Non-transferrin-bound iron reaches mitochondria by a chelator-inaccessible mechanism: biological and clinical implications

Non-transferrin-bound iron, commonly found in the plasma of iron-overloaded individuals, permeates into cells via pathways independent of the transferrin receptor. This may lead to excessive cellular accumulation of labile iron followed by oxidative damage and eventually organ failure. Mitochondria are the principal destination of iron in cells and a primary site of prooxidant generation, yet their mode of acquisition of iron is poorly understood. Using fluorescent probes sensitive to iron or to reactive oxygen species, targeted to cytosol and/or to mitochondria, we traced the ingress of labile iron into these compartments by fluorescence microscopy and quantitative fluorimetry. We observed that 1) penetration of non-transferrin-bound iron into the cytosol and subsequently into mitochondria occurs with barely detectable delay and 2) loading of the cytosol with high-affinity iron-binding chelators does not abrogate iron uptake into mitochondria. Therefore, a fraction of non-transferrin-bound iron acquired by cells reaches the mitochondria in a nonlabile form. The physiological role of occluded iron transfer might be to confer cells with a "safe and efficient cytosolic iron corridor" to mitochondria. However, such a mechanism might be deleterious in iron-overload conditions, because it could lead to surplus accumulation of iron in these critical organelles. transport; fluorescence; oxidative stress     

Transferrin acquisition of catabolized erythrocyte iron in the rat

Rat plasma contains two isotransferrins rather than the single iron-binding protein found in plasma of other species, and it was recently proposd that differences between the biological behavior of each isotransferrin accounted for observations previously attributed to behavioral differences between each of the two transferrin iron-binding sites. The two isotransferrins were isolated from rat plasma by DEAE-Sephadex ion-exchange chromatography and isoelectric focusing. The pH-dependent iron-dissociating and reticulocyte iron-donating properties of each isotransferrin were investigated and found to be indistinguishable. Like human transferrin, one iron-binding site retains its affinity for iron below pH 6 and this property was used to investigate the $\text{in}$$\text{vivo}$ acquisition of catabolic iron in order to determine whether the process occurs at one specific or both binding sites. Plasma radioactive iron, derived from injected ⁵⁹Fe-labelled heat denatured erythrocytes was bound with high specificity to the transferrin iron-binding site that was most resistant to acidic dissociation. This finding supports Fletcher and Huehns' hypothesis that each of the two rat transferrin iron-binding sites is endowed with a separate functional role.     

Functional heterogeneity and pH-dependent dissociation properties of human transferrin

Human diferric transferrin was partially labeled with ⁵⁹Fe at low or neutral pH (chemically labeled) and by replacement of diferric iron previously donated to rabbit reticulocytes (biologically labeled). Reticulocyte ⁵⁹ uptake experiments with chemically labeled preparations indicated that iron bound at near neutral ph was more readily incorporated by reticulocytes than iron bound at low pH. The pH-dependent iron dissociation studies of biologically labeled transferrin solutions indicated that Fe³⁺, bound at the site from which the metal was initially utilized by the cells, dissociated between pH 5.8 and 7.4. In contrast, lower pH (5.2–5.8) was required to effect dissociation of iron that had remained bound to the protein after incubation with reticulocytes. These findings suggest that each human transferrin iron-binding site has different acid-base iron-binding properties which could be related to the observed heterogenic rabbit reticulocyte iron-binding properties of human transferrin and identifies that the near neutral iron-donating site initially surrenders its iron to these cells.     

Quantifying Integrated Proteomic Responses to Iron Stress in the Globally Important Marine Diazotroph Trichodesmium

