Faculty of Pharmaceutical Sciences, The University of British Columbia, Vancouver, British Columbia, Canada V6T 1Z3
1 To whom correspondence should be addressed at Faculty of Pharmaceutical Sciences, The University of British Columbia, 2146 East Mall, Vancouver, BC, CANADA V6T 1Z3. Fax: (604) 8223035. E-mail: fabbott{at}interchange.ubc.ca.
Received March 11, 2005; accepted April 20, 2005
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ABSTRACT |
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Key Words: valproic acid; oxidative stress; 15-F2t-isoprostane; hepatotoxicity; -glutathione S-transferase; lipid peroxidation.
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INTRODUCTION |
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More recently, there are a number of studies suggesting that excessive generation of free-radical intermediates are associated with VPA, possibly as a consequence of VPA biotransformation (Jurima-Romet et al., 1996), alterations in glutathione homeostasis (Cotariu et al., 1990
; Graf et al., 1998
; Seckin et al., 1999
; Tang et al., 1995
), and/or depletion of cofactors required for antioxidant defense (Graf et al., 1998
; Hurd et al., 1984
). A rapid in vitro assay was developed for the detection of metabolism-dependent cytotoxicity on isolated human lymphocytes and provided a method to study the mechanisms underlying lymphocyte toxicity exhibited by VPA (Tabatabaei et al., 1999
). In support of this hypothesis, exposure of VPA to human lymphocytes isolated from patients who had developed hepatotoxicity while on VPA therapy demonstrated a marked increase in lymphocyte cell death compared to lymphocytes from VPA-treated patients who did not show liver toxicity (Farrell and Abbott, 1991
). Mechanistic studies were carried out to evaluate the contribution of reactive metabolite and reactive oxygen species as the mechanism of the metabolism-dependent VPA-induced lymphocyte toxicity. The data obtained indicate that the observed cytotoxicity in the lymphocyte model was the result of the microsomal metabolism-dependent generation of hydrogen peroxide in the medium that can readily cross cell membranes and subsequently interact intracellularly with iron to produce the highly reactive hydroxyl free radicals (Tabatabaei et al., 1999
). In those individuals who have compromised antioxidant defense mechanisms, the induction of oxidative stress by VPA may be responsible for or contribute to the mechanism of idiosyncratic hepatotoxicity.
A recent study demonstrated that the administration of VPA led to a dose-dependent elevation of plasma and liver levels of the lipid peroxidation marker, 15-F2t-isoprostane (15-F2t-IsoP, also called 8-isoprostane or 8-iso-prostaglandin F2) (Tong et al., 2003
). While the effects of VPA on 15-F2t-IsoP levels were consistent with an induction of oxidative stress, two other independent measures of oxidative stress, thiobarbituric acid reactive substances (TBARS) and lipid hydroperoxides (LPO), were unchanged by a single dose of VPA. However, the question remains whether the elevation in 15-F2t-IsoP precedes liver toxicity.
The objective of the present study was to determine the temporal relationship between oxidative stress and hepatotoxicity in rats treated with VPA and, in doing so, to provide new insight into the potential role of oxidative stress in VPA-mediated hepatotoxicity in rats. If the hepatotoxicity were induced through the formation of oxidative stress, an expected increase or accumulation of oxidative stress markers would occur prior to hepatotoxicity. 15-F2t-IsoP, TBARS, and LPO were used as markers of oxidative stress, whereas histopathological findings (necrosis and steatosis), and serum -glutathione-S-transferase (
-GST) levels were used as markers of hepatotoxicity. VPA metabolites, in particular 4-ene-VPA and (E)-2,4-diene-VPA, were monitored to investigate whether the observed oxidative stress and hepatotoxic events were associated with the formation in these putative reactive metabolites. The results from the present study suggest that oxidative stress precedes hepatotoxicity in VPA-treated rats.
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MATERIALS AND METHODS |
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Animal experiments.
