Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0345904 (liver cancer)
 15,188 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hexachlorobenzene (HCB) induces hepatic porphyria and liver cancer in female rats, whereas toxicity is minimal in male rats. HCB is biotransformed to sulfur-containing metabolites originating from conjugation to glutathione (GSH). This study aimed to assess differences in GSH conjugation of HCB between male and female rats. Sprague-Dawley rats of both sexes were given (po, 10 ml/kg in corn oil) five consecutive doses of 100 mg/kg HCB [2 bid (7:30, 15:30) + 1 sid (7:30)]. This cumulative dose produced porphyria in female but not male rats after a delay period of 6 weeks. Animals were killed 0, 6, 12, 18, or 24 hr after the last dose. Hepatic GSH level showed a diurnal cycle in rats of both sexes, but it was more pronounced in males; the minimum level was observed at 12 hr after dosing. The GSH level in HCB-treated male rats was significantly lower than control at 6, 18, and 24 hr, whereas no significant differences were observed for HCB-treated female rats. Biliary excretion of pentachlorothiophenol, a metabolite originating from GSH conjugation of HCB, was higher in male than female rats. Liver cytosolic GSH transferase activity toward 3,4-dichloronitrobenzene was significantly higher than control level in male but not female rats given HCB. GSH transferase activity toward 1,2-epoxy-3-(p-nitrophenoxy)propane in male and female rats was not increased by HCB treatment. The liver HCB concentration at 24 hr after dosing was higher in male rats than in female rats but decreased faster thereafter. These results suggest that hepatic GSH conjugation of HCB is more important in male than in female rats. This may be related to the reduced liver porphyria observed in HCB-treated male rats compared to female rats.
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PMID:Sex-related difference in hepatic glutathione conjugation of hexachlorobenzene in the rat. 153 60

The influence of nutritional factors on aflatoxin B1 (AFB1)-induced liver tumours was investigated in rats. When a dose of 500 micrograms AFB1/kg body weight was given to rats in the absence of any anticarcinogen, 80 per cent of the rats developed liver tumours as compared to 0 to 40 per cent in those which received anticarcinogens. While beta-carotene totally inhibited the development of liver tumours ascorbic acid, selenium, and uric acid reduced the percentages of tumour-bearing rats to 13 per cent each. GSH and vitamin E also reduced these percentages to 20 and 40 per cent respectively. The reduction of tumour incidence by each anticarcinogen was associated with induction of increased microsomal enzyme activity. Inhibition of AFB1-induced liver cancer development thus seems to occur through microsomal enzyme induction and AFB1 activation.
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PMID:Association of reduction of AFB1-induced liver tumours by antioxidants with increased activity of microsomal enzymes. 212 79

A long-term study, using male Wistar rats, was initiated to determine whether the effects of dietary constituents on AFB1-induced liver cancer could be associated with altered microsomal enzyme activity. They were maintained on mice pellets mixed with specific dietary constituents for 7 days and then given a single carcinogenic dose of AFB1 (500 micrograms/rat). After three months, the dietary constituents were discontinued and the animals were left on mice pellets and drinking water only for a period of about 20 months. At the end of the trial period, it was observed that dietary mixtures containing small quantities of either beta-carotene, ascorbic acid, GSH, vitamin E, selenium salt, or uric acid, effectively inhibited the development of AFB1-induced liver cancer and induced increased microsomal enzyme activity. Whereas beta-carotene and uric acid were the most effective inhibitors, vitamin E was the least, yet a significant inhibitor of liver cancer. Hepatic levels of cytochrome P-450, aniline hydroxylase and chlorpromazine demethylase were significantly induced in rats fed fortified food followed by AFB1 treatment than in control animals. The inhibition of liver cancer by dietary factors was probably due to their ability to induce the activity of hepatic microsomal enzymes. Increased enzyme activity could lead to rapid activation of AFB1 metabolism, resulting in loss of activated AFB1 metabolites that attack cell components. Inhibition of liver cancer is therefore associated with induction of increased microsomal enzyme activity.
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PMID:Inhibition of AFB1-induced liver cancer and induction of increased microsomal enzyme activity by dietary constituents. 261 10

