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)

The incubation of lambda DNA in the reaction system of alloxan plus NADPH-cytochrome P450 reductase (fp2) in the presence of ferritin caused strand breaks after a lag time of about 5 min. Addition of ferritin to the reaction system at concentrations below 50 micrograms/ml caused the strand breaks of DNA in a concentration-dependent fashion. Catalase, scavengers of hydroxyl radicals (HO.) and iron-chelators almost completely inhibited the DNA strand breaks, but superoxide dismutase (SOD) did not, suggesting that the strand breaks are induced by the generation of HO. via the reaction of H2O2 and Fe(II), namely, the Fenton reaction. When the ferritin was incubated in the reaction system of alloxan plus fp2, the iron release from ferritin increased with incubation time depending on the amount of fp2. The addition of increasing concentrations of ferritin to the reaction system resulted in progressive increase in the iron release and a decrease in the electron spin resonance signal intensity of alloxan radical (HA.), the one electron reduced form of alloxan, suggesting that HA. generated in the reaction system is capable of releasing iron from ferritin. These results support the possibility that the iron released from ferritin may be involved in the diabetogenic action of alloxan.
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PMID:Effect of ferritin on lambda DNA strand breaks in the reaction system of alloxan plus NADPH-cytochrome P450 reductase: ferritin's role in diabetogenic action of alloxan. 774 95

Gas and tar phases of commercially available filter cigarettes were tested for ferritin-iron-releasing effects and polyunsaturated-fatty-acid oxidant capacity in vitro. A vacuum pump-dependent apparatus with Cambridge filters was used to separate gas and tar; the former was directly smoked into reaction mixtures, while the latter was extracted from Cambridge filters in aqueous medium and freshly used at 40 to 80% final concentrations. Both phases induced ferritin iron release, which was not antagonized by superoxide dismutase (SOD). In specific experiments, we have also shown that gas and tar extracts could cross an organic (i.e., chloroform)-phospholipid layer before mobilizing ferritin iron. Once delocalized from ferritin, iron could trigger lipid peroxidation; however, a marked prooxidant effect (inhibited by 20 microM deferoxamine mesylate and significantly decreased by 40 microM vitamin E) was observed only with gas, whereas tar extracts showed antioxidant effects. Accordingly, tar extracts could also antagonize lipid peroxidation driven by non-chelated iron or by peroxyl radicals. In the absence of ferritin, gas-induced lipid peroxidation was very low, and tar extracts were apparently ineffective. Thus, the intrinsic lipoperoxidative capacity of cigarette smoke is low and is due to gas; however, when smoke interacts with ferritin, a marked iron-driven peroxidation becomes manifest essentially with gas, tar components acting as antioxidants. The present data suggest that cigarette-smoke-mediated iron mobilization from ferritin may represent a specific prooxidant mechanism related to cigarette smoking in vivo.
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PMID:Cigarette smoke, ferritin, and lipid peroxidation. 784 2

Weekly intramuscular injections of 3 mg of iron as horse spleen ferritin into adult Geotria australis over 10 weeks, resulted in a progressive increase in that form of iron in the serum. However, as with control animals, the ferritin in the liver of injected lampreys consisted of one subunit type, whose M(r) (20,300) differed from those of the two subunit types of horse spleen ferritin. Thus, lampreys had converted horse spleen ferritin iron into endogenous ferritin iron, presumably in their liver. Marked rises in hepatic non-haem iron during the first 2 weeks and between weeks 8 and 10 of iron injections were accompanied by pronounced increases in superoxide dismutase (SOD) activity. This rise, which parallels the rise in SOD activity that occurs as iron increases during the very protracted upstream migration of G. australis, is consistent with the view that SOD protects against iron-mediated damage by removing the superoxide radical, which facilitates the formation of the highly toxic hydroxyl radical. A levelling off of the iron concentration between weeks 2 and 8 was accompanied by a decline in SOD activity, even though nonhaem iron levels were well above those of control animals. Enhanced SOD activity may therefore only be required when there is an elevated flux of iron in the liver through low-molecular-mass intermediates. A small amount of ferritin iron was converted into the more inert haemosiderin iron.
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PMID:Hepatic molecular conversion and detoxification of ferritin iron in adult lampreys (Geotria australis), following natural and induced iron loading. 784 99

Due to the chemical nature of oxygen, its tendency to accept a single electron to create the superoxide radical, and the fact that every aerobic cell must deal with this difficult situation, the production of oxygen-derived free radicals is an almost universal accompaniment to cellular pathology. In sepsis or immunologic disease, the activated phagocyte becomes a major producer of active oxygen species, contributing to oxidative injury to host tissues. The resulting oxidative stress is seriously exacerbated by the availability of iron, liberated from the body's store of ferritin. The antioxidant vitamins and the body's antioxidant enzymes (superoxide dismutase, catalase, and glutathione peroxidase) can help to restore and maintain proper oxidant/antioxidant balance.
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PMID:Oxygen-derived free radicals. 792 95

