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)

A ferritin cDNA, AtFer1, from seedlings of Arabidopsis thaliana has been characterized. The deduced amino acid sequence of the AtFer1 protein indicates that A. thaliana ferritin shares the same characteristics as the plant ferritin already characterized from the Leguminosae and Graminacea families: (i) it contains an additional sequence in its N-terminal part composed of two domains: a transit peptide responsible for plastid targeting and an extension peptide; (ii) amino acids that form the ferroxidase centre of H-type animal ferritin, as well as Glu residues characteristic of L-type animal ferritin, are conserved in AtFer1; (iii) the C-terminal part of the A. thaliana ferritin subunit defining the E-helix is divergent from its animal counterpart, and confirms that 4-fold-symmetry axis channels are hydrophilic in plant ferritin. Southern blot experiments indicate that AtFer1 is likely to be encoded by a unique gene in the A. thaliana genome, although a search in the NCBI dbEST database indicates that other ferritin genes, divergent from AtFer1, may exist. Iron loading of A. thaliana plantlets increased ferritin mRNA and protein abundance. In contrast to maize, the transcript abundance of a gene responding to abscisic acid (RAB18) did not increase in response to iron loading treatment, and A. thaliana ferritin mRNA abundance is not accumulated in response to a treatment with exogenous abscisic acid, at least in the culture system used in this study. In addition, iron-induced increases in ferritin mRNA abundance were the same as wild-type plants in abi1 and abi2 mutants of A. thaliana, both affected in the abscisic acid response in vegetative tissues. Increased AtFer1 transcript abundance in response to iron is inhibited by the antioxidant N-acetylcysteine. These results indicate that an oxidative pathway, independent of abscisic acid, could be responsible for the iron induction of ferritin synthesis in A. thaliana.
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PMID:Characterization of a ferritin mRNA from Arabidopsis thaliana accumulated in response to iron through an oxidative pathway independent of abscisic acid. 876 54

Control of cellular iron homoeostasis is performed by iron regulatory protein 1 (IRP1) through post-transcriptional modifications. This protein is sensitive to intracellular iron availability, being activated at low iron levels and inactivated at high iron levels, conditions that signal the increased expression of the transferrin receptor or of ferritin respectively. IRP1 is known to be activated by some oxidants such as H2O2 and NO. delta-Aminolaevulinic acid (ALA), previously found to produce reactive oxygen species and a carbon-centred radical, to release iron from ferritin, and to increase rat liver and brain non-haem iron and ferritin, was investigated for its effects on IRP1 activity in cultured hamster pulmonary fibroblasts. We have found that 1-2 mM ALA produced a 2-3-fold activation of IRP. On incubation with 1-4 mM succinylacetone methyl ester, a potent ALA dehydratase inhibitor, a 3-4-fold activation of the protein was observed, accompanied by a 40% increase in the intracellular ALA concentration. When cells were incubated in the presence of ALA or succinylacetone methyl ester, N-acetylcysteine inhibited IRP1 activation, suggesting that the observed effect is mediated by an oxidative process. We surmise that ALA-induced IRP1 activation might act as a co-sensor of iron homoeostasis.
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PMID:Haem precursor delta-aminolaevulinic acid induces activation of the cytosolic iron regulatory protein 1. 939 27

Iron may be important in catalyzing excessive production of reactive oxygen species (ROS). Cellular iron homeostasis is regulated by iron regulatory proteins (IRPs), which bind to iron-responsive elements (IRE) of mRNAs for ferritin and transferrin receptor (TfR) modulating iron uptake and sequestration, respectively. Although iron is the main regulator of IRP activity, IRP is also influenced by other factors, including the redox state. Therefore, IRP might be sensitive to pathophysiological alterations of redox state caused by ROS. However, previous studies have produced diverging evidence on the effect of oxidative injury on IRP. Results obtained in an animal model close to a pathophysiological condition, such as ischemia reperfusion of the liver as well as in a cell-free system involving an enzymatic source of O2 and H2O2, indicate that IRP is downregulated by oxidative stress. In fact, IRP activity is inhibited at early times of post-ischemic reperfusion. Moreover, the concerted action of O2 and H2O2 produced by xanthine oxidase in a cell-free system caused a remarkable inhibition of IRP activity. IRP seems a direct target of ROS; in fact, in vivo inhibition can be prevented by the antioxidant N-acetylcysteine and by interleukin-1 receptor antagonist. In addition, modulation of iron levels of the cell-free assay did not affect the downregulation imposed by xanthine oxidase. Conceivably, downregulation of IRP activity by O2 and H2O2 may facilitate iron sequestration into ferritin, thus limiting the pro-oxidant challenge of iron.
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PMID:Effect of reactive oxygen species on iron regulatory protein activity. 966 19

