Hereditary low level of plasma ceruloplasmin in LEC rats associated with spontaneous development of hepatitis and liver cancer

Ideal Experimental Rat Models for Liver Diseases

There are many limitations for conducting liver disease research in human beings due to the high cost and potential ethical issues. For this reason, conducting a study that is difficult to perform in humans using appropriate animal models, can be beneficial in ascertaining the pathological physiology, and in developing new treatment modalities. However, it is difficult to determine the appropriate animal model which is suitable for research purposes, since every patient has different and diverse clinical symptoms, adverse reactions, and complications due to the pathological physiology. Also, it is not easy to reproduce identically various clinical situations in animal models. Recently, the Guide for the Care and Use of Laboratory Animals has tightened up the regulations, and therefore it is advisable to select the appropriate animals and decide upon the appropriate quantities through scientific and systemic considerations before conducting animal testing. Therefore, in this review article the authors examined various white rat animal testing models and determined the appropriate usable rat model, and the pros and cons of its application in liver disease research. The authors believe that this review will be beneficial in selecting proper laboratory animals for research purposes.

Preliminary study of spontaneous hepatitis in Long-Evans Cinnamon rats: a blood exchange may improve fetal hepatitis

Long-Evans Cinnamon rats are a Wilson disease model highly susceptible to fulminant hepatitis around the age of 20 weeks, and hepatoma over the age of one year. Although prophylaxis has been established for the otherwise fatal hepatitis, effective treatment remains unknown. A blood exchange was tested to determine whether the prognosis of spontaneous hepatitis could be modified in icteric female rats. When bilirubinuria appeared, the rats immediately underwent surgery. Rats under anesthesia were first cannulated into the right atrium via the carotid vein, followed by 2.5 mL of blood exchange with heparinized fresh blood from Long-Evans agouti rats. Treated rats and controls were then observed for 2 months. Compared to the 50% mortality of untreated rats, all icteric rats that received a blood exchange survived the acute episode. We confirmed that Wilson disease animals are highly susceptible to acute hepatitis and show a poor prognosis. However, a single blood exchange improved spontaneous hepatitis in this animal model. This would serve as a first step for establishing a treatment for fatal hepatitis in animals. A blood exchange may improve fulminant hepatitis of Wilson disease model rats.

The Long-Evans Cinnamon rat: an animal model for Wilson's disease

The Long-Evans Cinnamon (LEC) rat is known to develop hepatitis and liver cancer spontaneously, phenomena attributed to abnormal copper metabolism. This mutant strain of rat shows some clinical features that are similar to those of Wilson's disease, including excessive copper in the liver, reduced excretion of copper into bile, a reduced level of serum copper and a remarkable decrease in serum ceruloplasmin activity. Molecular studies have revealed that the copper transporting P-type ATPase, atp7b, which is the rat gene homologous to human ATP7B, was found to be defective in the LEC rat. These observations have confirmed that the LEC rat is a rodent model for Wilson's disease. In addition, recent studies have suggested that the ATP7B protein is involved in the intracellular transport of hepatic copper. The absence or diminution of ATP7B function results in abnormal copper metabolism in the LEC rat and in patients with Wilson's disease.

Activation of serum response factor in the liver of Long-Evans Cinnamon (LEC) rat

We have studied the DNA binding activities of transcription factors in the liver of Long-Evans Cinnamon (LEC) rats, an animal model of Wilson's disease. Owing to a genetic defect, this strain of rats accumulates excessive copper in the liver and develops severe hepatitis and hepatocellular carcinoma. We found that the DNA binding activity of the serum response factor (SRF) was higher in the liver of LEC rats (approximately 2-fold) than in that of Wistar rats. There was a close correlation between the intensity of the activity and the concentrations of copper in the nuclear protein. The DNA binding activity of Sp1, on the other hand, showed similar levels in both LEC and Wistar rats. SRF may play an important role in the development of hepatocellular carcinoma in LEC rats by mediating the proto-oncogene c-fos induction. We suggest that the copper in nuclear protein may be involved in the activation of SRF.

