Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P02794 (ferritin)
17,525 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Lipid peroxide formation was initiated by the addition of either ADP-complexed Fe3+ or cumene hydroperoxide to a suspension of isolated hepatocytes. The reaction was monitored by malonaldehyde measurements. Upon the addition of iron, malonaldehyde production in the cells started immediately but ceased within 30-60 min, and the response was dose-related with iron concentrations ranging from 19 to 187 muM. Malonaldehyde formation was associated with increased oxygen uptake and conjugated diene production. The addition in vitro of N,N,N',N'-tetramethyl-p-phenylenediamine, menadione or p-benzoquinone inhibited the iron-induced malonaldehyde production. It was also possible to demonstrate an apparent disappearance of malonaldehyde from fresh cells by addition of adequate amounts of N,N,N',N'-tetramethyl-p-phenylenediamine (100 muM). The attenuation of the iron-induced malonaldehyde production was found to be correlated with an increased binding of iron to an intracellular ferritin fraction. Further, malonaldehyde formation was also associated with a conversion of reduced glutathione to the oxidized form which, in turn, revealed a faster permeation out of the cells into the surrounding medium of the oxidized than of the reduced thiol. So, concomitant with the redox alterations, there was also an overall loss of glutathione from the cells. Cumene hydroperoxide-induced malonaldehyde production could be initiated by the addition of this peroxide in concentrations ranging from 150 muM to the liver cell incubate. With concentrations below 150 muM, a lag phase was present which seemed to be glutathione-dependent. It is concluded that iron enters the cell, then is probably reduced inside the cell by NADPH via the NADPH-cytochrome P-450 reductase, and in the reduced state initiates lipid peroxidation. The reaction is inhibited by intracellular mechanisms, the glutathione redox system being of principal importance, and possibly terminated by the iron-apoferritin complex formation.
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PMID:Further studies on lipid-peroxide formation in isolated hepatocytes. 0 Dec 55

On account of its easy access in aqueous solution to the two states ferrous (FeII) and ferric (FeIII), iron is ideally suited for the activation of molecular oxygen. It is, therefore, logical to seek links between the normal and pathological metabolism of iron and oxygen activation. The pathways of intracellular iron metabolism require changes in the oxidation state of iron both in its deposition in the storage form, ferritin, and in its mobilization from the storage form and use in the cell. Evidence is presented which shows that iron oxidation and deposition in ferritin involves activation of molecular oxygen with formation of a stable peroxo-complex as an intermediate in which the oxygen is bound between two iron atoms attached to adjacent polypeptide chains. The release of iron from ferritin is thought to involve reduction by a flavin, which is associated with the protein, and serves as a cofactor being alternately reduced by NADH or NADPH and oxidized by iron(III). The nature of the low-molecular-weight iron complex which serves to transfer storage iron to transferrin and to supply iron for intracellular use remains to be established. The consequence of excessive iron overload can be rationalized on the basis of oxidative free-radical reactions which provoke lesions typical of deregulated oxygen activation. In some cases these pathological defects can be reversed by iron chelators. Progress in the development of chelation therapy for iron overload are reviewed.
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PMID:Interactions between iron metabolism and oxygen activation. 25 65

By the use of ferritin-conjugated antibody (conjugate) indirect immunoelectron microscopy, NADPH-cytochrome c reductase was localized on rat liver microsomes. Most microsomes in the sections had from 1 to 12 conjugates on their outer surfaces. Among the conjugates, 83% was estimated to bind to NADPH-cytochrome c reductase at a molecular ratio of 1:1, 12% at the ratio of 2:1, and 5% at the ratio of 3 or 4:1. The correlation between immunochemical and morphological data confirmed that most of the NADPH-cytochrome c reducatase reacted with the conjugates. Subsequent morphological analyses have revealed that the enzyme is distributed homogeneously on the outer surfaces of microsomes but heterogeneously within microsomes in groups of three to five enzyme molecules.
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PMID:Immunochemical and immunoelectron microscope studies on localization of NADPH-cytochrome c reductase on rat liver microsomes. 81 76

