Marc B. Bailie

1-Naphthylisothiocyanate-induced elevation of biliary glutathione

1-Naphthylisothiocyanate (ANIT) has been used for many years to study cholangiolitic hepatotoxicity in laboratory animals. Hallmarks of ANIT hepatotoxicity include portal edema and inflammation with bile duct epithelial and hepatic parenchymal cell necrosis. In rats, ANIT hepatotoxicity is dependent upon hepatic glutathione. Studies in vitro have demonstrated that ANIT combines reversibly with glutathione and suggest that intracellular formation and secretion of this glutathione-ANIT conjugate from hepatic parenchymal cells may be responsible for the efflux of glutathione observed upon exposure to ANIT. In vivo, glutathione conjugates produced within hepatic parenchymal cells are typically transported into bile for elimination. Therefore, large concentrations of ANIT in bile may result from hepatic parenchymal cell secretion of a reversible glutathione-ANIT conjugate. To investigate this hypothesis, bile and plasma concentrations of ANIT were determined in rats 1, 4, 8, 12 and 24 hr after administration (100 mg/kg, p.o.). Liver and bile glutathione concentrations were also evaluated. Plasma ANIT concentrations ranged between 2 and 5 microM at 1, 4, 8 and 12 hr and were 0.9 microM at 24 hr after administration. ANIT concentrations in bile at 1, 4, 8 and 12 hr were 60, 28, 21 and 22 microM, respectively. Thus, ANIT was concentrated in bile. Hepatic glutathione was not affected by ANIT during the first 12 hr after administration; however, a moderate elevation occurred by 24 hr. In contrast, a marked elevation in bile glutathione concentration (two times control) occurred 1, 4 and 8 hr after ANIT administration. Thus, the early accumulation of ANIT in bile was coincident with an elevation in bile glutathione. These findings support the hypothesis that glutathione functions to concentrate ANIT in bile. The large concentration of this toxicant in bile may be injurious to bile epithelium, a primary cellular target in ANIT hepatotoxicity.

Acetaminophen nephrotoxicity in the rat. Renal metabolic activation in vitro

High doses of acetaminophen (APAP) result in hepatic centrilobular and renal cortical necrosis in man and the F344 rat. Hepatic necrosis is considered to be due to the generation of an arylating intermediate via a microsomal cytochrome P-450 dependent system. Renal microsomes also metabolize APAP to an arylating intermediate via a P-450 dependent mechanism. Thus, at least part of the renal damage from APAP may be due to a biochemical mechanism similar to that in liver. Additionally, APAP is deacetylated to p-aminophenol (PAP) in renal and hepatic cytosol and microsomes. Previous results demonstrated that PAP may be activated in renal microsomes via an NADPH-independent mechanism. Therefore, significant metabolic activation of APAP in the kidney may occur subsequent to deacetylation. Covalent binding of [ring-14C]APAP to renal subcellular fractions was used to substantiate this hypothesis. Under appropriate incubation conditions, enzymatic NADPH-independent covalent binding of [ring-14C]APAP could be demonstrated in renal microsomes but not in 100,000g supernatant fractions. Combination of these subcellular fractions resulted in greater covalent binding of [ring-14C]APAP than in the individual subcellular fractions alone. Addition of glutathione, bis(p-nitrophenyl)phosphate (a deacetylase inhibitor), or PAP inhibited this covalent binding. In contrast, NADPH-independent covalent binding of [ring-14C]APAP could not be demonstrated in any combination of hepatic subcellular fractions. Experiments comparing [ring-14C]APAP and [acetyl-14C]APAP covalent binding to renal 10,000g supernatant fractions indicate that the compound which binds to renal macromolecules is derived from PAP. Thus, these results are consistent with the hypothesis that APAP can be metabolically activated in the kidney after deacetylation to PAP.