The influence of the superoxide-generating system, xanthine oxidase, on the release of iron from various vertebrate ferritins was determined both in the presence and absence of superoxide dismutase. The initial rate of iron release in the presence of this system was higher for ferritins from human, trout and rat liver than for those from lamprey liver and horse spleen. The proportion of this iron release that was superoxide-dependent in the case of rat, human and trout ferritins was 92, 86 and 84% respectively, whereas no such superoxide-dependent iron release occurred from the ferritins of lamprey liver and horse spleen. On the other hand, the rate of superoxide-independent iron release was of comparable magnitude for all of the species examined. The rate of superoxide-dependent iron release was related neither to the iron: protein ratios nor to the subunit size of the ferritins. However, it is significant that the ferritins with a high rate of superoxide-dependent iron release came from tissues known to be susceptible to iron damage. It is thus proposed that the resistance of lamprey liver ferritin to the mobilization of iron by superoxide ions accounts in part for the tolerance of the lamprey liver to high iron loads.
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PMID:Iron release from ferritin and its sensitivity to superoxide ions differs among vertebrates. 804 81

Glucose-6-phosphatase (G6Pase) is a microsomal enzyme which is very sensitive to inactivation by lipid peroxidation. Experiments were carried out to evaluate whether ferritin, which is the major storage form of iron within cells, could catalyze inactivation of G6Pase and to determine the mechanism responsible for this effect of ferritin. Incubation of microsomes with NADPH in the absence of ferritin led to decreased activity of G6Pase. Ferritin stimulated this inactivation of G6Pase in a time- and concentration-dependent manner. Ferritin did not stimulate G6Pase inactivation when NADH replaced NADPH as the microsomal reductant. Superoxide dismutase but not catalase or DMSO prevented the ferritin-stimulated inactivation of G6Pase suggesting a role for superoxide, but not H2O2 or hydroxyl radical, in the overall mechanism. Trolox, at concentrations which prevent lipid peroxidation, also prevented the ferritin-catalyzed inactivation of G6Pase. Inhibition of G6Pase by ferritin was further enhanced in the presence of ATP but was inhibited in the presence of EDTA or desferrioxamine; ferric-ATP stimulates, whereas ferric-EDTA inhibits microsomal lipid peroxidation. The redox cycling agent paraquat increased the ability of ferritin to inactivate G6Pase by a reaction prevented by superoxide dismutase, trolox, EDTA, and desferrioxamine, but not by catalase or DMSO. Ferritin stimulated microsomal light emission, a reaction reflecting lipid peroxidation, with time and concentration dependence, and sensitivity to scavengers (trolox, superoxide dismutase), iron chelators and paraquat, identical to the inactivation of G6Pase. These results indicate that one possible toxicological consequence of ferritin-catalyzed lipid peroxidation is inhibition of microsomal enzymes such as G6Pase.
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PMID:Ferritin-dependent inactivation of microsomal glucose-6-phosphatase. 818 31

Iron mobilized from ferritin has been shown to catalyze production of potent reactive oxygen intermediates. Experiments were carried out to evaluate the ability of ferritin to catalyze nuclear generation of hydroxyl radical in the presence of either NADPH or NADH. In the absence of redox cycling agents, ferritin did not catalyze nuclear oxidation of hydroxyl radical scavenging agents (2-keto-4-thiomethylbutyric acid, dimethylsulfoxide, ethanol) even if EDTA was added to chelate any released iron. The addition of menadione or paraquat resulted in a ferritin-dependent oxidation of chemical scavengers; menadione promoted the catalysis by ferritin with either NADPH or NADH, whereas paraquat was much more reactive with NADPH as the nuclear reductant. The presence of an externally added iron chelator was required for elevated rates of scavenger oxidation, with EDTA and DTPA being more reactive than ATP or citrate and desferrioxamine being inhibitory. The ferritin-catalyzed hydroxyl radical scavenger oxidation was sensitive to superoxide dismutase, catalase, and competitive scavengers. In the absence or presence of ferritin, rates of NADPH- or NADH-dependent H2O2 production were low; menadione increased H2O2 production with both NADPH and NADH, whereas paraquat was mostly effective with NADPH. Depending on the nature of the added chelating agent (e.g., EDTA, ATP) and the reductant, rates of nuclear production of .OH in the presence of redox cycling agent plus ferritin were 10 to 70% as high as rates found with redox cycling agent plus ferric-chelate (e.g., ferric-EDTA, ferric-ATP). Since reactive oxygen intermediates such as the hydroxyl radical can alter the structural integrity of the nucleus and interact with DNA, the ability of ferritin to promote nuclear generation of hydroxyl radical may play a role in the toxicity associated with iron as well as redox cycling agents.
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PMID:Ferritin stimulation of hydroxyl radical production by rat liver nuclei. 831 76

