* Toxicology Division II, Laboratory of Pathology, Institute of Environmental Toxicology, 4321 Uchimoriya, Mitsukaido, Ibaraki 303-0043, Japan;
Center for Tsukuba Advanced Research Alliance and Institute of Basic Medical Sciences, University of Tsukuba, Tsukuba, Ibaraki 305-8577, Japan; and
Chemistry Division, Institute of Environmental Toxicology, 4321 Uchimoriya, Mitsukaido, Ibaraki 303-0043, Japan
Received July 16, 2000; accepted September 26, 2000
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ABSTRACT |
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Key Words: Nrf2; knockout mice; acetaminophen; hepatotoxicity; ARE; oxidative stress; electrophile; UDP-glucuronosyltransferase; glutathione; -glutamylcysteine synthetase.
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INTRODUCTION |
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While searching for proteins that regulate expression of the ß-globin gene during differentiation, the Nrf family of transcription factors was identified. Originally, Nrf2 was isolated in 1994 from a human K562 erythroid cell line and in 1995 from a chicken erythroid cDNA library (HD3) (Itoh et al., 1995; Moi et al., 1994
). The designation Nrf2 (NF-E2 related factor 2) was derived from the known transcription factor p45 subunit of NF-E2 (Nuclear Factor Erythroid 2), with which it shows high sequence homology. Within the family of bZip transcription factors, Nrf2, p45 NF-E2, and their homologues constitute a discrete subfamily whose members share regions of homology with that of the Drosophila Cap'n'Collar (CNC) protein (Chan et al., 1993
; Itoh et al., 1995
; Kobayashi et al., 1999
; Moi et al., 1994
). While the expression of p45 is limited to erythroid cells and megakaryocytes, Nrf2 is widely expressed in tissues that include muscle, kidney, lung, intestine, and liver (Itoh et al., 1995
; Moi et al., 1994
). Furthermore, elimination of Nrf2 expression does not influence erythropoiesis (Chan et al., 1996
; Itoh et al., 1997
; Kuroha et al., 1998
). Thus, until recently, the precise function of Nrf2 was unknown. The fact that the Nrf2 binding site, namely the NF-E2 binding motif or MARE (Maf-recognition element), is highly similar to the ARE, and that its tissue-specific expression is most similar to that of ARE-regulated genes led to the speculation that Nrf2 is an important regulator of ARE-mediated gene expression (Itoh et al., 1997
; Venugopal and Jaiswal, 1996
).
The genes that were first shown to be controlled by Nrf2 in vivo encode drug-metabolizing enzymes such as GST and quinone oxidoreductase 1 (NQO1) (Itoh et al., 1997); these genes are inducible by the antioxidant butylated hydroxyanisole (BHA) which acts through the ARE present in their regulatory regions. Dietary administration of 0.7% BHA for 16 to 20 days greatly impaired the induction of NQO1 and 3 classes of GST (Alpha, Mu, and Pi) in both the liver and intestine of homozygous nrf2 knockout mice compared to their heterozygous littermates (Itoh et al., 1997
). It was recently demonstrated that detoxification-enzyme genes are not unique in their regulation by Nrf2. For example, Nrf2 was shown to be essential for the induction of HO-1, peroxiredoxin MSP23, and the cystine transporter (Xc-) by electrophilic agents in mouse peritoneal macrophages (Ishii et al., 2000
). HO-1 and peroxiredoxin have antioxidative activities, whereas Xc- increases the intracellular cysteine necessary for GSH synthesis. The involvement of Nrf2 in the regulation of HO-1 and
GCS, an enzyme which catalyzes the rate-limiting step in the synthetic pathway of GSH, has also been reported by other investigators (Alam et al., 1999
; Moinova and Mulcahy, 1999
). The requirement of Nrf2 in the regulation of such genes was further confirmed by the depressed expression of UDP-GT (Ugt1a6), catalase, and SOD1 observed in nrf2 knockout mice (Chan and Kan, 1999
).
The molecular mechanism of Nrf2 activation by reactive electrophiles has partially been clarified (Ishii et al., 2000; Itoh et al., 1999
). Keap1, a homologue of the Drosophila actin binding protein Kelch, binds to the N-terminal Neh2 domain of Nrf2, thereby retaining this transcription factor in the cytoplasm (Adams et al., 2000
; Itoh et al., 1999
; Xue and Cooley, 1993
). Treatment of cells with reactive electrophiles counteracts this sequestration of Nrf2 by Keap1, such that Nrf2 translocates to the nucleus and upregulates ARE-mediated transcription.