Adult male Sprague-Dawley rats (250300 g) were from the University of British Columbia Animal Care Facility. They were fed with rat diet (Labdiet 5001 rodent diet, PMI Feeds Inc., Richmond, IN) and water ad libitum and maintained in a room on a 12 h light/12 h dark cycle at constant temperature (22°C) and humidity. The University of British Columbia Animal Care Committee approved all animal experimentation. Rats were treated with an aqueous solution of VPA (dissolved in 0.9% saline) and injected ip at a dose of 500 mg/kg once a day for 2, 4, 7, 10, or 14 consecutive days. Our previous study demonstrated that a dose of 500 mg/kg VPA produced maximal elevation in plasma and liver levels of 15-F2t-IsoP (Tong et al., 2003). The control group was treated with 0.9% saline solution (vehicle control, 1 ml/kg, ip) for 14 consecutive days. Based on the tmax of plasma 15-F2t-IsoP following a single 500 mg/kg VPA dose (Tong et al., 2003
), rats were sacrificed 30 min following the last injection by decapitation, and trunk blood was collected in Vacutainer® blood collection tubes. Serum and plasma were immediately prepared and snap-frozen in liquid nitrogen for the analysis of VPA metabolites, oxidative stress, and toxicity biomarkers. The livers were weighed, rinsed with ice-cold phosphate buffered saline (pH 7.4), and homogenized in 50 mM phosphate buffer (pH 7.4) with 5 mM D-saccharolactone and 0.005% butylated hydroxytoluene on ice. The homogenate was snap-frozen in liquid nitrogen for the determination of VPA metabolites and oxidative stress biomarkers. All biological samples were stored at 80°C.
Determination of plasma and liver 15-F2t-IsoP levels.
Plasma and liver levels of 15-F2t-IsoP were determined by an EIA assay (Cayman Chemical Co., Ann Arbor, MI) as previously described (Tong et al., 2003). Plasma 15-F2t-IsoP was measured directly by adding 50 µl of fresh rat plasma to the 96-well EIA plates. For the determination of total liver 15-F2t-IsoP, liver homogenate samples (500 µl) were subjected to alkaline hydrolysis by incubation with an equal volume of 15% KOH for 1 h at 40°C, followed by protein precipitation with 12 M HCl (final sample pH of 12). For the determination of free liver 15-F2t-IsoP, liver homogenate was subject only to protein precipitation. The samples were centrifuged (1600 x g for 10 min) to pellet the protein and processed by liquid-liquid extraction with ethyl acetate (5 ml) by gentle rotation for 30 min. The samples were centrifuged again (1600 x g for 10 min) to aid in the separation of the layers. The organic layer was dried under a stream of N2 (30°C), reconstituted in acidified water (2 ml, pH 3), and processed by a solid-phase extraction procedure adapted from Nourooz-Zadeh et al. (1995)
. Samples were extracted on a 24-channel Vac Elut Vacuum Manifold using Waters Oasis® C18 cartridges (Waters Ltd., Mississauga, ON, Canada). The cartridges were preconditioned with 2 ml methanol and 2 ml water (pH 3). Samples were washed with 3 ml water (pH 3) followed by 3 ml acetonitrile/water (15/85, v/v) and eluted with 6 ml hexane/ethyl acetate/propan-2-ol (30/65/5, v/v/v). The eluant was evaporated under N2, and the residue was reconstituted in 1 ml of EIA phosphate buffer (Cayman Chemical Co., Ann Arbor, MI). 15-F2t-IsoP was determined spectrophotometrically at 405 nm on a multi-well plate reader.
Determination of liver LPO levels.
LPO levels were determined using a commercial kit (Cayman Chemical Co., Ann Arbor, MI). Plasma and liver homogenate samples (500 µl) were deproteinated and extracted under acidic conditions with 1 ml ice-cold deoxygenated chloroform, and the chloroform extract was removed following centrifugation (1600 x g for 5 min at 0°C) for LPO determination. The LPO assay is based on redox reactions between hydroperoxides and ferrous ions to produce ferric ions, and the resulting ferric ions are detected using thiocyanate ion as the chromagen. Chloroform extracts (500 µl) were mixed with 50 µl chromagen reagent (2.3 mM ferrous sulfate in 0.2 M HCl and 1.5% methanolic solution of ammonium thiocyanate), and 300-µl samples were transferred to a glass 96-well plate, and absorbance was determined at 500 nm. This assay used 13-hydroperoxy-octadecadienoic acid as a lipid hydroperoxide standard to construct a standard curve (linearity from 0.5 to 5 nmol hydroperoxide).
Determination of plasma and liver TBARs.
