Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0596263 (carcinogenesis)
 64,820 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Rat and hamster liver cytosolic glutathione (GSH) S-transferases purified by GSH-affinity chromatography have been examined for their effects on the microsome mediated binding of aflatoxin B1 (AFB1) to DNA and on the conjugation of AFB1-2,3-epoxide with GSH. Like previous studies with cytosolic preparations (Raj et al. (1984) Carcinogenesis 5, 879), our present study with purified GSH S-transferases showed 2-3-fold more inhibitory activity of AFB1-DNA binding with hamster than that with the rat. Concomitant with the inhibition of AFB1-DNA binding, increase in AFB1-GSH conjugation occurred. Subunit compositions of GSH S-transferases indicate preponderance of Yb and Ya subunits in the hamster and rat, respectively. The role of GSH S-transferases in modulating AFB1-DNA binding and AFB1 induced hepatocarcinogenesis is discussed.
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PMID:Effect of purified rat and hamster hepatic glutathione S-transferases on the microsome mediated binding of aflatoxin B1 to DNA. 309 33

Several structurally different tumor promoters altered to various degrees both glutathione (GSH) peroxidase (EC 1.11.1.9) and ornithine decarboxylase (ODC, L-ornithine carboxy-lyase, EC 4.1.1.17) activities in mouse epidermis in vivo. At 5 h after their application to the skin, the complete tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) and the stage 2 promoter mezerein were the most potent in inhibiting GSH peroxidase activity and inducing ODC activity. In comparison, the effects of anthralin, phorbol-12,13-didecanoate, benzoyl peroxide, H2O2, and phorbol-12,13-dibenzoate were much smaller, whereas the nontumor promoter phorbol, the hyperplastic agent ethyl phenylpropiolate, and the stage 1 promoter 4-O-methyl TPA did not alter GSH peroxidase and ODC activities. Various treatments including i.p. injections of 40 micrograms of Na2SeO3 and 100 mumol of GSH and/or topical applications of 40 mumol of D-alpha-tocopherol (vitamin E) 20 or 15 min, respectively, before tumor promoter treatment inhibited in an additive manner the effects of either TPA or mezerein on both GSH peroxidase activity and ODC induction. Moreover, these Na2SeO3, GSH, and/or vitamin E treatments inhibited in the same additive manner the tumor-promoting activity of TPA in the initiation-promotion protocol. However, when tested in the 2-stage promotion protocol with 4 doses of TPA followed by twice weekly applications of mezerein, Na2SeO3 plus vitamin E and GSH plus vitamin E treatments inhibited remarkably the tumor-promoting activity of mezerein but were ineffective in the first stage of promotion. The sequence and magnitude for the effects of 7,12-dimethylbenz[alpha]anthracene (DMBA) on GSH peroxidase and ODC activities were very different from those of the tumor promoters. In contrast with their antitumor-promoting activity, the treatments with Na2SeO3 plus vitamin E and GSH plus vitamin E failed to inhibit the carcinogenicity of a single large dose of DMBA and even enhanced the induction of skin tumors by repeated applications of subcarcinogenic doses of DMBA. These results suggest that the promoting component of DMBA carcinogenesis may be different from that of TPA. Moreover, the anticarcinogenicity of Na2SeO3, GSH, and vitamin E may be linked to their ability to facilitate or enhance the activity of the natural GSH-dependent antioxidant protective system of the epidermal cells during the later stages of skin tumor promotion.
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PMID:Effects of combined treatments with selenium, glutathione, and vitamin E on glutathione peroxidase activity, ornithine decarboxylase induction, and complete and multistage carcinogenesis in mouse skin. 309 11