Considering its function, Nrf2 is expected to play an important role in the defense mechanisms against xenobiotic toxicity. In fact, the high sensitivity of nrf2 knockout mice to butylated hydroxytoluene (BHT)-induced pulmonary injury has recently been reported (Chan and Kan, 1999); the mechanism of their high sensitivity was, however, not clearly demonstrated. APAP was used as a chemical model in the present study to examine the mechanism by which Nrf2 plays a protective role against the toxicity of xenobiotics and to elucidate the relationship between Nrf2-regulated gene expression and such protection. APAP is widely used in tablet form for its antipyretic and analgesic properties, and its metabolic pathways are well characterized (Cohen et al., 1998
). At low doses, the majority of APAP is readily conjugated with glucuronic acid and sulfate and subsequently eliminated. A small portion of APAP undergoes biotransformation by cytochrome P450s to an electrophilic quinoneimine that nonenzymatically reacts with GSH for excretion. Exposure to high doses of APAP saturates the glucuronidation and sulfation pathways and depletes the GSH pool, thus enabling the reactive APAP intermediate to bind to important intracellular macromolecules and result in cytotoxicity. Both the ARE-regulated phase II drug-metabolizing enzyme UDP-GT, and the antioxidant molecule GSH, whose synthesis depends on the ARE-regulated
GCS enzyme, are important in the detoxification of APAP.
In the present study, we demonstrated that nrf2 knockout mice are highly sensitive to APAP-induced hepatotoxicity as a result of a lowered activity of drug-metabolizing enzymes and antioxidant systems, which represent the major Nrf2-regulated defense mechanisms against xenobiotic toxicity.
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MATERIALS AND METHODS |
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Animals.
Two- to 4-month-old male homozygous (/) and heterozygous (+/) nrf2 knockout mice (ICR/129SVJ chimeric mice [Itoh et al., 1997]) and their wild-type littermates (+/+) were used in this study. DNA was taken from the tail of each mouse and analyzed by polymerase chain reaction (PCR) to confirm its genotype. The mice were housed in stainless-steel cages in an animal room maintained at 24 ± 2°C and using a 12-h light/dark cycle (light on at 7:00 A.M. and off at 7:00 P.M.). Food (certified diet M, Oriental Yeast Co, Ltd., Tokyo, Japan) and water were made freely available to the mice, except where otherwise stated.
Treatment of animals.
In the dose-response study the administration protocol was performed according to Manautou et al. (1996). After overnight fasting, APAP (in 50% propylene glycol as vehicle) was administered to the mice, po, between 8:30 and 9:30 A.M. at doses of either 0, 150, 300, or 600 mg/kg, 5 ml/kg being used in each case. Four mice of each genotype were used for each dose, except for the 150-mg/kg dose in which only 3 heterozygous knockout mice were used. Food was withheld until 2 h after dosing, but water was available throughout the experiment. The animals were sacrificed 24 h after dosing.
In the time-course study a dose of 300 mg/kg APAP was administered to the mice and the animals were sacrificed at 0 (after overnight fasting and without dosing), 2, 8, or 24 h after dosing. Other experimental conditions were the same as those used in the dose-response study. An additional 8 homozygous knockout and wild-type mice were sacrificed after overnight fasting and without dosing, for the purpose of metabolic baseline activity analysis.
Biochemical assays.
Following withdrawal of blood from the posterior vena cava of anesthetized animals, plasma alanine transaminase (ALT) activity was determined using an automated biochemical analyzer, CHEM1® (Bayer Corp., Tarrytown, NY). The animals were sacrificed by exanguination, livers were removed, and microsomes were prepared. Microsomal protein concentration was determined by the method of Lowry et al. (1951). Cytochrome P450 content was determined according to Omura and Sato (1964). Hepatic UDP-GT activity from detergent-treated microsomes was determined using APAP as the aglycon substrate according to Bock and Bock-Henning (1987) and Manautou et al. (1996). NPSH was extracted from samples of each liver using 1 M perchloric acid and measured by the enzymatic cycling method of Tietze (1969) as modified by Griffith (1980).
Histopathology.