Trichodesmium is a biogeochemically important marine cyanobacterium, responsible for a significant proportion of the annual ‘new’ nitrogen introduced into the global ocean. These non-heterocystous filamentous diazotrophs employ a potentially unique strategy of near-concurrent nitrogen fixation and oxygenic photosynthesis, potentially burdening Trichodesmium with a particularly high iron requirement due to the iron-binding proteins involved in these processes. Iron availability may therefore have a significant influence on the biogeography of Trichodesmium. Previous investigations of molecular responses to iron stress in this keystone marine microbe have largely been targeted. Here a holistic approach was taken using a label-free quantitative proteomics technique (MS^E) to reveal a sophisticated multi-faceted proteomic response of Trichodesmium erythraeum IMS101 to iron stress. Increased abundances of proteins known to be involved in acclimation to iron stress and proteins known or predicted to be involved in iron uptake were observed, alongside decreases in the abundances of iron-binding proteins involved in photosynthesis and nitrogen fixation. Preferential loss of proteins with a high iron content contributed to overall reductions of 55–60% in estimated proteomic iron requirements. Changes in the abundances of iron-binding proteins also suggested the potential importance of alternate photosynthetic pathways as Trichodesmium reallocates the limiting resource under iron stress. Trichodesmium therefore displays a significant and integrated proteomic response to iron availability that likely contributes to the ecological success of this species in the ocean.     

Heme Iron Uptake by Caco-2 Cells is a Saturable,Temperature Sensitive and Modulated by Extracellular pH and Potassium

It is known that heme iron and inorganic iron are absorbed differently. Heme iron is found in the diet mainly in the form of hemoglobin and myoglobin. The mechanism of iron absorption remains uncertain. This study focused on the heme iron uptake by Caco-2 cells from a hemoglobin digest and its response to different iron concentrations. We studied the intracellular Fe concentration and the effect of time, K⁺ depletion, and cytosol acidification on apical uptake and transepithelial transport in cells incubated with different heme Fe concentrations. Cells incubated with hemoglobin-digest showed a lower intracellular Fe concentration than cells grown with inorganic Fe. However, uptake and transepithelial transport of Fe was higher in cells incubated with heme Fe. Heme Fe uptake had a low V _max and K _m as compared to inorganic Fe uptake and did not compete with non-heme Fe uptake. Heme Fe uptake was inhibited in cells exposed to K⁺ depletion or cytosol acidification. Heme oxygenase 1 expression increased and DMT1 expression decreased with higher heme Fe concentrations in the media. The uptake of heme iron is a saturable and temperature-dependent process and, therefore, could occur through a mechanism involving both a receptor and the endocytic pathway.     

Evidence for the functional equivalence of the iron-binding sites of rat transferrin

The role of the two iron-binding sites of rat transferrin in the exchange of iron with cells has been assessed using urea polyacrylamide gel electrophoresis to separate and quantitate the four possible molecular species of transferrin generated during the incubation of ¹²⁵I-labelled transferrin with rat reticulocytes and hepatocytes. Addition of diferric transferrin to reticulocytes led directly to the appearance of apotransferrin together with small and comparable amounts of the two monoferric transferrins. After 2 h 44.8% of the iron had been removed by the cells, and of the iron-depleted transferrin 71.8% was apotransferrin, the remainder being monoferric transferrin, 16.1% with N-terminal iron and 12.1% with C-terminal iron. A similar pattern emerged with hepatocytes, but the rate of iron removal was slower and the proportion of apotransferrin generated was lower. After 4 h 10.9% of the iron had been removed from the transferrin and the distribution of the iron-depleted protein was: apotransferrin 26.9% and monoferric (N-terminal) 39.2%, (C-terminal) 33.9%. The appearance of apotransferrin during each incubation and the generation of both monoferric transferrins suggest that both cell types are able to remove iron from differic transferrin in pairwise fashion and that they do not appreciably distinguish between the two iron-binding sites of the protein. Release of iron from hepatocytes to apotransferrin lead to the appearance of both monferric species and then to increasing amounts of diferric transferrin. The process of iron release did not seem to distinguish between the vacant iron-binding sites of transferrin.     