The concentration of TBARS was calculated as malondialdehyde (MDA) equivalents using a commercial kit (Oxi-Tek®, Zeptometrix Corporation, Buffalo, NY). Samples (100 µl) of plasma or supernatant from liver homogenate after 10,000 x g (15 min, 4°C) centrifugation were mixed with an equal volume of sodium dodecyl sulfate solution and 2.5 ml of 5% thiobarbituric acid/acetic acid reagent. Samples were incubated for 60 min at 95°C. After centrifugation at 1600 x g, samples were transferred into a 96-well plate, and fluorescence was monitored on a multi-well plate reader with excitation set at 508 nm (20 nm band width) and emission at 560 nm (20 nm bandwidth). This assay used an MDA standard to construct a standard curve (0.55 nmol/ml MDA).
Determination of serum -GST activity.
Fresh serum was prepared immediately after the rats were sacrificed, and -GST was measured in rat serum as a marker for hepatic damage by a commercially available enzyme immunoassay method (Biotrin Rat Alpha GST EIA, Biotrin, Dublin, Ireland).
-GST, a cytosolic enzyme located predominantly in liver parenchyma, was demonstrated to be a sensitive and specific biomarker of hepatocyte injury (Clarke et al., 1997
; van Wagensveld et al., 1997
). The quantitative immunoassay is based on the sequential addition of serum sample (1:50 dilution) and rabbit anti-rat
-GST IgG conjugated to streptavidin-peroxidase complex to micro-assay wells coated with anti-rat
-GST IgG with washing between each step. After the peroxidase substrate was added to the ELISA plate, the resultant color intensity was determined on a multi-well plate reader (absorbance determined at 450 nm) and was proportional to the amount of
-GST present in the sample. The assay was linear from 1.56 to 25 µg/ml based on
-GST standard solution.
Histopathology.
Livers from all treated groups were rinsed with ice-cold saline, and a small cross-section of the liver was obtained and fixed in 10% formalin-phosphate buffered saline when the rats were sacrificed. Hematoxylin and eosin stain was used for light microscopy. The severity of liver pathology was assessed as follows: necrosis (the percentage of the cross section containing necrotic foci) was scored 1+ (<25%), 2+ (26 to 50%), 3+ (51 to 75%), and 4+ (>75%). Steatosis (expressed as the percentage of liver cells containing fat) was scored in a similar way as described for the determination of necrosis. At least two different sections were examined per liver sample, and the pathologist was blind to the treatment groups when assessing the histology.
Determination of VPA metabolites.
Oxidative and desaturated VPA metabolites were determined by GC/MS using negative ion chemical ionization and single ion monitoring. The sample preparation and assay procedures are described in a previous study (Tong et al., 2003). VPA-1-O-acyl glucuronide (VPA-G) levels were determined in liver homogenate by an LC/MS assay using negative electrospray ionization and single ion monitoring. The assay utilizes purified VPA-G as a standard and 2H6-VPA-G as its internal standard to measure VPA-G levels directly by a validated method described elsewhere (Tong et al., 2005a
).
Instrumentation and analytical methods.
GC/MS analysis of VPA and its metabolites was carried out using an HP 6890 gas chromatograph interfaced to an HP5973 mass selective detector (Hewlett-Packard, Avondale, PA). The gas chromatograph was equipped with a capillary splitless injector and an HP7683 autosampler. The mass spectrometric data acquisition and handling software, HP Enhanced Chemstation Software G1701BA (V B.01.00) was used to control the operation of all instruments.
LC/MS analysis of VPA-G was performed using a Fisons VG Quattro tandem mass spectrometer (Micromass, Montreal, Canada) interfaced with a Hewlett Packard (Avondale, PA, USA) 1090 II Liquid chromatograph. Instrument operation and data acquisition were controlled by MassLynx® (v3.1, Micromass) software.
Fluorescent analysis for the TBARs assay was performed on a Cytofluor® Series 4000 (Applied Biosystems, Bedford, MA) multi-well fluorescent plate reader. Spectrophotometric analysis for the 15-F2t-IsoP, LPO, and -GST assays were performed on a Labsystems Multiscan Ascent® multi-well plate reader (Thermo Electron Corp., Burlington, ON, Canada).
Statistical analysis.
Statistical significance of the difference between the means of multiple groups was analyzed by one-way analysis of variance and, where appropriate, was followed by Bonferonni's multiple comparison post hoc test. The level of significance was set a priori at p < 0.05.
