Alteration of iron regulatory proteins (IRP1 and IRP2) and ferritin in the brains of scrapie-infected mice

Considerable evidence suggests that oxidative stress may be involved in the pathogenesis of Transmissible Spongiform Encephalopathies (TSEs). To investigate the involvement of iron metabolism in TSEs, we examined the expression levels of iron regulatory proteins (IRPs), ferritins, and binding activities of IRPs to iron-responsive element (IRE) in scrapie-infected mice. We found that the IRPs-IRE-binding activities and ferritins were increased in the astrocytes of hippocampus and cerebral cortex in the brains of scrapie-infected mice. These results suggest that alteration of iron metabolism contributes to development of neurodegeneration and that some protective mechanisms against iron-induced oxidative damage may occur during the pathogenesis of TSEs.     

Up-regulation of divalent metal transporter 1 is involved in 1-methyl-4-phenylpyridinium (MPP(+))-induced apoptosis in MES23.5 cells

Apoptosis has been identified as one of the important mechanisms involved in the degeneration of dopaminergic neurons in Parkinson's disease (PD). Our previous study showed increased iron levels in the substantia nigra as well as loss of dopaminergic neurons in 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine-induced PD mouse models. 1-Methyl-4-phenylpyridinium (MPP⁺) is commonly used to establish a cellular model of PD. Although intracellular iron plays a crucial role in MPP⁺-induced apoptosis, the molecular mechanism linking increased iron and MPP⁺-induced neurodegeneration is largely unknown. In the present study, we investigate the involvement of divalent metal transporter 1 (DMT1) that accounts for the ferrous iron transport in MPP⁺-treated MES23.5 cells. In the treated cells, a significant influx of ferrous iron was observed. This resulted in a decreased mitochondrial membrane potential. Additionally, an elevated level of ROS production and activation of caspase-3 were also detected, as well as the subsequent cell apoptosis. These effects could be fully abolished by iron chelator desferal (DFO). Increased DMT1 (−IRE) expression but not DMT1 (+IRE) accounted for the increased iron influx. However, there were no changes for iron regulatory protein 1 (IRP1), despite decreased expression of IRP2. Iron itself had no effect on IRP1 and IRP2 expression. Our data suggest that although DMT1 mRNA contains an iron responsive element, its expression is not totally controlled by this. MPP⁺ could up-regulate the expression of DMT1 (−IRE) in an IRE/IRP-independent manner. Our findings also show that MPP⁺-induced apoptosis in MES23.5 cells involves DMT1-dependent iron influx and mitochondria dysfunction.     

Does cellular iron dysregulation play a causative role in Parkinson's disease?

Selective dopaminergic cell loss in Parkinson's disease is correlated with increased levels of cellular iron. It is still hotly debated as to whether the increase in iron is an upstream event which acts to promote neurodegeneration via formation of oxidative stress or whether iron accumulates as a by-product of the neuronal cell loss. Here we review evidence for loss of iron homeostasis as a causative factor in disease-associated neurodegeneration and the primary players which may be involved. A series of recent studies suggest that iron regulatory proteins (IRPs) coordinate both cellular iron levels and energy metabolism, both of which are disrupted in Parkinson's disease (PD) and may in turn contribute to increased levels of oxidative stress associated with the disease. Iron has also been recently been implicated in promotion of alpha-synuclein aggregation either directly or via increasing levels of oxidative stress suggesting an important role for it in Lewy body formation, another important hallmark of the disease.     

Expression of a recombinant IRP-like Plasmodium falciparum protein that specifically binds putative plasmodial IREs

Plasmodium falciparum iron regulatory-like protein (PfIRPa, accession AJ012289) has homology to a family of iron-responsive element (IRE)-binding proteins (IRPs) found in different species. We have previously demonstrated that erythrocyte P. falciparum PfIRPa binds a mammalian consensus IRE and that the binding activity is regulated by iron status. In the work we now report, we have cloned a C-terminus histidine-tagged PfIRPa and overexpressed it in a bacterial expression system in soluble form capable of binding IREs. To overexpress PfIRPa, we used the T7 promoter-driven vector, pET28a(+), in conjunction with the Rosetta(DE3)pLysS strain of E. coli, which carries extra copies of tRNA genes usually found in organisms such as P. falciparum whose genome is (A+T)-rich. The histidine-tagged recombinant protein (rPfIRPa) in soluble form was partially purified using His-bind resin. We searched the plasmodial database, plasmoDB, to identify sequences capable of forming IRE loops using a specially developed algorithm, and found three plasmodial sequences matching the search criteria. In gel retardation assays, rPfIRPa bound three 32P-labeled putative plasmodial IREs with affinity exceeding the affinity for the mammalian consensus IRE. The binding was concentration-dependent and was not inhibited by heparin, an inhibitor of non-specific binding. Immunodepletion of rPfIRPa resulted in substantial inhibition of the signal intensity in the gel retardation assays and in Western blot-determinations of rPfIRPa protein levels. Endogenous PfIRPa retained all three putative 32P-IREs at the same position on the gel as the recombinant PfIRPa.     

