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

It has recently been proposed that cellular iron homeostasis in mammalian cells is regulated at the post-transcriptional level by the reciprocal control of transferrin receptor and ferritin mRNA expression via an iron-regulatory factor. This iron-regulatory factor has been shown to be a cytoplasmic aconitase which can bind to iron-responsive elements in the corresponding mRNAs with greater or lesser affinity as a function of the iron status of the cell. In the present study, we show that in vivo the affinity of iron-regulatory factor for iron-responsive elements in liver reflects the long-term iron status of the tissue in animal models for iron overloading and iron deficiency, when combined with altered transferrin saturation and serum iron levels. In contrast hepatic iron overload achieved without altering such haematopoeitic indices, had a less pronounced effect. In both spleen and heart, the affinities of iron-regulatory factor changed in parallel with both altered iron status and haematological markers. In brain and duodenum, there were no consistent changes in iron-regulatory-factor activity with iron loading or depletion. Iron-regulatory-factor activity in kidney responded in an as yet unexplained manner.
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PMID:Control of cellular iron homeostasis by iron-responsive elements in vivo. 751 31

Replenishment of ascorbate in cultured cells, which are almost uniformly vitamin-deficient, increases ferritin mRNA translation in response to iron by 20-fold (Toth, I., Rogers, J. T., McPhee, J. A., Elliott, S. M., Abramson, S. L., and Bridges, K. R. (1995) J. Biol. Chem. 270, 2846-2852). We now demonstrate that ascorbate increases cytosolic aconitase activity. The iron-responsive element-binding protein (IRP-1) exists in three states: bound to mRNA without aconitase activity, free in the cytosol without aconitase activity, and free in the cytosol with aconitase activity. Ascorbate converts free IRP-1 to the enzymatically active form. Enhanced ferritin synthesis with subsequent iron stimulation is due to the altered equilibrium of the free IRP-1. The cellular biology of iron is closely intertwined with that of ascorbate.
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PMID:Ascorbic acid enhances ferritin mRNA translation by an IRP/aconitase switch. 764 38

Iron metabolism and its molecular regulation are reviewed. Ferric iron is bound to mucin in the stomach and delivered to the duodenum where it can be absorbed. Iron is transported across the apical membrane of the gut mucosa by integrin. Once within the mucosal cell, iron may be stored, utilized in protein synthesis, or exported to the serum. In the serum, iron is carried by transferrin. Diferric transferrin binds to transferrin receptor on the surface of cells and is endocytosed. In the cell, iron is bound to high and low molecular weight ligand and is thought to shuttle iron within the cell. Iron can be stored intracellularly within ferritin, or can be utilized in a number of iron containing proteins synthesized by the mitochondrion, including heme, aconitase, and cytochromes. The first chain of enzymes in the biosynthesis of heme is erythroid 5-aminolevulinate synthase (eALAS). Intracellular iron concentration regulates the synthesis of ferritin, transferrin receptor, and eALAS, thus controlling our iron metabolism. Iron regulates these proteins post-transcriptionally via iron responsive elements (IRE), which are highly conserved stem-loop structures found in messenger ribonucleic acid (mRNA), and an IRE binding protein (IRE-BP), which responds to increased intracellular iron concentrations by binding the IRE, and repressing mRNA translation or stabilizing the mRNA, depending on whether the IRE is located in the upstream or downstream untranslated regions of the mRNA. Cellular responses to iron depletion and iron over-load can be explained in terms of these regulatory mechanisms.
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PMID:Iron metabolism and its regulation. A review. 776 65

Cellular iron metabolism comprises pathways of iron-protein synthesis and degradation, iron uptake via transferrin receptor (TfR) or release to the extracellular space, as well as iron deposition into ferritin and remobilization from such stores. Different cell types, depending on their rate of proliferation and/or specific functions, show strong variations in these pathways and have to control their iron metabolism to cope with individual functions. Studies with cultured cells have revealed a specific cytoplasmic protein, called 'iron regulatory protein' (IRP) (previously known as IRE-BP or IRF), that plays a key role in iron homoeostasis by regulating coordinately the synthesis of TfR, ferritin, and erythroid 5-aminolevulinate synthase (eALAS). Present in all tissues analysed, IRP is identical with the [4Fe-4S] cluster containing cytoplasmic aconitase. Under conditions of iron chelation, IRP is an apo-protein which binds with high affinity to specific RNA stem-loop elements (IREs) located 5' of the initiation codon in ferritin and eALAS mRNA, and 3' in the untranslated region of TfR mRNA. At 5' sites IRF blocks mRNA translation, whereas 3' it inhibits TfR mRNA degradation. Both effects compensate for low intracellular iron concentrations. Under high iron conditions, IRP is converted to the holo-protein and dissociates from mRNA. This reverses the control towards less iron uptake and more iron storage. Iron can therefore be considered as a feedback regulator of its own metabolism. It has recently become evident that nitric oxide, produced by macrophages and other cell types in response to interferon-gamma, induces the IRE-binding activity of IRF. Moreover measurements of the RNA-binding activity of IRP in tissue extracts may provide valuable information on iron availability.
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PMID:Molecular regulation of iron proteins. 788 Nov 53

