* Department of Pathology, University of Texas Medical Branch, Galveston, Texas 77555-0609 and
Department of Pharmacology, Louisiana State University Health Science CenterShreveport, Shreveport, Louisiana 71130-3932
Received March 4, 2003; accepted April 17, 2003
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ABSTRACT |
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Key Words: methylenedianiline; glutathione depletion; bromoheptane; buthionine sulfoximine; GSH/GSSG; CoASH/CoASSG; oncosis; apoptosis.
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INTRODUCTION |
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Our previous studies demonstrated that acute administration of DAPM to rats produces striking changes in several biliary constituents, followed by necrosis and sloughing of biliary epithelial cells (BEC), cholestasis, and cholangitis (Kanz et al., 1992). Effects on the biliary system occur prior to hepatocellular injury, as evidenced by minimal increases in serum indicators of hepatic injury. Furthermore, alterations in biliary constituents are preceded by ultrastructural changes in BEC mitochondria and loss of lumenal microvilli, while morphologic effects on tight junctions between BEC or between hepatocytes are absent (Kanz et al., 1998
). The identity of the DAPM metabolite(s) responsible for injury to BEC is unknown. However, bile transfer experiments indicate that the proximate toxicant is excreted into bile (Kanz et al., 1995
).
Biliary excretion of xenobiotics is typically a major elimination pathway, particularly for substrates conjugated with glucuronic acid and glutathione (GSH) (Vore, 1993). Although conjugation reactions are generally considered detoxification mechanisms, in some instances, conjugation results in the formation of highly reactive intermediates that produce significant toxicity (see review by Anders and Dekant, 1998
). For example, GSH conjugation and biliary excretion have been proposed as the route by which the model bile duct toxicant
-naphthylisothiocyanate (ANIT) concentrates in bile and produces BEC injury (Jean and Roth, 1995
). When liver GSH is depleted prior to ANIT treatment, biliary concentrations of ANIT and concomitantly, ANIT hepatotoxicity, are diminished (Dahm and Roth, 1991
; Jean and Roth, 1995
). Because DAPM treatment leads to cholangitis and cholestasis comparable with that produced by ANIT (Kanz et al., 1992
), and because the proximate toxicant of DAPM is excreted into bile (Kanz et al., 1995
), modulation of DAPM injury by total glutathione (GSx) depletion seemed plausible. Thus, our aim was to investigate the effect of hepatic GSx depletion on the time course and degree of DAPM injury to BEC using a dosage (50 mg/kg) that produces moderate to marked BEC damage with minimal hepatocyte injury. The effect of GSx depletion on DAPM injury was assessed using endpoints for hepatotoxicity (serum parameters, histopathology, histochemistry), thiol/disulfide status (GSx/glutathione disulfide [GSSG], coenzyme A [CoASH]/coenzyme A-glutathione disulfide [CoASSG] ratios), lipid peroxidation (thiobarbituric acid-reactive substances [TBARS]), and conjugation capacity (phase II enzyme activities).
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MATERIALS AND METHODS |
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Chemicals.
4,4'-Diaminodiphenylmethane (DAPM, 99% purity) and 1-bromoheptane (BH, 99% purity) were purchased from Aldrich Chemical Co. (Milwaukee, WI). Buthionine-[S,R]-sulfoximine (BSO), 1-chloro-2,4-dinitrobenzene (CDNB), CoASH (reduced form), CoASSG, N-ethylmaleimide (NEM), 5,5'-dithio-bis-2-nitrobenzoic acid (DTNB), 3-hydroxysteroid dehydrogenase, GSH (reduced form), GSSG, glutathione reductase, glycine, hydrazine sulfate, ß-nicotinamide adenine dinucleotide (ß-NAD), ß-nicotinamide adenine dinucleotide phosphate (reduced form, ß-NADPH), tetrabutylammonium hydrogen sulfate (TBAH), 1,1,3,3-tetraethoxypropane, and taurocholate were obtained from Sigma Chemical Co. (St. Louis, MO).
Experimental protocol.
