Transferrin Receptor mRNA Research Articles

Alteration of iron homeostasis following chronic exposure to manganese in rats

Recent studies suggest that manganese-induced neurodegenerative toxicity may be partly due to its action on aconitase, which participates in cellular iron regulation and mitochondrial energy production. This study was performed to investigate whether chronic manganese exposure in rats influenced the homeostasis of iron in blood and cerebrospinal fluid (CSF). Groups of 8–10 rats received intraperitoneal injections of MnCl 2 at the dose of 6 mg Mn/kg/day or equal volume of saline for 30 days. Concentrations of manganese and iron in plasma and CSF were determined by atomic absorption spectrophotometry. Rats exposed to manganese showed a greatly elevated manganese concentration in both plasma and CSF. The magnitude of increase in CSF manganese (11-fold) was equivalent to that of plasma (10-fold). Chronic manganese exposure resulted in a 32% decrease in plasma iron ( p<0.01) and no changes in plasma total iron binding capacity (TIBC). However, it increased CSF iron by 3-fold as compared to the controls ( p<0.01). Northern blot analyses of whole brain homogenates revealed a 34% increase in the expression of glutamine synthetase ( p<0.05) with unchanged metallothionein-I in manganese-intoxicated rats. When the cultured choroidal epithelial cells derived from rat choroid plexus were incubated with MnCl 2 (100 μM) for four days, the expression of transferrin receptor mRNA appeared to exceed by 50% that of control ( p<0.002). The results indicate that chronic manganese exposure alters iron homeostasis possibly by expediting unidirectional influx of iron from the systemic circulation to cerebral compartment. The action appears likely to be mediated by manganese-facilitated iron transport at brain barrier systems.

Ligand-induced Structural Alterations in Human Iron Regulatory Protein-1 Revealed by Protein Footprinting

Human iron regulatory protein-1 (IRP-1) is a bifunctional protein that regulates iron metabolism by binding to mRNAs encoding proteins involved in iron uptake, storage, and utilization. Intracellular iron accumulation regulates IRP-1 function by promoting the assembly of an iron-sulfur cluster, conferring aconitase activity to IRP-1, and hindering RNA binding. Using protein footprinting, we have studied the structure of the two functional forms of IRP-1 and have mapped the surface of the iron-responsive element (IRE) binding site. Binding of the ferritin IRE or of the minimal regulatory region of transferrin receptor mRNA induced strong protections against proteolysis in the region spanning amino acids 80 to 187, which are located in the putative cleft thought to be involved in RNA binding. In addition, IRE-induced protections were also found in the C-terminal domain at Arg-721 and Arg-728. These data implicate a bipartite IRE binding site located in the putative cleft of IRP-1. The aconitase form of IRP-1 adopts a more compact structure because strong reductions of cleavage were detected in two defined areas encompassing residues 149 to 187 and 721 to 735. Thus both ligands of apo-IRP-1, the IRE and the 4Fe-4S cluster, induce distinct but overlapping alterations in protease accessibility. These data provide evidences for structural changes in IRP-1 upon cluster formation that affect the accessibility of residues constituting the RNA binding site.

Ehrlichia chaffeensis and E. sennetsu, but not the human granulocytic ehrlichiosis agent, colocalize with transferrin receptor and up-regulate transferrin receptor mRNA by activating iron-responsive protein 1.

Ehrlichia chaffeensis and E. sennetsu are genetically divergent obligatory intracellular bacteria of human monocytes and macrophages, and the human granulocytic ehrlichiosis (HGE) agent is an obligatory intracellular bacterium of granulocytes. Infection with both E. chaffeensis and E. sennetsu, but not HGE agent, in the acute monocytic leukemia cell line THP-1 almost completely inhibited by treatment with deferoxamine, a cell-permeable iron chelator. Transferrin receptors (TfRs) accumulated on both E. chaffeensis and E. sennetsu, but not HGE agent, inclusions in THP-1 cells or the cells of the promyelocytic leukemia cell line HL-60. Reverse transcription-PCR showed an increase in the level of TfR mRNA 6 h postinfection which peaked at 24 h postinfection with both E. chaffeensis and E. sennetsu infection in THP-1 or HL-60 cells. In contrast, HGE agent in THP-1 or HL-60 cells induced no increase in TfR mRNA levels. Heat treatment of E. chaffeensis or the addition of monodansylcadaverine, a transglutaminase inhibitor, 3 h prior to infection inhibited the up-regulation of TfR mRNA. The addition of oxytetracycline 6 h after E. chaffeensis infection caused a decrease in TfR mRNA which returned to the basal level by 24 h postinfection. These results indicate that both internalization and continuous proliferation of ehrlichial organisms or the production of ehrlichial proteins are required for the up-regulation of TfR mRNA. Results of electrophoretic mobility shift assays showed that both E. chaffeensis and E. sennetsu infection increased the binding activity of iron-responsive protein 1 (IRP-1) to the iron-responsive element at 6 h postinfection and remained elevated at 24 h postinfection. However, HGE agent infection had no effect on IRP-1 binding activity. This result suggests that activation of IRP-1 and subsequent stabilization of TfR mRNA comprise the mechanism of TfR mRNA up-regulation by E. chaffeensis and E. sennetsu infection.