Samples of each liver were fixed in 10% neutral buffered formalin for 24 h, processed by routine methodology, stained with hematoxylin and eosin (H&E), and examined by light microscopy. Hepatic lesions were graded from to +++ (, no lesions; ±, degeneration of centrilobular hepatocytes; +, slight centrilobular necrosis (necrotic hepatocytes present in 1- to 3-cell layers from the central vein); ++, moderate centrilobular necrosis (necrotic hepatocytes present in more than 3-cell layers from the central vein but limited to less than half of the liver section); +++, severe centrilobular necrosis (necrotic areas occupying half or more than half of the liver section)). Histopathological evaluation was performed blind, in which the identity of both the genotype and type of treatment was not revealed to those undertaking the examination.
Immunohistochemistry.
Deparaffinized liver sections were placed in 3% hydrogen peroxide for 15 min to quench endogenous peroxidase activity. Sections were heated in 0.1 M citrate buffer, pH 6.0, in a microwave oven for 6 min and rinsed twice, 5 min each wash, with phosphate-buffered saline containing 0.05% Triton X-100 (PBST). After blocking non-specific binding sites with 4% BlockAce (Dai-Nippon Pharmaceutical, Osaka) for 20 min, sections were incubated in a rabbit polyclonal antibody against APAP (Biogenesis, Kingston, NH; 1:250) for 30 min; negative control sections were incubated in PBST only. Sections were rinsed with PBST, incubated in biotinylated goat antibody against rabbit immunoglobulin at a 1:1000 dilution (DAKO Japan, Tokyo) for 30 min, rinsed twice with PBST, and incubated in streptavidin-horseradish peroxidase at a 1:500 dilution (Vector Laboratories, Burlingame, CA) for 30 min. Diaminobenzidine was used as chromogen, followed by counterstaining with hematoxylin. Each step was performed at room temperature, except where otherwise stated.
Determination of GCS and Ugt1a6 mRNAs.
Total cellular RNA was extracted by RNAzolTM B (TEL-TEST, Inc., Friendswood). The RNA samples (20 µg) were subjected to electrophoresis and transferred to Zeta-Probe GT membranes (Bio-Rad Japan, Tokyo). The membranes were probed with [32P]-labelled cDNA against Ugt1a6 and the catalytic heavy and regulatory light chains of GCS; ß-actin cDNA was used as a positive control. We obtained the cDNA probe against each gene by RT-PCR, using mouse liver RNA as a template.
The primer used for each gene was as follows:
GCS heavy chain:
Forward primer 5'-ATGGGGCTGCTGTCCCATGG-3'
Reverse primer 5'-AGCCTGATGCTCTCCTAGTA-3'
GCS light chain:
Forward primer 5'-CTGCAGACCGGGAACCAGCT-3'
Reverse primer 5'-AGATCAGAGGTGCCTATAGC-3'
Ugt1a6:
Forward primer 5'-CTTCCTGCAGGGTTTCTCTTCC-3'
Reverse primer 5'-CAACGATGCCATGCTCCCC-3'
The hybridized membranes were processed to autoradiographs and quantitated by MacBas software.
Statistical analysis.
Results are expressed as mean ± standard deviation, where available. Statistical analyses of differences between values of the vehicle control group (0 mg/kg) or those before dosing (0 h) from mice of the same genotype were made by Dunnett's multiple comparison test. Comparison between baseline metabolic activities of wild-type and knockout mice were made using the Student's t-test. A value of p 0.05 was considered significant.
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RESULTS |
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Plasma ALT level markedly increased in the homozygous knockout mice at 8 h after dosing, although the change was not statistically significant because of large interindividual differences among animals. On the other hand, wild-type mice showed only a marginal increase after 24 h (Fig. 3A). No significant changes in ALT levels were detected in heterozygous mice at any of the time points tested. These results indicate that hepatic damage occurs earlier in homozygous knockout mice compared to wild-type animals. However, since the only histopathological change detected in the latter was slight hepatocellular necrosis, even after 24 h (Table 2
), it is possible that the hepatic injury in the wild-type mice after 8 h was too subtle to be detected by the analysis of ALT.