A vitamin A (retinyl acetate)-deficient diet enhanced liver cancer in rats exposed to aflatoxin B1 (AFB1) and also caused a 29% incidence of colon cancer. The following factors were considered in attempts to define conditions under which vitamin-A-deprived rats were more susceptible to colon cancer induced by AFB1: liver morphology, enterohepatic recirculation, level of reduced glutathione (GSH) in liver, and differing capacities for conjugation of aflatoxin to GSH. Enzyme concentrations in liver, in intestinal and colon mucosa, and in intestinal and colon contents suggested that AFB1 may have different metabolites and that there may be differing susceptibilities of colon mucosa to carcinogenesis. Binding studies supported this hypothesis. Previous studies have shown that colon epithelium from vitamin-A-deficient rats binds more AFB1 than colon epithelium from normal, vitamin-A-supplemented animals. In the present study, vitamin A supplementation to the vitamin-A-deficient rats before oral administration of 3H-AFB1 significantly decreased the binding capacity at 12 and 15 hours after dosing with the carcinogen. These results suggest that the effect of vitamin A on the metabolism of the carcinogen, particularly on binding of AFB1 to cellular macromolecules, may be the mechanism by which vitamin A modifies aflatoxin's carcinogenic potential, influenced in part through enzymatic mechanisms.
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PMID:Vitamin A and aflatoxin: effect on liver and colon cancer. 641 17

DNA single-strand (ss) breaks were detected in the livers of B6C3F1 mice immediately following exposure to 4000-8000 p.p.m. methylene chloride (MC) for 6 h. This damage was undetectable 2 h after exposure, suggesting an active DNA repair process. Similarly, DNA ss breaks were detected in whole lung homogenates taken from mice exposed to 2000-6000 p.p.m. MC. The DNA of mouse Clara cells incubated in vitro with MC was also damaged at concentrations of 5 mM MC and above. Pre-treatment of mice with the glutathione depletor buthionine sulphoximine (BSO) caused a decrease in the amount of DNA damage detected, suggesting a GST-mediated mechanism. DNA damage was also reduced in Clara cells when incubated in vitro with MC in the presence of BSO. In CHO cells induction of DNA damage was dependent upon exogenous MC metabolism by mouse liver S100 fraction (but not microsomes) in the presence of GSH. DNA ss breaks were not induced by MC in hamster hepatocytes in vitro at concentrations from 5 to 90 mM MC, nor in eight individual samples of normal human hepatocytes exposed to MC at similar concentrations. The ability of MC to induce DNA ss breaks in the four species studied is entirely compatible with the known carcinogenicity of this chemical in animals and offers experimental evidence to suggest that humans would not be susceptible to MC-induced liver cancer. The DNA ss breaks correlate with the metabolism of MC by the GST pathway and provide an explanation for the lack of sensitivity of hamsters and rats to MC-induced liver cancer.
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PMID:Methylene chloride-induced DNA damage: an interspecies comparison. 763 22

