Pharmacokinetics explain in vivo/in vitro discrepancies of carcinogen-induced gene expression alterations in rat liver and cultivated hepatocytes.

Cultivated hepatocytes represent a well-established in vitro system. However, the applicability of hepatocytes in toxicogenomics is still controversially discussed. Recently, an in vivo/in vitro discrepancy has been described, whereby the non-genotoxic rat liver carcinogen methapyrilene alters the expression of the metabolizing genes SULT1A1 and ABAT, as well as the DNA damage response gene GADD34 in vitro, but not in vivo. If the collagen sandwich cultures of hepatocytes really produce false-positive data, this would compromise its application in toxicogenomics. To revisit the putative in vivo/in vitro discrepancy, we first analyzed and modeled methapyrilene concentrations in the portal vein of rats. The relatively short half-life of 2.8 h implies a rapid decrease in orally administered methapyrilene in vivo below concentrations that can cause gene expression alterations. This corresponded to the time-dependent alteration levels of GADD34, ABAT and SULT1A1 RNA in the liver: RNA levels are altered 1, 6 and 12 h after methapyrilene administration, but return to control levels after 24 and 72 h. In contrast, methapyrilene concentrations in the culture medium supernatant of primary rat hepatocyte cultures decreased slowly. This explains why GADD34, ABAT and SULT1A1 were still deregulated after 24 h exposure in vitro, but not in vivo. It should also be considered that the earliest analyzed time point in the previous in vivo studies was 24 h after methapyrilene administration. In conclusion, previously observed in vitro/in vivo discrepancy can be explained by different pharmacokinetics present in vitro and in vivo. When the in vivo half-life is short, levels of some initially altered genes may have returned to control levels already 24 h after administration.

Functional and toxicological consequences of metabolic bioactivation of methapyrilene via thiophene S-oxidation: Induction of cell defence, apoptosis and hepatic necrosis.

UNLABELLED: Methapyrilene, [N,N-dimethyl-N'-pyridyl-N'(2-thienylmethyl)-1,2-ethanediamine] (MP) was withdrawn from, clinical use due to reported periportal hepatic necrosis and hepatocarcinogenicity in the rat, via S-oxidation of the thiophene group. In this study MP is used as a model hepatotoxin to further characterise the functional consequences of S-oxidation of the thiophene group in vivo, in rat models and in vitro, in freshly isolated rat hepatocyte suspensions. In vivo histological studies revealed the early depletion of glutathione (GSH), which was confined to the damaged periportal area, in contrast to an increase in GSH levels in the centrilobular region. Additionally, the induction of cell defence was demonstrated by an increase in the protein levels of heme-oxygenase 1 (HO-1) and glutamate cysteine ligase, catalytic subunit (GCLC) in vivo. Histological examination demonstrated that cytotoxicity progresses initially via apoptosis before an increase in necrosis over the 3-day administration. An apoptotic-like mechanism was observed in vitro via the measurement of cytochrome c release and caspase activation. CONCLUSION: This study provides evidence for a complex pathway of MP-induced hepatotoxicity which progresses through early adaptation, apoptosis, necrosis and inflammation, all underpinned by the zonal induction and depletion of GSH within the liver.

Identification of the thiophene ring of methapyrilene as a novel bioactivation-dependent hepatic toxicophore.

