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  • Review Article
  • Published:

Human iron transporters

Abstract

Human iron transporters manage iron carefully because tissues need iron for critical functions, but too much iron increases the risk of reactive oxygen species. Iron acquisition occurs in the duodenum via divalent metal transporter (DMT1) and ferroportin. Iron trafficking depends largely on the transferrin cycle. Nevertheless, non-digestive tissues have a variety of other iron transporters that may render DMT1 modestly redundant, and DMT1 levels exceed those needed for the just-mentioned tasks. This review begins to consider why and also describes advances after 2008 that begin to address this challenge.

Because the author recently had the opportunity to address a closely related topic [14], this review will largely be an update on that one with the emphasis on exploring issues that have arisen since then or were overlooked before or are specific for human iron transporters, again trying to encourage researchers to move to improve our understanding rather than to follow fashion. It will repeat information only where essential for understanding of a topic. New recent relevant reviews include coverage of iron acquisition and storage [8], impaired iron homeostasis in Parkinsonism [28], normal iron homeostasis from a molecular viewpoint [56], normal and pathological iron homeostasis in the eye [18], hereditary hemochromatosis [52], hepcidin’s role as a regulator [36] and recycling of iron primarily by macrophage [2].

Human cells and tissues manage iron carefully. Nearly all of them need iron to supply redox functions in many pathways in both heme and non-heme proteins. Iron, however, helps to generate reactive oxygen species (ROS) via the same capability, thus the need for careful management.

Figure 1 depicts some iron fluxes that occur in humans. Essentially, all nutritional iron enters by absorption in the duodenum. Regulation of this absorption is critical because there is no known regulated process for removal of iron from the body. Newly absorbed iron moves through portal venous flow to the liver, where it is utilized for liver functions and stored by processes that at least normally buffer the supply of iron to other tissues. The largest flux is via circulation to the bone marrow, where erythropoiesis utilizes iron primarily to form hemoglobin that endures in circulating red blood cells for ~120 days. When red cells become effete, their iron is recovered in circulating and splenic macrophage and Kupffer cells of the liver. This recovery is normally very efficient, and most of the iron is reutilized in continuing erythropoiesis. The transporters that serve the fluxes just outlined are relatively well understood. One observation that captured the author’s attention, however, relates to divalent metal transporter 1 (DMT1), the major iron importer; Beaumont’s group [50] quantitated the relative amounts of DMT1mRNA (actually for two DMT1 isoforms, but transporter isoforms will be considered below) and found that the quantities in tissues other than the marrow and duodenum were often as high or higher than those in these two critical tissues. So, why is there so much iron transport capacity in other tissues? The observations are easily reproduced, so discounting them is not helpful. The left side of the figure begins to consider possible fluxes of iron relative to these organs. The airways will need iron nutritionally for their development, function, and survival. They will also have to contend with unneeded iron entering them in association with particulates such as desert and volcanic dust, when all we had to contend with was natural challenges and the detritus of human activities now that we have civilization. This iron may be absorbed and “regurgitated” by airways cells [16] to reach the GI tract via the mucociliary escalator. Iron also reaches the kidneys to supply local functions via circulation. There it clearly filters [51] and is re-adsorbed. The brain demands iron for many functions. Does iron ever recycle from this tissue? These are statements and questions where approaches are often absent or at early stages. Given that transfer into and recovery from erythrocytes occupies the majority of normal iron flux and much of the remainder involves duodenal acquisition, one can speculate that other tissues have a large “surge” capacity, and some of this review will be concerned with why.