Cellular iron metabolism

Iron is essential for oxidation-reduction catalysis and bioenergetics, but unless appropriately shielded, iron plays a key role in the formation of toxic oxygen radicals that can attack all biological molecules. Hence, specialized molecules for the acquisition, transport (transferrin), and storage (ferritin) of iron in a soluble nontoxic form have evolved. Delivery of iron to most cells, probably including those of the kidney, occurs following the binding of transferrin to transferrin receptors on the cell membrane. The transferrin-receptor complexes are then internalized by endocytosis, and iron is released from transferrin by a process involving endosomal acidification. Cellular iron storage and uptake are coordinately regulated post-transcriptionally by cytoplasmic factors, iron-regulatory proteins 1 and 2 (IRP-1 and IRP-2). Under conditions of limited iron supply, IRP binding to iron-responsive elements (present in 5' untranslated region of ferritin mRNA and 3' untranslated region of transferrin receptor mRNA) blocks ferritin mRNA translation and stabilizes transferrin receptor mRNA. The opposite scenario develops when iron in the transit pool is plentiful. Moreover, IRP activities/levels can be affected by various forms of "oxidative stress" and nitric oxide. The kidney also requires iron for metabolic processes, and it is likely that iron deficiency or excess can cause disturbed function of kidney cells. Transferrin receptors are not evenly distributed throughout the kidney, and there is a cortical-to-medullary gradient in heme biosynthesis, with greatest activity in the cortex and least in the medulla. This suggests that there are unique iron/heme metabolism features in some kidney cells, but the specific aspects of iron and heme metabolism in the kidney are yet to be explained.

Inactivation of Both RNA Binding and Aconitase Activities of Iron Regulatory Protein-1 by Quinone-induced Oxidative Stress

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.

Increased Placental Iron Regulatory Protein-1 Expression in Diabetic Pregnancies Complicated by Fetal Iron Deficiency

Placental transferrin receptor (TfR) protein expression is increased in diabetic pregnancies that are complicated by low fetal iron stores, suggesting regulation of placental iron transport by fetoplacental iron status. In cell culture, iron homeostasis is regulated by coordinate stabilization of TfR mRNA and translation inactivation of ferritin mRNA by iron regulatory proteins (IRP-1 and -2) which bind to iron-responsive elements (IREs) on the respective mRNAs. Concentrations of IRP-1, IRP-2 and TfR mRNA were measured in 10 placentae obtained from diabetic and non-diabetic human pregnancies with a wide range of fetoplacental iron status. IRP-1 activity was present in human placenta and correlated closely with TfR mRNA concentration (r=0.82;P=0.007). IRP-2 activity and protein were not detected. In a second experiment, placentae were collected from 12 diabetic pregnancies, six with low fetal cord serum ferritin and placental non-heme iron concentrations, and six with normal iron status. IRP-1 activity and TfRBmaxfor diferric transferrin were greater in the iron-deficient group (P<0.05). IRP-1 activity correlated inversely with cord serum ferritin (r=0.75;P<0.01) and placental non-heme iron (r=0.61;P=0.05) concentration. Placental IRP-1 activity is directly related to TfR mRNA concentration and is more highly expressed in iron-deficient placentae. The study provides direct in vivo evidence for IRP regulation of TfR expression in the human placenta.