Localization of renal Cu-binding metallothionein induced by Au injection into rats

The localization of Au-induced metallothionein (MT) in kidneys is reported. Au, Cu and Zn contents in kidneys and liver increased after Au injection. Especially the Cu content in the kidney increased in comparison with the Zn content. The yellow-orange autofluorescent signals which are a marker of Cu-MT were observed predominantly in the outer stripe of the outer medulla with a ring shape in the kidneys of Au-injected rats. MT mRNA was also located in only the outer stripe of the outer medulla. Neither autofluorescence nor MT mRNA was found in the kidneys of control rats. These results indicate that MT was biosynthesized in only the outer stripe of the outer medulla and the biosynthesized MT was bound to Cu. Representative Sephadex G-75 elution profiles of the renal cytosol of rats injected with Au showed that Au, Cu and Zn contents in MT fractions increased after Au injection. Interestingly, Cu in MT fractions dramatically increased in comparison with Zn in the MT fractions in spite of Au injection into rats. Only the Cu-containing MT fractions emitted a yellow-orange autofluorescence. The accumulated Cu in the kidneys of Au-injected rat was thought to be associated with renal toxicity.

Visualization of yellowish-orange luminescence from cuprous metallothioneins in liver of Long-Evans Cinnamon rat

We describe the first use of an emission probe, based on the cuprous thiolate chromophore, for direct microscopical observation of cuprous metallothioneins located in liver of 15-week-old (just before spontaneous hepatitis) Long-Evans Cinnamon rats. The rats show remarkable accumulations of copper and cuprous metallothioneins. In the mildly fixed liver, we visualized the same yellowish-orange luminescence as the specific emission from cuprous metallothioneins, following excitation in 330-385 nm region. In liver from Long-Evans Agouti rat, a counter part of Long-Evans Cinnamon rat, no similar luminescence was found. So, it was thought that cuprous metallothioneins accumulated in the Long-Evans Cinnamon rat liver might emit the yellowish-orange light. To verify this presumption, we tentatively defined three histochemical criteria, quenching tests by oxidation, protonation and mercury treatment, based on the coordination chemical characteristics of metallothioneins. The emission completely satisfied these criteria. Furthermore, the reliability of these criteria was supported by immunocytochemical and biochemical results. Consequently, all results sufficiently indicate that the yellowish-orange luminescence in the Long-Evans Cinnamon rat liver is the emission from cuprous metallothioneins.

Hepatocellular carcinoma induction in LEC rats by a low dose of 2-amino-3,8-dimethylimidazo[4,5-f]quinoxaline

A food-borne heterocyclic amine, 2-amino-3,8-dimethylimidazo[4,5-f]quinoxaline (MeIQx), induces hepatocellular carcinomas (HCCs) in F344 male rats at an incidence of 95%, when fed in the diet at 400 ppm for 61 weeks. In this study, the effect of a low dose of MeIQx was examined in Long-Evans with cinnamon-like coat color (LEC) rats, which have a mutation in Atp7b and suffer from hereditary hepatitis and HCCs, with high levels of copper accumulation in the liver. Rats of the LEC and Long-Evans with agouti coat color (LEA) sibling lines were given a diet containing 40 ppm MeIQx from the age of 23 weeks to 63 weeks, for a total administration period of 40 weeks. In LEC rats, HCCs were observed in 8/8 animals administered MeIQx, and 2/8 rats receiving a normal diet. The number of HCCs per rat (mean +/- SD) was 2.8 +/- 2.0 and 0.3 +/- 0.5, respectively. In the LEA rats, however, no tumors were induced by administration of MeIQx. These results indicate that damaged liver associated with compensatory cell proliferation is much more susceptible to chemical hepatocarcinogens, including MeIQx, than the normal liver.