Iron regulatory protein-1 (IRP-1) controls the expression of several mRNAs by binding to iron-responsive elements (IREs) in their untranslated regions. In iron-replete cells, a 4Fe-4S cluster converts IRP-1 to cytoplasmic aconitase. IRE binding activity is restored by cluster loss in response to iron starvation, NO, or extracellular H2O2. Here, we study the effects of intracellular quinone-induced oxidative stress on IRP-1. Treatment of murine B6 fibroblasts with menadione sodium bisulfite (MSB), a redox cycling drug, causes a modest activation of IRP-1 to bind to IREs within 15-30 min. However, IRE binding drops to basal levels within 60 min. Surprisingly, a remarkable loss of both IRE binding and aconitase activities of IRP-1 follows treatment with MSB for 1-2 h. These effects do not result from alterations in IRP-1 half-life, can be antagonized by the antioxidant N-acetylcysteine, and regulate IRE-containing mRNAs; the capacity of iron-starved MSB-treated cells to increase transferrin receptor mRNA levels is inhibited, and MSB increases the translation of a human growth hormone indicator mRNA bearing an IRE in its 5'-untranslated region. Nonetheless, MSB inhibits ferritin synthesis. Thus, menadione-induced oxidative stress leads to post-translational inactivation of both genetic and enzymatic functions of IRP-1 by a mechanism that lies beyond the "classical" Fe-S cluster switch and exerts multiple effects on cellular iron metabolism.
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PMID:Inactivation of both RNA binding and aconitase activities of iron regulatory protein-1 by quinone-induced oxidative stress. 1003 8

Previous studies using cell and whole embryo cultures have shown that free radicals play an important role in the ethanol-induced death of mouse neural crest cells (NCCs; a significant cell type with respect to the genesis of alcohol-related birth defects). This investigation was spurred by reports of increased iron in ethanol-exposed fetuses and the knowledge that iron can initiate the production of reactive oxygen species. Initially, the ameliorative potential of two iron chelators, deferoxamine and phenanthroline, relative to ethanol-induced cell death was examined. Cotreatment of cultured NCCs with 100 mM ethanol and either 1 or 10 microM deferoxamine or 10, 50, or 250 microM phenanthroline significantly increased the percentage of viable cells as compared with exposure to 100 mM ethanol alone. These data indicate that iron is involved in the ethanol-induced cytotoxicity. To support this premise, the direct toxicity of iron to NCCs was also examined. As expected, loading the cells with Fe(II)/Fe(III) using 8-hydroxyquinoline as a carrier had an adverse effect on their viability as did treatment with a neurotoxin, 6-hydroxydopamine, that releases iron from ferritin storage. Cotreatment with an antioxidant, N-acetylcysteine, significantly diminished the toxicity of ethanol alone, that resulting from iron loading, as well as from the combination of ethanol exposure and iron loading. These results confirm the role of free radical-mediated damage in ethanol-induced cytotoxicity and highlight the potential role of iron relative to the genesis of alcohol-related birth defects.
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PMID:Iron-mediated free radical injury in ethanol-exposed mouse neural crest cells. 1087 4