Non-iron Metals Bind with Iron Regulatory Protein to Influence Its Function

An iron regulatory protein (IRP) is an RNA-binding protein that regulates the expression of several mRNAs such as transferrin receptor (Tf-Rc) and ferritin mRNAs in response to the availability of cellular iron (Fe). IRP interacts with the iron-responsive element (IRE) in both of mRNAs to regulate the life span and to modulate the translation rate of ferritin. IRP was also identified as cytosol aconitase. We previously demonstrated that aluminum (Al)as well as Fe decrease the expression of Tf-Rc mRNA in rat cortical cells treated with Al-and Fe-nitrilotriacetate. In this study, we examined the effect of non-Fe metals on IRP using gel shift and the enzyme assays. IRE was transcriptionally synthesized in vitro and IRP purified from the beef liver. Non-Fe metals including mercury, cadmium, copper, manganese and nickel decreased the binding activities of IRP to IRE with an increase in the aconitase activity in a dose-dependent manner. These data suggest that non-Fe metals bind IRP in 3Fe-4S state to influence its function.

Molecular Cloning of Mouse Glycolate Oxidase: HIGH EVOLUTIONARY CONSERVATION AND PRESENCE OF AN IRON-RESPONSIVE ELEMENT-LIKE SEQUENCE IN THE mRNA

Iron regulatory proteins (IRPs) control the synthesis of several proteins in iron metabolism by binding to iron-responsive elements (IREs), a hairpin structure in the untranslated region (UTR) of corresponding mRNAs. Binding of IRPs to IREs in the 5' UTR inhibits translation of ferritin heavy and light chain, erythroid aminolevulinic acid synthase, mitochondrial aconitase, and Drosophila succinate dehydrogenase b, whereas IRP binding to IREs in the 3' UTR of transferrin receptor mRNA prolongs mRNA half-life. To identify new targets of IRPs, we devised a method to enrich IRE-containing mRNAs by using recombinant IRP-1 as an affinity matrix. A cDNA library established from enriched mRNA was screened by an RNA-protein band shift assay. This revealed a novel IRE-like sequence in the 3' UTR of a liver-specific mouse mRNA. The newly identified cDNA codes for a protein with high homology to plant glycolate oxidase (GOX). Recombinant protein expressed in bacteria displayed enzymatic GOX activity. Therefore, this cDNA represents the first vertebrate GOX homologue. The IRE-like sequence in mouse GOX exhibited strong binding to IRPs at room temperature. However, it differs from functional IREs by a mismatch in the middle of its upper stem and did not confer iron-dependent regulation in cells.

Loops and Bulge/Loops in Iron-responsive Element Isoforms Influence Iron Regulatory Protein Binding: FINE-TUNING OF mRNA REGULATION?

A family of noncoding mRNA sequences, iron-responsive elements (IREs), coordinately regulate several mRNAs through binding a family of mRNA-specific proteins, iron regulatory proteins (IRPs). IREs are hairpins with a constant terminal loop and base-paired stems interrupted by an internal loop/bulge (in ferritin mRNA) or a C-bulge (in m-aconitase, erythroid aminolevulinate synthase, and transferrin receptor mRNAs). IRP2 binding requires the conserved C-G base pair in the terminal loop, whereas IRP1 binding occurs with the C-G or engineered U-A. Here we show the contribution of the IRE internal loop/bulge to IRP2 binding by comparing natural and engineered IRE variants. Conversion of the internal loop/bulge in the ferritin-IRE to a C-bulge, by deletion of U, decreased IRP2 binding by >95%, whereas IRP1 binding changed only 13%. Moreover, IRP2 binding to natural IREs with the C-bulge was similar to the DeltaU6 ferritin-IRE: >90% lower than the ferritin-IRE. The results predict mRNA-specific variation in IRE-dependent regulation in vivo and may relate to previously observed differences in iron-induced ferritin and m-aconitase synthesis in liver and cultured cells. Variations in IRE structure and cellular IRP1/IRP2 ratios can provide a range of finely tuned, mRNA-specific responses to the same (iron) signal.