The effects of alpha-phenyl-tert-butyl nitrone (PBN) on copper-induced rat fulminant hepatitis with jaundice

In the present study we demonstrated the protective effects of the spin-trapping agent alpha-phenyl-tert-butyl nitrone (PBN) against fulminant hepatitis with jaundice in LEC rats. In LEC rats an excess amount of copper is accumulated in the liver and causes hepatitis with severe jaundice. PBN was subcutaneously administered every 2 d at the concentration of 128 mg/kg, beginning with 13-week-old rats and continuing for 17 weeks. PBN prevented the loss of body weight, reduced death rate, and suppressed the increase in GTP and GOT values reflecting hepatic cell destruction. Ocular inspection also confirmed the suppressive effects of PBN on jaundice. In parallel with these phenomena, the amounts of thiobarbituric acid-reactive substances (TBARS) in livers of PBN-administered rats were found to be lower than those of non-PBN-administered rats. Little histological changes were observed in PBN-administered rats in comparison with non-PBN-administered rats. The protective effect of PBN on the formation of oxidative damage in liver DNA was observed but not so remarkable as that on lipid peroxidation. From these results, it was concluded that PBN had the liver-protective effects against fulminant hepatitis with jaundice. This suggested that free radicals play an important role in abnormally accumulated copper-induced liver injury and that PBN potentially has therapeutic value for the treatment of hepatitis.

Deletion of the Wilson's disease gene in hereditary hepatitis LEC rats

LEC rats develop disorder of cooper metabolism and hepatitis similar to those of human Wilson's disease. We recently demonstrated that the gene responsible for hepatitis (hts) of LEC rats is homologous to Wilson's disease gene (WD). The present study showed a deletion of at least 90 base pair of WD cDNA in LEC rats, which corresponds to nucleotides 3981 to 4071 in human WD cDNA sequence. This deletion was linked with hepatic copper accumulation and hepatitis, and considered to be a primary mutation for hepatic disorder in the LEC rat. The WD gene was assigned to rat chromosome 16 at band q12.2-q12.4 by fluorescence in situ hybridization (FISH).

The LEC rat has a deletion in the copper transporting ATPase gene homologous to the Wilson disease gene

The Long-Evans Cinnamon (LEC) rat shows similarity to Wilson disease in many clinical and biochemical features. We have cloned cDNAs for the rat gene (Atp7b) homologous to the human Wilson disease gene (ATP7B) and have used them to identify a partial deletion in the Atp7b gene in the LEC rat. The deletion removes at least 900 bp of the coding region at the 3' end, includes the crucial ATP binding domain and extends downstream of the gene. Our results provide convincing evidence for defining the LEC rat as an animal model for Wilson disease. This model will be important for studying liver pathophysiology, for developing therapy for Wilson disease and for studying the pathway of copper transport and its possible interaction with other heavy metals.

The WD gene for Wilson's disease links to the hepatitis of LEC rats

LEC rats develop an autosomal recessive hepatitis and subsequently liver cancer associated with copper accumulation in the liver similar to that of Wilson's disease. Using 71 backcross [(WKAH x LEC) x LEC] rats, linkage analysis of the hepatitis with the WD gene for Wilson's disease revealed identical segregation and no recombination event between these two genes. This result indicates that the WD gene is a prime candidate for the hts gene responsible for the hepatitis of LEC rats, and suggests that the hepatitis of LEC rats may be caused by a defect in a copper-transporting ATPase expressed in the liver.