Methapyrilene (MP), a 2-thiophene H(1)-receptor antagonist, is a model toxicant in the genomic and proteomic analyses of hepatotoxicity. In rats, it causes an unusual periportal necrosis that is hypothetically attributed to chemically reactive and cytotoxic metabolites. We have characterized the bioactivation of MP by hepatic microsomes and primary rat hepatocytes, and we established a possible causal linkage with cytotoxicity. Methapyrilene tritiated at C-2 of the diaminoethane moiety ([3H]MP) was metabolized via an NADPH-dependent pathway to intermediates that combined irreversibly with microsomes (rat > mouse approximately human). This binding was attenuated by the cytochrome P450 (P450) inhibitor 1-aminobenzotriazole and thiols but not by trapping agents for iminium ions and aldehydes. Reactive intermediates were trapped as thioether adducts of monooxygenated MP. Mass spectrometric and hydrogen/deuterium exchange analysis of the glutathione adduct produced by rat liver microsomes indicated that the metabolite was most probably a thioether of MP S-oxide substituted in the thiophene ring. The glutathione adduct was formed by rat hepatocytes and eliminated in bile by rats administered [3H]MP intravenously. MP produced concentration- and time-dependent cytotoxicity, depleted glutathione, and underwent irreversible binding to the hepatocytes before a significant increase in cell damage was observed. P450 inhibitors reduced turnover of the drug, production of the glutathione adduct, irreversible binding, and cytotoxicity but inhibited glutathione depletion selectively. MP underwent lesser turnover and bioactivation in mouse hepatocytes and was not cytotoxic. Analogs with phenyl and p-methoxyphenyl rings were much less hepatocytotoxic than MP. Hepatotoxicity in rats was diminished by predosing with 1-aminobenzotriazole. For the first time, a thiophene ring substituent is identified as a bioactivation-dependent toxicophore in hepatocytes.

Methapyrilene hepatotoxicity is associated with increased hepatic glutathione, the formation of glucuronide conjugates, and enterohepatic recirculation.

The mechanisms by which acute administration of methapyrilene, an H(1)-receptor antihistamine causes periportal necrosis to rats are unknown. This study investigated the role of the hepato-biliary system in methapyrilene hepatotoxicity following daily administration of 150 mg/kg per day over 3 consecutive days. Biliary metabolites of methapyrilene were tentatively identified. In male Han Wistar rats administration of methapyrilene significantly increased hepatic reduced glutathione (GSH) to 140% of control levels 24 h following the last dose. There were no significant changes in the activities of glutathione-related enzymes, glutathione peroxidase (GPx) and reductase (GSH), glutathione S-transferase (GST), and gamma-glutamyl cysteine synthetase (gamma-GCS) over 3 days of methapyrilene administration. Methapyrilene treatment resulted in no significant increase in excretion of biliary oxidized glutathione (GSSG), a sensitive marker of oxidative stress in vivo, following the third dose. [3H]Methapyrilene-derived radioactivity was detected in bile, to a greater extent than in feces, indicating that methapyrilene and/or metabolites underwent enterohepatic recirculation. Cannulation and exteriorization of the bile duct (to interrupt enterohepatic recirculation) afforded some protection against the hepatotoxicity, assessed by clinical chemistry and histopathology. Liquid chromatography-mass spectrometry (LC-MS) analysis of bile indicated the presence of unmetabolized methapyrilene, methapyrilene O-glucuronide and desmethyl methapyrilene O-glucuronide. These data demonstrate that acute methapyrilene hepatotoxicity in vivo is not a consequence of GSH depletion, or oxidative stress, but that enterohepatic recirculation of biliary metabolites may be important. Progressive exposure to non-oxidizing, reactive metabolic intermediates may be responsible for hepatotoxicity.

Metabolism of methapyrilene by Fischer-344 rat and B6C3F1 mouse hepatocytes.

1. Suspension cultures of freshly isolated F344 rat and B6C3F1 mouse hepatocytes were compared for their ability to transform various concentrations of methapyrilene (MP). 2. MP metabolites were isolated and purified by h.p.l.c., and were identified by comparing their chromatographic and mass spectral properties with those of authentic standards. 3. Both rat and mouse hepatocytes transformed MP to tentatively identified 2-thiophenecarboxylic acid (I), and definitively identified mono-N-desmethyl methapyrilene glucuronide (II), methapyrilene glucuronide (III), methapyrilene N-oxide (V), and mono-N-desmethyl methapyrilene (VII).

Modulation of rat hepatic cytochromes P450 by chronic methapyrilene treatment.