DAPM was dissolved in absolute ethanol, then diluted to 25 mg/ml in 35% ethanol using 40°C deionized water. The solution was kept warm until given by gavage at 2 ml/kg. Rats received a total ethanol dose of 0.56 g/kg, which was not expected to elicit major alterations in hepatic redox status because the reported threshold ethanol dose to induce GSH depletion is 3 g/kg (Videla et al., 1980
). 1-Bromoheptane (0.5 mmol/ml in corn oil) and buthionine sulfoximine (0.555 mmol/ml in phosphate-buffered saline [PBS]) were administered by gavage at 2 ml/kg and ip at 4.5 ml/kg, respectively. Experiments began at 9:00 A.M. when rats (four per group) were pretreated with BH or corn oil, followed by pretreatment with BSO or PBS at 10:00 A.M. Treatment of rats with 50 mg DAPM/kg or 35% ethanol (vehicle) occurred 30 min later (at 10:30 A.M.). Rats were sacrificed at 0, 3, or 6 h after DAPM treatment.
Rats were anesthetized with ether and opened along the ventral midline. Blood was collected from the inferior vena cava; blood samples were allowed to clot on ice, centrifuged, and the sera stored at 20°C. Livers were rapidly removed, blotted, weighed, and chopped into pieces. Small pieces were immediately freeze-clamped using liquid nitrogen-cooled tongs and stored in liquid nitrogen until assayed for CoASH and CoASSG. Pieces of liver were washed with PBS, minced, and homogenized (1:5, wt/vol) in 5% sulfosalicylic acid. After centrifugation, supernatants were aliquoted undiluted or mixed 1:1 (vol/vol) with 10 mM NEM and stored at 80°C until total GSx and GSSG, respectively, were measured. Additional pieces of liver were rapidly homogenized in 250 mM phosphate-buffered sucrose (pH 7.4), then centrifuged at 9000 g, and the supernatants (S-9 fractions) were stored at 80°C until assayed. Finally, liver slices from two major lobes were collected and fixed in 10% buffered formalin for histological assessment.
Hepatotoxicity.
Serum alanine aminotransferase (ALT), alkaline phosphatase (ALP), bilirubin, and -glutamyltransferase (GGT) were determined using Sigma reagent kits 57, 20, 550, and 419, respectively. Serum bile salts were determined enzymatically according to the method of Koss et al. (1974)
using 3
-hydroxysteroid dehydrogenase with taurocholate as a standard.
Hepatic enzyme activities.
Glutathione S-transferase (GST) activity toward CDNB in liver S-9 fractions was assayed by monitoring the change in optical density at 340 nm, which represents the rate of formation of a conjugate between CDNB and GSH (Habig et al., 1974). Uridine diphosphate (UDP)-glucuronosyltransferase activity in S-9 fractions was determined using p-nitrophenol by the method of Mulder and Van Doorn (1975)
. Protein in S-9 fractions was measured by the bicinchoninic acid method (Smith et al., 1985
).
Liver TBARS.
Liver aliquots were homogenized in 10 mM phosphate-buffered (pH 7) saline (1:10, wt:vol) containing 50 µM butylated hydroxytoluene as an antioxidant (Esterbauer and Cheeseman, 1990; Pikul et al., 1983
) and centrifuged. Supernatant aliquots were mixed with 10% trichloroacetic acid, incubated at 75°C for 2 min, mixed with 0.67% thiobarbituric acid, then incubated for another 10 min. After centrifugation of the samples, optical densities of supernatants were measured at 532 nm (Zhang et al., 1997
). Concentrations of TBARS were calculated using a standard curve generated with 1,1,3,3-tetraethoxypropane.
Liver GSx and GSSG.
GSx and GSSG were assayed by the enzymatic recycling method of Tietze (1969) using glutathione reductase, DTNB, and NADPH. GSx was measured at 405 nm in 96 well plates (BIO-RAD Microplate Reader, Bio-Rad Laboratories, Hercules, CA) according to Baker et al.(1990)
. GSH standards were prepared in the same buffer, and acid solutions as samples and were assayed at the same time. GSSG was determined in samples after conjugation of GSH with NEM and removal of excess NEM by C18 SepPak (Waters, Milford, MA) chromatography. GSSG standards and samples were assayed at 412 nm in a Beckman DU-8 spectrophotometer (Beckman Coulter, Inc., Fullerton, CA).
Liver CoASH and CoASSG.