Increase of UDP-glucuronosyltransferase activities toward xenobiotics during the development of hereditary hepatitis in LEC rats

UDP-glucuronosyltransferase activities were induced spontaneously during the development of hepatitis in LEC (Long Evans Cinnamon-like coat color) rats. Transition of hepatic microsomal UDP-glucuronosyltransferase activities was observed during the development of the LEC rat, which displayed spontaneous fulminant hepatitis with severe jaundice at about 12-16 weeks after birth. UDP-glucuronosyltransferase activities toward various substrates in 8-week-old LEC and LEA (Long Evans Agouti coat color; control) rats were similar. After 8 weeks of age, the transferase activities of LEA rats towards all substrates tested, except for bilirubin, decreased slightly during the next 24 weeks. In LEC rats, the transferase activities towards serotonin and several phenolic xenobiotics, such as 4-nitrophenol, 1-naphthol and 4-methylumbelliferone, but not 4-hydroxybiphenyl, increased about 2-fold at 16 weeks of age. During the 24 weeks following the first 8 weeks of age, the high level activities towards the xenobiotics continued, with the exception of bilirubin transferase activity which decreased gradually. These results suggest that a form of UDP-glucuronosyltransferase, which catalyzes the glucuronidations of serotonin and these xenobiotics except for 4-hydroxybiphenyl, is induced during the development of hepatitis in the LEC rat.

Decreased expression of liver glutathione peroxidase in Long-Evans cinnamon mutant rats predisposed to hepatitis and hepatoma

The Long-Evans Cinnamon rat is a mutant strain that contracts hereditary hepatitis and, eventually, spontaneous hepatoma. Recently, abnormal copper accumulations in Long-Evans Cinnamon rat livers were shown to be genetically linked to the development of hepatitis. Because reduced glutathione and glutathione-related enzymes are known to play important roles in cellular resistance to transition metal toxicity, we determined the levels of reduced glutathione and glutathione-related enzymes in seven different tissues of Long-Evans Cinnamon and control Long-Evans Agouti rats. Of the enzymes examined, only hepatic glutathione peroxidase was markedly decreased in Long-Evans Cinnamon rats. Glutathione peroxidase content in the liver of Long-Evans Cinnamon rats was 39%, 53% and 58% of the control values at 9 (normal stage), 19 (acute hepatitis stage) and 27 (chronic hepatitis stage) wk of age, respectively. Northern-blot analysis revealed that messenger RNA levels of glutathione peroxidase in the livers of Long-Evans Cinnamon rats were about 40% of the control levels. The activity of glutathione S-transferase was slightly decreased in the livers of Long-Evans Cinnamon rats. These data suggest that the liver of the Long-Evans Cinnamon rat is poorly protected against active oxygen species, the production of which is enhanced in the presence of excess copper. Glutathione-reductase activity in the livers of Long-Evans Cinnamon rats increased to 166% and 148% of the control levels at 19 and 27 wk of age, respectively. No significant changes were observed in the activity of gamma-glutamylcysteine synthetase or in the content of total reduced glutathione in the liver of the Long-Evans Cinnamon rat.(ABSTRACT TRUNCATED AT 250 WORDS)

Oxygen radical induced mutagenesis is DNA polymerase specific

Oxygen free radicals are produced in large amounts by normal cellular processes. Damage to DNA by these reactive species has been implicated in mutagenesis and may be important in the etiology of a variety of human diseases. In this study we investigate the types of mutations produced in vitro as a result of DNA damage by oxygen free radicals. We used a lacZ alpha forward mutation assay in which M13 viral DNA is damaged in vitro, replicated with purified DNA polymerase alpha or beta, transfected into E. coli, and screened for mutations by reduced alpha-complementation of beta-galactosidase activity. By determining the effects of damaged templates on the fidelity of individual DNA polymerases involved in replication and repair, we address the role of specific DNA polymerases in mutagenesis induced by reactive oxygen species. Aerobic incubation of DNA with 100 microM CuCl, 10 microM H2O2 and 100 microM ascorbic acid results in a 3.3-fold and a 3.6-fold elevation in mutation frequency for polymerases alpha and beta, respectively. The specificity and location of the induced mutations, however, are entirely different. For polymerase alpha, A to C, and C to A transversions and deletions of C are each elevated more than 10-fold over their frequencies on undamaged template. For polymerase beta, A to T, C to T, C to A, G to C, and G to T substitutions, and deletions of G are elevated by damage. The frequency of mutants containing two or more closely spaced substitutions is also markedly increased by template damage although the types of mutations and their positions are again specific to each DNA polymerase. We conclude that, for oxidative lesions, the frequency and the types of mutations are determined in part by the DNA polymerase that encounters the site of damage.