Studies on Sudden Fatalities Among Piglets Following Parenteral Iron Therapy

An investigation was carried out in order to clarify whether there is a correlation between the latent iron-binding capacity, UIBG, in the serum of suckling piglets and sudden fatalities occurring among these animals when they are treated with 250 mg trivalent iron in the form of a complex also containing dextrin, sorbitol, citric acid and lactic acid. In all, 97 animals from 9 litters were used. By administering 100 mg oral divalent iron to 22 animals, the iron-binding capacity was saturated or appreciably reduced 3 hrs. after the oral treatment. After this time, the animals were treated with parenteral iron. Seventeen other animals were treated with 100 mg divalent iron and immediately afterwards with parenteral iron. Three hrs. later, the iron-binding capacity of the animals was exceeded. In 32 of the control animals, UIBG was high before the parenteral treatment. No fatalities were observed among the animals treated with parenteral iron. Twenty-three of the animals had a high iron-binding capacity in spite of having diarrhoea. On parenteral treatment of these animals with the iron complex, no fatalities were observed which could be ascribed to the treatment. The mechanism for the sudden fatalities among suckling piglets after parenteral administration of iron is discussed.     

Evaluation of iron-binding capacity,amino acid composition,functional properties of Acetes japonicus proteolysate and identification of iron-binding peptides

Recovery of functional iron-binding protein hydrolysate from Acetes japonicus employing enzymatic hydrolysis and iron-chelating peptide identification were conducted in this study. The result showed that under the optimal hydrolysis condition including Flavourzyme, pH 5, 50 °C, E:S ratio of 27.4 U/g protein and hydrolysis time of 4.8 h, the obtained proteolysate displayed the maximal iron-binding capacity (IBC) of 177.7 μgFe²⁺/g protein and comprehended 38,77 % of essential amino acids. Functional features of the Acetes proteolysate encompassing solubility, heat stability, foaming and emulsifying property, oil and water holding capacity were also noteworthy. Peptide fractionation was performed using ultrafiltration and the 1−3 kDa fraction expressed the highest IBC of 120.43 ± 0.15 μgFe²⁺/g protein, 13.7 times lower than that of disodium ethylenediaminetetraacetate (Na₂EDTA). From this fraction, two iron-binding peptides of DSVNFPVHGL (1083.53 Da) and FKVGQENTPILK (1372.77 Da) were identified utilizing nano-UHPLC-MS/MS as well as their de novo spatial structures and interaction with ferrous ion were simulated by PEP-FOLD 3. As a whole, the proteolysate/peptides could be filled as an iron chelator which could shield human body from iron deficient-related disorders or as a functional proteolysate preparation to upgrade food properties.     

Iron-binding Proteins in Milk and Resistance to Escherichia coli Infection in Infants

Human milk contains large quantities of iron-binding protein, of which the greater proportion is lactoferrin, though small amounts of transferrin are also present. Three samples of human milk with unsaturated iron-binding capacities of between 56 and 89% had a powerful bacteriostatic effect on Escherichia coli O111/B4. The bacteriostatic properties of milk were abolished if the iron-binding proteins were saturated with iron. Purified human lactoferrin, in combination with specific E. coli antibody, strongly inhibited the growth of E. coli, and this effect was also abolished by saturating the lactoferrin with iron.Guinea-pig milk also contains lactoferrin and transferrin. Newly born guinea-pigs fed on an artificial diet and dosed with E. coli O111 had higher counts of E. coli O111 in the intestine than suckled animals. The apparent suppressive effect of guinea-pig milk on E. coli in the intestine could be reversed by feeding the iron compound haematin. It seems that iron-binding proteins in milk may play an important part in resistance to infantile enteritis caused by E. coli.     

Further evaluation of the biphasic kinetics of iron removal from transferrin by 3,4-LICAMS

Summary Further evaluation of the kinetic data for Fe³⁺ removal from isolated differic and monoferric transferrins by the tricatechol ligand 3,4-LICAMS has allowed full characterization of the four microscopic rate constants. A very small cooperativity exists between the two iron-binding sites with respect to their rates of iron release. The activation free energy profile for the system is presented.     

