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)

Hereditary hemochromatosis is the most common cause of iron overload in adults and is probably the second most common cause of iron overload in children in the United States next to transfusional overload. Serious morbidity from this disorder of iron absorption can occur in early as well as in middle and advanced age, iron overload having been reported in children with hereditary hemochromatosis as early as 2 years of age. Younger persons differ from older persons in that the risk for iron loading in females appears to be equal to the risk for males, in contrast to a preponderance of males among older patients. Also, younger patients frequently demonstrate cardiac and gonadal involvement, with cardiac failure commonly leading to death, whereas older patients are more likely to have liver involvement and diabetes mellitus, with liver failure and hepatoma commonly leading to death. Because early diagnosis and treatment can prevent the toxicities of iron overload, appropriate screening can be lifesaving. Transferrin saturation is the most reliable screening test. Liver biopsy with objective measurement of hepatic iron stores is the most important diagnostic criterion at present, although reliable noninvasive methods for quantitating body iron are being developed. Young individuals who should be screened for iron overload include patients with cardiac myopathies, hypogonadism, amenorrhea, loss of libido, diabetes mellitus, other endocrine disorders, cirrhosis of the liver, and arthritis, as well as the siblings, parents, and children of patients with hereditary hemochromatosis or iron loading of unknown cause.
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PMID:Hereditary hemochromatosis in children, adolescents, and young adults. 305 60

The susceptibility of rat liver tissue to oxidative stress during its neoplastic transformation was analyzed by both qualitative and quantitative measurements of the carbonyl products of lipid peroxidation. Diethylnitrosamine was used as initiating agent of hepatocarcinogenesis and lipid peroxidation levels were monitored in the homogenates from normal liver, hyperplastic nodules and tumour, incubated in the presence or in the absence of ascorbate or adenosine diphosphate-iron complex. While the basal levels of lipid peroxidation in the three experimental conditions were found to be quite similar, in the presence of the pro-oxidant stimulus a remarkable reduction in aldehyde production was shown not only by the hepatoma tissue but also by the preneoplastic nodules.
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PMID:Resistance to oxidative stress by hyperplastic and neoplastic rat liver tissue monitored in terms of production of unpolar and medium polar carbonyls. 309 Oct 76

The mRNAs for the heavy and light subunits of the iron-storage protein ferritin occur in cells largely as inactive ribonucleoprotein particles, which are recruited for translation when iron enters the cell. Cytoplasmic extracts from rat tissues and hepatoma cells were shown by an electrophoretic separation procedure to form RNA-protein complexes involving a highly conserved sequence in the 5' untranslated region of both ferritin heavy- and light-subunit mRNAs. The pattern of complex formation was affected by pretreatment of rats or cells with iron. Crosslinking by UV irradiation showed that the complexes contained an 87-kDa protein interacting with the conserved sequence of the ferritin mRNA. We propose that intracellular iron levels regulate ferritin synthesis by causing changes in specific protein binding to the conserved sequence in the ferritin heavy- and light-subunit mRNAs.
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PMID:Cytoplasmic protein binds in vitro to a highly conserved sequence in the 5' untranslated region of ferritin heavy- and light-subunit mRNAs. 312 26

Hepatocellular carcinoma cells of the PLC/PRF/5 cell line had 1.9 x 10(5) transferrin receptors per tumor cell with a Kd of 1.5 x 10(-8) M. At high concentrations of transferrin the binding was not saturable. Transferrin internalization by hepatoma cells was shown by time and temperature-dependent binding studies and by pronase experiments. Transferrin recycling was confirmed by the demonstration of a progressive increase in the cellular molar ratios of iron to transferrin and by chase experiments. Ammonium chloride interfered with iron unloading. The vinca alkaloid vincristine inhibited iron and transferrin uptake. The hepatocarcinoma cells appeared to lack asialoglycoprotein receptors and therefore internalized partially desialated transferrin by the regular route. Iron uptake from transferrin was markedly inhibited by the hydrophobic ferrous chelator 2,2' bipyridine but was relatively unaffected by the hydrophilic ferric chelator desferroxamine. The implication that ferrous iron was involved in postendocytic transvesicular membrane iron transport was supported by a study in which hepatoma cells were shown to take up large amounts of ferrous iron suspended in 270 mM sucrose at pH 5.5. The interaction at this pH between surface labeled hepatoma cell extracts and ferrous iron on a Sephacryl S-300 column suggested that the postendocytic transvesicular transport of iron through the membrane was in part protein mediated. The endocytosed iron in hepatoma cells was found in association with ferritin (33%), transferrin (31%) and a low molecular weight fraction (21%).
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PMID:Transferrin iron interactions with cultured hepatocellular carcinoma cells (PLC/PRF/5). 316 34