Fig. 1
figure 1

Iron flux among specific tissues. The conventional scheme is in the center and to the right. Iron enters the body after absorption primarily in the duodenum (center) of the gastrointestinal (GI) tract. Portal veinous flow carries it to the liver (top right), where a portion will be stored if the supply exceeds immediate demands so the liver serves as a buffer. The main flux from the liver is to the bone marrow represented here by a femur (middle right) where incorporation in developing red blood cells (lower right) requires an even greater flux. Aged red cells are removed by macrophage (middle), many of which can reside in the spleen or marrow and Kupffer cells in the liver. These cells recycle the iron to the marrow for reutilization in erythropoiesis. It is also accepted that the circulation delivers iron to the lungs (upper left), kidneys (middle left), and brain (lower left) as well as to all other tissues but the flux into these tissues is lower. Is there reflux from these tissues? Certainly or probably would be the answers but the specifics represent frontiers in the study of iron homeostasis as do many of the specifics of the arrival of iron in these organs (see text). Also noted is that we certainly acquire some iron via the airways although that acquisition is not considered iron nutrition. Iron may move from the airways to the GI tract or from the kidneys back into circulation after filtration, and perhaps iron can be removed from the brain. In humans, the estimate for normal duodenal uptake flux is 1–2 mg/day of iron [21], balanced by unregulated excretion of the same magnitude; while 20–25 mg/day enters erythrocytes balanced by a similar recovery from effete red cells. I have not found good estimates for other tissues but speculate that the other fluxes shown here are <1 mg/day. The relative sizes of the arrows represent these estimates and guesses. The macrophage is redrawn from Fig. 4 of an earlier review [14] with permission

Duodenal iron acquisition

Figure 2 depicts the passage of iron through a duodenal enterocyte. One can consider three stages in order: Uptake from the lumen of the GI tract; intracellular passage; and exit from the cell. We should remember, however, that the cell must also obtain iron from the circulation for its own needs when the nutritional supply is inadequate and that not all the iron that enters the cell from the lumen will exit on the mucosal side. DMT1 is the transporter responsible for Fe2+ entry but the iron has to be reduced by ascorbate through the action of Dcytb. The iron must be transcytosed to where it will exit the cell and enter the circulation. Transcytosis is definitely the stage about which the least is known. Although there is evidence that DMT1 moves with the iron [32], Núñez’ group [37] recently reminded us that such data can also account for a loss of iron uptake after an iron challenge, traditionally called the mucosal block [54]. Earlier, there were similar observations in Caco2 cells supporting this interpretation [46]. Critical experiments are still needed to learn if these explanations for DMT1 movement are reliable. The findings that departure of DMT1 from the apical membrane correlates with decreased apical flux in Caco-2 cells and that antisense to DMT1 inhibits this flux [37] both support the mucosal block as an explanation, but participation of DMT1 in transcytosis is not excluded by such data. Iron exit from enterocytes depends on the transporter Fpn plus oxidation of Fe2+ to Fe3+ by Hp or Cp so that transferrin (Tf) can bind the exported Fe3+. We have already covered regulation of the export process [14] but call attention here to how repositioning of Fpn may help to accomplish this regulation even without turnover of the Fpn in the proteosome [37].

Fig. 2
figure 2

Enterocyte iron absorption. The critical entry transporter on the apical surface of the enterocyte is DMT1. Given that DMT1 is specific for Fe2+ (as opposed to Fe3+), Fe3+ must be reduced prior to or concomitant with entry. The ferrireductase, duodenal cytochrome B (Dcytb), accomplishes this but does not appear to be an absolute requirement. Subsequently, iron must get to where it exits the cell, a process celled transcytosis (dashed arrow). The exit transporter, ferroportin (Fpn, but also called MTP1, Ireg1 or Slc40), probably acts on Fe2+ but reoxidation to Fe3+ by hephaestin (Hp) or ceruloplasmin (Cp) as well as binding of the resultant Fe3+ to apo-transferrin (Tf) could occur in a relatively concerted fashion. The Tf receptor (TfR1) is probably also a part of the exit process although its role here, the reverse of the Tf cycle (below), is not yet well defined. Also yet to be well defined is the role of DMT1 (here shown with a ?) in possible basolateral uptake of iron noted in basolateral membrane vesicles [24] and recently supported [37]. Núñez et al. also propose that Fpn can allow iron to exit back into the lumen of the GI tract (also shown here with a ?). The figure is modified from Fig. 1 of the earlier review [14] with permission

Earlier, we [14] called attention to the lack of recent research on a speculative role of mucins interacting with DMT1 in the cellular acquisition of iron from the lumen of the duodenum. A few months later, coculture of cells that model enterocytes with the ones that model goblet (mucin-secreting) cells was described [27]. Such cocultures appear to predict iron bioavailability for foods [34] and look like a system where new insights can develop. Perhaps they can also encourage a new level of insight into how phytates, polyphenols, and other inhibitors render iron-rich plant foods like spinach into poor sources of iron.