Mechanism of chloroform nephrotoxicity: IV. Phenobarbital potentiation of in vitro chloroform metabolism and toxicity in rabbit kidneys

Metabolism of chloroform (CHCl3) by a cytochrome P-450-dependent process to a reactive metabolite may be required to elicit hepatic and renal toxicities. Specific inducers or inhibitors of cytochrome P-450 have been employed frequently as tools to demonstrate this relationship between metabolism and toxicity in the liver. The experiments reported herein were designed to identify the relationship between metabolism and toxicity of CHCl3 in the kidney of rabbits, a species in which renal cytochrome P-450 is induced by phenobarbital. Pretreatment with phenobarbital enhanced the toxic response of renal cortical slices to CHCl3 in vitro as indicated by decreased p-aminohippurate and tetraethylammonium accumulation. Phenobarbital pretreatment also potentiated in vitro 14CHCl3 metabolism to 14CO2 and covalently bound radioactivity in rabbit renal cortical slices and microsomes. Addition of L-cysteine significantly reduced covalent binding in renal microsomes from both phenobarbital-treated and control rabbits and was associated with the formation of the radioactive phosgene-cysteine conjugate 2-oxothiazolidine-4-carboxylic acid (OTZ). Formation of OTZ was enhanced in renal microsomes from phenobarbital-pretreated rabbits. Thus, this in vitro model supports the hypothesis that the kidney metabolizes CHCl3 to the nephrotoxic metabolite, phosgene.

Relationship between α-naphthylisothiocyanate-induced liver injury and elevations in hepatic non-protein sulfhydryl content

Acute administration of alpha-naphthylisothiocyanate (ANIT) to rats has been used as a model of intrahepatic cholestasis. The mechanism of toxicity of ANIT is unknown, although recent evidence suggests a causal or permissive role for glutathione (GSH) (Dahm LJ and Roth RA, Biochem Pharmacol 42: 1181-1188, 1991). In these studies, ANIT treatment elevated hepatic non-protein sulfhydryl (NPSH) content, an indicator of GSH content, when liver injury was evident. The purpose of the present study was to characterize the effects of ANIT on hepatic NPSH content and to relate these changes to the development of liver injury. In rats fasted for 24 hr, administration of ANIT (100 mg/kg, per os [p.o.]) did not change hepatic NPSH content, bile flow, or serum measurements of total bilirubin concentration, alanine aminotransferase (ALT) activity, or gamma-glutamyltransferase (GGT) activity by 12 hr post-treatment relative to corn oil vehicle controls. However, by 24 hr after ANIT treatment, rats exhibited cholestasis and elevations in serum markers of liver injury. These markers were associated temporally with an increase in hepatic NPSH content, which consisted entirely of GSH. To determine whether the cholestasis caused by ANIT treatment might have caused the elevation of hepatic NPSH content, an extrahepatic cholestasis in rats was produced by ligation of the common bile duct. Bile duct ligation elevated hepatic NPSH content between 6 and 12 hr after ligation. Administration to rats of a non-hepatotoxic analog of ANIT, beta-naphthylisothiocyanate, also elevated hepatic NPSH content 24 hr after treatment. Taken together, these results indicate that the elevation in hepatic NPSH content after ANIT treatment is associated temporally with the onset of liver injury, but this elevation does not appear to participate causally in the mechanism of injury.

Influence of surgically implantable telemetry solutions on in-life and post-mortem toxicology endpoints.

INTRODUCTION Understanding the appropriate application of telemetry and other technologies for nonclinical investigation of functional safety issues in the context of ongoing toxicology evaluations is a current industry challenge. One major issue is related to the potential impact of surgical implantation of a telemetry device on contemporarily established measures of drug toxicity, and potential for confounding pathological issues related to the systemic and local response of the experimental animal to the presence of a foreign body. This study was designed to evaluate the potential local and systemic impact of different implanted telemetry devices with varying requisite degrees of surgical complexity on general toxicology study endpoints. METHODS Sixteen male beagle dogs 1) no surgical instrumentation [n=4], 2) Jacketed External Telemetry (JET) with femoral artery blood pressure implant (PA-C10 LA) [n=4], or 3) fully implantable (DSI-D70-CCTP) devices [n=8], were assigned to experimental groups and evaluated within the context of a standard repeat-dose toxicology design to determine the potential impact of these treatments on routine in-life and post-mortem toxicological endpoints. RESULTS Device implantation, regardless of the level of invasiveness/complexity was without effect on any in-life safety parameter, including clinical chemistry and hematology, assessed in the experimental design. Histopathological findings were limited to the expected, primarily minimal to mild localized effects characteristic of a foreign body reaction (fibrosis, inflammation) in the area immediately in contact with the body of the transmitter device and associated sites of ECG lead and pressure catheter interface with local tissues. DISCUSSION This study represents the first definitive evaluation of the influence of variably invasive telemetry device implantation on standardized, essential toxicology endpoints in the context of a simulated repeated dose experimental design. The data suggest that, when carefully evaluated, the local effects of implanted telemetry devices can be managed in the context of a standard Investigational New Drug (IND)-enabling toxicology study. This study provides support for the potential incorporation of unrestrained cardiovascular assessments via implanted or external telemetry into standard multi-dose toxicology studies.