The experiments reported here identify nitric oxide as a molecular effector of activated macrophage induced cytotoxicity. Cytotoxic activated macrophages synthesize nitric oxide from a terminal guanidino nitrogen atom of L-arginine which is converted to L-citrulline without loss of the guanidino carbon atom. In addition, authentic nitric oxide gas causes the same pattern of cytotoxicity in L10 hepatoma cells as is induced by cytotoxic activated macrophages (iron loss as well as inhibition of DNA synthesis, mitochondrial respiration, and aconitase activity). The results suggest that nitric oxide is the precursor of nitrite/nitrate synthesized by cytotoxic activated macrophages and, via formation of iron-nitric oxide complexes and subsequent degradation of iron-sulfur prosthetic groups, an effector molecule.
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PMID:Nitric oxide: a cytotoxic activated macrophage effector molecule. 319 52

Uptake of 59Fe as well as 125I-labelled Fe-transferrin into HeLa cells points to the existence of a limited number of specific binding sites. This is in contrast to hepatocytes and hepatoma cells (Hep G2) where metal uptake from transferrin is very low, not saturable and cannot be prevented by an excess of the protein. Iron uptake into these cells is much higher from the citrate complex. The same is true for plutonium uptake into rat hepatocytes, while the uptake of this metal into Hep G2 cells is very small regardless of the ligand. In contrast to iron, plutonium presented as citrate is taken up into HeLa cells much better than plutonium presented as transferrin. The uptake of both metals from the citrate complex requires a high activation energy and can be prevented only by inhibition of oxidative phosphorylation. Other processes such as endocytosis, intactness of microtubuli, assembly of microfilaments or pH of the lysosomes do not seem to be of importance. Metal uptake from the citrate complex can be prevented only by the presence of other chelating agents and/or by transferrin. It can be assumed, therefore, that the metals react directly with constituents of the cell membrane, a process in which chelating agents can successfully compete if they form strong enough complexes with the metals.
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PMID:Factors influencing the uptake of iron and plutonium into cells. 327 98

There is increasing evidence that both iron overload and iron deficiency are associated with significant abnormalities of immune function. In diseases associated with iron overload there is increased susceptibility to both infection and neoplasia. The precise mechanisms are still being unravelled but iron overload has been shown to impair antigen-specific immune responses and to reduce the number of functional helper precursor cells. Similarly, iron in vitro in concentrations reported to be present in the serum of patients with iron overload impairs the generation of cytotoxic T-cells, enhances suppressor T-cell activity and reduces the proliferative capacity of helper T-cells. The predominant tumor seen in iron overload is primary hepatocellular carcinoma; however other aetiological factors appear to be involved in addition to iron overload, especially hepatic cirrhosis. Nevertheless, primary liver cancer occurs much more frequently in hemochromatosis than in other forms of cirrhosis. Iron deficiency is associated with an altered response to infection but the relationship is again a complex one. The cellular mechanisms involved have yet to be clearly defined, although impaired T and B cell function have been demonstrated.
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PMID:Iron status and cellular immune competence. 328 53