The Tf cycle: iron trafficking into erythroid cells as well as most other tissues

Most cells acquire iron via the Tf cycle (Fig. 3). Physiologically, iron usually enters cells after binding to Tf; the Fe-Tf or Fe2-Tf in turn binds to TfR1 on the cell surface. The Fe-Tf–TfR1 complex in turn enters the cell via endocytosis. Hence, we clearly must classify TfR1 semantically as a human iron transporter. Acidification of the endosome provokes dissociation of Fe3+ from the Tf–TfR1. Although we previously unintentionally implied [14] that this step makes Fe3+ available as a substrate for reduction by Steap3, it could be that Steap3 participates in the release of the iron as Fe2+ because the reduction potential of the iron is more within a range where intracellular reductants can drive the reaction when Fe3+ is associated with Tf–TfR1 [9]. Unless the sequence is as now suggested, there is a need to find a physiological reductant although proof that reduction occurs when the iron is still associated with Tf–TfR1 remains to be supplied.

Fig. 3
figure 3

The Tf cycle. The figure represents what happens in most cells but is specifically applicable to erythroid precursors. At the extracellular pH of 7.4, TfR1 on the cell surface binds Fe-Tf (with the Fe on either the N- or C-terminal lobe) or Fe2-Tf preferentially over apo-Tf. Endocytosis of the Fe-Tf–TfR1 complex occurs, and then the pH of that vesicle drops after the action of the vacuolar H+-ATPase. As it reaches ~6.0, the Tf–TfR1 complex releases Fe3+ cooperatively. This release might be stimulated by reduction to Fe2+ by a ferrireductase, six-transmembrane epithelial antigen of the prostate (Steap3), represented here by a gray oval and by having a departing iron already reduced (see text). Apo-Tf–TfR1 exocytoses as a complex from the recycling endosome to the cell surface. The neutral pH at this location promotes the release of the apo-Tf from TfR1. The released Fe2+ is a substrate for DMT1 transport, exiting directly to the mitochondrion or indirectly after passage through the cytosol, perhaps as a constituent of the labile iron pool (LIP). DMT1 on the cell surface can probably directly import non-Tf-bound iron (NTBI). The figure is modified from [14] with permission

In the previous review [14], we considered ferritin (ft) in a separate section, but the recent discovery that a form of ft can enter cells via the human TfR1 [30] places ft as an alternative substrate for the Tf cycle. Ft normally consists of 24 subunits of two types called H and L to distinguish the heavier chain from the lighter. The proportion of H and L ft varies. Li et al. show that TfR1 is a receptor also for H ft but not for L ft and that binding leads to H ft entering endosomes and lysosomes. Potentially, H ft can be a source of iron for cells and tissues via this route. The authors clearly distinguish this pathway from that for H ft reliant on T-cell immunoglobulin-domain and mucin-domain protein 2 (TIM-2) in mice [3, 7, 17]. They state that murine TfR1 does not bind human H ft nor murine H ft, suggesting that the mechanism for receptor recognition of H ft diverged between humans and mice. The properties imply that one should look for how well the pathway actually contributes to iron trafficking in human mutants with atransferrinemia or hypotransferrinemia, but that the similar mouse mutants will not be of value in such an appraisal.

Macrophage and Nramp1

Nramp1 (Natural resistance–associated macrophage protein 1) has its highest expression in macrophage as its name implies [14] and citations therein. There has now been an important advance that helps to define its functions and direction of transport [47]. The investigators showed that loss of either DMT1 or Nramp1 leads to a minor deficit in recycling hemoglobin after erythrophagocytosis. Simultaneous loss of both transporters, however, severely impairs iron recycling. Their work shows that Nramp1 plays a role in the phagosome similar to the one that DMT1 plays in the endosome: Exit of iron toward its destination of recovery for another round of hemoglobin formation. Their data also bear on the controversy on whether Nramp1 is a proton symporter like DMT1 or an antiporter because the function of Nramp1 is now demonstrably partially redundant to DMT1 [47], implying that Nramp1 is a proton symporter that provides a measure of resistance to many infections by depleting the phagosome of iron and perhaps manganese.

