Intracellular Iron Status Research Articles

Increased susceptibility to oxidative stress in scrapie-infected neuroblastoma cells is associated with intracellular iron status

The molecular mechanism of neurodegeneration in prion diseases remains largely uncertain, but one of the features of infected cells is higher sensitivity to induced oxidative stress. In this study, we have investigated the role of iron in hydrogen peroxide (H 2O 2)-induced toxicity in scrapie-infected mouse neuroblastoma N2a (ScN2a) cells. ScN2a cells were significantly more susceptible to H 2O 2 toxicity than N2a cells as revealed by cell viability (MTT) assay. After 2 h exposure, significant decrease in cell viability in ScN2a cells was observed at low concentrations of extracellular H 2O 2 (5–10 μM), whereas N2a cells were not affected. The increased H 2O 2 toxicity in ScN2a cells may be related to intracellular iron status since ferrous iron (Fe 2+) chelator 2,2′-bipyridyl (BIP) prevented H 2O 2-induced decrease in cell viability. Further, the level of calcein-sensitive labile iron pool (LIP) was significantly increased in ScN2a cells after H 2O 2 treatment. Finally, the production of reactive oxygen species (ROS) was inhibited by 30% by iron chelators desferrioxamine (DFO) and BIP in ScN2a cells, whereas no significant effect of iron chelators on basal ROS production was observed in N2a cells. This study indicates that cellular resistance to oxidative stress in ScN2a cells is associated with intracellular status of reactive iron.

Divalent metal transporter 1

In the last few years, the field of iron metabolism has exploded with the discovery of many new proteins including ferroportin, hephaestin, hepcidin, duodenal cytochrome b and the topic of this review, divalent metal ion transporter 1 (DMT1). DMT1 functions in transport of ferrous iron, and some, but not all divalent metal ions across the plasma membrane and/or out of the endosomal compartment. DMT1 mRNA has been found in every cell type in which it has been sought and its structure is highly conserved in evolution with similar proteins expressed in plants, insects, microorganisms and vertebrate animals. Rodents with defects in iron absorption and utilization were identified long before it was determined that the defect was due to a single nucleotide mutation in DMT1. Study of these animals reveals that transport of iron and other divalent metal ions by DMT1 is pH dependent, but the exact manner in which pH exerts its effect is unknown. The structure of the DMT1 gene is complex. Alternative usage of 3' exons, results in forms with and without iron responsive elements (IREs), while alternative usage of 5' exons and less well defined products of alternative splicing results in an array of isoforms with incompletely defined function. Expression of some isoforms is tissue specific and appears to affect subcellular targeting of the protein. At least one signal for DMT1 expression appears to be intracellular iron status, however, other, as yet undefined signals may also contribute to DMT1 expression. Interestingly, DMT1 function may differ subtly between humans and other animals; the spontaneous DMT1 mutation found in mice and rats appears to limit iron uptake in the intestine and iron utilization in red cell precursors, whereas the only known human mutation has its primary effect on iron utilization by erythroid cells. The importance of DMT1 function at the level of the whole organism and the individual cell and mechanisms of its regulation on a molecular scale are only beginning to be understood; an appreciation of these process will lead to an understanding of the role of iron in various cellular processes and improved treatments for both anemia and iron-overload.

Regulation of the Intracellular Free Iron Pool by Dpr Provides Oxygen Tolerance to Streptococcus mutans

Dpr is an iron-binding protein required for oxygen tolerance in Streptococcus mutans. We previously proposed that Dpr could confer oxygen tolerance to the bacterium by sequestering intracellular free iron ions that catalyze generation of highly toxic radicals (Y. Yamamoto, M. Higuchi, L. B. Poole, and Y. Kamio, J. Bacteriol. 182:3740-3747, 2000; Y. Yamamoto, L. B. Poole, R. R. Hantgan, and Y. Kamio, J. Bacteriol. 184:2931-2939, 2002). Here, we examined the intracellular free iron status of wild-type (WT) and dpr mutant strains of S. mutans, before and after exposure to air, by using electron spin resonance spectrometry. Under anaerobic conditions, free iron ion concentrations of WT and dpr strains were 225.9 +/- 2.6 and 333.0 +/- 61.3 microM, respectively. Exposure of WT cells to air for 1 h induced Dpr expression and reduced intracellular free iron ion concentrations to 22.5 +/- 5.3 microM; under these conditions, dpr mutant cells maintained intracellular iron concentration at 230.3 +/- 28.8 microM. A decrease in cell viability and genomic DNA degradation was observed in the dpr mutant exposed to air. These data indicate that regulation of the intracellular free iron pool by Dpr is required for oxygen tolerance in S. mutans.

