UNIPROT:P02794 - FACTA Search

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

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

Transmission electron microscopy has been used to study intracellular sickle hemoglobin polymer in unfractionated cells from the arterial and venous blood of patients and after external deoxygenation. We detect polymerized hemoglobin in up to 10% of the cells in the venous circulation, especially in cells that are "cigar-shaped" and appear to be irreversibly sickled. We could not see well-defined polymer in mixed arterial samples; nevertheless, we found electron opaque spots, which could be ferritin granules, hemosiderin, or small aggregates of hemoglobin S. However, upon sequential chemical deoxygenation using 1.0% sodium metabisulphite, polymer formation was seen at oxygen saturation values of 75%-85%. Cells that were physically deoxygenated using gas mixtures containing nitrogen-carbon dioxide-oxygen mixtures were found to contain distinct polymers of deoxyhemoglobin S at oxyhemoglobin saturation values of 50%-75%. As deoxygenation increases, we detect short, randomly arranged polymer in a loose network, with occasional long polymers. Upon further deoxygenation, the length and number of polymer forms increased. Between 0% and 50% saturation, most erythrocytes were full of long, parallel, closely packed polymers that tend to align and run parallel to the cell membrane. In both chemical and physically deoxygenated blood samples, cells were seen at 50%-75% oxyhemoglobin saturation that retained their normal biconcave disc shape, although they contained significant amounts of polymer. The structural changes in sickle erythrocytes seen in vitro due to physical or chemical deoxygenation of cells, may reflect in vivo intracellular changes in the sickle cell patient.
...
PMID:Electron microscopic studies of the intracellular polymerization of sickle hemoglobin. 338 46

The human hepatoma cell line Hep 3B, which has the hepatitis B virus genome, shows over 80% decrease of copper/zinc superoxide dismutase activity, over 90% decrease of manganese superoxide dismutase activity, over 70% decrease of catalase activity, absence of glutathione peroxidase and glutathione S-transferase activities, over 270-fold increase of ferritin content and 25-fold increase of total iron compared to normal autopsy liver. These conditions of low antioxidant enzyme activities and iron overload are those which support the accumulation of oxygen free-radicals and DNA damage commonly considered to be carcinogenic mechanisms.
...
PMID:Antioxidant systems in tumour cells: the levels of antioxidant enzymes, ferritin, and total iron in a human hepatoma cell line. 350 92

Some chemicals that contaminate our environment exert their toxic effects by virtue of their ability to form free radicals. In the absence of sufficient quenching reactions, these reactive radicals can attack biomolecules, resulting in their oxidative degradation. Biological membranes which contain polyunsaturated fatty acids are most susceptible to oxidative degradation (lipid peroxidation), although oxidation of DNA may have more severe biological consequences. Free radicals species can be generated by at least two mechanisms in vivo. The first, of which carbon tetrachloride (CCl4) is the classic example, is the biotransformation of the chemical to a free radical species. Metabolism of CCl4 to the trichloromethyl radical by the hepatic mixed-function oxidase system results in the initiation of lipid peroxidation, protein-lipid cross linkages, and trichloromethyl adducts with DNA, protein, and lipid. The second mechanism for forming free radicals involves their reduction to less stable free radical intermediates which are oxidized by molecular oxygen to give superoxide (O2-.). In the presence of transition metals, such as iron, O2-. can be converted to other oxygen radical species, such as the hydroxyl radical (.OH), an extremely powerful oxidant capable of cleaving DNA, oxidizing protein, and initiating lipid peroxidation. Under many conditions, lipid peroxidation appears not to be initiated by .OH, but rather by an iron-oxygen complex. Regardless of the identity of the initiating species, transition metals are required for most of the deleterious reactions of oxygen. Superoxide and certain organic radicals have been found to release iron from ferritin.
...
PMID:Free radicals and environmental toxins. 352 96