The antihistaminic compound methapyrilene (MP) when chronically administered has been shown to be a rat-specific hepatocarcinogen. To examine the effects of chronic MP treatment on the hepatic microsomal cytochromes P450. Fischer 344 rats were gavaged for 10 weeks (5 days on, 2 days off) with either vehicle or 50, 100, or 150 mg MP/kg body weight. Chronic MP treatment was found to have a significant effect on several microsomal enzymatic activities. Small (17-28%) but significant (P less than 0.05) decreases were observed for total P450 levels and the activities of erythromycin N-demethylase (catalyzed by P450IIIA), N-nitrosodimethylamine demethylase (catalyzed by P450IIE1) and pentoxyresorufin O-dealkylase (catalyzed by P450IIB1). In addition, a relatively large decrease (approximately 80%) was observed for the activity of benzphetamine N-demethylase (representative of P450IIC11) and an induction of about 40% was observed for ethoxyresorufin O-dealkylase (catalyzed by P450IA). The metabolism of testosterone by microsomes isolated from the rats chronically treated with MP indicated that several reactions were compromized. Specifically, testosterone 2 alpha-hydroxylase, indicative of P450IIC11, was reduced greatly (86%), whereas testosterone 6 beta-hydroxylase, reflecting P450IIIA, and testosterone 7 alpha-hydroxylase, indicative of P450IIIA1, were affected only slightly by MP treatment (approximately 25%). Immunoblot analyses of the various microsomal samples were performed to determine if chronic MP treatment had direct effects on the level of expression of the cytochromes P450. Decreases in the levels of P450IIIA, IIE1, and IIC11, determined by immunoblot analyses, closely paralleled those observed for their marker catalytic activities. Further studies will be required to determine the mechanism by which MP affects the levels of the cytochromes P450 (i.e. increased degradation or decreased synthesis).

Plasma elimination and urinary excretion of methapyrilene in the rat.

The metabolism and elimination of methapyrilene (2-[(2-dimethylaminoethyl)-2-thenylamino]pyridine) were characterized after the iv administration of 0.7 mg/kg or 3.5 mg/kg methapyrilene HCl plus [14C]methapyrilene HCl to adult male Fischer-344 rats. Approximately 40% and 35% of the administered dose was excreted in the urine in the first 24 hr in the low and high dose groups, respectively, as determined by liquid scintillation spectrophotometry. Fecal excretion accounted for 38% and 44% of the administered dose in the first 24 hr in the low and high dose groups, respectively, as confirmed via combustion analysis. The 24-hr urinary metabolic products consisted of one major and five minor radiolabeled compounds. The major metabolite was isolated with reversed-phase HPLC and identified as methapyrilene N-oxide. This was accomplished by comparison of the chromatographic and mass spectral characteristics of this metabolite with that of authentic methapyrilene N-oxide. Methapyrilene and mono-N-desmethyl methapyrilene also were identified after isolation with reversed-phase HPLC and comparison of their mass spectral and/or chromatographic properties with those of authentic compounds. The plasma metabolic profile was essentially the same as the urinary profile. The elimination of methapyrilene from plasma occurred through a first-order process. The terminal plasma elimination t1/2 of methapyrilene did not increase with increasing doses (2.75 hr, 0.7 mg/kg; 2.81 hr, 3.5 mg/kg); thus, methapyrilene does not exhibit dose-dependent elimination over this 5-fold dose range.

The in vivo metabolism of methapyrilene, a hepatocarcinogen, in the rat.

1. The metabolism of methapyrilene (I), was examined in vivo by g.l.c. and g.l.c.-mass spectrometric analysis of rat urinary extracts. 2. Dosing the animals with tetradeuterium-labelled I helped identify 7 different metabolites of I in the urine, including (5-hydroxylpyridyl)-methapyrilene, which was identified by comparison with a synthetic reference standard. 3. After 4 weeks of treatment with I, rats also excrete detectable amounts of the 3- and (6-hydroxylpyridyl)-methapyrilene metabolites suggesting that pretreatment with I alters the metabolism of the pyridine ring. 4. Metabolic removal of the 2-thienylmethylene moiety is also facile, as large amounts of N'-(2-pyridyl)-N,N-dimethylethylenediamine and its metabolite N'-[2(5-hydroxylpyridyl)]-N,N-dimethylethylenediamine are excreted under all dosing regimens. 5. Urinary concn of both I and metabolites decline with time, despite continuous dosing, indicating a change in absorption, metabolism, and/or excretion of I on repeated dosing.