indicate that the deficiency in rat lung metabolism of ACR to acrylic acid previously observed is not compensated by the other detoxication pathway in vivo, mercapturic acid formation. The health hazard arising from inhalation of ACR is likely to be higher than that from other routes of exposure.

Biotransformation of acrylates. Excretion of mercapturic acids and changes in urinary carboxylic acid profile in rat dosed with ethyl and 1-butyl acrylate.

1. The excretion of urinary metabolites was studied in rat dosed intraperitoneally with ethyl acrylate and 1-butyl acrylate. 2. Physiological carboxylic acids, namely, 3-hydroxypropanoic acid, lactic acid and acetic acid were determined by hplc and may be derived from the xenobiotic acrylates. 3. A significant increase in the amounts of 3-hydroxypropanoic acid and acetic acid excreted within 24 h after dosing was found in both the ethyl acrylate and 1-butyl acrylate-exposed rats. 4. A slight increase in the excretion of lactic acid (p < 0.10) was also found in animals exposed to ethyl and 1-butyl acrylates. 5. Two mercapturic acids, N-acetyl-S-(2-carboxyethyl)cysteine and the corresponding N-acetyl-S-[(2-alkoxycarbonyl)ethyl]cysteine were formed from both acrylate esters and were determined by glc. For ethyl acrylate the conversion to mercapturic acids amounted to 11% of the administered dose, whereas for 1-butyl acrylate the corresponding conjugates decreased from 3.6% to 0.5 mmol/kg to 1.6% at 3.0 mmol/kg. 6. Mercapturic acids appear to be potential biological markers of exposure to acrylate esters. However, more sensitive methods would be required for their determination than those available at present.

Metabolic pathways of 1-butyl [3-13C]acrylate. Identification of urinary metabolites in rat using nuclear magnetic resonance and mass spectroscopy.

1-Butylacrylate, an industrial monomer, is rapidly metabolized by carboxylesterase-catalyzed hydrolysis to acrylic acid and 1-butanol. Acrylic acid enters the intermediary metabolism and is efficiently degraded to carbon dioxide as the metabolic end product. To obtain a virtually complete metabolic pattern, rats were dosed by a single intraperitoneal dose of 1 mmol/kg 1-butyl [3-13C]acrylate. The urine was then analyzed by a one-dimensional 1H-detected and two-dimensional 1H-13C shift-correlated heteronuclear multiple-quantum NMR experiment. In this experiment, three urinary metabolites, namely, 3-hydroxypropanoic acid, N-acetyl-S-(2-carboxyethyl)cysteine, and N-acetyl-S-(2-carboxyethyl)cysteine sulfoxide, were identified comparing their 1H and 13C chemical shifts with those of authentic standards. In another experiment, to enhance minor metabolic pathways, rats were dosed with 0.25 mmol/kg of a carboxylesterase inhibitor, tri-o-tolyl phosphate, prior to 0.5 mmol/kg butyl [3-13C]acrylate. Under these conditions, N-acetyl-S-(2-carboxyethyl)cysteine, N-acetyl-S-[2-(butoxycarbonyl)-ethyl]cysteine, and N-acetyl-S-(2-carboxyethyl)cysteine sulfoxide were found in urine. No metabolites which would arise from a possible metabolic activation of 1-butyl acrylate to 1-butyl oxiranecarboxylate and its subsequent hydrolysis or glutathione conjugation were found. It is estimated that any metabolite amounting to more than 1% of the dose should be detected under these conditions. To study the routes by which BA enters the intermediary metabolism, incorporation of the label into urinary carboxylic acids was followed by GC/MS. Significant enrichment was found in 3-hydroxypropanoic acid and citric and isocitric acid but not in lactic acid.(ABSTRACT TRUNCATED AT 250 WORDS)

Exposure to various benzene derivatives differently induces cytochromes P450 2B1 and P450 2E1 in rat liver.

Benzene (B), toluene (T), ethylbenzene (EB), styrene (S) and xylene isomers (oX, mX, pX) are important environmental pollutants and B is a proved human carcinogen. Their inhalation by male Wistar rats (4 mg/l, 20 h/day, 4 days) caused cytochrome P450 (P450) induction. The degree of P450 2B1 induction increased and that of 2E1 decreased in the series B, T, EB, S, oX, mX and pX, as estimated by Western blots, while neither solvent was as effective for 2B1 induction as phenobarbital and B was more effective for 2E1 than ethanol. The levels of several other P450s decreased after exposure to these solvents, B being most effective. Exposure to these solvents increased in vitro hepatic microsomal oxidation of B and aniline (AN) (2E1 substrates) 3 to 6-fold, indicating induction of this P450. T oxidation was increased 2 to 4-fold and chlorobenzene (ClB) oxidation 3-fold. Sodium phenobarbital (PB, 80 mg/kg/day, 4 days, i.p.) did not increase ethylmorphine (EM) and benzphetamine (BZP) demethylation (2B1 substrates), neither of the B derivatives did so, and oX decreased it; however, pentoxyresorufin O-dealkylation was well related to the immunochemically detected 2B1 levels in control, PB and B microsomes. PB did not increase B, but increased T and ClB oxidation 2-4 and 3-fold, respectively, indicating possible 2B1 role in their oxidation. B oxidation after various inducers was related to immunochemical 2E1 levels, T and ClB oxidation to both 2B1 and 2E1 and AN oxidation to 2E1 and 1A2 levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Biotransformation of diethenylbenzenes. IV. A simple high-performance liquid chromatographic method for separation of urinary metabolites of 1,3-diethenylbenzene on analytical and semi-preparative scales.

