UMLS:C0019204 - FACTA Search

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Query: UMLS:C0019204 (hepatocellular carcinoma)
71,386 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hematoxylin and eosin-stained sections representing ten cases of hepatocellular carcinoma showed many tumor cells with ground-glass cytoplasm identical to that found in hepatocytes containing hepatitis B surface antigen (HBsAg). However, the aldehyde fuchsin stain was negative, as were the were the immunoperoxisidase stains for HBsAg and core antigen (HBcAg). Electron microscopically, the ground-glass appearance corresponded to the presence of non-membrane-bound amorphous or fibrillar inclusions. Immunohistochemically, the ground-glass material reacted with antiserum to human fibrinogen, suggesting synthesis of this protein by the carcinoma cells. Although the ground-glass appearance in hepatocellular carcinomas may sometimes be associated with HBsAg, special stains or technics are necessary to confirm its presence.
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PMID:Ground-glass cells in hepatocellular carcinoma. 625 12

Fixation by periodate/lysine/paraformaldehyde, a method purported to cross-link specifically plasma membrane glycoproteins, was evaluated using Novikoff rat ascites hepatocellular carcinoma cells. Cells were treated with periodate/lysine, periodate/glycine, and periodate/lysine/paraformaldehyde and subsequently reduced with NaB3H4. The glycoproteins labeled with 3H were resolved by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and visualized by fluorography. The effects of reactant concentrations on 3H-labeling of cellular components, cell viability, and cross-linkage of 3H-labeled proteins were examined. The effect of increasing the localized density of plasma membrane glycoproteins on the extent of cross-linkage by periodate and lysine was investigated using cells in which patching of the plasma membrane glycoproteins had been induced by ferritin-conjugated concanavalin A/rabbit antiferritin antiserum. Also investigated was the periodate-independent to mixtures of periodate and lysine or glycine. Results of these studies did not support a mechanism of cross-linking involving reaction between the free base lysin and aldehyde groups on periodate oxidized carbohydrate residues but suggested a complex interaction between periodate oxidized plasma membrane glycoproteins and polymeric complexes of lysine and formaldehyde.U
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PMID:Evaluation of periodate/lysine/paraformaldehyde fixation as a method for cross-linking plasma membrane glycoproteins. 626 47

In isolated rat liver cells in which lipid peroxidation is stimulated by CCl4, a strong inhibition of S-adenosylmethionine decarboxylase (SAMD) activity occurs. Some purified aldehydes, which are produced during lipid peroxidation, are able to inhibit SAMD activity in Yoshida hepatoma cells. The most active aldehyde is hydroxypentenal (HPE). It inhibits by 50% SAMD activity at 0.5 mM concentration in entire hepatoma cells, or in hepatoma cell sap, and at 0.1 mM concentration in partially purified hepatoma cell sap fractions.
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PMID:Effect of aldehydes on polyamine metabolism. III. Inhibition of S-adenosyl methionine decarboxylase (SAMD) by CCl4 and by aldehydes produced during lipid peroxidation. 645 40

It is well established that many types of tumor cells have reduced lipid peroxidation capacity compared to their normal counterparts. Changes in the activity of enzymes metabolizing aldehydes produced by lipid peroxidation have also been reported in a variety of tumor cells. We have investigated the relationship between changes in lipid peroxidation and changes in aldehyde-metabolizing enzymes in normal hepatocytes and two representative rat hepatoma cell lines, McA-RH-7777 and JM2. Compared to hepatocytes, both 7777 and JM2 cells have significantly lower basal and prooxidant-induced levels of lipid peroxidation than normal hepatocytes. Using 4-hydroxynonenal (4-HNE) as substrate, both cell lines also have significantly reduced activities of alcohol dehydrogenase (ADH) and glutathione S-transferase (GST) compared to hepatocytes. JM2 cells have significantly increased aldehyde dehydrogenase (ALDH) and aldehyde reductase (ALRD) activities with 4-HNE. In 7777 cells the ALDH and ALRD activities are not different from hepatocytes. The changes in enzyme activity are inversely correlated with the sensitivity of cells to 4-HNE. JM2 cells, with increased ALDH and ALRD and decreased ADH and GST, are much more resistant to the toxic effects of 4-HNE than 7777 cells. Normal hepatocytes and JM2 cells are approximately equally resistant to 4-HNE even though hepatocytes rely primarily on GST-mediated aldehyde conjugation to metabolize 4-HNE. Coupled with previous results from our laboratories, the overall increased sensitivity of certain hepatoma cells to lipid aldehydes appears due to decreased ability of these hepatoma cells to remove toxic products of lipid peroxidation. Moreover, hepatoma cells with increased levels of aldehyde dehydrogenase and aldehyde reductase appear most like hepatocytes in their ability to metabolize lipid aldehydes.
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PMID:Role of aldehyde metabolizing enzymes in mediating effects of aldehyde products of lipid peroxidation in liver cells. 803 12