Defective regulation of iron transporters leading to iron excess in the polymorphonuclear leukocytes of patients on maintenance hemodialysis

Background: Although hemodialysis (HD) patients are suspected of having defectively regulated iron metabolism, intracellular iron status has never been investigated thoroughly. To clarify the iron metabolism of HD patients, proteins involved in iron import (transferrin receptor [TfR]), as well as export (ferroportin 1), were investigated in polymorphonuclear leukocytes (PMNLs). Relations between iron status and several PMNL functions also were tested. Methods: Seventeen HD patients and 17 controls were recruited. Relative quantitative polymerase chain reaction was used to measure ferroportin 1 and TfR messenger RNA (mRNA), and ferroportin 1 and TfR expression were semiquantified by means of Western blot analysis or immunohistochemistry. PMNL functions also were examined. Results: Serum iron levels were significantly lower in HD patients than controls, and serum ferritin levels, as well as PMNL ferritin and iron content, were elevated in HD patients. Ferroportin 1 mRNA levels were substantially lower in PMNLs from HD patients, whereas TfR mRNA levels were higher. Western blot analysis and immunohistochemistry confirmed that expression of the corresponding proteins paralleled those of the mRNAs. PMNL phagocytic and bactericidal activity did not differ between HD patients and controls. Chemotactic peptide f-Met-Leu-Phe-stimulated degranulation activity of lactoferrin (Lf) was decreased significantly in HD patients, whereas those of myeloperoxidase and elastase were accelerated. Lf release correlated negatively with intracellular ferritin level. Conclusion: We show for the first time that increased iron levels in PMNLs of HD patients were associated with downregulation of ferroportin 1 and upregulation of TfR, which might be linked to hypercytokinemia.

Effects of sham air and cigarette smoke on A549 lung cells: implications for iron-mediated oxidative damage

Inhalation of airborne pollution particles that contain iron can result in a variety of detrimental changes to lung cells and tissues. The lung iron burden can be substantially increased by exposure to cigarette smoke, and cigarette smoke contains iron particulates, as well as several environmental toxins, that could influence intracellular iron status. We are interested in the effects of environmental contaminants on intracellular iron metabolism. We initiated our studies using lung A549 type II epithelial cells as a model, and we evaluated the effects of iron dose and smoke treatment on several parameters of intracellular iron metabolism. We show that iron at a physiological dose stimulates ferritin synthesis without altering the transferrin receptor (TfR) mRNA levels of these cells. This is mediated primarily by a reduction of iron regulatory protein 2. Higher doses of iron reduce iron regulatory protein-1 binding activity and are accompanied by a reduction in TfR mRNA. Thus, for A549 cells, different mechanisms influencing IRP-IRE interaction allow ferritin translation in the presence of TfR mRNA to provide for iron needs and yet prevent excessive iron uptake. More importantly, we report that smoke treatment diminishes ferritin levels and increases TfR mRNA of A549 cells. Ferritin serves as a cytoprotective agent against oxidative stress. These data suggest that exposure of lung cells to low levels of smoke as are present in environmental pollutants could result in reduced cytoprotection by ferritin at a time when iron uptake is sustained, thus enhancing the possibility of lung damage by iron-mediated oxidative stress.

Receptor sérico de transferrina en niños sanos. Valor diagnóstico en la anemia infecciosa y en la ferropénica

The serum transferrin receptor (TfR) presents certain advantages over other parameters of cellular iron status because it does not vary in acute or chronic diseases. To establish reference ranges of TfR in healthy children for our laboratory, to define the distribution of this variable in children with acute illness and in those with iron deficiency, and to evaluate the diagnostic yield of TfR, the transferrin-receptor/ferritin ratio (TfR/F) and the transferrin-receptor-ferritin index (TfR-F) in distinguishing ferropenic from infectious anemia. A descriptive, cross-sectional analysis was conducted in 132 children aged from 6 months to 16 years for a period of 18 months. The subjects were classified in three groups: healthy children, children with acute illness, and children with iron deficiency. The distribution of TfR and its diagnostic yield were evaluated. Of the 132 subjects, 30 were excluded because they lacked one or more of the parameters under analysis and 19 were excluded because they showed a thalassemic trait. In the 30 healthy children, the mean TfR concentration was 1.2 mg/l (SD 0.36) and the median was 1.02 (IQR 0.7-1.7). In the 32 children with acute illness, with or without anemia, TfR values were similar to those found in healthy children (p > 0.05). TfR values were higher in children with iron deficiency (21 patients; mean TfR value: 1.67 mg/l SD 0:98) than in healthy children but this difference was not statistically significant (p 0.08). The highest TfR values were found in the group with ferropenic anemia (mean TfR value: 2.13 mg/l SD 1.14) with a statistically significant difference between healthy children (p 0.04) and those with iron deficiency without anemia (p 0.01). The TfR/F ratio showed an optimal diagnostic yield in distinguishing ferropenic from acute disease anemia. If this ratio is higher than 80.7 ferropenia can be suspected as the cause of the anemia with a global value of the test of 100 % (95 % CI: 75.91-99.42). TfR could be useful in evaluating intracellular iron status in children. Acute disease does not alter TfR values and, in combination with ferritin, TfR offers an optimal diagnostical yield in distinguishing ferropenic from acute illness anemia.

