Brain capillary endothelial cells mediate iron transport into the brain by segregating iron from transferrin without the involvement of divalent metal transporter 1

Rats were studied for [(59)Fe-(125)I]transferrin uptake in total brain, and fractions containing brain capillary endothelial cells (BCECs) or neurons and glia. (59)Fe was transported through BCECs, whereas evidence of similar transport of transferrin was questionable. Intravenously injected transferrin localized to BCECs and failed to accumulate within neurons, except near the ventricles. No significant difference in [(125)I]transferrin distribution was observed between Belgrade b/b rats with a mutation in divalent metal transporter I (DMT1), and Belgrade +/b rats with regard to accumulation in vascular and postvascular compartments. (59)Fe occurred in significantly lower amounts in the postvascular compartment in Belgrade b/b rats, indicating impaired iron uptake by transferrin receptor and DMT1-expressing neurons. Immunoprecipitation with transferrin antibodies on brains from Belgrade rats revealed lower uptake of transferrin-bound (59)Fe. In postnatal (P)0 rats, less (59)Fe was transported into the postvascular compartment than at later ages, suggesting that BCECs accumulate iron at P0. Supporting this notion, an in situ perfusion technique revealed that BCECs accumulated ferrous and ferric iron only at P0. However, BCECs at P0 together with those of older age lacked DMT1. In conclusion, BCECs probably mediate iron transport into the brain by segregating iron from transferrin without involvement of DMT1.     

Gene expression of divalent metal transporter 1 and transferrin receptor in duodenum of Belgrade rats

Regulation of iron absorption is thought to be mediated by the amount of iron taken up by duodenal crypt cells via the transferrin receptor (TfR)-transferrin cycle and the activity of the divalent metal transporter (DMT1), although DMT1 cannot be detected morphologically in crypt cells. We investigated the uptake of transferrin-bound iron by duodenal enterocytes in Wistar rats fed different levels of iron and Belgrade (b/b) rats in which iron uptake by the transferrin cycle is defective because of a mutation in DMT1. We showed that DMT1 in our colony of b/b rats contains the G185R mutation, which in enterocytes results in reduced cellular iron content and increased DMT1 gene expression similar to levels in iron deficiency of normal rats. In all groups the uptake of transferrin-bound iron by crypt cells was directly proportional to plasma iron concentration, being highest in iron-loaded Wistar rats and b/b rats. We conclude that the uptake of transferrin-bound iron by developing enterocytes is largely independent of DMT1.     

ATP-driven copper transport across the intestinal brush border membrane

The divalent metal ion transporter DMT1 is localized in the brush border membrane (BBM) of the upper small intestine and has been shown to be able to transport Mn2+, Fe2+, Co2+, Ni2+, and Cu2+. Belgrade rats have a glycine-to-arginine (G185R) mutation in DMT1, which affects its function. We investigated copper transport with BBM vesicles of Belgrade rats loaded with calcein, which exhibits fluorescence quenching by various metal ions. Transport of copper was disrupted in unenergized BBM vesicle of b/b Belgrade rats, as had been described for iron transport, while +/b vesicles exhibited normal transport by DMT1. When either b/b or +/b vesicles were loaded with ATP and magnesium, similar high-affinity accumulation of copper was observed in both types of vesicles. Thus, brush border membranes possess an ATP-driven, high-affinity copper transport system which could serve as the primary route for copper uptake by the intestine.     

Dietary iron induces rapid changes in rat intestinal divalent metal transporter expression

The divalent metal transporter (DMT1, also known as NRAMP2 or DCT1) is the likely target for regulation of intestinal iron absorption by iron stores. We investigated changes in intestinal DMT1 expression after a bolus of dietary iron in iron-deficient Belgrade rats homozygous for the DMT1 G185R mutation (b/b) and phenotypically normal heterozygous littermates (+/b). Immunofluorescent staining with anti-DMT1 antisera showed that DMT1 was located in the brush-border membrane. Duodenal DMT1 mRNA and protein levels were six- and twofold higher, respectively, in b/b rats than in +/b rats. At 1.5 h after dietary iron intake in +/b and b/b rats, DMT1 was internalized into cytoplasmic vesicles. At 1.5 and 3 h after iron intake in +/b and b/b rats, there was a rapid decrease of DMT1 mRNA and a transient increase of DMT1 protein. The decrease of DMT1 mRNA was specific, because ferritin mRNA was unchanged. After iron intake, an increase in ferritin protein and decrease in iron-regulatory protein binding activity occurred, reflecting elevated intracellular iron pools. Thus intestinal DMT1 rapidly responds to dietary iron in both +/b and b/b rats. The internalization of DMT1 may be an acute regulatory mechanism to limit iron uptake. In addition, the results suggest that in the Belgrade rat DMT1 with the G185R mutation is not an absolute block to iron.     