Dihydrodiol dehydrogenase(s) (DD) have been implicated in the detoxication of proximate (trans-dihydrodiol) and ultimate carcinogenic (anti-diol-epoxide) metabolites of polycyclic aromatic hydrocarbons (PAHs). These activities are catalyzed by soluble hydroxysteroid dehydrogenases and/or by aldehyde reductases. Molecular cloning indicates tha these enzymes have a high degree of sequence identity with members of the aldo-keto reductase super family. Substrate specificity studies indicate that non-K-region trans-dihydrodiols are the preferred substrates and that anti-dio-epoxides are not oxidized by the enzyme. The products of the DD reaction are transient catechols which auto-oxidize to PAH-o-quinones. As a consequence of this auto-oxidation superoxide anion, hydrogen peroxide and semiquinone radicals are generated. Studies on the biotransformation of (+/-)-trans-7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene indicate that in subcellular fractions from uninduced rat liver, DD plays a significant role in the metabolism of this proximate carcinogen. Thus, the formation of benzo[a]pyrene-7,8-dione is only superseded by the formation of tetraols which are derived from the anti-diol epoxide of benzo[a]pyrene [anti-BPDE;(+/-)-anti-7 beta, 8 alpha-dihydroxy-9 alpha, 10 alpha-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene]. PAH-o-quinones produced by DD can inactivate the enzyme. These PAH-o-quinones also vary in their reactivity towards cellular nucleophiles, their cytotoxicity and their genotoxicity. Non-bay region and methylated bay-region PAH-o-quinones generated by DD are the most reactive Michael acceptors, and are also the most cytotoxic in hepatoma cells. Cytotoxicity results from the 1e- redox-cycling of the PAH-o-quinone, concomittant production of superoxide anion and a subsequent alteration in redoxstate. PAH-o-quinones are also genotoxic thus [3H]-benzo[a]pyrene-7,8-dione readily forms deoxyguanosine-adducts with native calf-thymus DNA, i.e., to the same extent as anti-BPDE. The cytotoxic and genotoxic properties of PAH-o-quinones suggest that DD may initiate a hitherto unrecognized pathway of PAH activation.
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PMID:Dihydrodiol dehydrogenase and its role in polycyclic aromatic hydrocarbon metabolism. 822 64

4-Hydroxynonenal (4-HNE), produced during the oxidative lipid breakdown of biological membranes, modulates various biochemical processes in normal liver and in hepatoma cells. It is very probable that the effects of 4-HNE are related to the quantity formed in the cells and to the cells' ability to metabolize it. Aldehyde catabolism takes place within the cells through oxidative and reductive enzymes, and through conjugation with intracellular glutathione. In this paper, the various enzymatic pathways involved in the metabolism of 4-HNE were studied in normal hepatocytes and in hepatoma cells. The hepatocyte pathway undergoes a complex variety of change during neoplastic transformation. In hepatoma cells, generally, 4-HNE metabolism was due mainly to aldehyde dehydrogenases, whereas in normal hepatocytes 4-HNE metabolism was mainly due to alcohol dehydrogenase and glutathione-S-transferase. The increase in oxidative enzymes compared to normal tissue was not the same in all types of hepatoma: in HTC hepatoma cells, the enzyme levels were considerably higher; in AH-130 hepatoma cells of Yoshida, they were lower in subcellular particles and similar in the cytosol. Indeed, consumption of externally-added 4-HNE in hepatoma cells was proportional to their content of 4-HNE metabolizing enzymes.
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PMID:Ability of different hepatoma cells to metabolize 4-hydroxynonenal. 832 85

One histidine residue (H235) is conserved in all known aldehyde dehydrogenases (ALDH), from Escherichia coli to human, except for those from P. oleovorans and rat hepatoma. Kinetic studies with horse liver mitochondrial ALDH indicated that a group with a pKa of 7 may be involved in the active site. Using site-directed mutagenesis, the four conserved histidine residues of the six histidines in rat liver mitochondrial ALDH were converted to alanines. Only modification of H235 and H29 caused alterations in properties of the enzyme. H29A had a decreased pI suggesting that this residue may normally be protonated. Its Vmax increased, as did the Km for NAD+, while the Km for propionaldehyde decreased. H235A had the same pI as the native enzyme but the Vmax decreased by 50%. Like native enzyme, H235A was active in Hepes and Mops buffer as well as in phosphate buffer. Purified H235A was thermally less stable than was native enzyme. H235 was also changed to F, Y, E, K, and Q. All of these substitutions resulted in the formation of insoluble aggregates or inclusion bodies when they were expressed in E. coli. It appears then that the highly conserved histidine residues may not be functioning as a general base in the deacylation step as we originally suggested. Instead, both H29 and H235 may be of structural importance and the presence of a histidine residue at position 235 may be required for the newly synthesized peptide to fold and/or assemble into the native conformation of ALDH.
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PMID:Role of the highly conserved histidine residues in rat liver mitochondrial aldehyde dehydrogenase as studied by site-directed mutagenesis. 837 84