Characterization of an Iron-dependent Regulatory Sequence Involved in the Transcriptional Control of AtFer1and ZmFer1 Plant Ferritin Genes by Iron

In eukaryotic cells, ferritin synthesis is controlled by the intracellular iron status. In mammalian cells, iron derepresses ferritin mRNA translation, whereas it induces ferritin gene transcription in plants. Promoter deletion and site-directed mutagenesis analysis, combined with gel shift assays, has allowed identification of a new cis-regulatory element in the promoter region of the ZmFer1 maize ferritin gene. This Iron-Dependent Regulatory Sequence (IDRS) is responsible for transcriptional repression of ZmFer1 under low iron supply conditions. The IDRS is specific to the ZmFer1 iron-dependent regulation and does not mediate the antioxidant response that we have previously reported (Savino et al. (1997) J. Biol. Chem. 272, 33319-33326). In addition, we have cloned AtFer1, the Arabidopsis thaliana ZmFer1 orthologue. The IDRS element is conserved in the AtFer1 promoter region and is functional as shown by transient assay in A. thaliana cells and stable transformation in A. thaliana transgenic plants, demonstrating its ubiquity in the plant kingdom.

Intracellular iron status as a hallmark of mammalian cell susceptibility to oxidative stress: a study of L5178Y mouse lymphoma cell lines differentially sensitive to H2O2

The redox properties of iron make this metal a key participant in oxygen-mediated toxicity. Accordingly, L5178Y (LY) mouse lymphoma cell lines, which display a unique inverse cross-sensitivity to ionizing radiation (IR) and hydrogen peroxide (H(2)O(2)), are a suitable model for the study of possible differences in the constitutive control of intracellular iron availability. We report here that the level of iron in the cytosolic labile iron pool (LIP), ie, potentially active in the Fenton reaction, is more than 3-fold higher in IR-resistant, H(2)O(2)-sensitive (LY-R) cells than in IR-sensitive, H(2)O(2)-resistant (LY-S) cells. This difference is associated with markedly greater content of ferritin H-subunits (H-Ft) in LY-S than in LY-R cells. Our results show that different expression of H-Ft in LY cells is a consequence of an up-regulation of H-Ft mRNA in the LY-S mutant cell line. In contrast, posttranscriptional control of iron metabolism mediated by iron-responsive element-iron regulatory proteins (IRPs) interaction is similar in the 2 cell lines, although IRP1 protein levels in iron-rich LY-R cells are twice those in iron-deficient LY-S cells. In showing that LY cell lines exhibit 2 different patterns of intracellular iron regulation, our results highlight both the role of high LIP in the establishment of pro-oxidant status in mammalian cells and the antioxidant role of ferritin. (Blood. 2000;95:2960-2966)

Volume-corrected ferritin and zinc protoporphyrin/heme ratio during pregnancy: the role of an intracellular iron measure

Purpose: To describe the relationship during pregnancy of an iron stores measure, serum ferritin, and an intracellular iron measure, zinc protoporphyrin/heme ratio (ZPP/H).Methods: Retrospective analyses of measurements of ferritin and ZPP/H from 316 iron-supplemented prenatal patients at a public hospital clinic. Each ferritin value was corrected for dilution, using formulas for estimating plasma volume expansion, yielding volume-corrected ferritin (VCF) values. After exclusions, 159 specimens from 103 patients at 4–37 weeks of gestation were analyzed by descriptive statistics and contingency tables.Results: VCF indicated diminished stores in 36% of specimens, but only 8% of specimens showed abnormal intracellular iron by ZPP/H. Normal VCF was strongly predictive (97%) of normal ZPP/H; abnormal VCF was only weakly predictive (17%) of abnormal ZPP/H. Co-occurrence of normal VCF with mildly compromised ZPP/H was found in 32% of specimens.Conclusions: Data are largely consistent with an established sequential model of the relationship between iron stores and intracellular iron. Even with correction for the effect of plasma volume expansion, ferritin has limited utility for assessing intracellular iron status during pregnancy. An intracellular iron measure such as ZPP/H offers important advantages for assessing iron status and supplement therapy during pregnancy.