CoASH and CoASSG in liver homogenates were determined by the method developed by Rogers et al. (2000), which utilizes conjugation of CoASH to NEM, followed by separation and quantitation using high-performance liquid chromatography (HPLC). Freeze-clamped liver aliquots (0.2 g) were powdered using a mortar and pestle filled with liquid nitrogen and immediately transferred into a chilled Dounce homogenizer containing 0.8 ml of 0.1-M phosphate buffer (pH 7.4) and 25 mM NEM. Aliquots of the homogenate were then added to 3.8% perchloric acid (1:1, vol:vol). Standards were prepared in the same buffer and acid solutions as samples and were assayed at the same time. Stock solutions of standards, prepared in 0.1-M phosphate buffer (pH 3.0), were diluted in 0.1-M phosphate buffer (pH 7.4) containing 40 µM NEM immediately before analysis. Final concentrations of the standards were 040 µM CoASH (now present as CoAS-NEM) and 05 µM CoASSG.
CoAS-NEM and CoASSG were analyzed by HPLC using a Waters 626 HPLC pump, a 600S gradient controller, and a 2487 dual-wavelength detector (Waters, Milford, MA). After injecting 0.1 ml of sample or standard, the separation was accomplished using a 15-cm, 4.6-mm I.D. Zorbax (MAC-MOD Analytical, Chadds Ford, PA) C18 reverse-phase column. Components of interest were eluted using a 30-min gradient from 88% A (25% methanol): 12% C (0.1 M tetrabutylammonium hydrogen sulfate, pH 5.2) to 12% A: 76% B (90% methanol): 12% C. Component elution was monitored by following absorbance at 260 nm. After sample elution, the column was washed for 15 min with 100% methanol, then reequilibrated with 88% A: 12% C for at least 10 min. For component identification, retention times of standards were compared with those in the samples. For quantitation, peak areas of standards were measured using Millennium 32 software, version 3.05 (Waters, Milford, MA), and standard curves were constructed.
Histopathology.
Formalin fixed liver tissues were processed by standard histological techniques, sectioned, and stained with hematoxylin and eosin for evaluation. Also, liver sections from the 6-h groups treated with BH + BSO + DAPM (or vehicle) were histochemically stained for DNA fragmentation of dying cells using the KLENOW-Frag-EL detection kit (Oncogene Research Products, Cambridge, MA) according to the manufacturers instructions, except that sections were counterstained with Mayers hematoxylin (Polyscientific, Bayshore, NY).
Statistics.
Data are expressed as mean ± SE of the mean (SEM). All data were analyzed by two-way ANOVA using SPSS (SAS Institute, Inc., Cary, NC), a statistical package for personal computers. Post hoc analyses compared treatment groups for the effects of time and for the effects of pretreatment/treatment at the same time point, using the Newman-Keuls multiple-comparisons test. A p value of < 0.05 was considered significant.
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RESULTS |
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Levels of GSx decreased by 40% in vehicle-pretreated control animals through 6 h (Fig. 1A
, open circles), analogous to previous reports of diurnal variation in hepatic GSx in rodents (Farooqui and Ahmed, 1984
; Jaeschke and Wendel, 1985
). GSSG levels declined more slowly (Fig. 1B
, open circles) but no appreciable effect on the GSx/GSSG ratios was observed at either 3 or 6 h in control rats (Fig. 1C
, open circles). The pretreatment protocol of BH followed 1 h later by BSO depleted hepatic GSx by
60% within 90 min (i.e., 0 h), which then plummeted to
96% depletion by 3 and 6 h (Fig. 1A
, open squares). This pretreatment had no initial effect on GSSG levels at 0 h, but by 3 and 6 h, GSSG values fell by
80% and
90%, respectively (Fig. 1B
, open squares). The faster depletion of GSx, compared with GSSG by BH + BSO, was sufficient to significantly decrease GSx/GSSG ratios at 3 but not 6 h (Fig. 1C
, open squares).
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Effect of Pretreatment and DAPM on Coenzyme A Thiol Status
Severe depletion of the cytosolic GSx pool can lead to depletion of the mitochondrial GSx pool, which enhances the vulnerability of cells to mitochondrial dysfunction and cell death (Meredith and Reed, 1983). Isolation of mitochondria for measurements of GSx/GSSG can lead to artifactual increases/decreases in disulfides/thiols due to lengthy procedures and numerous manipulations. Recently, measurement of the CoASH/CoASSG ratio has been proposed as a potential biomarker of the thiol/disulfide status of mitochondria (ODonovan et al., 2002
; Rogers et al., 2000
) because 8095% of liver CoASH is present in mitochondria (Siess et al., 1978
; Soboll et al., 1976
) and because CoASSG is believed to form via nonenzymatic oxidation of CoASH and GSH or via sulfhydryl exchange between GSSG and CoASH (Crane et al., 1982
; Dyer and Wilken, 1972
).