Liver tissues were obtained from 20 liver cancer patients from Thailand, an area where the incidence of this tumour is high and where exposure to aflatoxin occurs. The expression of hepatic cytochrome P450s (P450) and glutathione S-transferase (GST) was examined and this expression was compared to the in vitro metabolism of aflatoxin B1 (AFB1). There was a > 10-fold inter-individual variation in expression of the various P450s including CYP3A4 (57-fold), CYP2B6 (56-fold) and CYP2A6 (120-fold). Microsomal metabolism of AFB1 to AFB1 8,9-epoxide (as measured by AFB1 tris-diol formation) and aflatoxin Q1 (AFQ1), the major metabolite produced, was significantly correlated with CYP3A3/4 expression (P < 0.001) and, to a lesser extent, with CYP2B6 expression (P < 0.01). There was a significantly reduced expression of major P450 proteins in microsomes from liver tumours compared to microsomes from the paired normal liver when analysed by Western immunoblot analysis. The production of AFQ1 and AFB1 tris-diol was almost uniformly reduced in tumours, but interestingly, the production of AFP1 was significantly increased. The immunoreactive expression of the major human classes of cytosolic GSTs (alpha, mu and pi) was also analyzed in normal and tumorous liver tissue. The expression of GSTA (alpha) and GSTM (mu) class proteins was markedly decreased and GSTP (pi) increased in the majority of tumour cytosols compared to normal liver. The cytosolic GST activity (1-chloro-2,4-dinitrobenzene conjugation) was significantly lower in liver tumours compared to normal liver (193 +/- 149 versus 875 +/- 299 nmol/min/mg, P < 0.0001), as was glutathione peroxidase (GPx) activity (cumene hydroperoxide) (26 +/- 23 versus 70 +/- 26 nmol/min/mg respectively, P < 0.005). Ten out of 14 individuals (71%) were homozygous null when genotyped for GSTM1. There was no detectable conjugation of AFB1 8,9-epoxide to glutathione by cytosol either from tumorous or normal liver. Thus, capacity of human cytosols to conjugate reactive AFB1 metabolites to GSH resembled AFB1-sensitive species such as rat, trout and duck rather than resistant species such as mouse and hamster. These data indicate a strong capacity of multiple forms of human hepatic P450s to metabolize AFB1 to both the reactive intermediate AFB1 8,9-epoxide and the detoxification product AFQ1. These results suggest that in view of the lack of significant GST-mediated protection against AFB1 in human liver, variations in expression of hepatic P450, due either to genetic polymorphisms or to modulation by environmental factors, may be important determinants in the risk of liver cancer development in AFB1-exposed populations.
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PMID:In vitro metabolism of aflatoxin B1 by normal and tumorous liver tissue from Thailand. 826 34

The epidemiological studies performed thus far have presented only limited evidence for the carcinogenicity of trichloroethylene (TRI) to humans. However, these studies had drawbacks such as insufficient size of cohort, short observation period, and inadequate TRI exposure assessment; therefore, no concrete conclusion has been reached concerning TRI carcinogenicity to humans. Despite the limited epidemiological evidence as to the carcinogenicity of TRI, the International Agency for Research on Cancer (IARC) has changed the carcinogenicity classification of TRI from Group 3 (not classifiable as to carcinogenicity to humans) to Group 2A (probably carcinogenic to humans). In regard to the new classification by the IARC, the committee for occupational exposure limits of the Japan Society for Occupational Health has made a proposal that it is too early to classify the carcinogenicity of TRI as Group 2A and that it is proper to promote exposure control with the carcinogenicity being classified as 2B for the moment. There are species differences in TRI carcinogenicity, particularly between rats and mice. Although experimental studies have found no evidence that TRI induces liver cancer in rats, there is ample evidence that TRI promotes the development of liver cancer in mice, particularly in B6C3F1 mice. The carcinogenicity of TRI in this strain of mice may be based on an epigenetic mechanism rather on a genotoxic mechanism and the liver cancer may be induced only after TRI has been inhaled for a long period of time at concentrations high enough to cause cytotoxicity. Conversely, with no reports showing TRI-induced renal tumors in mice, the possibility has been suggested that this chemical induces such tumors in male rats. The species differences are mainly accounted for by differences in the metabolism of TRI between rats and mice. From a general survey of the literature, it can be concluded that TRI itself is not mutagenic. However, the conjugation of TRI with glutathione (GSH), a minor pathway of TRI metabolism, results in mutagenic metabolites in the kidney of rats. The acute toxicity of TRI is neurotoxicity based on its anesthetic action. An exposure to extremely high levels of TRI may cause the liver and kidney disorders. Repeated exposures to high levels of TRI may result in neuro-, hepato-, and/or nephrotoxicity. The main symptoms appearing after chronic exposure at low levels are neurological changes represented by subjective symptoms relating to central and autonomic nervous systems, or by a lowered conduction velocity of the nerves or a prolonged latency of the nerve responses. For the present, it is reasonable to use the neurological findings for establishing the reference values of TRI for both work and general environments. A value of 25 ppm (135 mg/m3) is proposed as a reference value for work environments, and 25-50 ppb (135-270 micrograms/m3) for the general environment (1/1,000 of the value for work environment).
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PMID:Assessment of the health effects of trichloroethylene. 924 13