The iron-responsive element-binding protein (IRE-BP) has been defined and identified as an RNA-binding protein found in iron-deprived eukaryotic cells. IRE-BP binds to stem-loop structures, iron-responsive elements (IREs), which are located in the untranslated regions of the mRNAs for several genes including ferritin, and the transferrin receptor. When bound, IRE-BP prevents ferritin translation and stabilizes the transferrin receptor transcript. When cells are iron replete, an iron-sulfur cluster is ligated to the IRE-BP, the protein loses RNA binding properties, and it acquires aconitase activity. Cytosolic aconitase from liver can be converted into the IRE-BP by oxidative removal of its Fe-S cluster. We describe here overexpression of IRE-BP in baculovirus-infected insect cells which yields IRE-BP devoid of an iron-sulfur cluster. We describe a one-step purification of the IRE-BP and a quantitative analysis of Fe, S2-, S0, protein, and enzyme activity on IRE-BP, as obtained in cell lysates, after purification, and after reconstitution to active aconitase. On the average not more than 3% of the over-expressed purified protein contained an intact Fe-S cluster, and it was demonstrated that that cluster was not lost during purification. Scatchard analysis of RNA-binding data was compatible with a single high-affinity RNA-binding form of the IRE-BP. Active aconitase could be reconstituted from the purified IRE-BP obtained from the expression system by addition of iron, thiol, and sulfide, and the characteristic epr spectrum of the 3Fe form of cytosolic aconitase was obtained after ferricyanide oxidation of the reconstituted material.
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PMID:Overexpression of iron-responsive element-binding protein and its analytical characterization as the RNA-binding form, devoid of an iron-sulfur cluster. 820 18

The translation of ferritin and erythroid 5-aminolevulinate synthase mRNAs is regulated via a specific high-affinity interaction between an iron-responsive element in the 5' untranslated region of ferritin and erythroid 5-aminolevulinate synthase mRNAs and a 98-kDa cytoplasmic protein, the iron-regulatory factor. Iron-regulatory factor was expressed in vaccinia-virus-infected HeLa cells (hIRFvac) and in Escherichia coli (hIRFeco). An N-terminal histidine tag allowed a rapid one-step purification of large quantities of soluble recombinant protein. Both hIRFvac and hIRFeco bound specifically to iron-responsive elements and were immunoprecipitated by iron-regulatory-factor antibodies. Using in-vitro-transcribed chloramphenicol-acetyltransferase mRNAs bearing an iron-responsive element in the 5' untranslated region, specific repression of chloramphenicol-acetyltransferase translation by hIRFvac and hIRFeco was demonstrated in wheat-germ extract. In addition, hIRFvac and hIRFeco were shown to display aconitase activity. Treatment of hIRFvac and hIRFeco with FeSO4 resulted in a drastic reduction in iron-responsive-element-binding of iron-regulatory factor, but caused a strong stimulation of its aconitase activity. The results establish that recombinant iron-regulatory factor is a bifunctional protein; after purification, it binds to iron-responsive elements and represses translation in vitro. Following iron treatment, iron-responsive-element binding is lost and aconitase activity is gained. No eukaryotic co-factor seems to be required for the conversion of the iron-responsive-element binding to the aconitase form of the protein.
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PMID:Recombinant iron-regulatory factor functions as an iron-responsive-element-binding protein, a translational repressor and an aconitase. A functional assay for translational repression and direct demonstration of the iron switch. 826 57

The iron-responsive element-binding protein (IRE-BP) binds to specific stem-loop RNA structures known as iron-responsive elements (IREs) present in a variety of cellular mRNAs (e.g., those encoding ferritin, erythroid 5-aminolevulinate synthase, and transferrin receptor). Expression of these genes is regulated by interaction with the IRE-BP. The IRE-BP is identical in sequence to cytosolic aconitase, and the function of the protein is determined by the presence or absence of an Fe-S cluster. The protein either functions as an active aconitase when the Fe-S cluster is present or as an RNA-binding protein when the protein lacks this cluster. Aconitase activity and IRE-binding activity are mutually exclusive, and interconversion between the two activities is determined by intracellular Fe concentrations. Mapping of the RNA-binding site of the IRE-BP by UV cross-linking studies defines a major contact site between IRE and protein in the active-site region. Modeling based on probable structural similarities between the previously crystallized mitochondrial aconitase and the IRE-BP predicts that these residues would be accessible to the IRE only were there a major change in the predicted conformation of the protein when cells are iron-depleted.
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PMID:The iron-responsive element-binding protein: localization of the RNA-binding site to the aconitase active-site cleft. 829 May 65