Expression of the neuronal transferrin receptor is age dependent and susceptible to iron deficiency

In order to characterize the mechanism by which Iron (Fe) is taken up by neurons, we examined the neuronal expression of transferrin receptor (TR) in rats during development and iron (Fe) deficiency by using immunohistochemistry, in vitro receptor autoradiography and in situ hybridization. In contrast to the continuous expression of TR in brain capillary endothelial cells regardless of the age of the animals studied, the expression of neuronal TR was almost absent at late embryonic and early postnatal ages but increased with increasing age to reach a plateau from postnatal (P) 21 through adulthood as verified by immunohistochemical staining. Reducing the Fe stores potentiated the expression of TR immunoreactivity in neurons of both young and adult rats in several grey matter regions. Increased TR immunoreactivity was also observed in neuronal extensions of neurons of the medial habenular nucleus, reticular neurons of the brainstem, and fibers projecting to the area postrema. TR immunoreactivity was never observed in white matter regions, except for that recorded in brain capillaries. In vitro receptor autoradiography verified the increased capacity for transferrin binding during Fe deficiency. By contrast, TR mRNA expression was not affected by Fe deficiency. These findings demonstrate that the expression of the neuronal TR protein is age dependent and susceptible to Fe deficiency.

Expression of the neuronal transferrin receptor is age dependent and susceptible to iron deficiency

In order to characterize the mechanism by which Iron (Fe) is taken up by neurons, we examined the neuronal expression of transferrin receptor (TR) in rats during development and iron (Fe) deficiency by using immunohistochemistry, in vitro receptor autoradiography and in situ hybridization. In contrast to the continuous expression of TR in brain capillary endothelial cells regardless of the age of the animals studied, the expression of neuronal TR was almost absent at late embryonic and early postnatal ages but increased with increasing age to reach a plateau from postnatal (P) 21 through adulthood as verified by immunohistochemical staining. Reducing the Fe stores potentiated the expression of TR immunoreactivity in neurons of both young and adult rats in several grey matter regions. Increased TR immunoreactivity was also observed in neuronal extensions of neurons of the medial habenular nucleus, reticular neurons of the brainstem, and fibers projecting to the area postrema. TR immunoreactivity was never observed in white matter regions, except for that recorded in brain capillaries. In vitro receptor autoradiography verified the increased capacity for transferrin binding during Fe deficiency. By contrast, TR mRNA expression was not affected by Fe deficiency. These findings demonstrate that the expression of the neuronal TR protein is age dependent and susceptible to Fe deficiency. J. Comp. Neurol. 398:420–430, 1998. © 1998 Wiley-Liss, Inc.

Antiproliferative effect of deferiprone on the Hep G2 cell line

Iron is an essential element in cellular metabolism and the growth of all living species, and is involved in DNA replication. The risk of hepatocellular carcinoma development is associated with an increase in iron availability. The aim of the present work was to investigate the effect of an oral iron chelator, deferiprone (CP20), on HepG2 cell-line proliferation in culture. HepG2 cell cultures were maintained in the absence of fetal calf serum (FCS) and in the presence or not (control cultures) of CP20 at the concentrations of 50 or 100 μM; deferoxamine (DFO) was used as an iron chelator reference. Cell proliferation was investigated by the analysis of DNA synthesis using [ 3H] methyl-thymidine incorporation and of the cell cycle by flow cytometry. Iron chelation efficiency in the culture model was studied by analyzing the effect of CP20 on radioactive iron uptake, intracellular ferritin level, and transferrin receptor expression. CP20, at the concentration of 50 or 100 μM, inhibited DNA synthesis after 48 hr of incubation and induced an accumulation of the cells in the S phase of the cell cycle. Iron chelators inhibited cellular iron uptake, decreased intracellular ferritin level, and increased transferrin receptor protein and mRNA levels. Our results show that CP20 as well as deferoxamine inhibit HepG2 cell proliferation and block cell cycle in the S phase.

Effect of Ascorbic Acid Administration on Serum Concentration of Transferrin Receptors