In previous studies, we reported that fasting/refeeding has a role in sustaining the initiation of liver cancer by a subnecrogenic (noninitiating) dose of diethylnitrosamine (DENA). This research investigated whether the metabolic alterations imposed by fasting/refeeding provide an imbalance between the generation of carcinogenic molecules and the scavenger defense mechanisms in rat liver. Metabolism of DENA, levels of reduced glutathione (GSH) and GSH transferase (GST) activity, as well as basal and stimulated malondialdehyde (MDA) production, were examined. Rats fasted for 4 days showed a decrease in the liver levels of GSH, GST activity, monounsaturated fatty acids and % of labeled nuclei. After 1 day of refeeding, at which point DENA was administered, the levels of GSH recovered, GST activity remained below control values, basal and stimulated MDA production and content of total polyunsaturated fatty acids in liver phospholipids decreased. One day after DENA treatment, MDA production further decreased, although the % of labeled nuclei increased. No significant changes in the content of arachidonic acid, the main target of peroxidation, were observed at any time. The results indicated that the induction of the hepatocellular carcinoma was associated with a depression of GST activity and lipid peroxidation when rats were given 20 mg/kg of DENA after 1 day of refeeding after 4-day fasting.
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PMID:Liver cancer is induced by a subnecrogenic dose of DENA when associated with fasting/refeeding: role of glutathione-transferase and lipid peroxidation. 1038 Dec 5

We previously reported the isolation of a novel cerebroside (1-O-(beta-D-glucopyranosyl)-(2S,3R,4E,8Z)-2-N-palmityloc tadecasphinga-4,8-diene; LCC) from the fruits of Lycium chinense MILL. (Solanaceae) which protected primary cultured rat hepatocytes from the toxicity induced by carbon tetrachloride (CCl4). The present study was conducted to determine the mechanism(s) by which LCC might exert its hepatoprotective activity. To determine the effect of LCC on the glutathione (GSH) redox system, we measured the activities of enzymes involved in the system as well as the levels of hepatic mitochondrial GSH and malondialdehyde (MDA). The hepatotoxicant, CCl4, routinely decreased levels of total and reduced GSH. The levels of these compounds were significantly maintained at the levels of the control cultures following treatment with LCC. The decreased activities of glutathione reductase and glutathione peroxidase in CCl4-injured rat hepatocytes were significantly increased by the treatment of LCC. Furthermore, the elevated levels of MDA seen in CCl4-injured rat hepatocytes were reduced after treatment with LCC in a concentration dependent manner over a range of 1-10 microM. From these results, we postulate that LCC may preserve the hepatic mitochondrial level of GSH by scavenging reactive oxygen species produced during CCl4-induced toxicity and thereby reduce lipid peroxidation and cellular damage.
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PMID:A novel cerebroside from lycii fructus preserves the hepatic glutathione redox system in primary cultures of rat hepatocytes. 1048 Mar 30

Increased glutathione (GSH) level occurs early during liver regeneration and in many drug and/or radiation-resistant tumors. Whether GSH level is elevated in liver cancer is unknown. GSH levels and expression of GSH synthetic enzymes were measured in hepatocellular carcinoma (HCC) and normal liver. GSH levels doubled in HCC. The mRNA levels of g-glutamylcysteine synthetase heavy subunit (GCS-HS) and GSH synthetase (GS) doubled, whereas the expression of GCS light subunit was unchanged. Nuclear run-on assay showed that the rate of gene transcription doubled for both GCS-HS and GS. In HCC, there is increased binding to anti-oxidant response, AP-1 and NF-kB, three cis-acting elements in the 5'-flanking region of the human GCS-HS important for its transcriptional regulation. The role of GSH in cell growth was examined by using HepG2 cells. Cell GSH level was varied by treating cells with cystine (0 to 0.2 mM) with or without GSH ester or buthionine sulfoximine. Cell GSH level correlated directly with growth rate. Finally, preventing the increase in GSH after two-thirds partial hepatectomy blunted liver regeneration. Thus, GSH level is increased during liver growth as a result of up-regulation of GCS-HS and GS. This increase, in turn, facilitates growth.
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PMID:Mechanism and significance of increased glutathione level in human hepatocellular carcinoma and liver regeneration. 1109 88


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