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RESULTS |
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Serum -GST Levels and Histology during VPA Treatment
Serum levels of -GST were significantly elevated after 4 days of VPA treatment (251 ± 17 µg/l) compared to basal levels determined in the control group treated with saline (57 ± 7 µg/l) (Fig. 4). The
-GST levels remained elevated to the same extent on days 7, 10, and 14.
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Liver steatosis was observed in seven rats (Table 1), and the incidence of lipid accumulation appeared to increase with the duration of VPA treatment: one rat in the 4-day group, and two rats in the 7-day group. Four out of five animals in the 10-day group exhibited steatosis (Fig. 5E). The observed steatosis was of zonal distribution conforming to the centrilobular zones (periacinar zone 3). In all cases, steatosis was never extensive, in terms of area, and was considered mild to moderate affecting approximately 1025% of the liver cross-section, with the exception of one animal on day 10.
Levels of VPA Metabolites during VPA Treatment
Levels of oxidative and mono- and di-unsaturated VPA metabolites were monitored in liver (Table 2) and plasma (Table 3). There was a trend of decreasing VPA metabolite levels in liver with increasing duration of VPA treatment. Significant decreases were observed with some of the liver VPA metabolites after 14 days of treatment, in particular 3-OH-VPA, 2-ene-VPA, 3-ene-VPA and (E,E)- and (E,Z)-2,3'-diene-VPA. The putative reactive VPA metabolites 4-ene-VPA and (E)-2,4-diene-VPA were not elevated throughout the duration of the study. Plasma VPA metabolites (Table 3) and hepatic VPA-G (Table 2) were similar in all groups treated with VPA over the duration of 14 days, with the exception of plasma (E)-2,4-diene-VPA, which was below the LOQ (2 ng/ml) by day 14 (Table 3).
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DISCUSSION |
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Fatty liver was not a predominant lesion observed in the current study. Other studies showed microvesicular steatosis as a common feature in rats at a near-lethal dose of 750 mg/kg over 48 h, but not with a lower dose of 350 mg/kg (Lewis et al., 1982). Kesterson et al. (1984)
demonstrated fatty liver in rats treated with 700 mg/kg/day for 4 days, but with a lower occurrence (two out of seven rats) at 600 mg/kg/day for 5 days. In the present study, the first incidence of fatty liver, although never extensive in area, occurred on day 4 of treatment (one out of four rats), with increasing occurrence observed after 10 days of treatment (four out of five rats) at 500 mg/kg/day. The lack of steatosis on day 14 was peculiar, and it was speculated to be related to the observation that necrosis was more severe at this time. Microvesicular steatosis was observed after a single 500-mg/kg dose of VPA in fasted rats by Olsen et al. (1986)
and with repeated dosing also at 500 mg/kg for 7 consecutive days in rats provided with food ad libitum (Sugimoto et al., 1987
).
The elevation in plasma and liver 15-F2t-IsoP preceded the occurrence of hepatotoxicity, as determined by histological assessment and by levels of serum -GST. After the second day of dosing, plasma and serum 15-F2t-IsoP increased when compared to the saline-treated group, and these levels remained elevated to the same extent throughout the 14-day study period. A trend of increased
-GST, however, not statistically significant, was observed after the second day and was highest with the one animal that exhibited inflammation of the liver capsule. It is possible that this trend may reach statistical significance with increased sample size. According to our data, the formation of 15-F2t-IsoP did not increase over time with repeated dosing. 15-F2t-IsoP is a member of the F2-isoprostanes, a series of prostaglandin F2
-isomers that is produced by a free radical-catalyzed (nonenzymatic) lipid peroxidation of arachidonic acid (Roberts and Morrow, 2000
). It has been generally accepted that the cascade from arachidonic acid to 15-F2t-IsoP is independent of cyclooxygenase (COX). The effects of VPA on 15-F2t-IsoP are unlikely to be due to COX activity, taking into consideration the reported lack of an effect of VPA on COX expression. VPA treatment has been associated with reduced arachidonic acid turnover in rats (Chang et al., 2001
) and attenuation of the arachidonic acid cascade as evidenced by reduced synthesis of COX-dependent products (Kis et al., 1999
; Szupera et al., 2000
). A recent study reported that chronic administration of VPA to rats reduced protein levels of COX-1 and COX-2, total COX activity, and the metabolites of arachidonic acid produced via COX (Bosetti et al., 2003
). These observations are not consistent with COX-dependent formation of 15-F2t-IsoP, and our interpretation is that the 15-F2t-IsoP levels in this study are reflective of oxidative stress and precede the onset of hepatotoxicity in VPA-treated rats (Fig. 6). Subsequent experiments with cultured rat hepatocytes support the evidence that oxidative stress, as measured by the 15-F2t-IsoP and DCF-DA assays, could occur in the absence of hepatocyte toxicity (Tong et al., 2005b
).