Homogenization of guinea pig liver in isotonic sucrose solution followed by the separation of the subcellular fractions by differential centrifugation releases the liver L-asparaginase (L-asparagine amidohydrolase, EC 3.5.1.1) activity into the supernatant fraction. Electron micrographs of the liver L-asparaginase-antibody complexes, precipitated from the clear supernatant phase by addition of L-asparaginase-specific antiserum, show membrane-liek structures and some amorphous material. The attachment of L-asparaginase to the membrane-like structures is indicated by the ferritin-labeled antibody technique. The immunoprecipitates possess low activities of 5'-nucleotidase, alkaline phosphodiesterase I, NADPH cytochrome c reductase, glucose-6-phosphatase, and acid phosphatase. This observation suggests that L-asparaginase found in the liver supernatant fraction is associated with cytomembrane components. Analysis of guinae pig serum L-asparaginase-antibody complexes is polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate gives three distinct protein bands. These bands correspond to heavy and light chains of rabbit immunoglobulins and the L-asparaginase subunits. Analysis of the liver L-asparaginase-antibody complexes by the above procedure shows similar but more diffuse protein bands.
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PMID:Evidence for the association of L-asparaginase with cytomembrane components in the guinea pig liver soluble fraction. 81 93

A number of xenobiotics are toxic because they redox cycle and generate free radicals. Interaction with iron, either to produce reactive species such as the hydroxyl radical, or to promote lipid peroxidation, is an important factor in this toxicity. A potential biological source of iron is ferritin. The cytotoxic pyrimidines, dialuric acid, divicine and isouramil, readily release iron from ferritin and promote ferritin-dependent lipid peroxidation. Superoxide dismutase and GSH, which maintain the pyrimidines in their reduced form, enhance both iron release and lipid peroxidation. Microsomes plus NADPH can reduce a number of iron complexes, although not ferritin. Reduction of Adriamycin, paraquat or various quinones to their radicals by the microsomes enhances reduction of the iron complexes, and in some cases, enables iron release from ferritin. Adriamycin stimulates iron-dependent lipid peroxidation of the microsomes. Ferritin can provide the iron, and peroxidation is most pronounced at low pO2. Complexing agents that suppress intracellular iron reduction and lipid peroxidation may protect against the toxicity of Adriamycin.
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PMID:Ferritin, lipid peroxidation and redox-cycling xenobiotics. 164 77

Bovine heart microsomes have been found to contain a non-heme iron protein which serves as an electron acceptor for NADPH-cytochrome P-450 reductase and therefore stimulates NADPH oxidation. This protein, tentatively referred to as Microsomal Iron Protein (MIP), has been extracted with Triton N-101 and purified by ion exchange chromatography on CM- and DEAE-celluloses and gel filtration on Sepharose 6B. MIP is an Mr = 66,000 monomer with 17 atoms of Fe(III)/molecule. Incubation with dithionite removes iron from MIP and abolishes the stimulation of NADPH oxidation, but subsequent incubation with nitrilotriacetic-Fe(III) reincorporates iron and restores the stimulation of NADPH oxidation. Oxygen is the ultimate electron acceptor. In the presence of oxygen, the enzymatic reduction of MIP Fe(III) is followed by the reoxidation of Fe(II) at the expense of oxygen, generating superoxide anion and regenerating MIP Fe(III) for the continuous oxidation of NADPH. In the absence of oxygen, electron transfer from the reductase to MIP Fe(III) causes the release of Fe(II), which limits the ability of MIP to serve as an electron acceptor and stimulate NADPH oxidation. The--NH2-terminal of MIP has been sequenced, and no homology has been found with the sequence of other iron storage or transport proteins such as ferritin or transferrin.
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PMID:Bovine heart microsomes contain an Mr = 66,000 non-heme iron protein which stimulates NADPH oxidation. 193 64

ADR-529 [(+)-1,2-bis(3,5-dioxopiperazin-1-yl)propane], a nonpolar, cyclic analogue of EDTA, protects against anthracycline cardiotoxicity in vivo. The protective mechanism presumably involves chelation of iron by a hydrolysis product of ADR-529, thus preventing the formation of reactive iron/oxygen species which can damage membrane lipids. We investigated the effects of ADR-529 and its hydrolysis products (the tetraacid and the diacid diamide) on NADPH- and ADP-Fe(3+)-dependent lipid peroxidation of rat liver microsomes and liposomes in the presence of cytochrome P-450 reductase. Hydrolyzed ADR-529 products caused inhibition of lipid peroxidation when in excess of the iron concentration. However, no inhibition of lipid peroxidation was detected by similar concentrations of nonhydrolyzed ADR-529. Microsomes did not affect the inhibition of lipid peroxidation, suggesting that rat liver microsomes do not hydrolyze ADR-529. Similarly, the diacid diamide hydrolysis product of ADR-529 inhibited ferritin- and adriamycin-iron-dependent liposomal lipid peroxidation in a concentration-dependent manner. No correlation between partially reduced oxygen species (O2.- and .OH; as measured by electron spin resonance) and lipid peroxidation (as assayed by malondialdehyde formation) was observed, suggesting that liposomal lipid peroxidation was strictly an iron-dependent phenomenon. These results suggest that inhibition of lipid peroxidation by iron chelation may be related to the protective effects of ADR-529 on in vivo anthracycline toxicity.
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PMID:Effects of (+)-1,2-bis(3,5-dioxopiperazin-1-yl)propane (ADR-529) on iron-catalyzed lipid peroxidation. 196 87