Hypoxia-inducible factor-2α and iron absorptive gene expression in Belgrade rat intestine

The divalent metal transporter (DMT1, Slc11a2) is an important molecule for intestinal iron absorption. In the Belgrade (b/b) rat, the DMT1 G185R mutation markedly decreases intestinal iron absorption. We used b/b rats as a model to examine the genes that could be compensatory for decreased iron absorption. When tissue hypoxia was assayed by detecting pimonidazole HCl adducts, the b/b liver and intestine exhibited more adducts than the +/+ rats, suggesting that hypoxia might signal altered gene expression. Total RNA in the crypt-villus bottom (C-pole) and villus top (V-pole) of +/+, b/b, and iron-fed b/b rats was isolated for gene array analyses. In addition, hepatic hepcidin and intestinal hypoxia-inducible factor-α (Hifα) expression were examined. The results showed that expression of hepatic hepcidin was significantly decreased and intestinal Hif2α was significantly increased in b/b and iron-fed b/b than +/+ rats. In b/b rats, the expression of Tfrc mRNA in the C-pole and of DMT1, Dcytb, FPN1, Heph, Hmox1, and ZIP14 mRNAs in the V-pole were markedly enhanced with increases occurring even in the C-pole. After iron feeding, the increased expression found in b/b rats persisted, except for Heph and ZIP14, which returned to normal levels. Thus in b/b rats depressed liver hepcidin production and activated intestinal Hif2α starting at the C-pole resulted in increasing expression of iron transport genes, including DMT1 G185R, in an attempt to compensate for the anemia in Belgrade rats.     

Olfactory ferric and ferrous iron absorption in iron-deficient rats

The absorption of metals from the nasal cavity to the blood and the brain initiates an important route of occupational exposures leading to health risks. Divalent metal transporter-1 (DMT1) plays a significant role in the absorption of intranasally instilled manganese, but whether iron uptake would be mediated by the same pathway is unknown. In iron-deficient rats, blood (59)Fe levels after intranasal administration of the radioisotope in the ferrous form were significantly higher than those observed for iron-sufficient control rats. Similar results were obtained when ferric iron was instilled intranasally, and blood levels of (59)Fe were even greater in the iron-deficient rats compared with the amount of ferrous iron absorbed. Experiments with Belgrade (b/b) rats showed that DMT1 deficiency limited ferric iron uptake from the nasal cavity to the blood compared with +/b controls matched for iron deficiency. These results indicate that olfactory uptake of ferric iron by iron-deficient rats involves DMT1. Western blot experiments confirmed that DMT1 levels are significantly higher in iron-deficient rats compared with iron-sufficient controls in olfactory tissue. Thus the molecular mechanism of olfactory iron absorption is regulated by body iron status and involves DMT1.     

Restricted transport of anti-transferrin receptor antibody (OX26) through the blood-brain barrier in the rat

Anti-transferrin receptor IgG2a (OX26) transport into the brain was studied in rats. Uptake of OX26 in brain capillary endothelial cells (BCECs) was > 10-fold higher than isotypic, non-immune IgG2a (Ni-IgG2a) when expressed as % ID/g. Accumulation of OX26 in the brain was higher in 15 postnatal (P)-day-old rats than in P0 and adult (P70) rats. Iron-deficiency did not increase OX26 uptake in P15 rats. Three attempts were made to investigate transport from BCECs further into the brain. (i) Using a brain capillary depletion technique, 6-9% of OX26 was identified in the post-capillary compartment consisting of brain parenchyma minus BCECs. (ii) In cisternal CSF, the volume of distribution of OX26 was higher than for Ni-IgG2a when corrected for plasma concentration. (iii) Immunohistochemical mapping revealed the presence of OX26 almost exclusively in BCECs; extravascular staining was observed only in neurons situated periventricularly. The data support the hypothesis of facilitated uptake of OX26 due to the presence of transferrin receptors at the blood-brain barrier (BBB). However, OX26 accumulation in the post-capillary compartment was too small to justify a conclusion of receptor-mediated transcytosis of OX26 occurring in BCECs. Accumulation of OX26 in the post-capillary component may result from a diphasic transport that involves high-affinity accumulation of OX26 by the BCECs, clearly exceeding that of Ni-IgG2a, followed by a second transport mechanism that releases OX26 non-specifically further into the brain. The periventricular localization suggests that OX26 probably also derives from transport across the blood-CSF barrier.     