Since Szent-Gyorgyi first purified ascorbic acid (vitamin C) in 1928 (1), a number of associations between ascorbic acid and iron metabolism have been described. At the molecular level, ascorbic acid mobilizes iron from the crystal core of ferritin in vitro by reducing Fe3 to Fe2 (2). Intracellularly, ascorbic acid enhances iron-induced translation of ferritin (3) by favoring the conversion of the iron regulatory protein (IRP) from the RNA binding form to aconitase (3). Ascorbic acid also retards degradation of ferritin by blocking lysosomal autophagy of ferritin and transformation to hemosiderin (4)(5). In humans, the oral administration of ascorbic acid enhances the absorption of non-heme iron from the diet (6) and leads to increases in serum iron in subjects with iron overload and ascorbic acid deficiency (7). Moreover, iron overload states are associated with reduced ascorbic acid concentrations, possibly because of increased catabolism of ascorbic acid (7)(8). The amount of labile iron in the cytosol influences the stability of transferrin receptor mRNA and the translation of ferritin mRNA (9)(10)(11). Posttranscriptional regulation occurs by means of an interaction between IRPs, proteins that sense changes in the chelatable intracellular iron pool, and iron-responsive elements located on untranslated regions of transferrin receptor mRNA and ferritin mRNA (12)(13)(14). In states of iron abundance, an IRP has aconitase activity and does not bind to iron-responsive elements, producing increased transferrin receptor mRNA degradation and increased ferritin mRNA translation. Conversely, when iron is deficient, an IRP loses aconitase activity and binds to iron-responsive elements, causing increased transferrin receptor mRNA stability and a repression of ferritin mRNA translation (15)(16). Thus, intracellularly, the presence of iron leads to inhibition of transferrin receptor expression and promotion of higher ferritin expression, whereas the deprivation of …

Lack of coordinate control of ferritin and transferrin receptor expression during rat liver regeneration.

Transferrin receptor (TfR) and ferritin, key proteins of cellular iron metabolism, are coordinately and divergently controlled by cytoplasmic proteins (iron regulatory proteins, IRP-1 and IRP-2) that bind to conserved mRNA motifs called iron-responsive elements (IRE). IRP, in response to specific stimuli (low iron levels, growth and stress signals) are activated and prevent TfR mRNA degradation and ferritin mRNA translation by hindering ferritin mRNA binding to polysomes. We previously found that, in regenerating liver, IRP activation was accompanied by increased TfR mRNA levels, but not by reduced ferritin expression. The basis for this unexpected behavior was investigated in the present study. Liver regeneration triggered by carbon tetrachloride (CCl4) stimulated by four- to fivefold the synthesis of both L and H ferritin chains. This increase was accompanied with a transcriptionally regulated twofold rise in the amount of ferritin mRNAs. Moreover, polysome-associated ferritin transcripts were fourfold higher in CCl4-treated animals than in control animals. Because RNA bandshift assays showed a fourfold increase in IRP-2 binding activity after CCl4 administration, activated IRP in regenerating liver seemed unable to prevent ferritin mRNAs binding to polysomes. This was confirmed by direct demonstration in the wheat germ translation system that the efficiency of IRP as a translational repressor of a mRNA bearing an IRE motif in front of a reporter transcript is impaired in CCl4-treated rats in spite of an enhanced IRE-binding capacity. In conclusion, we show for the first time that the paradigm of coordinate and opposite control of ferritin and TfR by IRP is contradicted in liver regeneration. Under these circumstances, growth-dependent signals may activate ferritin gene transcription and at the same time hamper the ability of activated IRP-2 to repress translation of ferritin mRNAs, thus preserving for growing liver cells an essential iron-storage compartment.

Cellular expression and regulation of iron transport and storage proteins in genetic haemochromatosis.

Genetic haemochromatosis is a common iron overload disorder of unknown aetiology. To characterize the defect of iron metabolism responsible for this disease, this study localized and semi-quantified the mRNA and protein expression of transferrin, transferrin receptor and ferritin in the liver and duodenum of patients with genetic haemochromatosis. Biopsies were obtained from iron-loaded non-cirrhotic patients with genetic haemochromatotic and control patients with normal iron stores. Additional duodenal biopsies were obtained from patients with iron deficiency. Immunohistochemical and in situ hybridization analysis for transferrin, transferrin receptor and ferritin was performed. Hepatic transferrin, transferrin receptor and ferritin protein expression was localized predominantly to hepatocytes and was increased in patients with genetic haemochromatosis when compared with normal controls. Interestingly, hepatic ferritin mRNA expression was not increased in these same patients. In the genetic haemochromatotic duodenum, ferritin mRNA and protein was localized mainly to crypt and villus epithelial cells and the level of expression was decreased compared with normal controls, but similar to iron deficiency. Duodenal transferrin receptor mRNA and protein levels colocalized to epithelial cells of the crypt and villus were similar to normal controls. Early in the course of genetic haemochromatosis and before the onset of hepatic fibrosis, transferrin receptor-mediated iron uptake by hepatocytes contributes to hepatic iron overload. Increased hepatic ferritin expression suggests this is the major iron storage protein. While persisting duodenal transferrin receptor expression may be a normal response to increased body iron stores in patients with genetic haemochromatosis, decreased duodenal ferritin levels suggest that duodenal mucosa is regulated as if the patient were iron deficient.