The GSx depletion protocol was found to produce only a modest effect on CoASH, e.g., a 25% increase at 6 h (Fig. 2A
, open squares) without an effect on CoASSG (Fig. 2B
, open squares). This differential effect of GSx depletion on coenzyme A thiol status increased the CoASH/CoASSG ratio by
60% at 6 h (Fig. 2C
, open squares). In contrast, treatment of GSx-depleted rats with DAPM produced a striking approximately sevenfold rise in the CoASSG level between 3 and 6 h (Fig. 2B
, closed squares). This striking rise in the coenzyme A-mixed disulfide at 6 h was associated with a
80% decline in the CoASH/CoASSG ratio (Fig. 2C
, closed squares).
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Effect of Pretreatment and DAPM on Serum Indices
Potential effects on hepatic integrity were assessed by monitoring serum levels of ALT, an index of leaky hepatocytes, as well as serum levels of bilirubin and bile salts, compounds efficiently removed from blood by hepatic uptake and export into bile. BH + BSO pretreatment unexpectedly elevated serum bile acids approximately fourfold at 0 h (Table 1); this elevation in bile acids was transient because bile acid values returned to baseline by 3 h. In contrast, a later elevation of two- to threefold in serum bile acids was evident at 6 h after treatment with DAPM alone or BH + BSO + DAPM. No appreciable changes in serum bilirubin or ALT (Table 1
), or in serum ALP or GGT (data not shown) were found, and no pretreatment or treatment effects were observed on liver/body weight ratios (data not shown).
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To characterize this pattern of cell death further, liver sections from animals given either DAPM or its vehicle following BH + BSO pretreatment were stained for nuclear DNA fragmentation by the KLENOW-Frag-EL procedure. Through in situ nick translation, this procedure is reported to detect DNA single-strand breaks or double-strand breaks with protruding 5' termini (Jin et al., 1999). Staining that apparently identified DNA fragmentation of apoptotic nuclei (brown staining, Fig. 4A
) was rarely observed in livers at 6 h after the GSx depletion protocol. However, staining for DNA fragmentation was regularly observed at 6 h in livers of animals treated with DAPM after GSx depletion (Figs. 4B,C
). The extent of this staining in apoptotic hepatocytes that were apparently engulfed within other hepatocytes was highly variable, ranging from dark clumps in cells where nuclear material was evident to no staining in cell fragments where substructure was absent (Fig. 4B
). Staining of engulfed cells was also observed more frequently in the livers with the largest number of cells exhibiting characteristics of apoptosis (Fig. 4B
). In contrast, no nuclear staining for DNA fragmentation was observed in hepatocytes exhibiting characteristics of oncosis that were surrounded by inflammatory cells (Fig. 4C
).
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DISCUSSION |
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In prior studies that used more than one agent to deplete GSH, simultaneous injection of DEM + BSO (Baggett and Berndt, 1986) or DEM given 0.5 h after BSO (Monroe and Eaton, 1988
) were reported to decrease GSx by 8595% within 2.5 h, but the sustained effects of administering these agents were not described. Our goal was to develop a pretreatment protocol that produced a significant yet persistent depletion of GSH using low concentrations of drug. Thus, we first rapidly depleted GSx by administration of a GST substrate (BH, 1 mmol/kg, an expected mercapturic acid excretion rate of
40 µmol/kg/h; Barnes et al., 1959
), then prevented resynthesis of GSH by administration of BSO (2.5 mmol/kg) 1 h later. This protocol depleted GSx by
60% at 0 h (i.e., 30 min after BSO), then to
96% by 3 h (i.e., 3.5 h after BSO), which was maintained for another 3 h (Fig. 1A
). Depletion of GSSG occurred more slowly but eventually reached
90% (Fig. 1B
). Furthermore, minimal levels of GSx were attained without an apparent increase in lipid peroxidation (as measured by TBARS) or effects on hepatic morphology (Fig. 3A
), UDP-glucuronosyltransferase or GST activities (Table 2
), or serum indicators of hepatotoxicity (Table 1
). The only indicator of impaired hepatic function was a transient, approximately threefold elevation of serum bile acids. Thus, pretreatment with BH + BSO is a promising new protocol for investigating the effects of GSx depletion on chemical and drug hepatotoxicity.