Concentrations of ferritin in alveolar cells and on the alveolar surface are increased in patients with a variety of respiratory disorders. Ferritin synthesis by cells is modulated by iron content but is also influenced by stimuli other than iron. In this study we sought to determine whether in vitro exposure to hypoxia- or nitric oxide (NO)-induced ferritin accumulation or release by human alveolar macrophages (AMs) or a lung cancer-derived epithelial cell line (A549). Changes in cell content of iron and ferritin (L- and H-types), as well as ferritin content of cell supernatants, were determined after in vitro exposure to hypoxia (1% or 10% O(2), 18 hours) or the NO donor S-nitroso-N-acetylpenicillamine (SNAP, 0.01-1.0 mmol/L, 18 hours). Exposure to 1% O(2) increased ferritin content in both cell types (>fourfold increase; P <.005) without changing iron content. Treatment with SNAP increased ferritin content of A549 cells in a dose-dependent manner, whereas treatment of AMs decreased cellular iron and ferritin content and increased supernate ferritin content. Pretreatment of cells with N-acetylcysteine (500 micromol/L) reduced hypoxia-induced ferritin accumulation in alveolar cells and completely inhibited NO-induced ferritin accumulation in A549 cells. These findings indicate that exposure to 1% O(2)can increase ferritin content in alveolar cells, whereas NO can increase ferritin content (A549 cells) or decrease ferritin content (AMs).
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PMID:Effects of hypoxia and nitric oxide on ferritin content of alveolar cells. 1276 71

The novel antioxidant 3-O-caffeoyl-one-methylquinic acid (MCGA3) is a methyl chlorogenic acid derivative isolated from bamboo leaves. MCGA3 scavenges reactive oxygen species (ROS) and inhibits lipid peroxidation and xanthine oxidase in vitro. In this study, we evaluated the cytoprotective effect of MCGA3, which occurs via heme oxygenase-1 (HO-1) induction in bovine vascular endothelial cells exposed to tert-butylhydroperoxide (tBHP). Cells treated with 1 mM tBHP (6-18 h) generated substantial ROS and concomitantly lost most intracellular lactate dehydrogenase (LDH), which then caused necrotic cell death. Of the several MCGA antioxidants and structurally related phenolic acids examined in this study, MCGA3 (0.01-0.15 mM) was found to completely block this necrosis and generation of ROS by tBHP. Surprisingly, MCGA3 by itself was found to be a potent inducer of HO-1. We observed the time- and dose-dependent induction of HO-1 mRNA and protein, which was closely associated with decreased intracellular ROS and necrosis against tBHP. Deesterified or Al-chelated MCGA3 or co-treatment with MCGA3 and actinomycin D abolished HO-1 induction and the antinecrotic effect of MCGA3. Zinc protoporphyrin IX and cycloheximide attenuated the cytoprotection afforded by MCGA3, but did not reduce HO-1 mRNA. Interestingly, N-acetylcysteine (1 mM) enhanced the HO-1 induction of MCGA3, but N-acetylcysteine itself did not induce HO-1. These results suggested that not only ortho-dihydroxyl groups but also aromatic ester and methoxyl ester moieties are necessary for full HO-1 induction and cytoprotection against toxic tBHP-derived ROS. Ferritin mRNA was also upregulated during all HO-1 induction by MCGA3, which might decrease iron and lower ROS levels. Consequently, the combined action of HO-1 and ferritin may protect cells from toxic tBHP-mediated necrosis.
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PMID:Cytoprotective effects of heme oxygenase-1 induction by 3-O-caffeoyl-1-methylquinic acid. 1473 89

The cardiotoxicity induced by the anticancer anthracycline doxorubicin (DOX) is attributed to reactions between iron and reactive oxygen species (ROS) that lead to oxidative damage. We found that DOX forms ROS in H9c2 cardiomyocytes, as shown by dichlorodihydrofluorescein oxidation and the expression of stress-responsive genes such as catalase or aldose reductase. DOX also increased ferritin levels in these cells, particularly the H subunit. A considerable increase in ferritin mRNA levels showed that DOX acted at transcriptional level, but an additional potential mechanism was identified as the down-regulation of iron regulatory protein-2, post-transcriptional inhibitor of ferritin synthesis. Pretreatment with DOX protected H9c2 cells against the damage induced by subsequent exposure to ferric ammonium citrate, and experiments with (55)Fe revealed that the protection was due to the deposition of iron in ferritin. Cytoprotection was also observed when DOX was replaced by glucose/glucose oxidase, a source of H(2)O(2), thus suggesting that DOX increases ferritin synthesis through the action of ROS. This concept was supported by three more lines of evidence. (i) DOX-induced ferritin synthesis was blocked by N-acetylcysteine, a scavenger of ROS. (ii) Mitoxantrone, a ROS-forming analogue, similarly induced ferritin expression and protected the cells against iron toxicity. (iii) 5-Iminodaunorubicin, an analogue lacking ROS-forming activity, did not induce ferritin synthesis or protect the cells against iron toxicity. These results characterize a paradoxically beneficial link between anthracycline-derived ROS, increased ferritin synthesis, and resistance to iron-mediated damage. The role of iron and ROS in anthracycline-induced cardiotoxicity may, therefore, be more complex than previously believed.
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PMID:Doxorubicin paradoxically protects cardiomyocytes against iron-mediated toxicity: role of reactive oxygen species and ferritin. 1473 95