Plasmin cleaves rabbit serum apohemopexin (Mr = 60,000) at a single site producing a heme-binding domain (I, Mr = 35,000) and a second domain (II, Mr = 25,000) (W. T. Morgan and A. Smith (1984) J. Biol. Chem. 259, 12001-12005). The absorbance spectra of heme-domain I are indicative of a bis-histidyl coordination complex with the central heme iron atom. Chemical modification of the 5 histidine residues of apo-domain I with diethylpyrocarbonate abolished heme binding, supporting this assignment. Upon binding heme, domain I migrates more rapidly in sucrose gradients, and, in sedimentation velocity experiments, the s value of domain I increases from 3.17 +/- 0.04 to 3.71 +/- 0.09, a notably large increase which indicates that the domain becomes much more compact. This conformational change which plays a pivotal role in hemopexin function requires the bis-histidyl coordination with heme iron and leads to a tighter association between domain I and domain II shown by the co-migration of heme-domain I and domain II in sucrose gradients. In turn, the association of heme-domain I with domain II increases the thermal stability of the heme-domain I chromophore. Results of binding studies using mouse hepatoma cells and isolated domains indicate that domain I not only binds heme but also plays a vital part in the hemopexin-receptor interaction. The change in conformation of domain I upon heme binding and the association between domains I and II induced by heme are both notable determinants of the strength of the hemopexin-receptor interaction, but an intact "hinge region" between the domains is not necessary for receptor binding. The importance of both domains in bringing about the transport function of hemopexin is confirmed by the ability of three (two specific for domain I and one for domain II) of seven monoclonal antibodies raised against hemopexin to inhibit the hemopexin-receptor interaction.
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PMID:Use of hemopexin domains and monoclonal antibodies to hemopexin to probe the molecular determinants of hemopexin-mediated heme transport. 337 21

Sn-protoporphyrin IX (SnPP), an inhibitor of heme oxygenase and a potential therapeutic agent for neonatal hyperbilirubinemia, is bound tightly by hemopexin. The apparent dissociation constant (Kd) at pH 7.4 is 0.25 +/- 0.15 microM, but estimation of the Kd for the SnPP-hemopexin complex is hampered by the fact that at physiological pH SnPP exists as monomers and dimers, both of which are bound by hemopexin. SnPP is readily displaced from hemopexin by heme (Kd less than 1 pM). The hemopexin-SnPP interaction, like that of heme-hemopexin, is dependent on the histidine residues of hemopexin. However, as expected from the differences in the coordination chemistries of tin and iron, the stability of the histidyl-metalloporphyrin complex is lower for SnPP-hemopexin than for mesoheme-hemopexin. Nevertheless, when SnPP binds to hemopexin, certain of the ligand-induced changes in the conformation of hemopexin which increase the affinity of the protein for its receptor are produced. Binding of SnPP produces the conformational change in hemopexin which protects the hinge region of hemopexin from proteolysis, but SnPP does not produce the characteristic increase in the ellipticity of hemopexin at 231 nm that heme does. Competition experiments confirmed that human serum albumin (apparent Kd = 4 +/- 2 microM) has a significantly lower affinity for SnPP than does hemopexin. Appreciable amounts of SnPP (up to 35% in adults and 20% in neonates) would be bound by hemopexin in the circulation, and the remainder of SnPP would be associated with albumin due to the latter's high concentration in serum. Essentially no non-protein-bound SnPP is present. Importantly, SnPP-hemopexin binds to the hemopexin receptor on mouse hepatoma cells with an affinity comparable to that of heme-hemopexin and treatment of the hepatoma cells with SnPP-hemopexin causes a rapid increase in the steady state level of heme oxygenase messenger RNA. These results show that hemopexin participates in the transport of SnPP to heme oxygenase and in its regulation by SnPP.
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PMID:Interaction of hemopexin with Sn-protoporphyrin IX, an inhibitor of heme oxygenase. Role for hemopexin in hepatic uptake of Sn-protoporphyrin IX and induction of mRNA for heme oxygenase. 337 22

Lipoperoxidative damage caused by exposure of isolated hepatocytes or cultivated hepatoma cells to ADP-iron or to 4-hydroxynonenal induces the synthesis of some proteins which are different under these two conditions but are always a subset of the proteins induced in each type of cells upon heat-shock (heat-shock proteins). For at least one of these proteins (hsp 31), induced by 4-hydroxynonenal, the increase is dose-dependent and the effect of heat and the chemical seems to be additive. Lipoperoxidation may be implicated in the induction of some of the heat shock proteins, but reproduces only incompletely the response of protein synthesis typical of heat-shock conditions.
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PMID:Oxidative stress induces a subset of heat shock proteins in rat hepatocytes and MH1C1 cells. 337 79

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