One curious finding of our study was that severe GSx depletion was associated with an 25% increase in hepatic CoASH by 6 h (Fig. 2A
) without an apparent effect on CoASSG levels (Fig. 2B
). We are currently unable to explain the increase in hepatic CoASH induced by GSx depletion. More extensive studies measuring numerous forms of CoA (e.g., CoASH, acetyl-CoA, acyl-CoA, fatty acyl-CoA; CoASSCoA, CoASSG) may be necessary to clarify this influence of GSx depletion on CoASH status.
Exacerbation of DAPM Toxicity following GSx Depletion
The hepatotoxic effects of DAPM observed in this study are consistent in direction and magnitude with our previous findings (Kanz et al., 1998): (1) morphological injury was confined to BEC in portal triads (Fig. 3B
), (2) alterations in serum markers of hepatocellular injury were minimal (Table 1
), and (3) liver levels of GSx and GSSG were not appreciably affected (Figs. 1A and 1B
). Results from this study also indicate that DAPM does not alter hepatic CoASH or CoASSG levels (Figs. 2A and 2B
), nor does it elevate TBARS in liver, suggesting that DAPM does not produce significant effects on the redox status of a majority of the cells in the liver (e.g., hepatocytes). However, our observations do not provide information regarding injury markers or thiol/disulfide ratios in BEC, the target cell of DAPM. Detection of specific constitutive changes induced by DAPM within BEC will require in vitro investigations with cultured cells.
Unlike the protection against biliary toxicity of ANIT observed by others in GSx-depleted animals (Dahm and Roth, 1991), we found that depletion of GSx enhanced DAPM toxicity. Depletion of hepatic GSx accelerated DAPM-induced BEC injury by at least 3 h, as well as increased the severity of BEC injury at 6 h (Fig. 3C
). Constitutively, the level of GSH in BEC is about one-third that of hepatocytes (Parola et al., 1990a
). These low levels of GSH make BEC particularly vulnerable to toxicants that oxidize GSH and produce glutathione-protein mixed disulfides (Parola et al., 1990b
). Thus, if the pretreatment protocol produced only a 50% depletion of GSx levels in BEC, GSx concentrations would have dropped below 5 nmol/mg protein (Parola et al., 1990a
,b
). At such minimal levels of GSx, BEC would have little protection against potential reactive intermediates of DAPM secreted into bile. In addition, we found that depletion of hepatic GSx altered the response to DAPM with noticeable hepatocyte damage, as evidenced by the scattered apoptotic or oncotic dying cells (Figs. 3D, 4B,C
) and by hepatocyte dysfunction, as evidenced by increases in serum bile acid (Table 1
) and increases in hepatic CoASSG levels (Fig. 2B
) and GST activity (Table 2
).
The approximately sevenfold increase in CoASSG at 6 h after DAPM may represent a late oxidant stress response in the liver, compartmentalized in the mitochondria (ODonovan et al., 2002; Rogers et al., 2000
), because 8095% of liver CoASH is found in the mitochondria (Siess et al., 1978
; Soboll et al., 1976
). Previously, Crane et al.(1982)
had shown that perfusion of isolated rat livers with t-butyl hydroperoxide for 10 min elevated hepatic CoASSG levels approximately fourfold while decreasing CoASH and acetyl-CoA levels by
80% and 75%, respectively, without substantial changes in total CoA species. These authors concluded that elevated levels of GSSG produced by hydroperoxide metabolism via glutathione peroxidase were responsible for increases in hepatic CoASSG. In our experiments, because increases in CoASSG were observed only at 6 h, a time point considerably after evident injury to BEC, it is unlikely that this late alteration in the presumed mitochondrial thiol/disulfide ratio is mechanistically important in BEC injury but it may be relevant to the unusual pattern of hepatocyte injury observed at 6 h (Figs. 3D, 4B,C
).