Recent progress in iron metabolism and iron-related anemia

Iron is an essential metal not only in oxygen delivery, but also in cell proliferation and drug metabolism, while it is a very toxic metal producing reactive oxygen species(ROS). In order to avoid the toxicity and shortage of iron, the level of iron is strictly regulated in the body and cells. The central player regulating the amount of iron in the body is hepcidin. Hepcidin inhibits the release of iron from enterocytes and macrophages by accelerating the degradation of ferroportin, which is an exporter of iron. The amount of cellular iron is regulated by the IRE (iron responsive element) and IRP (iron regulatory protein) system. IRP1 and 2, whose activities depend on the concentration of cellular iron, bind to IRE, and regulate the translation of iron-related genes, which have IRE in 5' or 3'-UTR to balance iron uptake and utilization. Iron is utilized for the generation of heme and the iron-sulfur (Fe-S) cluster in mitochondoria. Mutations of genes involved in heme biosynthesis, iron-sulfur (Fe-S) cluster biogenesis, or Fe-S cluster transport cause an accumulation of iron in mitochondoria, leading to the onset of inherited sideroblastic anemia. The most common inherited sideroblastic anemia is X-linked sideroblastic anemia (XLSA) caused by mutations of the erythroid-specific delta-aminolevulinate synthase gene (ALAS2), which is the first enzyme involved in heme biosynthesis in erythroid cells. However, there are still significant numbers of cases with genetically undefined, inherited sideroblastic anemia. Molecular analysis of these cases will contribute to the understanding of mitochondrial iron metabolism.     

Skin fibroblasts from pantothenate kinase-associated neurodegeneration patients show altered cellular oxidative status and have defective iron-handling properties

Pantothenate kinase-associated neurodegeneration (PKAN) is a neurodegenerative disease belonging to the group of neurodegeneration with brain iron accumulation disorders. It is characterized by progressive impairments in movement, speech and cognition. The disease is inherited in a recessive manner due to mutations in the Pantothenate Kinase-2 (PANK2) gene that encodes a mitochondrial protein involved in Coenzyme A synthesis. To investigate the link between a PANK2 gene defect and iron accumulation, we analyzed primary skin fibroblasts from three PKAN patients and three unaffected subjects. The oxidative status of the cells and their ability to respond to iron were analyzed in both basal and iron supplementation conditions. In basal conditions, PKAN fibroblasts show an increase in carbonylated proteins and altered expression of antioxidant enzymes with respect to the controls. After iron supplementation, the PKAN fibroblasts had a defective response to the additional iron. Under these conditions, ferritins were up-regulated and Transferrin Receptor 1 (TfR1) was down-regulated to a minor extent in patients compared with the controls. Analysis of iron regulatory proteins (IRPs) reveals that, with respect to the controls, PKAN fibroblasts have a reduced amount of membrane-associated mRNA-bound IRP1, which responds imperfectly to iron. This accounts for the defective expression of ferritin and TfR1 in patients' cells. The inaccurate quantity of these proteins produced a higher bioactive labile iron pool and consequently increased iron-dependent reactive oxygen species formation. Our results suggest that Pank2 deficiency promotes an increased oxidative status that is further enhanced by the addition of iron, potentially causing damage in cells.     

Iron increases translation initiation directed by internal ribosome entry site of hepatitis C virus

Although increased liver iron in individuals with chronic hepatitis C virus (HCV) is associated with a poor response to interferon therapy, the underlying molecular mechanisms are poorly understood. In this study, we show that iron enhances the translation initiation mediated by the internal ribosome entry site (IRES) of HCV. We also demonstrate by UV cross-linking analysis that specific cellular proteins bind to HCV 5' untranslated region (5' UTR) in an iron-dependent manner. Notably, p85 and p110 are competed out for their binding to HCV 5' UTR when excess amounts of iron-responsive element (IRE) competitor RNAs are treated. This indicates that at least these two factors are common proteins for binding to HCV 5' UTR and IRE. Our results, taken together, suggest that intracellular iron modulates the iron sensing pathway and HCV IRES-dependent translation by changing the binding affinities of the common cellular factors to IRE and HCV IRES, respectively. As a consequence, the coordinated regulation of gene expression by intracellular iron could provide favorable conditions for HCV proliferation.     

