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)

Citric acid is produced industrially by depriving Aspergillus niger of iron. The lack of Fe deactivates mitochondrial aconitase and interrupts the krebs cycle, causing the mitochondria to release citric acid as a siderophore (an Fe getter). When the mitochondrion has plenty of Fe and the cell has enough ATP, aerobic phosphorylation stops and fatty acid or haem synthesis take place, when the cell has plenty of haem, haem synthesis stops. Since most of the Fe activity in the cell is related to the mitochondria, I hypothesise that in the animal cell when the mitochondria are low in Fe, citric acid acts as a signal that triggers the production of transferrin receptor messenger RNA (TrR mRNA) in the nucleus, which in the absence of Fe causes the expression of transferrin receptor. When the cell has plenty of Fe, cytosolic aconitase detaches itself from the transferrin receptor and ferritin mRNA stopping expression of the former and initiating expression of the latter. The detached cytosolic aconitase transforms the citric acid, blocking the production of the transferrin receptor mRNA.
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PMID:Do mitochondria regulate cellular iron homeostasis through citric acid and haem production? Implications for cancer and other diseases. 1245 Jul 75

Manganese (Mn) may interfere with iron regulation by altering the binding of iron regulatory proteins (IRPs) to their response elements found on the mRNA encoding proteins critical to iron homeostasis. To explore this, the effects of 24-h in vitro manganese exposure (1, 10, 50, and 200 microM Mn) on: (i) total intracellular and labile iron concentrations; (ii) the cellular abundance of transferrin receptor (TfR), H- and L-ferritin, and mitochondrial aconitase proteins; and (iii) IRP binding to a [32P](-) labeled mRNA sequence of L-ferritin were evaluated in undifferentiated PC12 cells. In vitro manganese exposure altered the cellular abundance of TfR, H-/L-ferritin, and m-aconitase, resulting in an increase in labile iron. This latter effect led to a decrease in IRP binding activity at the lower (10 and 50 microM) manganese exposures. In contrast, 200 microM manganese exposure increased IRP binding, in spite of the significant increase in labile iron. These data indicate that at lower exposures, manganese directly interfered with IRP-dependent translational events, producing an increase in labile iron, which in turn signaled a decrease in IRP binding at 24 h. At higher exposures, the intracellular burden of manganese resulted in overt cytotoxicity and appeared to compromise the normal compensatory response to increased labile iron, producing increased IRP binding. We conclude that low to moderate manganese exposure interferes with cellular iron regulation, and thus may serve as a contributory mechanism underlying manganese neurotoxicity.
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PMID:Alterations in cellular IRP-dependent iron regulation by in vitro manganese exposure in undifferentiated PC12 cells. 1272 48

The iron regulatory proteins (IRPs) are an example of different proteins regulating the same metabolic process, iron uptake and metabolism. IRP1 is an iron-sulfur cluster-containing protein that can be converted from a cytosolic aconitase to an RNA binding posttranscriptional regulator in response to nitric oxide (NO). IRP2 lacks aconitase activity and its expression is decreased by NO signaling. In macrophages, NO is produced in response to such inflammatory ligands as interferon-gamma, which is expressed in response to mitogenic and antigenic stimuli, and lipopolysaccharide, a marker of bacterial invasion. Until recently, research results predict that the cellular response to increased NO production should be a decrease in ferritin synthesis, due to IRP1 binding to ferritin mRNA, and an increase in transferrin receptor biosynthesis, due to IRP1 binding to the transferrin mRNA. Surprisingly, however, macrophages exhibit decreased transferrin receptor concentration in response to inflammatory ligands. Bouton and Drapier discuss the physiological role and the mechanisms that may underlie this contradictory response.
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PMID:Iron regulatory proteins as NO signal transducers. 1274 46

The two iron regulatory proteins IRP1 and IRP2 bind to transcripts of ferritin, transferrin receptor and other target genes to control the expression of iron metabolism proteins at the post-transcriptional level. Here we compare the effects of genetic ablation of IRP1 to IRP2 in mice. IRP1-/- mice misregulate iron metabolism only in the kidney and brown fat, two tissues in which the endogenous expression level of IRP1 greatly exceeds that of IRP2, whereas IRP2-/- mice misregulate the expression of target proteins in all tissues. Surprisingly, the RNA-binding activity of IRP1 does not increase in animals on a low-iron diet that is sufficient to activate IRP2. In animal tissues, most of the bifunctional IRP1 is in the form of cytosolic aconitase rather than an RNA-binding protein. Our findings indicate that the small RNA-binding fraction of IRP1, which is insensitive to cellular iron status, contributes to basal mammalian iron homeostasis, whereas IRP2 is sensitive to iron status and can compensate for the loss of IRP1 by increasing its binding activity. Thus, IRP2 dominates post-transcriptional regulation of iron metabolism in mammals.
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PMID:Genetic ablations of iron regulatory proteins 1 and 2 reveal why iron regulatory protein 2 dominates iron homeostasis. 1472 53