We have studied the effects of plasma and of cumene hydroperoxide (CUM) on adenosine diphosphate ribosyl transferase (ADPRT) from mononuclear leukocytes (HML) of patients with colonic adenomatous polyps (n = 22), with colonic hyperplastic polyps (n = 5) and with neither type of polyp (controls) (n = 6). ADPRT was measured after incubation of HML with plasma alone (termed the plasma value), and with plasma plus CUM (50 microM) (the activated value); the difference elicited by CUM was termed the induced value. There was no significant difference in values between the control and hyperplastic polyp groups: these were combined for further analysis. The plasma (P = 0.038), activated (P = 0.009) and induced (P = 0.0024) values of the combined group all differed significantly from those of the adenoma group. At low exposures, CUM stimulated both ADPRT and unscheduled DNA synthesis and, at higher exposures, inactivated both. Pretreatment of HML with vitamin E protected against these effects of CUM, while pretreatment with diamide (which depletes GSH) accentuated the effects. This study demonstrates a differential reaction of ADPRT in patients harboring colonic adenomas and suggests that the origin of this difference may lie in cellular responses to oxidative stress.
Carcinogenesis 1988 Mar
PMID:Effects of cumene hydroperoxide on adenosine diphosphate ribosyl transferase in mononuclear leukocytes of patients with adenomatous polyps in the colon. 312 91

Rainbow trout are known to be more susceptible to aflatoxin B1 (AFB1) hepatocarcinogenesis than coho salmon, or trout pre-fed the carcinogenesis inhibitors beta-naphthoflavone (beta NF), Aroclor 1254 or indole-3-carbinol. The study reported here examined the relationship between AFB1-glutathione (GSH) conjugation and AFB1 carcinogenesis in salmon, trout and trout pre-fed the three inhibitors. The AFB1-glutathione (AFB1-SG) conjugate was not detected in salmon bile and was present in trout bile in amounts representing less than 0.2% of the administered dose 24 hr after injection of [3H]AFB1. The major conjugates were glucuronides of aflatoxicol and aflatoxicol M1. In incubations of isolated liver cell fractions, less than 0.5% of the original AFB1 dose was recovered as AFB1-SG in salmon and trout preparations, compared to 25% in mouse-liver cell preparations. The GSH concentration in livers of the control trout was higher than that for coho salmon but lower than that for trout pre-fed beta NF. Liver GSH-transferase activity in control trout livers was much higher than in the control salmon livers, but was only 62% of that found for trout fed beta NF. There was no apparent relationship among the various groups between liver GSH concentrations, liver GSH-transferase activity, or biliary GSH conjugate, and the degree of carcinogenic response of AFB1. Thus current evidence does not indicate a major role for aflatoxin B1 epoxide-GSH detoxification in coho salmon, or rainbow trout fed any of the three anticarcinogens tested. These results in salmonid fish are contrary to those which suggest AFB1-SG conjugation as a major determinant of AFB1 carcinogenesis and its dietary modulation in rodent models.
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PMID:The significance of glutathione conjugation for aflatoxin B1 metabolism in rainbow trout and coho salmon. 313 Feb 99

Oxidative stress has been suggested to play an integral role in the cancer process. It may be particularly significant during tumor progression, where there is likely to be a large amount of free radicals generated by infiltrating inflammatory cells and dying tumor cells. In order to test this hypothesis, a variety of free radical scavengers and antioxidants were assessed for their ability to inhibit tumor progression. The murine skin multistage carcinogenesis model was used to generate papillomas, which are a population of putative precancerous lesions. Various test agents were applied topically to papillomas in order to determine if they would decrease the incidence of the malignant lesion, squamous cell carcinoma. The agents tested included: reduced glutathione (GSH), butylated hydroxyanisole, vitamin E, copper(II) (3,5-diisopropylsalicylate)2, sodium benzoate, N-acetyl cysteine and disulfiram. Under the conditions of our experiments, only GSH and disulfiram inhibited tumor progression to a significant degree. Additional studies indicated that GSH prevented cancer development in a dose-dependent manner. Another experiment demonstrated that when papillomas received repeated topical applications of diethylmaleate, a GSH-depleting agent, tumor progression was enhanced. Collectively these data suggest that sufficient glutathione levels may be important in preventing cancer formation.
Carcinogenesis 1988 Sep
PMID:Effect of exogenous glutathione on tumor progression in the murine skin multistage carcinogenesis model. 313 44