Iron-binding proteins with vitreous humour

The soluble protein composition of Macaque monkey vitreous humour was studied in order to understand its iron-binding properties. The protein content of vitreous humour was 217 μg/ml ± 4.6%, 40% of which was serum albumin and 30% an iron-binding protein of hydrodynamic properties identical to that of trasferrin or lactoferrin. Relative to serum, the vitreous humour contained a 13-fold excess of this protein(s). Isoelectric focusing, iron-binding and immunoelectrophoretic studies indicated that both vitreous humour and aqueous humour contained lactoferrin as well as serum transferrin. The iron-binding capacity of these proteins in vitreous humour was equivalent to the mass of haemoglobin iron contained in at least 570 000 monkey erythrocytes. It was concluded that the intraocular lactoferrin originated from within the eye. These iron-binding proteins may play a protective role in ocular disturbances such as viterous haemorrahge, iron foreign body toxicity and infection.     

Properties and role of ferritin in the hemolymph of the chiton Clavarizona hirtosa

The major iron-binding protein found in the hemolymph of the chiton Clavarizona hirtosa has been purified for the first time and identified as ferritin. This ferritin, which is present at a concentration of approx. 400 μg·ml⁻¹, has a M_r of 28 000 and 25 500, exhibits microheterogeneity with isoelectric values in the range 5.3–6.0, binds 1500–2500 Fe atoms·mol⁻¹ and is immunologically distinct from horse spleen ferritin. The initial rate of iron accumulation by ferritin molecules was determined to be markedly higher than that exhibited by horse spleen ferritin. Taken together, these data suggest that ferritin found in the hemolymph serves as a key component of the high-capacity transport system necessary to deliver iron to the rapidly mineralizing tissue of the radula in these molluscs.     

Iron uptake byDesulfovibrio vulgaris outer membrane components in artificial vesicles

Desulfovibrio vulgaris lipopolysaccharide and outer membrane proteins (OMPs) were incorporated into vesicles ofD. vulgaris phospholipid and studied for [⁵⁵Fe]binding activity. Both lipopolysaccharide and an extract of two major OMPs caused large increases in⁵⁵Fe uptake over control (phospholipid only) vesicles. CommercialSalmonella typhimurium lipopolysaccharide gave a similar result, but the effect was inhibited by calcium ions; this was not the case forDesulfovibrio. The lipid A portion ofS. typhimurium lipopolysaccharide had a high iron-binding ability, whereasDesulfovibrio lipid A iron binding was little different from control values;D. vulgaris lipopolysaccharide thus has a specific iron-binding site within its polysaccharide side chain.     

Ability ofVibrio vulnificus to obtain iron from transferrin and other iron-binding proteins

The ability of virulent and avirulent strains ofVibrio vulnificus to overcome iron limitations by using iron bound to iron-binding proteins was examined. While no strains were able to obtain iron from lactoferrin or ferritin when these proteins were not fully saturated with iron, growth was enhanced by the iron-saturated form of these proteins. None of the strains was able to scavange iron from 30% saturated transferrin, but there were strain differences in the ability to obtain iron from the saturated form. The virulent strains were able to compete more efficiently with transferrin when it was fully saturated with iron than were the avirulent strains.     

The Mycobacterium tuberculosis High-Affinity Iron Importer,IrtA, Contains an FAD-Binding Domain