The essential nutrients zinc (Zn) and selenium (Se) provide an antioxidant function to animal cells by very different mechanisms. Se is an integral part of Se-dependent glutathione peroxidases, a group of water-soluble enzymes that catalyze the destruction of water-soluble and, in some cases, membrane-bound hydroperoxides. In dietary Se deficiency, Se-dependent glutathione peroxidase activities are decreased; at Se intakes above that which is required for optimal growth, there is a slight to moderate increase in Se-dependent glutathione peroxidase activities. Because of the enzymatic nature of the major role of Se as an antioxidant, Se can be categorized as having a general antioxidant function, controlling peroxide levels in cells by degrading hydroperoxides. On the other hand, Zn functions as an antioxidant only at specific sites, and is not a required cofactor for an antioxidant enzyme. Although Zn plays a structural role in the enzyme Cu, Zn superoxide dismutase, the activity of this enzyme is not decreased in Zn deficiency and its activity is usually depressed at high Zn intakes. Zn may function as a site-specific antioxidant by two mechanisms. Firstly, it competes with Fe and Cu for binding to cell membranes and some proteins, displacing these redox-active metals and making them more available for binding to ferritin and metallothionein, respectively. Secondly, Zn binds the sulfhydryl groups in proteins, protecting them from oxidation. Zn status does not directly control tissue peroxide levels but can protect specific molecules against oxidative and peroxidative damage.
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PMID:Zinc and selenium, site-specific versus general antioxidation. 831 37

The nonenzymatic reactions of dihydrolipoamide with a number of low-potential quinones, possessing either a fully or a partially substituted quinone ring at pH 7.0 were accompanied by consumption of oxygen in a significant excess of the quinone concentration, thus establishing their redox cycling. Contrary to this, only partially substituted quinones caused the consumption of oxygen in the presence of reduced glutathione due to reoxidation of reduced quinone-glutathione conjugates. Among compounds tested, 9,10-phenanthrene quinone catalyzed the most rapid consumption of oxygen in the presence of dihydrolipoamide with subsequent formation of lipoamide and H2O2. The rate constant of anaerobic reduction of phenanthrene quinone by dihydrolipoamide was 8.6 +/- 1.6 x 10(3) M-1 s-1 (pH 7.0, 0.1 M phosphate, 20% ethanol, 25 degrees C). The consumption of oxygen and formation of lipoamide were inhibited by superoxide dismutase, indicating that the redox cycling involves the autooxidation of 9,10-dihydroxy phenanthrene, mediated by superoxide. The reaction was accompanied by the reduction of added cytochrome c, which was insignificantly inhibited by superoxide dismutase, and the reductive mobilization of iron from ferritin, activated by superoxide dismutase. These data raise the possibility that dihydrolipoamide, usually regarded as an antioxidant, under certain conditions may exert moderate prooxidant activity, initiating the formation of radicals and activated forms of oxygen.
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PMID:Dihydrolipoamide-mediated redox cycling of quinones. 838 46

The identification of 6-hydroxydopamine (6-OHDA) and N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) as dopaminergic neurotoxins that can induce parkinsonism in humans and animals has contributed to a better understanding of Parkinson's disease (PD). Although the involvement of similar neurotoxins has been implicated in PD, the etiology of the disease remains obscure. However, the recently described pathology of PD supports the view for a state of oxidative stress in the substantia nigra (SN), resulting as a consequence of the selective accumulation of iron in SN zona compacta and within the melanized dopamine neurons. Whether iron is directly involved cannot be ascertained. Nevertheless, the biochemical changes due to oxidative stress resulting from tissue iron overload (siderosis) are similar to those now being identified in parkinsonian SN. These include the reduction of mitochondrial electron transport, complex I and III activities, glutathione peroxidase activity, glutathione (GSH) ascorbate, calcium-binding protein, and superoxide dismutase and increase of basal lipid peroxidation and deposition of iron. The participation of iron-induced oxygen free radicals in the process of nigrostriatal dopamine neuron degeneration is strengthened by recent studies in which the neurotoxicity of 6-OHDA has been linked to the release of iron from its binding sites in ferritin. This is further supported by experiments with the prototype iron chelator, desferrioxamine (Desferal), a free-radical inhibitor, which protects against 6-OHDA-induced lesions in the rat. Indeed, intranigral iron injection in rats produces a selective lesioning of dopamine neurons, resulting in a behavioral and biochemical parkinsonism.
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PMID:The possible role of iron in the etiopathology of Parkinson's disease. 841 92


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