Manganese metabolism is impaired in the Belgrade laboratory rat

Homozygous Belgrade rats have a hypochromic anaemia due to impaired iron transport across the cell membrane of immature erythroid cells. This study aimed at investigating whether there are also abnormalities of Mn metabolism in erythroid and other types of cells. The experiments were performed with homozygous (b/b) and heterozygous (+/b) Belgrade rats and Wistar rats and included measurements of Mn uptake by reticulocytes in vitro, Mn absorption from in situ closed loops of the duodenum, and plasma clearance and uptake by several organs after intravenous injection of radioactive Mn bound to transferrin (Tf ) or mixed with serum. Similar measurements were made with ⁵⁹Fe-labelled Fe in several of the experiments. Mn uptake by reticulocytes and absorption from the duodenum was impaired in b/b rats compared with +/b or Wistar rats. The plasma clearance of Mn-Tf was much slower than Mn-serum, but both were faster than the clearance of Fe-Tf. Uptake of ⁵⁴Mn by the kidneys, brain and femurs was less in b/b than Wistar or +/b rats, but uptake by the liver was greater in b/b rats. Similar differences were found for ⁵⁹Fe uptake by kidneys, brain and femurs but ⁵⁹Fe uptake by the liver was also impaired in the liver. It is concluded that the genetic abnormality present in b/b rats affects Mn metabolism as well as Fe metabolism and that Mn and Fe share similar transport mechanisms in the cells of erythroid tissue, duodenal mucosa, kidney and blood-brain barrier. Accepted: 20 February 1997     

Transport of divalent transition-metal ions is lost in small-intestinal tissue of b/b Belgrade rats

Belgrade rats exhibit microcytic, hypochromic anemia and systemic iron deficiency due to a glycine-to-arginine mutation at residue 185 in a metal ion transporter of a divalent metal transporter/divalent cation transporter/solute carrier 11 group A member 2 or 3 (DMT1/DCT1/SLC11A2), a member of the natural-resistance-associated macrophage protein (Nramp) family. By use of rabbit duodenal tissue, a calcein fluorescence assay has previously been developed to assess transport of divalent metal ions across the small-intestinal brush border membrane (BBM). The assay was readily applied here to rat BBM to learn if it detects DMT1 activity. The results demonstrate protein-mediated transport across the BBM of all tested ions: Mn(2+), Fe(2+), and Ni(2+). Transport into BBM vesicles (BBMV) from (b/b) Belgrade rats was below the detection limit. BBMV of +/b origin had substantial activity. The kinetic rate constant for Ni(2+) membrane transport for +/b BBMV was within the range for normal rabbit tissue. Vesicles from +/b basolateral membranes (BLM) showed similar activity to BBMV while b/b BLM vesicles (BLMV) lacked transport activity. Immunoblots using isoform-specific antibodies demonstrated that intestinal levels of b/b DMT1 were increased compared to +/b DMT1, reflecting iron deficiency. Immunoblots on BBMV indicated that lack of activity in b/b vesicles was not due to a failure of DMT1 to localize to the BBMV; an excess of specific isoforms was present compared to +/b BBMV or duodenal extracts. Immunoblots from BLMV also exhibited enrichment in DMT1 isoforms, despite their distinct origin. Immunofluorescent staining of thin sections of b/b and +/b proximal intestines confirmed that DMT1 localized similarly in mutant and control enterocytes and showed that DMT1 isoforms have distinct distributions within intestinal tissue.     

Iron trafficking inside the brain

Iron, an essential element for all cells of the body, including those of the brain, is transported bound to transferrin in the blood and the general extracellular fluid of the body. The demonstration of transferrin receptors on brain capillary endothelial cells (BCECs) more than 20 years ago provided the evidence for the now accepted view that the first step in blood to brain transport of iron is receptor-mediated endocytosis of transferrin. Subsequent steps are less clear. However, recent investigations which form the basis of this review have shed some light on them and also indicate possible fruitful avenues for future research. They provide new evidence on how iron is released from transferrin on the abluminal surface of BCECs, including the role of astrocytes in this process, how iron is transported in brain extracellular fluid, and how iron is taken up by neurons and glial cells. We propose that the divalent metal transporter 1 is not involved in iron transport through the BCECs. Instead, iron is probably released from transferrin on the abluminal surface of these cells by the action of citrate and ATP that are released by astrocytes, which form a very close relationship with BCECs. Complexes of iron with citrate and ATP can then circulate in brain extracellular fluid and may be taken up in these low-molecular weight forms by all types of brain cells or be bound by transferrin and taken up by cells which express transferrin receptors. Some iron most likely also circulates bound to transferrin, as neurons contain both transferrin receptors and divalent metal transporter 1 and can take up transferrin-bound iron. The most likely source for transferrin in the brain interstitium derives from diffusion from the ventricles. Neurons express the iron exporting carrier, ferroportin, which probably allows them to excrete unneeded iron. Astrocytes lack transferrin receptors. Their source of iron is probably that released from transferrin on the abluminal surface of BCECs. They probably to export iron by a mechanism involving a membrane-bound form of the ferroxidase, ceruloplasmin. Oligodendrocytes also lack transferrin receptors. They probably take up non-transferrin bound iron that gets incorporated in newly synthesized transferrin, which may play an important role for intracellular iron transport.     