Thiourea and superoxide dismutase were effective antidotes to paraquat toxicity in an HL60 cell culture system, whereas other hydroxyl scavengers were ineffective. The efficacy of thioureas was not due to blockage of intracellular paraquat uptake, inhibition of NADPH-P-450 reductase, or reaction with the paraquat radical. Thiourea also competitively inhibited the reduction of cytochrome c by the xanthine/xanthine oxidase superoxide-generating system, and the release of iron from ferritin by superoxide radicals. The reaction of superoxide with thiourea produced a sulfhydryl compound distinct from products formed by hydrogen peroxide or hydroxyl radicals. Spectrophotometric and chromatographic studies indicated the carbon-sulfide double bond was converted to a sulfhydryl group which reacted with Ellman's reagent. Additional confirmatory evidence for the sulfhydryl compound was obtained with carbon-13 NMR and mass spectroscopies. Thus, thioureas are direct scavengers of superoxide radicals as well as hydroxyl radicals and hydrogen peroxide. The rate constant for the reduction of thiourea by superoxide was estimated at 1.1 x 10(3) M-1 s-1. The implication of this finding on free radical studies, the mechanism of paraquat toxicity, and the metabolism of thioureas is discussed.
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PMID:Thioureas react with superoxide radicals to yield a sulfhydryl compound. Explanation for protective effect against paraquat. 215 25

Incubation of rabbit heart microsomes with Adriamycin and NADPH resulted in the oxidation of approximately 25% of protein thiols and 66% inhibition of Ca-ATPase activity. Thiol oxidation and Ca-ATPase inactivation were iron-dependent and could be catalysed by ferritin. Removal of contaminating catalase revealed that both processes required H2O2 which could be supplied by O2 under aerobic conditions. However, O2- was not involved. Butylated hydroxytoluene (BHT), alpha-tocopherol and beta-carotene inhibited lipid peroxidation of microsomes, but did not inhibit thiol oxidation or the inactivation of Ca-ATPase. Likewise, the hydroxyl radical scavengers benzoate, formate and mannitol were not inhibitory. Glutathione (GSH), however, prevented inactivation of Ca-ATPase. It is concluded that Adriamycin-enhanced redox reactions involving iron and H2O2 are responsible for oxidizing microsomal thiol groups and inhibition of Ca-ATPase. Disruption of Ca transport within the myocyte by this process could contribute to the cardiotoxicity of Adriamycin.
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PMID:Thiol oxidation and inhibition of Ca-ATPase by adriamycin in rabbit heart microsomes. 215 95

Iron-catalyzed free radical reactions, such as the peroxidation of membrane lipids or the inactivation of critical enzymes, have been implicated in the cardiotoxicity of Adriamycin. Fe3+ reduction is an important step in both processes. The reduction of Fe3+, Fe3+ ADP, or Fe3(+)-ferritin by rabbit heart microsomes, Adriamycin, and NADPH was 10% inhibited by ICRF-187 (ADR-529) in N2 and 77% inhibited by ICRF-198, the hydrolysis product of ICRF-159 (the racemic form of ICRF-187). Lipid peroxidation and CaATPase inactivation catalyzed by Fe3+, Fe3+ ADP, or Fe3(+)-ferritin were substantially inhibited by ICRF-198 but only partially inhibited by ICRF-187. The cardioprotective action of ICRF-187 during Adriamycin treatment may be a result of its hydrolysis to the d isomer of ICRF-198 which inhibits reduction of Fe3+, thus limiting the role of iron in tissue damaging free radical reactions.
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PMID:dl-N,N'-dicarboxamidomethyl-N,N'-dicarboxymethyl-1,2-diaminopropane (ICRF-198) and d-1,2-bis(3,5-dioxopiperazine-1-yl)propane (ICRF-187) inhibition of Fe3+ reduction, lipid peroxidation, and CaATPase inactivation in heart microsomes exposed to adriamycin. 215 15


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