Other biomarkers of oxidative stress, LPO and TBARs, were also examined in our study in relation to the onset of hepatotoxicity. We found that levels of liver LPO were elevated after the onset of hepatotoxicity (day 7) and remained elevated with an increasing trend to day 14. Liver and serum TBARs were not elevated until day 14, which corresponded to the time point when necrosis was most prevalent. These results are consistent with previous findings that a single dose of VPA did not alter liver and plasma TBARs and liver LPO levels (Tong et al., 2003). The increase in LPO and TBARs detected at time points after the first onset of hepatic necrosis may imply that necrosis occurred first, giving rise to the elevated biomarkers of lipid peroxidation. However, it may also be argued that LPO and TBARs are less sensitive markers of lipid peroxidation and the colorimetric assays are indirect and less specific as compared to the measurement of 15-F2t-IsoP by EIA. 15-F2t-IsoP may represent an earlier lipid peroxidation event, while MDA, which is a degradation product of polyunsaturated fatty acid hydroperoxides detected using the TBARs assay, may simply represent later lipid peroxidation events because of the necrosis. A lack of temporal correlation among reactive oxygen species biomarkers was also reported in another study that examined pulmonary artery endothelial cells treated with H2O2 (Hart et al., 1998
). Specifically, the levels of TBARs and LPO were not significantly elevated in cells treated with H2O2 (50100 µM) at a time point that produced a maximal increase in 15-F2t-IsoP, however; not until the highest concentration of H2O2 (250 µM) were increases in levels of TBARs and LPO observed. These results were ascribed to be due to differences in biomarker sensitivity.
Our study is the first to simultaneously characterize VPA metabolite profiles, hepatotoxicity, and oxidative stress events within the same time frame of VPA treatment in the whole animal. With respect to the reactive metabolite hypothesis, there was no elevation in hepatic and plasma levels of the putative VPA reactive metabolites 4-ene-VPA and (E)-2,4-diene-VPA. These findings are consistent with reported studies that examined VPA metabolite profiles and hepatotoxicity in patients and showed a lack of correlation between hepatotoxicity and serum levels of 4-ene-VPA (Siemes et al., 1993). A similar conclusion was also reached following comparative studies of VPA and 2-ene-VPA in rats, where the incidence of liver microvesicular steatosis was observed to be independent of plasma levels of 4-ene-VPA and (E)-2,4-diene-VPA (Loscher et al., 1993
). It was therefore suggested that these metabolites were not the decisive factors in VPA-induced hepatotoxicity, whereas more recent studies indicated that urinary N-acetylcysteine conjugates of (E)-2,4-diene-VPA was a better indicator of reactive metabolite exposure (Gopaul et al., 2000a
,b
). Furthermore, the ß-oxidation related metabolites 2-ene-VPA, 3-ene-VPA, 3-OH-VPA, and (E,E)- and (E,Z)-2,3'-diene-VPA were decreased in the liver by days 1014, suggesting that inhibition of ß-oxidation was not apparent until after the onset of oxidative stress and hepatotoxicity. In contrast to the P450 and ß-oxidation metabolites of VPA, VPA-G levels remained unchanged throughout the study period.
In summary, VPA treatment to rats for up to 14 consecutive days initiated a sequence of events whereby increases in hepatic and plasma levels of 15-F2t-IsoP occurred prior to the rise in serum -GST levels and the onset of liver steatosis and necrosis. Consistent with the present findings in rats, treatment of primary cultures of rat hepatocytes with VPA increased the levels of the oxidative stress markers, 15-F2t-IsoP and 2',7'-dichlorofluorescein levels, under conditions where the hepatocytes were devoid of toxicity (Tong et al., 2005b
). Collectively, our novel findings indicate that VPA does cause oxidative stress in liver and that the oxidative stress precedes the hepatotoxicity.
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ACKNOWLEDGMENTS |
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