Circulating Transferrin Receptor Assay—Coming of Age

Transferrin receptors are transmembrane proteins present on the surface of most cells. Under normal circumstances, the iron required for cellular metabolism is acquired via transferrin receptors. Several recent reviews detail the methods of iron acquisition, the intracellular throughput of transferrin receptors, and the controlling mechanisms in the cell‘s quest to acquire and store iron (1)(2)(3). The cells of different organ systems show considerable differences in the concentration of cellular transferrin receptor, the highest concentrations being found in cells of organs with the highest iron requirements, such as the erythroid bone marrow and placenta (4). The concentration of cell surface transferrin receptor is carefully regulated by transferrin receptor mRNA according to the internal iron content of the cell and its individual iron requirements. Iron-deficient cells contain increased numbers of receptor, while receptor numbers are downregulated in iron-replete cells (4)(5). Transferrin receptor was identified in serum (6) after investigators recognized that the molecule was secreted into culture media in reticulocyte and erythroleukemia cell models (7)(8), and the concentrations of secreted receptor were found to correlate with the total receptor content of the cells. Subsequent studies showed that serum concentrations of transferrin receptor increase in iron-deficiency anemia, making it a useful marker in the diagnosis of microcytic anemias (9). Circulating transferrin receptor is a truncated form of tissue receptor (10), produced by proteolytic cleavage of cellular receptor, and for the most part circulates attached to transferrin (11)(12). The reference interval for concentration of circulating receptor varies between different assay systems, depending on the choice of calibrators. In this issue of Clinical Chemistry , the transferrin receptor assay recently approved by the US Food and Drug Administration is described by Allen et al. (13). The calibrators used in this enzyme immunoassay system are …

Regulation of expression of ferritin H-chain and transferrin receptor by protoporphyrin IX.

The effect of protoporphyrin IX (hemin without iron) on the expression of transferrin receptor and ferritin was investigated in Friend leukemia cells. Cells treated with protoporphyrin IX exhibit enhanced transferrin-receptor expression and markedly reduced ferritin synthesis. Stimulation of transferrin-receptor expression is observed at both the mRNA and protein level. The effect on ferritin synthesis is mediated by translational inhibition of the mRNA, which, in contrast, is transcriptionally stimulated by protoporphyrin IX treatment. The regulation of transferrin receptor and ferritin in response to iron perturbations has been studied extensively and is mediated by the binding of iron-regulatory proteins (IRP) to the iron-responsive elements (IRE) present in the 3' and 5' untranslated regions of the transferrin-receptor and ferritin mRNA, respectively. To elucidate the molecular mechanisms underlying the effects of protoporphyrin IX on ferritin and transferrin-receptor expression, the role of the IRE sequence was investigated both in vivo by transfection experiments, with a construct containing the coding region for the chloramphenicol acetyltransferase (CAT) reporter gene under the translational control of the ferritin IRE, and in vitro by RNA band-shift assays. Whereas, examination of IRP binding to the IRE by in vitro assays suggests an apparent inactivation of IRP by protoporphyrin IX treatment, CAT assays indicate that protoporphyrin IX is able to induce in vivo a translational inhibition similar to that obtained by treatment with the iron chelator Desferal. This observation raises the possibility of different effects on the IRP activity exerted by porphyrin treatment in intact tissue-culture cells and in vitro. We conclude that translation of ferritin mRNA and degradation of transferrin-receptor mRNA are inhibited in intact tissue-culture cells by protoporphyrin IX through a mechanism similar to that exerted by iron chelation, thus involving depletion of the intracellular iron pool. These results can improve the understanding of the regulation of ferritin gene expression in some pathological conditions associated with disturbed heme synthesis.