We examined age-related changes in the protein and the mRNA expression of aldose reductase in livers of Long-Evans with a cinnamon-like color (LEC) rats, which develop hereditary hepatitis and hepatoma with aging, using Long-Evans with an agouti color rats as controls. The levels of the protein and mRNA of aldose reductase increased after 20 weeks, at the stage of acute hepatitis, and were maintained at 60 weeks of age, while those of aldehyde reductase seemed to be constant at all ages. The expression of aldose reductase was marked in cancerous lesions in hepatoma-bearing LEC rat liver compared to uninvolved surrounding tissues. These results indicated that elevation of aldose reductase accompanied hepatocarcinogenesis and may be related to the acquisition of immortality of the cancer cells through detoxifying cytotoxic aldehyde compounds.
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PMID:Induction of aldose reductase gene expression in LEC rats during the development of the hereditary hepatitis and hepatoma. 864 63

A synthetic geranylgeranoic acid (GGA) induced apoptotic cell death in a human hepatoma cell line, HuH-7, but not in mouse primary cultured hepatocytes. Prior to chromatin condensation, GGA induced a dramatic loss of the mitochondrial membrane potential in 1 hour and in a dose dependent manner in HuH-7 cells, but not in the primary hepatocytes. Pretreatment with synthetic tetrapeptide cysteine protease inhibitor, either acetyl-Tyr-Val-Ala-Asp-chloromethylketone or acetyl-Asp-Glu-Val-Asp-aldehyde, blocked GGA-induced apoptosis without preventing a rapid loss of the mitochondrial membrane potential. alpha-Tocopherol prevented the cells from GGA-induced apoptosis as well as from a rapid loss of the membrane potential. The present study strongly suggests that GGA induces apoptosis in hepatoma cells through derangement of mitochondrial function and subsequent activation of the cysteine protease cascade.
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PMID:Rapid loss in the mitochondrial membrane potential during geranylgeranoic acid-induced apoptosis. 902 60

It has been shown previously that oxidative stress by ferrous iron in vitro leads to an inhibition of proliferation of murine ascites tumour cells in vivo. This effect is associated with increased lipid peroxidation in terms of formation of the highly reactive aldehyde 4-hydroxynonenal (HNE), which has been shown to inhibit the proliferation of numerous tumours and to induce differentiation. It was the purpose of this article to study the occurrence and metabolism of HNE and its inducibility by oxidative stress in hepatomas of different degrees of differentiation to find further evidence for a possible role of HNE in proliferation and/or differentiation, because it is known that in hepatoma cells with a very low degree of differentiation basal lipid peroxidation is hardly detectable, while in normal hepatocytes the basal level of thiobarbituric acid reactive substances (TBArS) is rather high. MH1C1 hepatoma cells and Yoshida AH-130 hepatoma cells were chosen as highly differentiated and poorly differentiated tumour cells, respectively, and rat hepatocytes served as a control for normal liver phenotype. Ferrous histidinate (Fe/His) did not have a cytotoxic effect on Yoshida and MH1C1 cells, as measured by the LDH release test. In cell culture studies Fe/His revealed a dose dependent inhibition of the proliferation of Yoshida cells. The incorporation of 3H-thymidine into DNA of these cells was also inhibited by Fe/His in a dose-dependent manner, while the precursor uptake into the cytoplasm was unaffected. The basal levels of HNE were in the order: hepatocytes > MH1C1 cells > Yoshida cells. Both hepatocytes and Yoshida cells responded to the presence of Fe/His with increased formation of TBArS. Compared with hepatocytes the response of the Yoshida cells was greatly reduced. The response of cells to Fe/His with respect to HNE formation was decreased in the order: hepatocytes > MH1C1 cells > Yoshida cells, but in this case the differences were not very pronounced. The metabolic capacity of the cells to consume HNE was also decreased in the order: hepatocytes > MH1C1 cells > Yoshida cells. In this case the differences were very pronounced. These findings support the view that Yoshida cells with a low degree of differentiation and a low basal level of HNE are released from an inhibitory effect of HNE operative in hepatocytes and that HNE is causally involved in the iron induced inhibition of proliferation of poorly differentiated hepatoma cells.
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PMID:Effect of oxidative stress by iron on 4-hydroxynonenal formation and proliferative activity in hepatomas of different degrees of differentiation. 916 94

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