Induction of detoxifying phase II genes by chemopreventive agents represents a coordinated protective response against oxidative stress and neoplastic effects of carcinogens. We have earlier shown that a novel antioxidant from the bamboo leaves constituent 3-O-caffeoyl-1-methylquinic acid (MCGA3) induces heme oxygenase-1 (HO-1) and protects endothelial cells from ROS-induced endothelial injury. The purpose of this study was to elucidate the induction mechanism of HO-1 and other phase II genes by MCGA3 in human umbilical vascular endothelial cells (HUVECs). Using Northern blotting and RT-PCR, we found that treatment of HUVECs with MCGA3 increased, in a dose and time-dependent manner, steady-state mRNA levels of the selected phase II genes including HO-1, ferritin, gamma-glutamylcysteine lygase, glutathione reductase, and glutathione transferase, which were dependent on Nrf2 nuclear translocation. The observed phase II gene induction by MCGA3 was found to be associated with MCGA3-mediated cytoprotective activity, ROS-scavenging potency, and the increase in the cellular levels of both reduced (GSH) and oxidized glutathione (GSSG). Interestingly, exposure to MCGA3 resulted in a decreased ratio of GSH/GSSG, which was negatively related with mRNA level of phase II genes. By employing N-acetylcysteine and GSH biosynthetic enzyme inhibitors as well as prooxidants, hemin and H(2)O(2), we show that a decreased intracellular GSH/GSSG homeostasis, at least in part, may be involved in the MCGA3-mediated phase II gene induction and Nrf2 translocation, although the attenuation of HO-1 expression with SP 600125 supports a partial involvement of JNK signaling.
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PMID:The novel antioxidant 3-O-caffeoyl-1-methylquinic acid induces Nrf2-dependent phase II detoxifying genes and alters intracellular glutathione redox. 1663 25

Patients with alcoholic liver disease frequently exhibit iron overload in association with increased hepatic fibrosis. Even moderate alcohol consumption elevates body iron stores; however, the underlying molecular mechanisms are unknown. Hepcidin, a circulatory peptide synthesized in the liver, is a key mediator of iron metabolism. Ethanol metabolism significantly down-regulated both in vitro and in vivo hepcidin mRNA and protein expression. 4-Methylpyrazole, a specific inhibitor of the alcohol-metabolizing enzymes, abolished the effects of ethanol on hepcidin. However, ethanol did not alter the expression of transferrin receptor1 and ferritin or the activation of iron regulatory RNA-binding proteins, IRP1 and IRP2. Mice maintained on 10-20% ethanol for 7 days displayed down-regulation of liver hepcidin expression without changes in liver triglycerides or histology. This was accompanied by elevated duodenal divalent metal transporter1 and ferroportin protein expression. Injection of hepcidin peptide negated the effect of ethanol on duodenal iron transporters. Ethanol down-regulated hepcidin promoter activity and the DNA binding activity of CCAAT/enhancer-binding protein alpha (C/EBPalpha) but not beta. Interestingly, the antioxidants vitamin E and N-acetylcysteine abolished both the alcohol-mediated down-regulation of C/EBPalpha binding activity and hepcidin expression in the liver and the up-regulation of duodenal divalent metal transporter 1. Collectively, these findings indicate that alcohol metabolism-mediated oxidative stress regulates hepcidin transcription via C/EBPalpha, which in turn leads to increased duodenal iron transport.
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PMID:Alcohol metabolism-mediated oxidative stress down-regulates hepcidin transcription and leads to increased duodenal iron transporter expression. 1725 19


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