Nuclear Domains in Skeletal Myotubes: The Localization of Transferrin Receptor mRNA Is Independent of Its Half-Life and Restricted by Binding to Ribosomes

The retention of mRNAs near the nuclei that synthesize them may be an important feature of the organization of multinucleated skeletal myotubes. Here, we assess the possible role of two factors in this localization. First, we examine the role of mRNA half-life, by studying the distribution of the mRNA for the transferrin receptor (TfR), whose half-life can be manipulated in culture by changing the availability of iron.In situhybridization of myotubes of the mouse muscle cell line C2 shows that TfR mRNA is concentrated in the core of the myotubes. Its distribution around the nuclei is often asymmetric and its concentration changes abruptly. Stable transcripts display the same asymmetric localization as unstable ones, suggesting that half-life does not determine subcellular localization of TfR mRNA. Differential effects of the protein synthesis inhibitors puromycin and cycloheximide suggest that the mRNA is retained in position by its association with ribosomes. We then examine the distribution of the rough endoplasmic reticulum (RER) and find it to be broader than the distribution of TfR mRNA. In contrast to TfR mRNA, the mRNA for a secreted immunoglobulin κ light chain has a more uniform distribution. Taken together, the results suggest that TfR mRNA may associate with RER subdomains by specific targeting.

Structure and dynamics of the iron responsive element RNA: implications for binding of the RNA by iron regulatory binding proteins

The iron responsive element (IRE) is a ∼30 nucleotide RNA hairpin that is located in the 5′ untranslated region of all ferritin mRNAs and in the 3′ untranslated region of all transferrin receptor mRNAs. The IREs are bound by two related IRE-binding proteins (IRPs) which help control intracellular levels of iron by regulating the expression of both ferritin and transferrin receptor genes. Multi-dimensional NMR and computational approaches were used to study the structure and dynamics of the IRE RNA in solution. The NMR data are consistent with formation of A-form helical stem regions, a one-base internal bulge and a Watson-Crick C·G base-pair between the first and fifth nucleotides in the loop. A superposition of refined structures indicates that the conserved C in the internal bulge, and three residues in the six-nucleotide hairpin loop are quite dynamic in this RNA. The structural roles of the stems, the loop and the bulge in the function of the IRE RNA and in possible interactions with the iron regulatory protein are discussed.

Unidirectional upregulation of the synthesis of the major iron proteins, transferrin-receptor and ferritin, in HepG2 cells by the acute-phase protein α1-antitrypsin

Background/Aims: We have previously shown that the hepatic acute-phase protein α1-antitrypsin (α1-AT) is an important mediator of changes in iron metabolism in the course of anaemia of chronic disease. α1-AT profoundly reduces growth of erythroid cells by interfering with transferrin-mediated iron uptake. In the present work we investigate the effects of α1-AT on hepatic iron metabolism, as the liver plays a central role in body iron metabolism and in metabolic changes during acute-phase response. Methods: The human hepatoma cell line Hep G2 was cultured in RPMI 1640+10% FCS. The effect of α1-AT on transferrin-receptor binding was investigated in equilibrium binding assays with 125I-transferrin. Expression of transferrin receptor was determined by saturation experiments and intracellular ferritin was measured in cell lysates after incubating cells either alone or with α1-AT. To determine iron regulatory protein binding activity to iron responsive elements we used gel retardation assays and Northern blot analysis was carried out to investigate transferrin receptor and ferritin mRNA expression. Results: α1-AT completely prevented transferrin from binding to its receptor and internalization of the transferrin-transferrin receptor complex on HepG2. In addition, α1-AT caused a distinct increase in iron regulatory protein binding activity to iron responsive elements, which is characteristic of iron deprivation. Normally, the synthesis of transferrin receptor and ferritin is regulated bidirectionally, but α1-AT promoted a unidirectional regulation. α1-AT increased the synthesis of both transferrin receptor and ferritin and, moreover, increased cellular amounts of transferrin receptor mRNA and ferritin H-chain mRNA. Conclusions: The effect of α1-AT on transferrin receptor synthesis appears to be mediated via activation of iron responsive element binding affinity of iron regulatory protein leading to an increased stability of transferrin receptor mRNA. Changes in ferritin, however, may be related to a transcriptionally mediated, iron-independent pathway which overrides the influence of activated iron regulatory protein. These specific changes in iron metabolism are the very ones seen in the course of anaemia of chronic disease. Our results emphasize the central role of α1-AT as a mediator of altered iron metabolism, characteristic of anaemia of chronic disease, not only with respect to erythroid cells but also with respect to liver cells.