To better understand the role of free radicals in liver carcinogenesis, endogenous antioxidant defense systems and the susceptibility of membranes to lipid peroxidation were evaluated in early lesions and in malignant tumors induced by the Solt-Farber resistant hepatocyte protocol. These parameters were also measured in the liver surrounding these tumors. In comparison with the normal liver, both nodules and carcinomas show a different biochemical pattern consisting of decreased glutathione peroxidase (GSH peroxidase) and catalase activities plus increased glutathione reductase (GSSG reductase) activity. In contrast, 1 week after the application of the initiation-selection protocol, the liver displays a high level of glutathione (GSH), high GSSG reductase activity, a reduced production of malondialdehyde and no changes in superoxide dismutase and GSH peroxidase activities. These data suggest that the liver is well protected against reactive oxygen species. During the carcinogenic process, the liver parenchyma surrounding the altered foci recovers from most of the modifications induced by the initiation-selection treatment. These results add additional support for the hypothesis that the appearance of early alterations in the liver, after a carcinogenic treatment, might be an adaptive response to a hazardous environment in which selected cell populations are transformed into nodules and/or carcinomas.
Carcinogenesis 1988 Nov
PMID:Analysis of antioxidant defense systems during rat hepatocarcinogenesis. 318 Mar 39

The effects of homocysteine (Hcy) on one non-transformed (Cl 8) and two malignant clones (Cl 16 and Cl T422) of the C3H/10T1/2 mouse embryo fibroblasts, were examined with regard to toxicity, ability to support growth and effects on methionine (Met) metabolism and glutathione level. Homocysteine in its reduced form (Hcy-SH) was toxic to all cell lines, and the LD90 was estimated to be 1.0 X 10(-4) M for Cl 8 and Cl 16 cells measured by plating efficiency, 0.8 X 10(-4) M for Cl 8 and 0.3 X 10(-4) M for Cl 16 when measured by total cell growth. At toxic concentrations, Hcy-SH showed a drastic effect on cell morphology both in the presence and absence of Met. The same effect was demonstrated with L-cysteine. No toxic effect was seen with homocystine (Hcy-SS-Hcy) or homocysteine thiolactone (Hcy-tl) at similar concentrations. Hcy-tl supported growth of both the non-transformed and malignant cells in Met-deficient medium but with decreasing efficiency in the order Cl 8, Cl 16 and Cl T422. The growth rate constant compared to that of Met-supplemented medium was 0.62 for Cl 8, 0.44 for Cl 16 and 0.38 for Cl T422 cells. The intracellular level of S-adenosylhomocysteine (AdoHcy) increased in all three cell lines in Hcy-tl-supplemented medium. The S-adenosylmethionine (AdoMet) content increased in Cl 8 cells, was constant in Cl 16 cells and decreased in Cl T422 cells under the same conditions. This resulted in a constant ratio of AdoMet/AdoHcy in the non-transformed cells (Cl 8) whereas this ratio decreased by 40% in Cl 16 and by 72% in Cl T422 cells when Hcy-tl replaced Met in the medium. The ability of Hcy-tl to support growth thus seemed to correlate well with alteration in Met metabolism in this cell culture system. The intracellular level of glutathione (GSH) was measured during exponential growth, but showed small variations between non-transformed cells and Cl 16 cells. However, Cl T422 cells showed a distinct lower level of GSH in Met-supplemented medium, and this increased 3- to 4-fold when Met was replaced with Hcy-tl.
Carcinogenesis 1988 Jan
PMID:Growth support and toxicity of homocysteine and its effects on methionine metabolism in non-transformed and chemically transformed C3H/10T1/2 cells. 333 51