Iron is an essential nutrient not freely available to microorganisms infecting mammals. To overcome iron deficiency, bacteria have evolved various strategies including the synthesis and secretion of high-affinity iron chelators known as siderophores. The siderophores produced and secreted by Mycobacterium tuberculosis, exomycobactins, compete for iron with host iron-binding proteins and, together with the iron-regulated ABC transporter IrtAB, are required for the survival of M. tuberculosis in iron deficient conditions and for normal replication in macrophages and in mice. This study further characterizes the role of IrtAB in M. tuberculosis iron acquisition. Our results demonstrate a role for IrtAB in iron import and show that the amino terminus domain of IrtA is a flavin-adenine dinucleotide-binding domain essential for iron acquisition. These results suggest a model in which the amino terminus of IrtA functions to couple iron transport and assimilation.′Mycobacterium tuberculosis, the causative agent of human tuberculosis, like most organisms, requires iron to sustain essential cellular functions. Due to the poor aqueous solubility of the ferric ion (Fe³⁺) in aerobic and neutral pH conditions, free ferric iron is not found in the mammalian host but is bound to iron-binding proteins such as transferrin, lactoferrin, and ferritin (30). A common mechanism by which bacteria acquire iron is the synthesis and secretion of siderophores (high-affinity iron chelators) that can solubilize iron in the environment or remove it from iron-binding proteins of the mammalian host. Fe³⁺-siderophore complexes are recognized by specific surface receptors and translocated through the plasma membrane by ABC-type transporters, using the energy generated by ATP hydrolysis (13). Dissociation of iron from the incorporated siderophore complex can occur via cleavage of the siderophore or by the action of a ferric reductase (13). Reduction of Fe³⁺ results in a weaker binding of Fe²⁺ to the siderophore, allowing release of iron that can then be utilized (21).To overcome iron limitation, M. tuberculosis synthesizes siderophores named mycobactin and exomycobactin. Mycobactin is very hydrophobic and remains cell associated, whereas exomycobactin (ExMB, also known as carboxymycobactin) is more hydrophilic and is secreted to the medium (8, 16). Fe³⁺-ExMB complexes can deliver iron to the cell by transfer of iron to mycobactin (7) or by a pathway that is mycobactin independent (17). Previously, we showed that inactivation of M. tuberculosis irtA (Rv1348) or irtB (Rv1349) genes, which encode membrane proteins of the ABC transporter family (2), results in decreased ability of M. tuberculosis to replicate in low-iron medium and to utilize Fe³⁺-ExMb as the sole iron source. Because IrtA and IrtB each encode a membrane protein with one permease domain fused to an ATPase domain, and irtA and irtB are organized in an operon, we postulated that these two proteins associate to form one ABC transporter necessary for iron acquisition in vitro and also for normal replication of M. tuberculosis in human macrophages and in infected mice lungs (18). We provide here evidence that supports a role for IrtAB as an iron importer and unveils essential properties of the amino-terminal domain (NTD) of IrtA. We propose a model by which IrtA-NTD couples iron transport to assimilation.     

The new role of poly (rC)-binding proteins as iron transport chaperones: Proteins that could couple with inter-organelle interactions to safely traffic iron

BackgroundIntracellular iron transport is mediated by iron chaperone proteins known as the poly(rC)-binding proteins (PCBPs), which were originally identified as RNA/DNA-binding molecules.Scope of reviewPCBPs assume a role as not only as cytosolic iron carriers, but also as regulators of iron transport and recycling. PCBP1 is involved in the iron storage pathway that involves ferritin, while PCBP2 is involved in processes that include: iron transfer from the iron importer, divalent metal ion transporter 1; iron export mediated by ferroportin-1; and heme degradation via heme oxygenase 1.Major conclusionsBoth PCBP1 and PCBP2 possess iron-binding activity and form hetero/homo dimer complexes. These iron chaperones have a subset of non-redundant functions and regulate iron metabolism independently.General significanceThis intracellular iron chaperone system mediated by PCBPs provide a transport “gateway” of ferrous iron that may potentially link with dynamic, inter-organelle interactions to safely traffic intracellular iron.     

Two microsomal-associated iron-binding proteins observed in rat small intestinal cells during iron absorption

Acrylamide gel electrophoresis of microsomal protein obtained from rat small intestinal mucosal cells, after an injection of [³H]leucine, demonstrated increased quantities of two soluble iron-binding proteins during iron absorption, one with a high molecular weight (about 400 000) and the other of intermediate molecular weight (80 000). Both proteins were present in a ribosomal-enriched sub-fraction obtained during purification of the microsomal membrame but were not identified among the purified membrane proteins.     

Role of membrane surface potential and other factors in the uptake of non-transferrin-bound iron by reticulocytes