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Histopathological examination revealed a degeneration in centrilobular hepatocytes with small cytoplasmic vacuoles (grade: ±) in all homozygous knockout mice after 2 h, while most wild type and heterozygous knockout mice showed no abnormality at this time point (Table 3 and Fig. 4
). Various degrees of centrilobular hepatocellular necrosis became apparent in all homozygous knockout mice after 8 h, but not in mice of other genotypes. Collectively, these data demonstrate that nrf2 knockout mice exhibit similar time-course changes of toxicity as those seen in wild-type mice exposed to higher doses of APAP (Brady et al., 1988
; Cohen, 1998; Mitchell, 1973), thus indicating a shared underlying mechanism of toxicity.
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DISCUSSION |
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Covalent binding of reactive APAP metabolites to cellular proteins seems to be an important process in the induction of hepatotoxicity (Cohen et al., 1998). As many as 23 proteins, some of which are considered critical for cellular functions, have been shown to bind to APAP in mouse liver (Qiu et al., 1998
). The anti-APAP antibody immunoreactivity in our study was localized in the centrilobular region of the livers of homozygous nrf2 knockout mice and specifically overlapped with the site of hepatic damage. This observation is in agreement with the previous analysis of Bartolone et al. (1989), who demonstrated accumulation of APAP-bound proteins in the centrilobular area after an oral dose of 600 mg/kg APAP. The fact that the anti-APAP antibody only stained the livers of homozygous nrf2 knockout mice, but not of the wild-type mice, shows that larger amounts of APAP metabolites have accumulated in the former.
The reactive metabolite of APAP, N-acetyl-p-benzoquinoneimine (NAPQI), is generated by a cytochrome P450-dependent metabolic pathway (Cohen et al., 1998). The relative amount of APAP bio-activated is determined by the activities of other drug metabolizing pathways, such as glucuronidation and sulfation, which detoxify and eliminate APAP. In mice, approximately 60 to 80% of the total APAP is metabolized through the glucuronidation pathway (Hazelton et al., 1986
; Kim et al., 1995
; Manautou et al., 1996
), and most of NAPQI is excreted after GSH conjugation, without causing toxicity. In the homozygous nrf2 knockout mouse, analyses of these major metabolic parameters revealed general decreases in the levels of detoxification enzyme activities, with no change being observed in that of the cytochrome P450 pathway. This would explain the accumulation of the larger amounts of APAP-conjugated proteins in the cell and corresponding severe hepatic damage found in the nrf2 homozygous knockout mouse (Fig. 8
). Sulfation, a minor detoxification pathway of APAP, was not examined in the present study. Whether or not the sulfotransferase gene is ARE-regulated or Nrf2 has any effect on its expression needs to be clarified in future.
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Oxidative stress appears to be an important factor associated with APAP toxicity. Indeed, metallothionein (MT)-I/II knockout mice were recently shown to be highly sensitive to APAP, perhaps due to the lack of the antioxidant function of MT (Liu et al., 1999). In mice, the oxidative stress produced by reactive APAP metabolites may act as a strong inducer of Nrf2-regulated gene expression mediated through the ARE. However, induction of detoxification enzymes and antioxidant systems by xenobiotics might be impaired in the nrf2 knockout mouse. It is interesting to note that, in the nrf2 knockout mouse, recovery of NPSH level to normal following APAP exposure was markedly delayed. Two possibilities may explain this result. First, the normal function of hepatocytes might have been lost in the homozygous knockout mice and recovery of NPSH level needed regeneration of hepatocytes. Second, the nrf2 knockout mice might not have been able to activate the compensatory pathway involved in recovering the NPSH level. We cannot eliminate either possibility, and further roles of Nrf2 in protecting against xenobiotics remain to be elucidated.
In contrast to the unequivocal phenotypic difference between homozygous knockout and wild-type mice, the sensitivity of heterozygous knockout animals to APAP appears to be comparable to that of wild-type mice. Based on the mortality, clinical chemistry, and histopathology data, no differences existed between the heterozygous and wild-type mice following APAP administration. Thus, a single copy of the Nrf2 gene seems to provide sufficient protection against APAP hepatotoxicity.
Our study clearly demonstrates that Nrf2 protects against APAP-induced toxicity by increasing the expression of both drug metabolizing enzymes and antioxidants. Additional studies on the Nrf2-mediated gene regulatory system would provide further insight into the integrated defense mechanisms of biological systems against xenobiotics and xenobiotic-induced oxidative stress.
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ACKNOWLEDGMENTS |
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NOTES |
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1 To whom correspondence should be addressed. Fax. 81-297-27-4518. E-mail: enomoto{at}iinet.ne.jp.
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