Administration of the nephrotoxicant mercuric chloride (HgCl2) was found to increase microsomal epoxide hydrolase (EH) activity in the kidneys of Fischer 344 (F344) and Sprague-Dawley (SD) rats, but the increases observed were 2- to 4-fold greater in SD rats than in F344 rats. This study was designed to characterize HgCl2-mediated increases in renal EH activity, and to investigate possible biochemical mechanisms underlying the strain difference. In male SD rats killed 24 h after the last of three daily i.p. injections of HgCl2 (0.1-1 mg/kg), increases in renal EH activity were dose dependent, reaching a maximum of 550% of control. Renal EH activities in identically treated F344 rats were enhanced only to 200% of control values, however, the extent of nephrotoxicity was similar in both strains. Following a single HgCl2 treatment (1 mg/kg), maximal increases in renal EH activities were observed in SD rats (450% of control) at 3 days, and in F344 rats (225%) at 1-2 days. Hepatic glutathione (GSH) concentrations were unaffected by HgCl2 treatment, whereas renal GSH was slightly elevated in both strains. Hepatic metallothionein (MT) concentrations were increased at 1 day to 300% and 400% of control in F344 and SD rats, respectively. Maximal renal MT concentrations were observed at 2 and 3 days in F344 (300% of control) and SD (225%) rats, respectively. Pretreatment with Zn(OAc)2, a potent inducer of renal and hepatic MT, reduced the nephrotoxicity of HgCl2, but did not alter HgCl2-mediated renal EH increases in either strain. In addition, possible strain differences in 203HgCl2 distribution were assessed, but 203Hg distribution was similar in both strains. These studies have demonstrated that renal EH activity is induced by HgCl2, and that there is a strain difference in this response. Differences in MT, GSH and organ distribution of Hg do not account for the strain difference. The possibility remains that other, yet to be defined, protection pathways may exist. Alternatively, renal EH may be differentially regulated between the two strains.
Carcinogenesis 1988 Feb
PMID:Strain difference in rat renal microsomal epoxide hydrolase elevation after mercuric chloride treatment. 333 2

Intraperitoneal injection of ethionine to male rats for up to 12 days caused a pronounced fall in S-adenosylmethionine (AdoMet) in liver, but did not or only slightly affect AdoMet in kidney and spleen. Liver and to a lesser degree kidney showed a dose-dependent, massive accumulation of the metabolic product, S-adenosylethionine (AdoEth), and this metabolic response was most pronounced within the first days of exposure. Trace amounts of AdoEth was demonstrated in the spleen. Both S-adenosylhomocysteine (AdoHcy) and homocysteine (Hcy) in the liver were markedly increased in a dose- and time-dependent manner. There was a moderate increase in Hcy content in spleen and kidney, whereas the AdoHcy levels in these tissues were not affected. The amount of reduced glutathione (GSH) was significantly increased in liver and kidney. This response in liver was evident within 2 days of ethionine exposure and then leveled off whereas there was a gradual increase in GSH in kidney. The GSH content in spleen was unaltered. In addition to a massive build-up of AdoEth, the unique features of the metabolic response of the liver are a pronounced decrease in the AdoMet/AdoHcy ratio (from 15 to 2) associated with an elevated Hcy content and a rapid increase in the amount of GSH. The possibility that the metabolic response of the liver could be assigned to the existence of isozymes or metabolic pathways unique to hepatic cells is discussed.
Carcinogenesis 1988 Feb
PMID:Differential metabolic response of rat liver, kidney and spleen to ethionine exposure. S-adenosylamino acids, homocysteine and reduced glutathione in tissues. 333 5

The mucosal glutathione content of the gastrointestinal wall amounted to 50-60% of its concentration in the liver. GSH S-aryltransferase activity (CDNB) was very low in the glandular stomach, colon and rectum amounting to only 5% of liver enzyme activity. There was a marked postpyloric increase in GSH S-aryltransferase activity with an oral-aboral decline along the small intestine. GSH peroxidase was much lower in the mucosa of the small and large intestine as compared to the stomach or liver, whereas GSSG reductase was more than twice as high in the gastrointestinal mucosa as compared to the liver showing a gradual increase in activity from proximal to distal segments. The low GSH S-transferase activities found in the stomach, colon and rectum may account for the high and exclusive susceptibility of these segments to carcinogenesis and the deficient inducibility of these enzymes in the gastrointestinal wall may reflect an insufficient adaption towards higher exposure to toxic or even carcinogenic xenobiotics.
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PMID:Glutathione and GSH-dependent enzymes in the gastrointestinal mucosa of the rat. 337 Jun 30


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