Leukotrienes and α-naphthylisothiocyanate-induced liver injury

alpha-naphthylisothiocyanate (ANIT) administration to rats results in periportal hepatic inflammation and injury. Glutathione (GSH) appears to be necessary for the liver injury to occur. The leukotrienes (LTs) are metabolites of arachidonic acid and potent mediators of inflammation that have been implicated in certain liver injury models. Inasmuch as GSH is a cofactor for the synthesis of cysteinyl-LTs and since inflammation is a prominent component of ANIT injury, we hypothesized that LTs are involved in producing the hepatic insult that results from ANIT administration. To test this hypothesis, rats were treated with one of several inhibitors of LT biosynthesis, A63162, Zileuton or MK-886. Each of these agents prevented the formation of LTB4 in Ca++ ionophore-stimulated whole blood from rats treated with the inhibitors. A63162 attenuated the hepatic parenchymal injury caused by ANIT and resulted in a modest decrease in ANIT-induced cholestasis. In contrast, neither Zileuton nor MK-886 attenuated liver injury. AT-125 (Acivicin) inhibits gamma-glutamyl transferase (GGT), the enzyme that catalyzes the formation of LTD4 from LTC4. AT-125 pretreatment did not prevent ANIT-induced hepatic parenchymal insult. It did, however, ameliorate the cholestasis caused by ANIT. In conclusion, the partial protection afforded by A63162 and AT-125 likely results from effects unrelated to the formation of LTs, since Zileuton and MK-886 inhibited LT synthesis without affording protection. The lack of protection by Zileuton and MK-886 in the face of LT synthesis inhibition suggests that LTs are not necessary for the expression of injury after ANIT administration.

Neither platelet activating factor nor leukotrienes are critical mediators of liver injury after lipopolysaccharide administration

The intravenous administration of lipopolysaccharide (LPS) to rats results in liver lesions characterized by the infiltration of both platelets and neutrophils into the liver and by midzonal hepatocellular necrosis. The liver injury is dependent on neutrophils, platelets and the coagulation system, as removal or inhibition of any of these components inhibits the development of hepatocellular necrosis. Platelet activating factor (PAF) and the cysteinyl leukotrienes (LTs) are potent inflammatory lipids that are critical for the development of some LPS-mediated alterations. To test the hypothesis that PAF, alone or in combination with LTs, contributes to the development of liver injury during LPS exposure, we conducted studies with the PAF receptor antagonist, WEB 2086, and the 5-lipoxygenase inhibitor, Zileuton. Female, Sprague-Dawley rats were pretreated with WEB 2086 (10 mg/kg, i.p.) alone or with Zileuton (40 mg/kg, p.o.) 1 h before the administration of LPS (4 mg/kg, i.v.) or its saline vehicle. Treatment with WEB 2086, alone or in combination with Zileuton, did not inhibit LPS-mediated hepatic neutrophil infiltration or liver injury, as assessed by histologic evaluation and increases in plasma alanine aminotransferase activity. Pretreatment with these agents also had no effect on the activation of the coagulation system or on the thrombocytopenia induced by LPS. These results suggest that PAF, alone or in combination with 5-lipoxygenase products, is not a critical mediator of LPS-induced hepatocellular injury in this model.