A simple ion-suppression separation on reversed-phase columns, which is applicable for both analytical and semi-preparative work, is described. Six urinary metabolites of 1,3-diethenylbenzene (I), namely 1-(3-ethenylphenyl)-1,2-dihydroxyethane beta-D-glucosiduronates (two isomers, II and III), N-acetyl-S-[1-(3-ethenylphenyl)-2-hydroxyethyl]cysteine (IV), N-acetyl-S-[2-(3-ethenylphenyl)-2-hydroxyethyl]cysteine (V), 3-ethenylphenylmandelic acid (VI) and 3-ethenylphenylglyoxylic acid (VII), were isolated (Fig. 1). Four of them, IV-VII, have been identified in our previous work; the two glucosiduronates were identified for the first time by 1H NMR spectroscopy, fast atom bombardment mass spectrometry, and enzymic hydrolysis yielding 1-(3-ethenylphenyl)-1,2-dihydroxyethane as an aglycone. The method was reproducible the concentration range 0.05-5 mg/ml, the coefficient of variation being less than 7% (n = 5). Excretion of II-VI within 24 h in the urine of rats dosed with a single intraperitoneal injection of 100, 300 and 600 mg/kg I was determined quantitatively. The utility of the method is discussed in comparison with gas chromatographic-mass spectrometric techniques used previously.

Biotransformation of diethenylbenzenes. III: Identification of metabolites of 1,3-diethenylbenzene in rat.

1. Biotransformation of 1,3-diethenylbenzene (1) in rat gave four major metabolites, namely, 3-ethenylphenylglyoxylic acid (2), 3-ethenylmandelic acid (3), N-acetyl-S-[2-(3-ethenylphenyl)-2-hydroxyethyl]-L-cysteine (4) and N-acetyl-S-[1-(3-ethenylphenyl)-2-hydroxyethyl]-L-cysteine (5) were isolated from urine and identified by n.m.r. and mass spectrometry. 2. Four minor metabolites, 3-ethenylbenzoic acid (6), 3-ethenylphenylacetic acid (7), 3-ethenylbenzoylglycine (8) and 2-(3-ethenylphenyl)ethanol (9) were identified by g.l.c.-mass spectrometric analysis of urine extract derivatized in two different ways. 3. All identified metabolites are derived from 3-ethenylphenyloxirane (10), a reactive metabolic intermediate. No product of any metabolic transformation of second ethenyl group has been identified. However, several minor unidentified metabolites were detected by g.l.c.-mass spectrometry. 4. Total thioether excretion in 24 h urine after a single i.p. dose of 1 amounted to 28.3 +/- 3.5 dose (mean +/- SD). No significant differences in the thioether fraction were observed in the dose range 100-300 mg/kg. 5. Thioether metabolites consisted mainly of mercapturic acids 4 and 5. The ratio of metabolites 5 to 4 was 62:38. Each mercapturic acid consisted of two diastereomers. Their ratio, as determined by quantitative 13C-n.m.r. measurement was 95:5 and 79:21 for mercapturic acids 4 and 5, respectively.

Investigation of the chemical basis of nitroalkane toxicity: tautomerism and decomposition of propane 1- and 2-nitronate under physiological conditions.

Unlike primary nitroalkanes, such as 1-nitropropane, the secondary nitroalkane 2-nitropropane is geno- and hepatotoxic. Nitroalkanes exist in equilibrium with alkane nitronates. In order to investigate the relationship between nitroalkane toxicity and generation and stability of nitronates, propane 1- or 2-nitronate (4-6 mM) were incubated in buffer (pH 3.8 -7.4) in the absence or presence of cysteine. Equilibrium formation and degradation were studied by 1H-NMR spectroscopy and ion pair HPLC chromatography. Propane 1-nitronate generated 1-nitropropane rapidly and almost quantitatively. In the case of propane 2-nitronate equilibrium at pH 7.4 was reached within 8 h, when 48% of initial nitronate had tautomerised to 2-nitropropane. The pKa of the reaction 2-nitropropane less than--greater than propane 2-nitronate measured by HPLC was 7.63. Equilibrium formation, hydrolysis and reduction of nitronates were pH-dependent and, in the case of propane 2-nitronate, yielded mainly acetone, nitrite and acetone oxime, apart from 2-nitropropane. Hydrolysis of propane 2-nitronate (4 mM) to nitrite was modulated by cysteine (4 mM) and p-methoxyphenol (0.4 mM). At pH 7.4 they increased nitrite generation by 300 and 28%, respectively, at pH 4.8 they decreased nitrite formation by 91 and 82%, respectively, probably by scavenging radical intermediates. Differences between nitroalkanes in terms of content of nitronate tautomer at equilibrium are probably an important chemical determinant of their toxic potential.