Horse spleen and human spleen ferritins increase the formation of hydroxyl radicals (OH) at both pH 4.5 and pH 7.4 in reaction mixtures containing ascorbic acid and H2O2. The generation of OH is inhibited by the chelator desferrioxamine. Human spleen haemosiderin also accelerates OH generation in identical reaction mixtures, but is far less effective (on a unit iron basis) than ferritin under all reaction conditions. It is proposed that conversion of ferritin into haemosiderin in iron overload is biologically advantageous in that it decreases the ability of iron to promote oxygen-radical reactions.
...
PMID:Formation of hydroxyl radicals in the presence of ferritin and haemosiderin. Is haemosiderin formation a biological protective mechanism? 371 94

Iron mobilized from ferritin is able to convert superoxide and hydrogen peroxide, which are produced in large amounts in rheumatoid arthritis (RA), to the extremely toxic hydroxyl radical. We have found that synovial fluid ferritin is increased significantly in RA patients compared with levels in controls. The high synovial fluid:serum ferritin ratio is compatible with the hypothesis that synovial fluid ferritin is derived from the synovial membrane. We found no difference in ferritin concentrations in the synovial membranes of RA patients compared with those of controls. Quantitative data on the amount of iron bound to ferritin showed that the level was 2.9 times higher in RA synovial membranes than in those of controls. Moreover, RA synovial fluid contained considerable amounts of iron bound to ferritin. Calculation of the iron saturation of ferritin revealed that RA synovial membranes contained a mean of 2,210 moles of iron per mole of ferritin: a significant elevation when compared with the mean value of 1,500 moles found in the synovial membranes of the controls. The decreased saturation of ferritin in RA synovial fluid, compared with that in the synovial membrane, could be caused by an uncompensated release of iron from ferritin, which has been induced by superoxide that is produced by stimulated granulocytes. The results demonstrate that in the joints of RA patients, sufficient ferritin loaded with iron is available to stimulate oxygen free radical damage.
...
PMID:Intraarticular ferritin-bound iron in rheumatoid arthritis. A factor that increases oxygen free radical-induced tissue destruction. 376 55

Of the 85 female marathon runners examined in this study, 14 (16%) had serum ferritin levels below 40 ng/ml but only two (2%) had iron deficiency anaemia (haemoglobin below 12 g/dl); 28 (33%) had serum folate levels below 4.8 ng/ml and of these two (2%) had haemoglobin levels below 12 g/dl and 13 (15%) had mean corpuscular volumes greater than 95 fl. One week after treatment with oral folate (5 mg/day) or iron (50 mg of elemental iron/day), serum ferritin and folate levels were normal but maximum oxygen uptake, maximum treadmill running time, peak blood lactate levels and the running speed at the blood 'lactate turnpoint' were not changed from values measured during an identical test performed 1 week earlier. These parameters were also unchanged in a third exercise test performed after a further 10 weeks of treatment. Serum folate or serum ferritin levels in a control (placebo-treated) group with initially high serum ferritin or folate levels fell with placebo treatment but maximum treadmill running time, maximum oxygen uptake values, peak blood lactate levels and the running speed at the blood 'lactate turnpoint' were unchanged. We conclude that biochemical evidence of iron and folate deficiency is relatively common in female distance runners; that 1 week of treatment corrects the biochemical evidence of folate and iron deficiency but that such treatment does not influence maximal exercise performance nor does it alter blood lactate levels during exercise. In the absence of iron deficiency anaemia, iron therapy for reduced serum ferritin levels, or folate therapy for low serum folate levels, may not improve maximal treadmill performance even in trained runners.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:The effect of iron and folate therapy on maximal exercise performance in female marathon runners with iron and folate deficiency. 382 89