DAPM treatment was found to increase liver GST activity mildly, which was further elevated in GSx-depleted rats treated with DAPM (Table 2). The increase in GST activity induced by DAPM is comparable in extent and timing with that previously reported for DEM and sodium valproate in rat liver (Seçkin et al., 1999
; Younes et al., 1980
). Known inducers of GSTs include electrophilic substrates for GSTs (Eaton and Bammler, 1999
) and specific transcription factors that bind to an antioxidant response element (ARE) in response to oxidative stress (Dhakshinamoorthy et al., 2000
). DAPM administration had no effect on TBARS and GSSG levels, which suggests that DAPM does not induce extensive lipid peroxidation or GSH oxidation. Therefore, the observed increases in GST activity are more likely due to the metabolism of DAPM to electrophilic intermediates. Support for DAPM metabolism to electrophiles is our preliminary identification of DAPM-glutathione conjugates in rat bile (Dugas, 2000, unpublished observation). One additional noteworthy fact regarding our results is that the pretreatment protocol for depleting
96% of liver GSx does not appear to alter cell homeostasis sufficiently to upregulate GSTs (Table 2
).
Apoptosis/Oncosis Pattern of DAPM Hepatocellular Injury
Numerous studies have shown that mitochondrial perturbations (respiratory uncoupling, calcium changes, activation of the mitochondrial permeability transition pore [MTP], loss of membrane potential, enhanced reactive oxygen species formation, release of cytochrome C) are critical events in the early, shared pathways that terminate in either oncosis or apoptosis (for review, see Kroemer et al., 1998). In fact, Lemasters (1999)
has proposed that cell death is a continuum ranging from apoptosis to oncosis and that tissue responses to insult are a mixture of events associated with both types. At 6 h after DAPM treatment of GSx-depleted animals, we observed hepatocytes with the swollen, leaky appearance of death by oncosis and other hepatocytes with the shrunken, compacted appearance of death by apoptosis (Fig. 3D
). Histochemical staining with the KLENOW-Frag-EL technique for DNA strand breaks was equivocal because only some of the hepatocytes engulfed by other cells showed KLENOW-Frag-EL-positive staining, and that was of highly variable staining intensity (Fig. 4B
). DNA strand breaks (as detected by TUNEL staining) have been reported in both apoptotic and oncotic cells (Grasl-Kraupp et al., 1995
; Ohno et al, 1998
); thus, the presence of DNA strand breaks is not a definitive marker of apoptosis. A pattern of mixed oncotic and apoptotic cell death has been reported previously in rat liver following toxicant administration (Levin et al., 1999
) and following tissue injury by other kinds of insults, such as ischemia/reperfusion and viral infection (Lemasters, 1999
). Based on the observed morphology, we conclude that DAPM induces both apoptosis and oncosis in hepatocytes depleted of GSx. This mixed oncotic and apoptotic cell death could be related to the DAPM-induced alterations in thiol/disulfide ratios in the presumed mitochondrial compartment. Alternatively, such severe GSx depletion may have modulated the sensitivity of hepatocytes to apoptotic cell death by other factors, such as inflammatory cytokines. Nagai et al.(2002)
recently showed that GSx depletion of isolated hepatocytes by DEM or phorone treatment produced dose-dependent necrosis, whereas GSx depletion in the presence of tumor necrosis factor
induced similar levels of necrosis with increased levels of apoptosis. These authors suggested that GSx depletion could be altering redox-sensitive steps in the apoptosis cascade, which could make cells more susceptible to activation of this pathway.
In summary, pretreatment of rats with BH + BSO produced a substantial and sustained depletion of hepatic glutathione without significant alterations in markers of cell injury or thiol/disulfide status. Administration of DAPM to rats with minimal amounts of hepatic glutathione accelerated injury to BEC and produced an unusual pattern of cell death, with dying hepatocytes exhibiting characteristics of either apoptosis or oncosis. Because glutathione depletion exacerbated BEC and hepatocyte injury induced by DAPM, unlike its protective influence on ANIT injury, our observations suggest that the mechanisms of BEC injury caused by the bile duct toxicants DAPM and ANIT are dissimilar. Further studies comparing DAPM and ANIT injury in rats depleted of GSx by the same protocol will be required to clarify differences in the mechanisms of these two bile duct toxicants.
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ACKNOWLEDGMENTS |
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Portions of this manuscript were presented at the 37th and 39th Annual Meetings of the Society of Toxicology in Seattle, WA, and Philadelphia, PA, respectively.
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NOTES |
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2 Current address: Chevron Phillips Chemical Co. LP, 10001 Six Pines Dr., Suite 4103, The Woodlands, TX 77380.
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