Oxidative denitrification of 2-nitropropane and propane-2-nitronate by mouse liver microsomes: lack of correlation with hepatocytotoxic potential.

2-Nitropropane (2-NP) is an industrial chemical with hepatotoxic and genotoxic properties. It exists in chemical equilibrium with propane-2-nitronate, which is much more genotoxic than 2-NP. In this work the link between toxicity and metabolism of 2-NP and its nitronate was investigated. To that end 2-NP or propane-2-nitronate were incubated with murine hepatic microsomes at concentrations of up to 10 mM, and generation of nitrite was measured as product of metabolic oxidation of the two species. Under the acidic reaction conditions of the colorimetric nitrite assay propane-2-nitronate decomposed chemically to nitrite. Therefore an ion-pair HPLC assay at neutral pH was developed which enabled determination of nitrite formed from the nitronate. The rate of metabolic nitrite generation from propane-2-nitronate was 5-10-fold that obtained with 2-NP. Metabolism of either species to nitrite was dependent on the presence in the incubate of viable microsomes and of NADPH, and it was inhibited in the presence of carbon monoxide or the cytochrome P-450 inhibitor SKF525A. Acetone could also be measured as a metabolite of 2-NP. Optical difference spectra were recorded in mixtures of propane-2-nitronate with liver microsomes from phenobarbital-pretreated rats. The spectral dissociation constant was found to be 30 mM, which compares with 10 mM reported for 2-NP. 2-NP and propane 2-nitronate were incubated with mouse hepatocytes in suspension and cytotoxicity was determined by measurement of leakage of cellular lactate dehydrogenase into the medium. Both species were hardly toxic, as concentrations of 20 mM were required to elicit significant damage to the cells. The results demonstrate that propane-2-nitronate, like 2-NP, undergoes microsomal oxidative denitrification, probably catalysed by cytochrome P-450. Metabolism of both species occurs at markedly different rates, but the difference in metabolism is not reflected by a difference in hepatocytotoxic potential.

Biotransformation of diethenylbenzenes. II. Metabolic pattern of 1,4-diethenylbenzene.

The metabolism of 1,4-diethenylbenzene in the rat was followed by gas chromatographic-mass spectrometric analysis of urine using three different derivatization procedures: (i) methylation-acetylation; (ii) methylation-trimethylsilylation; (iii) methylation followed by conversion into trimethylsilyloximes. Fifteen metabolites were found in the urine of rats dosed with a single intraperitoneal injection of 1,4-diethenylbenzene (300 mg/kg). Nine of them were identified in our previous study [I. Lindhart et al., Xenobiotica, 19 (1989) 645], but the other six have not previously been reported. New metabolites, namely, 1-ethenyl-4-(1-hydroxyethyl)benzene, 4-(1,2-dihydroxyethyl)benzoic acid, (4-carboxymethylphenyl)acetylglycine, N-acetyl-S-[2-carboxy-1-(4-ethenylphenyl)ethyl]-L-cysteine, and two isomeric beta-D-glucosiduronates derived from 1-(4-ethenylphenyl)ethane-1,2-diol, were identified by mass spectrometry of their derivatives and comparison of them with the spectra of analogous metabolites of styrene and 4-methylstyrene. Acetylation of methylated urine extracts seems to be the most suitable derivatization procedure, but a combination of at least two procedures is needed if the virtually complete metabolic pattern of diethenylbenzene is to be obtained. Possible routes of biotransformation leading to the newly identified metabolites are discussed.

The reaction of alkylnitronates with glutathione.

Nitroalkanes are agents of occupational importance, and 2-nitropropane has been shown to be mutagenic and hepatotoxic. Here the reaction of alkylnitronates, such as propyl-2-nitronate, with glutathione and other thiol nucleophiles has been studied by using TLC, HPLC, and spectroscopic methods. Propyl-2-nitronate, but not 2-nitropropane, reacted with glutathione in acidic media. The reaction yielded an inseparable mixture of oxidized glutathione and a product that was identified as S-nitrosoglutathione. S-Nitrosoglutathione is known to be generated by reaction of nitrous acid with glutathione and furnishes a characteristic UV spectrum, but its NMR and mass spectral properties are described here for the first time. The 1H NMR spectrum of S-nitrosoglutathione showed in principle the resonance signals of glutathione except that the cysteine beta-protons gave two broad signals shifted downfield by 1 ppm as compared to the resonance frequencies of the glutathione cysteine beta-protons. The interpretation of the spectrum was aided by investigation of the properties of S-nitroso-N-acetylcysteine, the product of the reaction of N-acetylcysteine with propyl-2-nitronate. The nitronates of primary nitroalkanes, such as nitromethane, nitroethane, or 1-nitropropane, did not react with glutathione. The reaction between propyl-2-nitronate and glutathione did not occur at pH values greater than 5; therefore, the relevance of these findings to the disposition of propyl-2-nitronate in vivo is unclear.