The LEC rat: a model for human hepatitis, liver cancer, and much more

The LEC rat is an inbred mutant strain with spontaneous hepatitis isolated from Long-Evans rats. Since approximately 40% of LEC rats die of fulminant hepatitis, the rat serves an animal model for studying the pathogenesis and treatment of human fulminant hepatitis. The remaining 60% of LEC rats survive and develop chronic (prolonged) hepatitis and subsequently develop liver cancer. Therefore, the LEC rat serves an important animal model for studying the significance of chronic hepatitis in the development of human liver cancer, which often develops in association with chronic hepatitis. The LEC rat can also be used as an animal model of Wilson's disease, since recent studies have disclosed high copper accumulation in the liver and low ceruloplasmin concentration in the serum of this mutant rat.

Histochemical demonstration of copper in LEC rat liver

Livers of LEC rats were histochemically stained for copper according to the modified Timm's method, which includes trichloroacetic acid (TCA) treatment. TCA pretreatment was effective in removing zinc and iron, leaving as the major metal in the liver. Hepatocytes in 3-month-old rats were stained intensely by the modified Timm's method, both in frozen sections and in paraffin-embedded specimens. The centrilobular hepatocytes were usually stained, but positive cells were also randomly distributed in the hepatic lobes, showing a mosaic pattern. The staining was intensified in 8- compared to 3-month-old LEC rats. In contrast hepatocytes from LEA rats, the normal counterpart of LEC rats, were faintly stained for copper. Proliferating cholangioles found in older LEC rats were shown to lack copper deposition, and hepatocellular carcinoma showed less copper deposits than the hepatocytes surrounding the tumor. The copper staining was augmented in livers of LEC rats subjected to copper-loading, but was less intense in the livers treated with D-penicillamine. The staining intensity under the various experimental conditions showed good correlation with the copper concentration. Lysosomal deposition of copper in hepatocytes was demonstrated by electron microscopic analysis for copper. Thus the modified Timm's method was shown to produce valuable results in demonstrating copper in LEC rat livers, providing important information for an understanding of the mechanism of copper deposition and hepatic disease of the animal.

Genetic linkage between copper accumulation and hepatitis/hepatoma development in LEC rats

The concentration of copper in the livers of Long-Evans rats with cinnamon-like coat color (LEC), in which hepatitis and then hepatomas develop spontaneously, was recently found to be abnormally high. Therefore, we examined the copper concentrations in the livers of LEC F1 backcrosses (LEC F1 x LEC) to determine the linkage of copper accumulation with development of hepatitis. Consistent with a previously reported ratio of rats with hepatitis to rats without hepatitis of about 1:1, hepatitis developed in 14 of 30 F1 backcrosses. The copper concentrations in the livers of all LEC F1 backcrosses with hepatitis were abnormally high and comparable to those of LEC rats. In contrast, the concentrations in all backcrosses without hepatitis were similar to those in normal Long-Evans with agouti coat color or Brown-Norway rats. Copper accumulation was shown to be closely linked with the development of hepatitis in LEC rats and appeared to be a possible cause of hepatitis. The concentrations of copper in the livers of Fischer 344 rats after carbon tetrachloride treatment were in the range for normal liver, indicating that a high copper concentration in the liver is specific to LEC rats and not a specific characteristic of hepatitis. Furthermore, we found that the size and level of ceruloplasmin mRNA in the livers of LEC rats were the same as those in LEA rats and that the size and level of ceruloplasmin polypeptide in their livers and plasma were almost the same as those in LEA rats. Therefore, these results suggest that the copper accumulation is not due to alteration of expression or to gross alteration of the ceruloplasmin gene.