Liver contributions

Several aspects of iron transporter properties and regulation in the liver have been covered before [14] and in citations therein. There is value now in updating two aspects: efforts to modulate transporters and the role of the second Tf receptor (TfR2).

Weiss’s group [31] have presented data showing that nifedipine, a calcium channel blocker, stimulates DMT1 transport activity. They also reported that nifedipine mobilizes iron from the liver of mice with primary and secondary iron overload and enhances urinary iron excretion. Another result was that nifedipine led to loss of serum iron in a fashion that related to DMT1 genotype in +/+ and +/mk mice where the mk mutation is G185R in DMT1. These results offer nifedipine as a means of modulating iron overload in a fashion that would be off-label use of a USA FDA-approved drug. We [33] have not been able to reproduce the stimulation of DMT1 by nifedipine and suggest that the ability of photodegraded nifedipine to serve as an iron channel [19, 44, 45] may account for some of their observations. Unfortunately, their statistical analysis [31] supporting the argument that the DMT1 mutation diminishes the loss of serum iron is flawed and the postulated role of DMT1 in supporting exit of iron would make DMT1 join Fpn as an iron exporter. We do have unpublished data (M. Garrick, L. Zhao, B. Hagerty, S. Gadersohi, A. Ghio, L. Garrick and B. Mackenzie 2009) that suggest that nifedipine treatment does decrease serum iron in rodents in a fashion that does not relate to the DMT1 genotype, so nifedipine could still be of interest for removing iron. Nifedipine’s mechanism for doing so, however, and whether it does diminish liver iron both require more studies.

Although stimulation of DMT1 activity remains elusive, there are multiple reports of potential inhibitors. Ebselen, a seleno compound that may act via redox activity, clearly inhibits DMT1 [53]. Several polysulfonated dyes are also inhibitors [4].

Most published approaches to Fpn are based on its regulation by hepcidin and other regulators. In this context, the critical involvement of the liver in TfR2 (and HFE) modulation of hepcidin has just been confirmed [13] in mice. Another study [41] examines the role of two isoforms of TfR2 mRNA. The α isoform is longer and encodes a full-length TfR2, while the β isoform is shorter. By generating a mouse that lacks the α isoform but retains as a knock-in the β isoform, this group suggests that its product is also involved in regulating Fpn transcription. Their results confirm the already identified function of the α isoform in hepcidin activation but also suggest that β TfR2 is more specifically involved in splenic Fpn function (iron efflux).

Contributions from transporter isoforms

Two human iron transporters have two or more isoforms with properties that insure that the isoforms act in different circumstances. These are DMT1 and Fpn.

The gene for human DMT1 produces 4 major transcripts (Fig. 4a). Although these are frequently referred to as alternative splicing, that terminology is incorrect and alternative transcripts should be used because the choice of promoter (for exon 1A or exon 1B) and the choice of where to add poly A (terminating exon 16/16A or exon 17) determine the result rather than the choice of splice sites. Because the 16A portion of exon 16/16A contains an IRE, transcripts containing it are designated +IRE. Those which lack an IRE are frequently referred to as −IRE. IREs are relevant to the regulation of gene expression because tissues also contain iron regulatory proteins (IRPs) that can bind to IREs. IRP1 binds to IREs when the labile iron pool (LIP) is low but loses its IRE-binding properties to become a cytosolic aconitase when LIP levels are higher. IRP2 is relatively stable, as well as capable of IRE binding when LIP levels are low, but is degraded when LIP levels increase. Thus, both IRPs bind IREs in relative cellular iron deficiency and fail to bind in relative sufficiency. IREs in the 5′ UTR of mRNAs diminish the initiation of translation when occupied by an IRP. Because IRE(s) in the 3′ UTR can stabilize mRNA against degradation when occupied by an IRP, they potentially contribute to post-transcriptional regulation. We previously discussed [14] how challenging it is to distinguish regulation involving choice of promoter when the promoter is iron/hypoxia responsive from post-transcriptional IRE-based regulation.