Platelet activating factor receptor blockade alone or in combination with leukotriene synthesis inhibition does not ameliorate α-naphthylisothiocyanate-induced hepatotoxicity

Alpha-naphthylisothiocyanate (ANIT) is a cholangiolitic hepatotoxicant that causes periportal edema, hepatic parenchymal and biliary epithelial cell necrosis, and cholestasis in the rat. A hallmark of ANIT hepatotoxicity is periportal inflammation that includes neutrophil infiltration. Neutrophils are requisite for the expression of ANIT-induced liver injury; however, the mechanism(s) of neutrophil accumulation in the liver and the role of these cells in ANIT hepatotoxicity is incompletely understood. Platelet activating factor (PAF) is a proinflammatory agent that is both a chemoattractant for and an activator of neutrophils. Therefore, we evaluated the role of PAF in ANIT-induced liver injury. Rats were treated with the PAF receptor antagonist, WEB 2086 (WEB), to determine if it afforded protection from ANIT hepatotoxicity. In a separate study, a combination of WEB and the leukotriene synthesis inhibitor, Zileuton (ZIL), was used to address the possible interaction of PAF and leukotrienes in ANIT-induced liver injury. Treatment of rats with WEB, alone or in combination with Zileuton, did not attenuate ANIT-induced liver injury as assessed by increases in plasma alanine aminotransferase or gamma-glutamyl transferase activities. In addition, neither treatment ameliorated ANIT-induced cholestasis assessed as increased plasma bilirubin concentration. These results suggest that PAF, alone or in combination with products of 5-lipoxygenase, does not contribute to ANIT-induced liver injury.

NERVE GROWTH FACTOR BINDING SITES ON HEPATIC PARENCHYMAL CELLS

SummaryNerve growth factor (NGF) binding sites on rat hepatocytes (HCs) in culture for 24 to 48 h were characterized using125I-NGF. Specific binding of125I-NGF to HCs was saturable. Scatchard analysis indicated a single population of binding sites with a Kd of 5.5 nM and a Bmax of 540 fmol/mg protein. In isolated hepatocyte membranes, specific binding of125I-NGF was also apparent with Kd and Bmax values of 10.8 nM and 3740 fmol/mg protein, respectively. Specific binding of125I-NGF to HCs was displaced by excess, unlabeled NGF but not by up to 1000-fold excess of either insulin or epidermal growth factor. Internalization/sequestration of125I-NGF into HCs was measured as radioactivity present in solubilized cells after exposure to high salt and acid. These studies indicated 83±11% of125I-NGF was accumulated by internalization/sequestration at a concentration of 1 nM125I-NGF. Internalization was reduced to 43±4% when incubations were carried out at 4° C. These results indicate the presence of a specific, low-affinity binding site for NGF on hepatocytes in culture.

Pharmacokinetics and relative bioavailability of D-penicillamine in fasted and nonfasted dogs.

BACKGROUND D-Penicillamine is the most commonly used copper-chelating agent in the treatment of copper-associated hepatitis in dogs. Response to therapy can be variable, and there is a lack of pharmacokinetic information available for dogs. Coadministering the drug with food to alleviate vomiting has been recommended for dogs, which contradicts recommendations for drug administration to humans. HYPOTHESIS Coadministration of d-penicillamine with food decreases relative bioavailability and maximum plasma drug concentrations (C(max)) in dogs. ANIMALS Nine purpose-bred dogs with a median body weight of 17.0 kg. METHODS Dogs received D-penicillamine (12.5 mg/kg PO) fasted and with food in a randomized, crossover design. Blood samples were collected before and 0.25, 0.5, 1, 2, 3, 4, 8, 12, and 24 hours after dosing. Total d-penicillamine concentrations were measured using liquid chromatography coupled with tandem quadrupole mass spectrometry. Pharmacokinetic parameters were calculated for each dog. RESULTS Two fasted dogs (22%) vomited after receiving d-penicillamine. Mean C(max) ± standard deviation (SD) was 8.7 ± 3.1 μg/mL (fasted) and 1.9 ± 1.6 μg/mL (fed). Mean area under the plasma concentration curve ± SD was 16.9 ± 5.9 μg/mL·h (fasted) and 4.9 ± 3.4 μg/mL·h (fed). There were significant reductions in relative bioavailability and C(max) in fed dogs (P < .001). CONCLUSIONS AND CLINICAL IMPORTANCE Coadministration of d-penicillamine with food significantly decreases plasma drug concentrations in dogs. Decreased drug exposure could result in decreased copper chelation efficacy, prolonged therapy, additional cost, and greater disease morbidity. Administration of d-penicillamine with food cannot be categorically recommended without additional studies.