Iron regulatory elements (IREs) are a family of 28 nucleotide, non-coding elements which regulate the translation of ferritin mRNA (iron storage), erythroid delta-aminolevulinic acid synthase mRNA (heme synthesis) and the stability of the transferrin receptor (TfR) mRNA (iron uptake). IREs in the 5' end control translation (ribosome binding) and IREs in the 3' end control turnover (degradation). The specific regulator protein, the IRE-BP, is a member of the aconitase family but binds RNA only in the apo form without the Fe-S cluster. Cellular iron alters the IRE/IRE-BP interaction leading to translation of ferritin and eALAS mRNAs but degradation of the TfR mRNA. IRE function requires proximity to the 5' cap, achieved either by a short leader (eALAS) or a long, base-pairing flanking region (FL) (ferritin); a conserved triplet of FL base pairs enhances repression of ferritin mRNA. TfR mRNA has five AU-rich IREs which can also form an alternate structure with inter-IRE base pairs, in the absence of the IRE-BP. Ferritin IREs regulate both translation repression (negative control-IRE-BP dependent) and enhancement (positive control-initiation factor dependent); IRE-BP binding induces conformational changes in the FL. IREs use CAGUGU/C to form a hairpin loop with specific variations in the stem such as internal or bulge loops. A current structural model obtained using metallonucleases (1,10-phenanthroline-Cu, Fe-EDTA, Fe-bleomycin) and a preliminary analysis of the NMR spectrum, is a distorted helix with folds. The effect of cellular iron, Fe-S clusters and heme on the IRE-BP/RNA is not completely understood.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The IRE (iron regulatory element) family: structures which regulate mRNA translation or stability. 834 79

Iron regulatory factor (IRF) is a cytoplasmic mRNA-binding protein that coordinates post-transcriptionally the expression of several important proteins in iron metabolism. Binding of IRF to iron-responsive elements (IRE) in the 5' untranslated region (UTR) of ferritin and erythroid 5-aminolevulinic acid-synthase mRNAs inhibits their translation, whereas binding to IREs in the 3' UTR of transferrin receptor (TfR) mRNA prevents the degradation of this mRNA. IRF binds RNA strongly after iron deprivation, but is inactive, yet present, under conditions of high cellular iron supply. Recently, IRF was also shown to have aconitase activity indicating the existence of an Fe-S cluster in the protein. In the current study we expressed human IRF in insect cells from recombinant baculovirus and analysed IRE-binding and aconitase activities under various culture conditions. Newly made apoprotein, synthesized in the absence of iron, was fully active in IRE-binding, but showed no aconitase activity. In contrast, IRF made by cells grown in high iron medium bound RNA poorly, but exhibited high aconitase activity with a Km of 9.2 microM for cis-aconitate. Apo-IRF was converted in vitro to active aconitase by Fe-S cluster-generating conditions, and under the same conditions lost its RNA-binding capacity. These results indicate that the two activities are mutually exclusive and controlled through formation of the Fe-S cluster.
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PMID:Iron regulatory factor expressed from recombinant baculovirus: conversion between the RNA-binding apoprotein and Fe-S cluster containing aconitase. 846 37

Iron is a required nutrient which, at high concentrations, can peroxidize cell lipids and other cellular components. To prevent excess iron from damaging cells, it is stored in ferritin, which consists of a shell of protein subunits of two related types, H (heavy) and L (light), surrounding a cavity in which the iron can be deposited. In order to prepare for a rapid increase in ferritin in response to a rise in cellular iron, a large number of dormant ferritin mRNAs are accumulated in the cytoplasm. These can be rapidly activated to yield a large population of ferritin subunits. Regulation is achieved through a 28-nucleotide "stem-and-loop" structure near the beginning of the H- and L-ferritin mRNAs. When this structure is associated with a binding protein (iron regulatory element binding protein, IRE-BP), translation of the ferritin mRNA cannot proceed. However, when intracellular iron accumulates, IRE-BP releases its hold and translation of the mRNA then takes place. IRE-BP has been identified as a cytosolic form of aconitase, containing several fourfold iron-sulfur clusters. Within each cluster one iron atom is labile; this may be the mechanism by which IRE-BP responds to intracellular iron levels. Finally, transcription of the L- and H-genes shows that L is preferentially transcribed in response to increased iron intake, whereas H responds to cell differentiation and other factors. More work is needed to define independent transcription of the individual genes, including regulation of components other than the 28-nucleotide segment.
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PMID:The ferritin genes: their response to iron status. 850 27


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