Fig. 4
figure 4

Iron transporter isoforms. a Alternate transcripts for DMT1. Exons are represented by blocks, introns by lines. Blocks are solid when the exons are found in mature mRNA but open when not (and instead untranscribed or part of an intron) except that 16A is stippled to emphasize when it is retained as part of an extended exon. Selection of one of the two promoters—1A [23] or 1B—leads to a choice of 5′ ends for DMT1 mRNA. Exons 2–15 are processed next (there is some alternate splicing for these but the physiological role is not yet defined). If polyadenylation occurs at the end of exon 16/16A, the entire exon remains in mature mRNA. The exon includes an iron-responsive element (IRE) that potentially can be bound by an iron regulatory protein (IRP). The mRNA will thus contain an IRE in the 3′ untranslated region (UTR). If polyadenylation occurs instead at the end of the next exon (17), splicing occurs from a small part of the preceding exon (16) and the IRE, and the remainder of 16A is part of the intron. This set of choices was first noted for rats [10], but soon also for humans [29]. Although the mRNA variants (1A, 1B, +IRE, −IRE) are frequently labeled alternative splicing, they actually represent alternate promoters and poly A sites. b The protein isoforms of DMT1. Human DMT1 has 543 internal amino acid residues common to all 4 forms here represented by black lines. Exon 1A contains an AUG codon, so it has 29 amino acid residues at the N-terminus (here represented by a dark gray line) encoded by exons 1A and 2. Exon 1B lacks an AUG, so the first amino acid residue (next AUG) is encoded within exon 2. Exon 17 encodes 25 unique amino acid residues, most conveniently designated −IRE and here represented by a light gray line. Exon 16A encodes 18 unique amino acid residues, most conveniently designated +IRE and here represented by a gray line. c Alternate transcripts for Fpn. As in a, exons are represented by blocks, introns by lines. Blocks are solid when the exons are found in mature mRNA but open when not (and instead untranscribed or part of an intron) except that parts of 1a are stippled to suggest how frequently they are retained as part of the exon when the 1b promoter initiates transcription. Selection of one of the two promoters—1a or b [57]—leads to a choice of 5′ ends for Fpn mRNA. (It is unfortunate that the authors chose to designate 1a and b in a fashion inconsistent with the choices made years earlier for DMT1 but this is their nomenclature.) When the 1b promoter is used, splicing proceeds from the 3′ donor sequence of exon 1b to one of the 3 possible splice acceptors within what is wholly exon 1a if the 1a promoter was to be selected. All 3 acceptors are 3′ to the IRE so any of the 3 transcripts that start from exon 1b exclude the IRE. This figure is based on data from Rouault’s group [57], but not modified from their figures

The 4 isoforms of DMT1 mRNA (1A/+IRE, 1A/−IRE, 1B/+IRE, and 1B/−IRE) also encode related but distinct proteins (Fig. 4b). Potentially, differences between the N-terminus that starts in exon 1A and the one that starts in exon 2 and differences between the 18 C-terminal amino acid residues of the +IRE form and the 25 of the −IRE could affect localization of the transporter within the cell, thus where it functions and even where it turns over. Existing data do suggest the presence of such distinctions [5, 15, 24, 26, 38, 39, 48, 49].

Recently, Rouault’s laboratory [57] described alternate transcripts for Fpn (Fig. 4c). It is the only known human iron export transporter, as such it regulates the exit of iron from enterocytes into circulation. Their findings resolve a paradox about the regulation of Fpn. Given that the only previously recognized mRNA isoform has an IRE in the 5′ UTR, IRPs binding to that IRE during iron deficiency would shut off synthesis of Fpn, preventing iron absorption when absorption is needed most. Zhang et al. have established that this paradox applies only to one isoform of Fpn mRNA where transcription initiates from its promoter upstream of exon 1a. For some other mRNA isoforms, transcription initiates farther upstream so that the first exon is 1b where splicing to the middle or beyond of exon 1a leads to omission of the IRE. The transcripts that start with exon 1b will then not be down-regulated by iron deficiency. There is a choice of 3 possible splice acceptor sites for the 1a–b splicing, but it is unclear whether this choice has any effect on Fpn gene expression as all 3 lead to Fpn mRNA lacking an IRE. These same transcripts are also well expressed in erythroid differentiation, supporting the postulate [40] that iron homeostasis in these cells has privileged regulation to handle the heavy demand for iron. The Fpn amino acid sequence predicted by all of the mRNA isoforms is invariant, indicating that the targeting of their products is the same.