Iron-regulated excretion of alpha-keto acids by Salmonella typhimurium.

Excretion of alpha-keto acids by clinical isolates and laboratory strains of Salmonella typhimurium was determined by high-performance liquid chromatography analysis of culture supernatants. The levels of excretion increased markedly with increasing iron stress imposed by the presence of alpha,alpha'-dipyridyl or conalbumin in the medium. The major product was pyruvic acid, but significant concentrations of alpha-ketoglutaric acid, alpha-ketoisovaleric acid, and alpha-ketoisocaproic acid were also observed. Maximal excretion occurred at iron stress levels that initially inhibited bacterial growth; the concentration of alpha,alpha'-dipyridyl at which this was observed differed between strains depending on their ability to secrete and utilize siderophores, suggesting that the intracellular iron status was important in determining alpha-keto acid excretion. However, prolonged incubation of the siderophore-deficient S. typhimurium strain enb-7 under conditions of high iron stress resulted in significant delayed bacterial growth, promoted by tonB-dependent uptake of iron complexed with the high accumulated levels of pyruvic acid and other alpha-keto acids. Strain RB181, a fur derivative of enb-7, excreted massive amounts of alpha-keto acids into the culture medium even in the absence of any iron chelators (the concentration of pyruvic acid, for example, was >25 mM). Moreover, RB181 was able to grow and excrete alpha-keto acids in the presence of alpha,alpha'-dipyridyl at concentrations threefold greater than that which inhibited the growth of enb-7.

Translational Regulation of Ferritin Synthesis by Iron

This review starts with a description of certain features of mammalian ferritins and their DNA and RNA structures relevant to translational control of ferritin synthesis. Although the amino acid sequences of the two ferritin subunits (H and L) diverge in about 50% of the coding region, their five alpha-helices and the exon sizes of their genes are compatible with the proposition that they diverged from a single ancestral gene. Of particular note is their long 5'-untranslated regions (5'UTRs) which include a 28-nucleotide sequence almost completely identical in the H- and L-subunits of a range of species. This motif near the cap region of the 5'-UTR, which forms a specific stem-loop structure, provides for regulation of the translation of H- and L-ferritin mRNAs. When intracellular levels of chelatable iron are not in excess, a large reserve of H- and L-mRNAs is present in the cell sap, restrained from translation by a protein with an Mr of about 90-100,000 which binds to the stem-loop structure. When excess iron floods the cytosol, this protein/RNA complex appears to dissociate and the 40S ribosome subunit is now able to initiate ferritin protein synthesis so that the dormant mRNAs become active and are transferred to the polyribosomes. The mechanism whereby the binding protein is regulated in response to iron is currently under investigation. The regulatory protein occurs in the cell sap and is present in several interchangeable forms which appear to differ in the redox state of specific sulphydryls within the protein. Under some circumstances, the abundance of these forms appears to be altered by intracellular iron status. It is unclear how iron influences binding of the regulatory protein to ferritin mRNA. Some investigators consider that iron binds in the form of heme to the regulatory protein, for which they offer in vitro evidence. We have examined the role of heme versus inorganic chelatable iron in the regulation of ferritin and heme oxygenase synthesis in rat fibroblasts and hepatoma cells. By manipulating the flow of iron between the intracellular chelatable iron and heme iron pools we have concluded that chelatable iron can act as a regulator of ferritin synthesis in a manner which is independent of heme formation. This conclusion does not exclude a role for heme in some specialized cell types.

A model for the structure and functions of iron-responsive elements

Most eukaryotic cells express two proteins, whose biosynthetic rates are determined by the intracellular iron status. The genes for both these proteins, ferritin and the transferrin receptor (TfR), are regulated at the post-transcriptional level, but by entirely different mechanisms. Ferritin mRNA levels are not affected by acute changes in iron availability. Ferritin biosynthesis is regulated translationally via a defined element contained within the 5' untranslated region (UTR) of the ferritin mRNA. This element has been highly conserved during evolution and has been termed an iron-responsive element (IRE). In contrast to ferritin, the regulation of TfR biosynthesis is mirrored by equivalent changes in TfR mRNA levels. The genetic information for this regulation is mostly located in the region of the gene encoding the 3' UTR of the TfR mRNA. Five elements that closely resemble the ferritin IRE are contained within the region which is critical for TfR regulation. The IRE is suggested to function by forming a specific stem-loop structure that interacts with a transacting factor in an iron-dependent fashion. We present a model that accommodates the mediation of distinct post-transcriptional regulatory phenomena via IREs.