Ferritin is a ubiquitous protein required for intracellular iron storage; its biosynthesis is mainly regulated by iron-regulatory proteins (IRP1 and IRP2) at post-transcriptional level. This regulation prevents iron excess from promoting the formation of reactive oxygen species (ROS). IRP1 is regulated by such factors as intracellular iron levels, the oxidants H(2)O(2) and NO. We recently demonstrated that oxalomalate (OMA, alpha-hydroxy-beta-oxalosuccinic acid), a competitive inhibitor of aconitase, which is an enzyme of the citric acid cycle, remarkably decreases the binding activity of IRP1. The aim of the present study was to investigate whether this molecule could affect the expression of ferritin. The RNA-binding activity of IRP1, evaluated by gel retardation assay, decreased after treatment of several cell lines with 5 mM OMA, with a maximal decrease of about 3-fold after 6 h. This effect remained almost constant up to 48 h after which it returned to basal levels. Intracellular ferritin levels, determined by Western blot analysis, increased in correlation with the OMA-induced decrease of IRP1 binding activity. Furthermore, treatment of cells with OMA caused a rise in ferritin mRNA levels. Interestingly, in cells exposed to iron challenge, OMA-induced overexpression of ferritin prevented formation of ROS and cellular lipid peroxidation. These data show that an inhibitor of aconitase, OMA, besides being involved in energetic metabolism, is able to control ferritin expression, probably through molecular mechanisms of either post-transcriptional regulation or transcriptional modulation, with advantageous consequences for the cell.
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PMID:Induction of ferritin expression by oxalomalate. 1511 Sep 95

Iron regulatory protein-1 (IRP-1) is a bifunctional [4Fe-4S] protein that functions as a cytosolic aconitase or as a trans-regulatory factor controlling iron homeostasis at a post-transcriptional level. Because IRP-1 is a sensitive target protein for nitric oxide (NO), we investigated whether this protein is nitrated in inflammatory macrophages and whether this post-transcriptional modification changes its activities. RAW 264.7 macrophages were first stimulated with interferon-gamma and lipopolysaccharide (IFN-gamma/LPS) and then triggered by phorbol 12-myristate 13-acetate (PMA) in order to promote co-generation of NO* and O*2-.. IRP-1 was isolated by immunoprecipitation and analyzed for protein-bound nitrotyrosine by Western blotting. We show that nitration of endogenous IRP-1 in NO-producing macrophages boosted to produce O*2- was accompanied by aconitase inhibition and impairment of its capacity to bind the iron-responsive element (IRE) of ferritin mRNA. Lost IRE-binding activity was not recovered by exposure of IRP-1 to 2% 2-mercaptoethanol and was not due to protein degradation. Inclusion of cis-aconitate with cell extract to stabilize the [4Fe-4S] cluster of holo-IRP-1 rendered protein insensitive to nitration by peroxynitrite, suggesting that loss of [Fe-S] cluster and subsequent change of conformation are prerequisites for tyrosine nitration. IRP-1 nitration was strongly reduced when IFN-gamma/LPS/PMA-stimulated cells were incubated with myeloperoxidase inhibitors, which points to the contribution of the nitrite/H2O2/peroxidase pathway to IRP-1 nitration in vivo. Interestingly, under these conditions, IRP-1 recovered full IRE binding as assessed by treatment with 2% 2-mercaptoethanol. Peroxidase-mediated nitration of critical tyrosine residues, by holding IRP-1 in an inactive state, may constitute, in activated macrophages, a self-protecting mechanism against iron-induced toxicity.
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PMID:Endogenous nitration of iron regulatory protein-1 (IRP-1) in nitric oxide-producing murine macrophages: further insight into the mechanism of nitration in vivo and its impact on IRP-1 functions. 1525 60