Neural tissue and related cell types

Because we previously reviewed this area [14] and there have been both an even more recently focused review [28] and another broader one that preceded [55], this section focuses on recent relevant data and a relationship that has been overlooked by many. Salazar et al. [43] have shown that the +IRE form of DMT1 is increased in the substantia nigra of Parkinson’s disease patients. Given that both microcytic mice (gene symbol mk) and Belgrade rats (gene symbol b) have a G185R mutation that impairs DMT1 transport activity [10, 11], they could determine whether similar increases in DMT1 were part of an inflammatory etiology of neurodegeneration in two rodent models of Parkinson’s disease or were part of a protective response. They used 1-methyl-4-phenyl-1, 2, 3, 6-tetrahydropyridine (MPTP) to induce Parkinsonism in mice. Homozygous mk/mk mice retained more tyrosine hydroxylase–positive neurons from the substantia nigra than control +/mk or +/+ mice after MPTP intoxication. Stereotactical injection of 6-hydroxydopamine (6-OHDA) into the hippocampus leads to retrograde transport of the 6-OHDA and loss of neurons from the substantia nigra. Similarly, b/b rats lost fewer tyrosine hydroxylase–positive neurons than control +/b or +/+ rats. Thus, DMT1 up-regulation in response to inflammation is likely to be part of a vicious cycle that contributes to neurodegeneration.

The increase in +IRE DMT1 in Parkinson’s disease and these models for Parkinsonism can be accounted for in multiple ways: NF-κB might be involved as it is frequently activated in inflammation, and the DMT1 1B promoter is responsive to this transcription factor [38, 39]. Another possibility is based on the observation that +IRE DMT1 increases. Possibly, IRP activation has occurred to stabilize +IRE DMT1 mRNA, although this response would be despite locally elevated iron levels. An interesting new connection relates to turnover of DMT1 protein. One of the studies of transcriptional regulation of DMT1 [38, 39] also showed that DMT1 isoforms are degraded primarily in the proteasome but also in the lysosome. Recently, we found that 1B DMT1 degradation depends on parkin [42]. Proteasomal degradation depends primarily on the ubiquitination pathway where 3 types of enzymes, E1-E3, are involved. E1 is responsible for ubiquitin activation; the E2 family is responsible for conjugation; while the E3 family ligates ubiquitin to the protein target (here DMT1). Parkin is an E3 ligase; mutants in the PARK-2 gene account for the majority of autosomal recessive juvenile Parkinson’s disease. Our data show that 1A DMT1 is not affected by transient expression of parkin, while +IRE and −IRE 1B DMT1 are degraded. By immuno-depleting 1A DMT1, we verified that the 1B (or 2) forms are degraded by wild type but not by mutant parkin [42]. Although most of our experiments were in neuronal models, lymphocytes from humans who have a PARK-2 mutation revealed that 1B DMT1 levels increased, so parkin affects DMT1 levels in non-neuronal tissue too [42].

Parkin is not the only E3 ubiquitin ligase that regulates DMT1 turnover; the Nedd4 family member WWP2 also diminishes DMT1 levels [12]. Although members of the Nedd4 family ordinarily interact with substrates via their so-called WW domains, DMT1 does not have any WW domains. Instead, DMT1 interacts with 2 WW domain-interacting proteins called Nedd4 family-interacting proteins 1 and 2 (Ndfip1 and Ndfip2), which are considered to have roles in protein trafficking. Interestingly, Ndfip1 knockout mice have increased DMT1 plus notable hepatic iron deposition, making Ndfip1 relevant to iron homeostasis. Using human neurons, Howitt and collaborators [22] found that the Ndfip1 is up-regulated and binds to DMT1 in response to Fe and cobalt (Co) exposure. Apparently, this response mediates the degradation of DMT1 to decrease metal entry. Ndfip1 over-expression protects neurons from metal toxicity; and decreasing Ndfip1 by RNAi leads to hypersensitivity to metals. Brains from Ndfip1 knockout mice exposed to Fe accumulate excess Fe within neurons. These data suggest that iron transporters and their regulation are very critically involved in neurodegeneration.