The functions of IRE1α in neurodegenerative diseases: Beyond ER stress

Inositol-requiring enzyme 1 α (IRE1α) is a type I transmembrane protein that resides in the endoplasmic reticulum (ER). IRE1α, which is the primary sensor of ER stress, has been proven to maintain intracellular protein homeostasis by activating X-box binding protein 1 (XBP1). Further studies have revealed novel physiological functions of the IRE1α, such as its roles in mRNA and protein degradation, inflammation, immunity, cell proliferation and cell death. Therefore, the function of IRE1α is not limited to its role in ER stress; IRE1α is also important for regulating other processes related to cellular physiology. Furthermore, IRE1α plays a key role in neurodegenerative diseases that are caused by the phosphorylation of Tau protein, the accumulation of α-synuclein (α-syn) and the toxic effects of mutant Huntingtin (mHtt). Therefore, targeting IRE1α is a valuable approach for treating neurodegenerative diseases and regulating cell functions. This review discusses the role of IRE1α in different cellular processes, and emphasizes the importance of IRE1α in neurodegenerative diseases.     

Identification of iron-regulated proteins ofMycobacterium tuberculosisand cloning of tandem genes encoding a low iron-induced protein and a metal transporting ATPase with similarities to two-component metal transport systems

Iron plays a central role in the pathogenesis ofMycobacterium tuberculosis, the principal causative agent of tuberculosis. To learn more about iron acquisition by this bacterium, its iron regulated proteins (IRPs) were investigated. Seven IRPs were identified — three increased by high iron concentrations, and four by low iron concentrations. The smallest protein induced by low iron, Irp10, is tightly iron regulated as it is virtually absent in bacteria cultured in the presence of high iron concentrations. The gene (irpA) encoding this protein and an adjacent open reading frame,mtaA, were cloned and sequenced. The protein encoded bymtaA(Mta72) has striking homology to metal transporting P-type ATPases. This study suggests that Irp10 and Mta72 function as a two-component metal transport system inM. tuberculosis.     

A trypanosomatid protein specifically interacts with a mammalian iron-responsive element

Intracellular iron homeostasis of vertebrates and invertebrates is mediated through the interaction of iron-regulatory proteins (IRPs) with mRNAs containing a bulged hairpin-loop structure termed the iron-responsive element (IRE). We detected a protein within extracts prepared from Leishmania tarentolae that specifically interacts with a mammalian IRE; mutations to the IRE that inhibit the interaction with the mammalian protein have a corresponding effect on the interaction with the L. tarentolae protein. The disassociation constant noted for the interaction of the mammalian IRE with the L. tarentolae protein was 0.7 ± 0.3 μM, whereas that recorded for the interaction with the mammalian IRP under these conditions was 5 ± 2 nM. The interacting L. tarentolae protein potentially places the RNA-binding site of the IRP near the root of the eukaryotic evolutionary tree. However, unlike that of the mammalian IRPs, the L. tarentolae IRE-binding activity was not induced by growth in iron-depleted media. Received: 21 June 1999 / Accepted: 15 September 1999     

Expression of Neisseria meningitidis iron-regulated outer membrane proteins, including a 70-kilodalton transferrin receptor, and their potential for use as vaccines

The iron-regulated proteins (IRPs) of five group B meningococcal strains expressing class 2 outer membrane proteins were compared with those of five strains expressing class 3 proteins. Three to four high-molecular-weight IRPs were expressed by each strain, but their molecular sizes varied between strains and were not related to class 2 or 3 protein expression. Transferrin and hemoglobin could be used as a sole iron source. By using anti-human transferrin antibodies, it was shown that meningococcal cells and purified outer membranes bound transferrin. Growth under conditions of iron limitation caused a several-fold increase in the amount of transferrin bound to the cell surface. The transferrin-binding protein was detergent solubilized from outer membranes and partially purified. The isolated protein bound human transferrin and had an apparent molecular mass of 70 kilodaltons. To evaluate the potential of vaccines containing IRPs, we prepared outer membrane vaccines from strains M986-NCV-1 (M986) (--:2a: P1.2) and 44/76-M25 (44/76) (--:15:P1.15) grown to fully express their IRPs. Both vaccines induced significant anti-IRP antibodies as measured by enzyme immunoassay and by Western immunoblot with both M986 and 44/76 outer membranes. By Western blot analysis, the M986 vaccine induced antibodies to two different IRPs, one of which was shared with 44/76. Since the IRPs are major in vivo-expressed outer membrane proteins and are required for survival in vivo, these proteins should be evaluated for their usefulness in a group B meningococcal vaccine.     