Hydrolytic polymerization of iron(III) occurs in many reactions in vivo, for example, the formation of bacterial magnetite in magnetotactic organisms, biomineralization of iron and the synthesis of the metallic core of the iron-storage protein ferritin. The ferritin core contains aggregates of up to 4,500 oxygen-bridged, octahedrally coordinated, high-spin iron(III) centres and is attached to the protein shell through carboxylate groups of amino-acid side chains. The X-ray and electron-diffraction patterns of this core resemble those of the mineral ferrihydrite, a hydrated iron oxide formed in nature, inter alia, by iron-dependent bacteria. The preparation and structural characterization of such large poly-iron aggregates has been a challenge to inorganic chemists. We have recently shown that tri- and tetranuclear iron(III) oxo complexes of the type thought to be important in ferritin-core formation can be prepared by reacting mononuclear [FeCl4]- and binuclear [Fe2OCl6]2- components in aprotic solvents (ref. 9 and S.M.G., W. H. Armstrong and S.J.L., in preparation). Here we report the discovery of a remarkable new molecule, [Fe11O6(OH)6(O2CPh)15], obtained by hydrolysis of the [Fe2O]4+ unit in the presence of limited amounts of water and carboxylate salts. The synthesis and properties of this soluble iron(III) oxohydroxo aggregate should help to elucidate the mechanism of formation of poly-iron centres.
...
PMID:A new synthetic approach to the ferritin core uncovers the soluble iron(III) oxo-hydroxo aggregate [Fe11O6(OH)6(O2CPh)15]. 395 37

Reticulated-siderocytes (reticulocytes which contain siderotic granules), obtained from the circulation of pigs after vigorous phlebotomy, were incubated in vitro. A rapid disappearance of granules from the reticulocytes was observed over 24 hr. Simultaneously with the decrease in granules, soluble ferritin accumulated in the media and siderotic granules developed in monocytes. The disappearance of the granules from the reticulated-siderocytes was oxygen-dependent and the loss of granules and the accumulation of ferritin in the media were both prevented by the addition of cyanide or dinitrophenol. It is concluded that the ferritin aggregates in the granules of reticulated-siderocytes are dispersed intracellularly into soluble ferritin, that soluble ferritin is excreted from the cell, and that one or both of these steps is dependent upon oxidative metabolism. Blood monocytes are capable of taking up soluble ferritin from the media and converting this into siderotic granules. Thus, a reticulocyte to plasma to monocyte ferritin pathway has been described.
...
PMID:Ferritin metabolism in reticulated-siderocytes. 541 77

Oxygen free radicals generated by xanthine oxidase are able to depolymerize hyaluronic acid in the presence of ferritin-bound iron. This suggests that ferritin can catalyse the Haber-Weiss reaction, leading to the formation of highly damaging hydroxyl radicals.
...
PMID:Xanthine oxidase induced depolymerization of hyaluronic acid in the presence of ferritin. 609 41

In the bone-marrow, non-haemoglobin iron can predominantly be found in the reticulum. Slight granules containing iron can also be observed in parts of erythroblasts by means of the Berlin blue reaction. These cells are called sideroblasts. In chemical respect, non-haemoglobin iron consists of ferritin soluble in water and haemosiderin insoluble in water. Erythroblasts will only take their iron from plasma transferrin. For the most part, this iron uptake is being regulated by erythropoietin adapting erythropoiesis to the oxygen requirements of the tissue. The iron contained in erythroblasts is predominantly utilized for haemoglobin synthesis in these cells. A slight part is being taken up by ferritin. The bone-marrow reticulum will phagocytise aged erythrocytes and store liberated iron as ferritin and haemosiderin. Part of the iron is being delivered again to plasma transferrin. With constant serum iron level the liberation of iron from the reticulo-endothelial tissue must correspond to the iron uptake by erythropoiesis. The absence of iron capable of being coloured in the bone-marrow reticulum is considered to be a reliable parameter of iron deficiency. It enables the diagnosis of iron deficiency anaemia to be made even in those patients with serum iron level and a total iron binding capacity lying within the normal range and no hypochromia of erythrocytes being present. It enables iron deficiency anaemia to be separated from sideropenic anaemia with reticulo-endothelial siderosis in differential-diagnostic manner. Even in patients with sideroblastic anaemia, iron colouring of bone-marrow smears is required for ensuring the diagnosis. Recently, a separation has also been made for idiopathic anaemia with abnormal sideroblasts. In these patients there is an increased risk for acute leukemia to develop.
...
PMID:[Iron in bone marrow]. 618 56

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>