There is another iron transporter connection to neuronal properties that provokes re-examination of some older metabolic data [6]. Carlson et al. created mice with hippocampal ablation of DMT1; local iron deficiency accompanied the loss of DMT1. Spatial memory training induced the increased hippocampal DMT1 expression in normal mice, but those with a hippocampal DMT1 knockout performed less well on spatial memory tasks. Hippocampal neurons are richly populated with N-methyl d-aspartate (NMDA) receptors that may well participate in the learning process. Another group [20] has shown that brief exposure of primary hippocampal cultures to 50 μM NMDA induces 24 h later increased expression of 1B and +IRE DMT1 mRNA, but not of DMT1−IRE mRNA. Both actinomycin D and the NMDA receptor antagonist, MK-801, block the induction. 1B and +IRE DMT1 mRNA also went up in the hippocampus of rats after spatial memory training. The mice with hippocampal ablation of DMT1 had weakened energy metabolism and diminished glutamatergic neurotransmission [6]. While the basis for weakened energy metabolism is likely to be the connection between local iron deficiency and mitochondrial dysfunction as reviewed previously [14], there is a surprising but ultimately reasonable linkage between iron transport and glutamate signaling [35]. McGahan et al. start from the recognition that IRP1 when iron replete is cytosolic aconitase, thus one can conclude that this enzyme is regulated by iron status. It catalyzes the reaction citrate → isocitrate. Cytoplasmic isocitrate dehydrogenase can then convert isocitrate → α-ketoglutarate while generating a reducing equivalent as NADPH. The reaction α-ketoglutarate → glutamate where glutamate dehydrogenase reductively aminates the substrate is a source of glutamate. The authors demonstrate that retinal-pigmented epithelial cells and cultured neuronal cells generate glutamate in an iron-dependent fashion. They point out that dysregulation of iron homeostasis and glutamate metabolism frequently occur together in neurodegenerative conditions. Although the excitatory toxicity of the glutamatergic response and the ROS contributions of excess iron usually attract attention from very different groups of researchers, this work points out that they should be considered together, even coordinately.

The same group [25] also uncovered a relationship where the level of iron transported into retinal-pigmented epithelial cells, neurons, or cultured lens epithelial cells would affect the cells’ ability to manage ROS. Glutamate is also a precursor of the cellular reductant glutathione (GSH) and critically involved in making cysteine available for GSH synthesis via a glutamate/cystine antiporter. In this study, the authors showed that iron regulates l-cystine uptake and the downstream production of GSH. Thus, at least under normal circumstances, increased iron importation could lead to improved management of ROS. This series of results and many other issues in iron homeostasis for the eye have been recently reviewed by the same group [18].

Perspectives

I have generated a list (Table 1) of potential transporters to provide the reader with a summary of the transporters currently worthy of consideration. It is very exciting to see advances made in iron transporters in just 1 year since the last review [14]. There is now a demonstration that the microRNA Let-7d down-regulates −IRE DMT1 mRNA as erythroid cells differentiate [1]. Nevertheless, the areas identified for future studies (some of which were past areas that had fallen out of favor) have seen little by the way of new results. I would like to believe that this is not my failure as a prophet but rather that there has not yet been enough time for a too cautious attitude among funding sources “to obtain new knowledge that is likely to move forward our management of degenerative diseases and aging”.

Table 1 Potential and actual human iron transporters

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Acknowledgments

I thank Dr. AL Crumbliss for drawing to my attention that it might be more felicitous to what actually happens to consider that Steap3 reduction could occur before release of iron from transferrin. Dr. Laura Garrick carefully read and critiqued multiple versions of this review.

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Garrick, M.D. Human iron transporters. Genes Nutr 6, 45–54 (2011). https://doi.org/10.1007/s12263-010-0184-8

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