铁转运相关蛋白在肌萎缩性侧索硬化症转基因鼠脊髓中的表达变化

目的探讨肌萎缩性侧索硬化症(ALS)转基因鼠脊髓内铁转运相关蛋白表达变化与铁稳态失衡的关联。方法选取h SOD1G93A转基因鼠(ALS鼠)和同窝野生型鼠(WT鼠),分别于生后70、95和122 d分离脊髓,每时间点每组各9只实验动物。Western blotting检测脊髓组织内铁转运蛋白二价金属转运蛋白-1(DMT1)、铁转运蛋白-1(FPN1)及调节蛋白铁调节蛋白-1(IRP1)的表达;免疫荧光双重标记检测脊髓腰段前角内细胞共定位情况。结果 Western blotting显示,与WT鼠比较,各时间点ALS鼠脊髓内DMT1表达均显著降低(P<0.05,P<0.01);70 d FPN1表达升高(P<0.05),95 d和122 d表达下降(P<0.01); 95 d、122 d IRP1表达降低(P<0.01)。免疫荧光双重标记显示,在70 d WT鼠和ALS鼠腰段脊髓中DMT1主要与β-微管蛋白Ⅲ(β-tubulinⅢ)共表达。与WT组相比,95 d ALS鼠脊髓腰段前角神经元内DMT1免疫反应强,而FPN1荧光强度减弱。随疾病进展,DMT1、FP...     

Iron metabolism, overview and recent insights

The paper is an up to date overview of knowledge on iron metabolism that integrate recent findings in this field. Significant advances were made in understanding the implication of protein factors (transporters, enzymes and regulation factors) in iron metabolism, as well as related genetic abnormalities. The research highlighted the complexity of mechanisms in charge of maintaining equilibrium of Fe in the body. The iron is vital to the life of cells, but its presence in excess is rather toxic. Iron is mostly required for hemoglobin synthesis. It is recycled between reticulo-endothelial macrophages and bone marrow that is the main user of iron. Intestinal absorption is a key step in determining iron capital in the body. Its rate is tightly controlled by several factors that act under influence of signals of unknown nature, which indicate iron needs and storage. The IRP/IRE (iron regulatory protein/iron responsive element) system controls cellular uptake, stores and exportation of iron, and heme synthesis. Mitochondrion is a dynamo of iron metabolism, being vital for heme synthesis and iron sulphur cluster genesis. The recent discovery of several mitochondrial proteins involved in iron metabolism resulted in better understanding mitochondrial iron movement, storage and exchange. Nevertheless, much remains to be known on the role of some actors such as HFE protein, hepcidin, hemojuvelin and transferrin receptor 2, and to determine the nature and mechanisms of signals regulating iron level in the body.     

Trace metal regulation of neuronal apoptosis: from genes to behavior

The genetically programmed form of neuronal death known as apoptosis plays a role in many neurodegenerative diseases including Alzheimer's disease, Parkinson's disease, amyotrophic lateral sclerosis (ALS) and Huntington's disease. Apoptosis is also responsible for neuronal death after traumatic brain and spinal cord injury, stroke, and seizures. The cognitive and behavioral consequences of all of these disorders can be devastating. Unfortunately the mechanisms that regulate neuronal apoptosis are complex. However, it is this very complexity that provides us with a wide array of potential targets for the development of anti-apoptotic strategies. Thus, our lab is currently exploring the molecular and cellular mechanisms responsible for neuronal apoptosis, with a particular focus on the role of the metals copper, zinc, and iron. Each of these metals is essential for normal central nervous system (CNS) development and function. However, imbalances, either excess or deficiency, can result in neuronal apoptosis. In this review, we show the relationship between these metals in neurodegenerative disorders and CNS injury, and the mechanisms that govern neuronal survival and apoptosis.     

Iron overload induces changes of pancreatic and duodenal divalent metal transporter 1 and prohepcidin expression in mice

It is well known that the iron content of the body is tightly regulated. Iron excess induces adaptive changes that are differentially regulated in each tissue. The pancreas is particularly susceptible to iron-related disorders. We studied the expression and regulation of key iron proteins in the pancreas, duodenum and liver, using an animal model of iron overload (female CF1 mice injected i.p. with iron saccharate, colloidal iron form). Divalent metal transporter 1, prohepcidin and ferritin (pancreas, duodenum, liver) were assessed by immunohistochemistry; divalent metal transporter 1 (pancreas, duodenum) by Western blot. In the iron overloaded mice, prohepcidin expression increased in islets of Langerhans and hepatocytes, and divalent metal transporter 1 expression decreased in cells of islets and in enterocytes. In the iron overloaded mice, ferritin expression decreased in islets of Langerhans and increased in acinar cells; hemosiderin was localized in connective tissue cells. The inverse relationship between divalent metal transporter 1 and prohepcidin may indicate a negative regulation by hepcidin, and hence reduction of iron stores in islets of Langerhans. Our data showed that in iron overloaded mice model, induced by colloidal iron form, a coordinated expression of key iron proteins in the pancreas, duodenum and liver may occur. Further research will be necessary to determine the adaptive responses induced by iron in the pancreas.