Metabolic, idiosyncratic toxicity of drugs: overview of the hepatic toxicity induced by the anxiolytic, panadiplon.

Preclinical drug safety evaluation studies, typically conducted in two or more animal species, reveal and define dose-dependent toxicities and undesirable effects related to pharmacological mechanism of action. Idiosyncratic toxic responses are often not detected during this phase in development due to their relative rarity in incidence and differences in species sensitivity. This paper reviews and discusses the metabolic idiosyncratic toxicity and species differences observed for the experimental non-benzodiazepine anxiolytic, panadiplon. This compound produced evidence of hepatic toxicity in Phase 1 clinical trial volunteers that was not predicted by rat, dog or monkey preclinical studies. However, subsequent studies in Dutch-belted rabbits revealed a hepatic toxic syndrome consistent with a Reye's Syndrome-like idiosyncratic response. Investigations into the mechanism of toxicity using rabbits and cultured hepatocytes from several species, including human, provided a sketch of the complex pathway required to produce hepatic injury. This pathway includes drug metabolism to a carboxylic acid metabolite (cyclopropane carboxylic acid), inhibition of mitochondrial fatty acid beta-oxidation, and effects on intermediary metabolism including depletion of glycogen and disruption of glucose homeostasis. We also provide evidence suggesting that the carboxylic acid metabolite decreases the availability of liver CoA and carnitine secondary to the formation of unusual acyl derivatives. Hepatic toxicity could be ameliorated by administration of carnitine, and to a lesser extent by pantothenate. These hepatocellular pathway defects, though not directly resulting in cell death, rendered hepatocytes sensitive to secondary stress, which subsequently produced apoptosis and hepatocellular necrosis. Not all rabbits showed evidence of hepatic toxicity, suggesting that individual or species differences in any step along this pathway may account for idiosyncratic responses. These differences may be roughly applied to other metabolic idiosyncratic hepatotoxic responses and include variations in drug metabolism, effects on mitochondrial function, nutritional status, and health or underlying disease.

Disruption of mitochondrial activities in rabbit and human hepatocytes by a quinoxalinone anxiolytic and its carboxylic acid metabolite.

The quinoxalinone anxiolytic, panadiplon, was dropped from clinical development due to unexpected hepatic toxicity in human volunteers. Subsequent experimental studies in rabbits demonstrated a hepatic toxicity that resembled Reye's syndrome. In the present studies, we examined the effects of panadiplon and a metabolite, cyclopropane carboxylic acid (CPCA) on hepatic mitochondrial activities in vitro and ex vivo. Acute inhibition of beta-oidation of [14C]palmitate was observed in rabbit and human hepatocyte suspensions incubated with 100 microM panadiplon. Panadiplon (30 microM) also reduced mitochondrial uptake of rhodamine 123 (R123) in cultured rabbit and human, but not rat hepatocytes, following 18 h exposure. CPCA also impaired beta-oxidation and R123 uptake in rabbit and human hepatocytes. R123 uptake and beta-oxidation in cells from some donors was not impaired by either agent, and cell death was not observed in any experiment. Hepatocytes isolated from panadiplon-treated rabbits had reduced palmitate beta-oxidation rates and inhibited mitochondrial R123 uptake; R123 uptake remained inhibited until 48-72 h in culture. Rabbit mitochondrial respiration experiments revealed a slightly lower ratio of ATP formed/oxygen consumed in panadiplon-treated animals: direct exposure of normal rabbit liver mitochondria to panadiplon did not have this effect. Hepatocytes isolated from panadiplon-treated rabbits showed reduced respiratory control ratios and lower oxygen consumption compared to controls. Our results indicate that panadiplon induces a mitochondrial dysfunction in the liver, and suggest that this dysfunction may be attributed to the carboxylic acid metabolite.

Potentiation of hypoxic injury in cultured rabbit hepatocytes by the quinoxalinone anxiolytic, panadiplon.

The quinoxalinone anxiolytic, panadiplon, produces hepatic metabolic inhibition (mitochondrial impairment), microvesicular steatosis and centrilobular necrosis in rabbits. Metabolic inhibition occurs in cultured hepatocytes without cytotoxicity, suggesting that hepatic injury is influenced by additional factors. The present experiments were conducted to determine if metabolic inhibition by panadiplon predisposed hepatocytes to hypoxic injury. Injury (cell death) was evaluated by lactate dehydrogenase (LDH) release from cells; ATP and glycogen levels were also evaluated. Under hypoxic conditions, control cultures showed a 6.5-fold increase in LDH release compared to normoxic controls, with a coincident 80% decrease in ATP and 50% decrease in glycogen levels. Under normoxic conditions 10 microgram/ml panadiplon treatment for 48 h reduced ATP and glycogen levels by 40% but did not cause an increase in LDH leakage. Cells treated with panadiplon, then exposed to hypoxia conditions, showed a significant level of injury compared to normoxic control cultures, and a further reduction in ATP. No additional decrease in glycogen ws observed. In an attempt to prevent panadiplon-mediated injury, glycolytic substrates (dihydroxyacetone or pyruvate) were included during normoxic and hypoxic incubations. Both cotreatments reduced the level of LDH leakage produced by panadiplon during hypoxia. Cotreatment did not generally increase ATP or glycogen levels (compared to panadiplon treatment groups) during hypoxia, though individual experiments showed a slight increase in ATP levels. During normoxia both cotreatments with panadiplon resulted in significantly higher glycogen levels than in panadiplon cultures alone. These results suggest that cellular glycogen and subsequently ATP levels are reduced during panadiplon exposure, metabolically predisposing hepatocytes to hypoxic injury.