Reticulocytes suspended in low ionic strength media such as isotonic sucrose solution efficiently take up non-transferrin-bound iron and utilize it for heme synthesis. The present study was undertaken to determine how such media facilitate iron utilization by the cells. The effects of changes in membrane surface potential, membrane permeability, cell size, transmembrane potential difference, oxidation state of the iron, and lipid peroxidation were investigated. Iron uptake to heme, cytosol, and stromal fractions of cells was measured using rabbit reticulo-cytes incubated with ⁵⁹Fe-labelled Fe(II) in 0.27 M sucrose, pH 6.5. Suspension of the cells in sucrose led to increased membrane permeability, loss of intracellular K⁺, decreased cell size, and increased transmembrane potential difference. However, none of these changes could account for the high efficiency of iron uptake which was observed. The large negative membrane surface potential which occurs in sucrose was modified by the addition of mono-, di-, tri-, and polyvalent cations to the solution. This inhibited iron uptake to a degree which for many cations varied with their valency. Other cations (Mn²⁺, Co²⁺, Ni²⁺, Zn²⁺) were also very potent inhibitors, probably due to direct action on the transport process. Ferricyanide inhibited iron uptake, while ferrocyanide and ascorbate increased the uptake of Fe(III) but not Fe(II). It is concluded that the high negative surface potential of reticulocytes suspended in sucrose solution facilitates iron uptake by aiding the approach of iron to the transport site on the cell membrane. The iron is probably transported into the cell in the ferrous form. © 1994 wiley-Liss, Inc.     

Transferrin modifications and lipid peroxidation: implications in diabetes mellitus

Free iron is capable of stimulating the production of free radicals which cause oxidative damage such as lipid peroxidation. One of the most important mechanisms of antioxidant defense is thus the sequestration of iron in a redox-inactive form by transferrin. In diabetes mellitus, increased oxidative stress and lipid peroxidation contribute to chronic complications but it is not known if this is related to abnormalities in transferrin function. In this study we investigated the role of transferrin concentration and glycation. The antioxidant capacity of apotransferrin to inhibit lipid peroxidation by iron-binding decreased in a concentration-dependent manner from 89% at > or = 2 mg/ml to 42% at 0.5 mg/ml. Pre-incubation of apotransferrin with glucose for 14 days resulted in a concentration-dependent increase of glycation: 1, 5 and 13 micromol fructosamine/g transferrin at 0, 5.6 and 33.3 mmol/l glucose respectively, p < 0.001. This was accompanied by a decrease in the iron-binding antioxidant capacity of apotransferrin. In contrast, transferrin glycation by up to 33.3 mmol/l glucose did not affect chemiluminescence-quenching antioxidant capacity, which is iron-independent. Colorimetric evaluation of total iron binding capacity in the presence of an excess of iron (iron/transferrin molar ratio = 2.4) also decreased from 0.726 to 0.696 and 0.585mg/g transferrin after 0, 5.6 and 33.3 mmol/l glucose, respectively, p < 0.01. In conclusion, these results suggest that lower transferrin concentration and its glycation can, by enhancing the pro-oxidant effects of iron, contribute to the increased lipid peroxidation observed in diabetes.     

A Bacterial Iron Exporter for Maintenance of Iron Homeostasis

Nutritional iron acquisition by bacteria is well described, but almost nothing is known about bacterial iron export even though it is likely to be an important homeostatic mechanism. Here, we show that Bradyrhizobium japonicum MbfA (Blr7895) is an inner membrane protein expressed in cells specifically under high iron conditions. MbfA contains an N-terminal ferritin-like domain (FLD) and a C-terminal domain homologous to the eukaryotic vacuolar membrane Fe²⁺/Mn²⁺ transporter CCC1. An mbfA deletion mutant is severely defective in iron export activity, contains >2-fold more intracellular iron than the parent strain, and displays an aberrant iron-dependent gene expression phenotype. B. japonicum is highly resistant to iron and H₂O₂ stresses, and MbfA contributes substantially to this as determined by phenotypes of the mbfA mutant strain. The N-terminal FLD was localized to the cytoplasmic side of the inner membrane. Substitution mutations in the putative iron-binding amino acid residues E20A and E107A within the N-terminal FLD abrogate iron export activity and stress response function. Purified soluble FLD oxidizes ferrous iron (Fe²⁺) to incorporate ferric iron (Fe³⁺) in a 2:1 iron:protein ratio, which does not occur in the E20A/E107A mutant. The FLD fragment is a dimer in solution, implying that the MbfA exporter functions as a dimer. MbfA belongs to a protein family found in numerous prokaryotic genera. The findings strongly suggest that iron export plays an important role in bacterial iron homeostasis.