Ferritin is the major iron storage protein regulating cytosolic concentration of iron by storing excess iron. Vertebrate ferritins are heteropolymeric proteins composed of heavy chain and light chain subunits. We have characterized two Caenorhabditis elegans genes (ftn-1 and ftn-2), which encode ferritin homologs showing high degree of similarity to mammalian ferritin heavy chains. Even though these two ferritins are more than 78% identical in amino acid sequence, our data show that expression patterns and responses to iron are quite different. Cytosolic aconitase (aco-1), iron regulatory protein, is known to regulate cellular iron concentration by modulating translation of the ferritin mRNA in addition to its enzymatic activity that converts citrate into iso-citrate. We have shown that the expression levels of aco-1 and ftn-1 genes are both regulated by iron treatment but in opposite ways. Interestingly, mutant animals lacking ACO-1 and FTN-1 show significantly reduced life-span upon iron stress, while N2 and ftn-2 animals show no difference. Our results suggest that ftn-1 and aco-1 are transcriptionally regulated by iron and are important for iron homeostasis affecting life-span upon iron stress conditions in C.elegans.
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PMID:Transcriptional regulation and life-span modulation of cytosolic aconitase and ferritin genes in C.elegans. 1532 44

Cytosolic ferritin sequesters and stores iron and, consequently, protects cells against iron-mediated free radical damage. However, the function of the newly discovered mitochondrial ferritin (MtFt) is unknown. To examine the role of MtFt in cellular iron metabolism, we established a cell line that stably overexpresses mouse MtFt under the control of a tetracycline-responsive promoter. The overexpression of MtFt caused a dose-dependent iron deficiency in the cytosol that was revealed by increased RNA-binding activity of iron regulatory proteins (IRPs) along with an increase in transferrin receptor levels and decrease in cytosolic ferritin. Consequently, the induction of MtFt resulted in a dramatic increase in cellular iron uptake from transferrin, most of which was incorporated into MtFt. The induction of MtFt caused a shift of iron from cytosolic ferritin to MtFt. In addition, iron inserted into MtFt was less available for chelation than that in cytosolic ferritin and the expression of MtFt was associated with decreased mitochondrial and cytosolic aconitase activities, the latter being consistent with the increase in IRP-binding activity. In conclusion, our results indicate that overexpression of MtFt causes a dramatic change in intracellular iron homeostasis and that shunting iron to MtFt likely limits its availability for active iron proteins.
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PMID:Overexpression of mitochondrial ferritin causes cytosolic iron depletion and changes cellular iron homeostasis. 1574 1

Potential interactions between zinc and iron during absorption and its functional consequences on intestinal oxidative damage and antioxidant status were studied using the zinc-deficient rat as a model. Zinc depletion produced mild-moderate iron deficiency in addition to zinc deficiency, which could be corrected by repletion with iron and zinc. The localization and intensity of both iron and zinc in the intestinal mucosa showed a pronounced decrease in the presence of the other metal, indicating negative interactions. Zinc-deficient intestine exposed to iron alone exhibited elevated peroxidative damage and compromised functional integrity, despite increased expression of ferritin. Inclusion of zinc significantly reduced the damage and improved the functional integrity, accompanied by decreased expression of ferritin. Decreased expression of ferritin in the presence of zinc was consistent with reduced aconitase activity, suggesting its modulation by zinc. Further, inclusion of iron along with zinc was associated with induction of ferritin and metallothionein in tune with the amount of iron and zinc localized in the intestinal mucosa, respectively. These results suggest that zinc and iron interact negatively with cytosolic aconitase, but prove beneficial in reducing the oxidative stress, apart from improving functional integrity and iron/zinc status.
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PMID:Modulation of aconitase, metallothionein, and oxidative stress in zinc-deficient rat intestine during zinc and iron repletion. 1619 27

Iron regulatory protein 1 (IRP1) is a bifunctional protein with activity as an RNA-binding protein or as a cytoplasmic aconitase. Interconversion of IRP1 between these mutually exclusive states is central to cellular iron regulation and is accomplished through iron-responsive assembly and disassembly of a [4Fe-4S] cluster. When in its apo form, IRP1 binds to iron responsive elements (IREs) found in mRNAs encoding proteins of iron storage and transport and either prevents translation or degradation of the bound mRNA. Excess cellular iron stimulates the assembly of a [4Fe-4S] cluster in IRP1, inhibiting its IRE-binding ability and converting it to an aconitase. The three-dimensional structure of IRP1 in its different active forms will provide details of the interconversion process and clarify the selective recognition of mRNA, Fe-S sites and catalytic activity. To this end, the apo form of IRP1 bound to a ferritin IRE was crystallized. Crystals belong to the monoclinic space group P2(1), with unit-cell parameters a = 109.6, b = 80.9, c = 142.9 A, beta = 92.0 degrees. Native data sets have been collected from several crystals with resolution extending to 2.8 A and the structure has been solved by molecular replacement.
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PMID:Crystallization and preliminary X-ray diffraction analysis of iron regulatory protein 1 in complex with ferritin IRE RNA. 1651 14


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