Cultured hepatocytes as investigational models for hepatic toxicity: practical applications in drug discovery and development.

Drugs can fail at any phase during discovery, preclinical or clinical development due to unacceptable levels of toxicity, and liver is commonly the principle target organ. Investigational toxicology methods, using appropriate models and hypotheses, can often resolve problems, identify toxic chemical substituents and salvage therapeutic discovery programs. While in vivo models are used to investigate hepatic drug effects in the context of toxicokinetics and systemic influences, cell culture models provide in vitro systems for investigating specific mechanisms in a precisely controlled environment. Using primary hepatocytes isolated from laboratory animals, we have explored several drug-induced hepatic disorders that surfaced during different phases of drug discovery and development. Additionally, the use of human hepatocytes has allowed us to address concerns for human exposure, examine human relevance of animal data, and provide perspective on problems encountered in clinical trials.

Inactivation of Serpulina hyodysenteriae flaA1 and flaB1 periplasmic flagellar genes by electroporation-mediated allelic exchange.

Serpulina hyodysenteriae, the etiologic agent of swine dysentery, contains complex periplasmic flagella which are composed of multiple class A and class B polypeptides. To examine the role these proteins play in flagellar synthesis, structure, and function and to develop strains which may provide insight into the importance of motility in the etiology of this pathogen, we constructed specific periplasmic flagellar mutations in S. hyodysenteriae B204. The cloned flaA1 and flaB1 genes were disrupted by replacement of internal fragments with chloramphenicol and/or kanamycin gene cassettes. Following delivery of these suicide plasmids into S. hyodysenteriae, homologous recombination and allelic exchange at the targeted chromosomal flaA1 and flaB1 genes was verified by PCR, sequence, and Southern analysis. The utility of a chloramphenicol resistance gene cassette for targeted gene disruption was demonstrated and found more amenable than kanamycin as a selective marker in S. hyodysenteriae. Immunoblots of cell lysates of the flagellar mutants with antiserum raised against purified FlaA or FlaB confirmed the absence of the corresponding sheath or core protein. Both mutations selectively abolished expression of the targeted gene without affecting synthesis of the other flagellar polypeptide. flaA1 and flaB1 mutant strains exhibited altered motility in vitro and were less efficient in movement through a liquid medium. Paradoxically, isogenic strains containing specifically disrupted flaA1 or flaB1 alleles were capable of assembling periplasmic flagella that were morphologically normal as evidenced by electron microscopy. This is the first report of specific inactivation of a motility-associated gene in spirochetes.

Induction of a hepatic toxic syndrome in the Dutch-belted rabbit by a quinoxalinone anxiolytic.

The non-benzodiazepine anxiolytic, panadiplon, was discontinued from clinical development due to evidence of hepatic toxicity in human volunteers that was not predicted by rat or monkey preclinical development studies. The present study was conducted to examine potential toxicity in the rabbit. Three groups of female rabbits were administered vehicle, 10 mg/kg per day or 20 mg/kg per day of panadiplon by oral gavage for 14 days. Animals in the 20 mg/kg group lost weight, and 6/10 developed a profound lethargy. Hepatic toxicity was observed in treated animals, evidenced by dose- and time-related increases in serum transaminase activities, gross hepatic lesions and multifocal centrilobular necrosis. Hepatic microvesicular steatosis was evident in treated animals; lipid analysis revealed a 123% increase in hepatic triglyceride. A time-dependent increase in serum triglyceride levels was observed in the high-dose group beginning on day 4. Hepatic glycogen was reduced, and histochemical examination revealed the reduction to be heterogeneous across the lobule with some areas showing a complete absence of glycogen. One rabbit in each drug-treated group showed mild hypoglycemia at day 12, and 4/10 rabbits in the high-dose group showed hyperglycemia at days 12-14. We conclude that panadiplon produced a microvesicular steatosis and hepatic toxicity in the rabbit. The observed toxicity resembled a Reye's syndrome-like toxicity produced by a variety of mitochondrial fatty acid oxidation inhibitors.

Hepatic changes produced by 30-day administration of a novel aminocyclitol antibiotic, trospectomycin sulfate, to laboratory animals.

The studies described here were done to characterize the hepatic response to a new aminocyclitol antibiotic, trospectomycin sulfate, administered intravenously (beagle dog) or subcutaneously (Sprague-Dawley rat) at a variety of dose levels, to investigate reversibility of observed changes, and to document any untoward effects of subchronic trospectomycin sulfate administration. Both species showed significant elevations in serum levels of alanine and aspartate transaminases in higher dose groups. In the dog only, a transient neuromuscular blockade was also observed within higher dose groups. No other functional, morphological, or serum chemical changes were observed. Examination of liver by electron microscopy revealed the presence of cytoplasmic lamellar inclusion bodies, concentrated in the bile canalicular region of the hepatocytes. Occurrence of the lamellar bodies and coincident transaminase increases were found to be reversible upon discontinuance of treatment (studied in the dog). Electron microscopy of acid phosphatase cytochemistry in the rat indicated that most, but not all, of the lamellar bodies contained this enzyme. This observation suggests that they may be derived from the lysosome, or once formed become lysosomal.