Brain iron homeostasis.

The anatomical and cellular distribution of non-haem iron, ferritin, transferrin, and the transferrin receptor have been studied in postmortem human brain and these studies, together with data on the uptake and transport of labeled iron, by the rat brain, have been used to elucidate the role of iron and other metal ions in certain neurological disorders. High levels of non-haem iron, mainly in the form of ferritin, are found in the extrapyramidal system, associated predominantly with glial cells. In contrast to non-haem iron, the density of transferrin receptors is highest in cortical and brainstem structures and appears to relate to the iron requirement of neurones for mitochondrial respiratory activity. Transferrin is synthesized within the brain by oligodendrocytes and the choroid plexus, and is present in neurones, consistent with receptor mediated uptake. The uptake of iron into the brain appears to be by a two-stage process involving initial deposition of iron in the brain capillary endothelium by serum transferrin, and subsequent transfer of iron to brain-derived transferrin and transport within the brain to sites with a high transferrin receptor density. A second, as yet unidentified mechanism, may be involved in the transfer of iron from neurones possessing transferrin receptors to sites of storage in glial cells in the extrapyramidal system. The distribution of iron and the transferrin receptor may be of relevance to iron-induced free radical formation and selective neuronal vulnerability in neurodegenerative disorders.     

Functional properties of transfected human DMT1 iron transporter

Recently, mutation of the DMT1 gene has been discovered to cause ineffective intestinal iron uptake and abnormal body iron metabolism in the anemic Belgrade rat and mk mouse. DMT1 transports first-series transition metals, but only iron turns on an inward proton current. The process of iron transport was studied by transfection of human DMT1 into the COS-7 cell line. Native and epitope-tagged human DMT1 led to increased iron uptake. The human gene with the Belgrade rat mutation was found to have one-fifth of the activity of the wild-type protein. The pH optimum of human DMT1 iron uptake was 6.75, which is equivalent to the pH of the duodenal brush border. The transporter demonstrates uptake without saturation from 0 to 50 microM iron, recapitulating earlier studies of isolated intestinal enterocytes. Diethylpyrocarbonate inhibition of iron uptake in DMT1-transfected cells suggests a functional role for histidine residues. Finally, a model is presented that incorporates the selectivity of the DMT1 transporter for transition metals and a potential role for the inward proton current.     

A spontaneous, recurrent mutation in divalent metal transporter-1 exposes a calcium entry pathway

Divalent metal transporter-1 (DMT1/DCT1/Nramp2) is the major Fe²⁺ transporter mediating cellular iron uptake in mammals. Phenotypic analyses of animals with spontaneous mutations in DMT1 indicate that it functions at two distinct sites, transporting dietary iron across the apical membrane of intestinal absorptive cells, and transporting endosomal iron released from transferrin into the cytoplasm of erythroid precursors. DMT1 also acts as a proton-dependent transporter for other heavy metal ions including Mn²⁺, Co²⁺, and Cu², but not for Mg²⁺ or Ca²⁺. A unique mutation in DMT1, G185R, has occurred spontaneously on two occasions in microcytic (mk) mice and once in Belgrade (b) rats. This mutation severely impairs the iron transport capability of DMT1, leading to systemic iron deficiency and anemia. The repeated occurrence of the G185R mutation cannot readily be explained by hypermutability of the gene. Here we show that G185R mutant DMT1 exhibits a new, constitutive Ca²⁺ permeability, suggesting a gain of function that contributes to remutation and the mk and b phenotypes.     

Heterogenous distribution of ferroportin-containing neurons in mouse brain

Iron is crucial for a variety of cellular functions in neuronal cells. Neuronal iron uptake is reflected in a robust and consistent expression of transferrin receptors and divalent metal transporter 1 (DMT 1). Conversely, the mechanisms by which neurons neutralize and possibly excrete iron are less clear. Studies indicate that neurons express ferroportin which could reflect a mechanism for iron export. We mapped the distribution of ferroportin in the adult mouse brain using an antibody prepared from a peptide representing amino acid sequences 223–303 of mouse ferroportin. The antibody specifically detected ferroportin in brain homogenates, whereas homogenates of cultured endothelial cells were devoid of immunoreactivity. In brain sections, ferroportin was confined to neuronal cell bodies and peripheral processes of cerebral cortex, hippocampus, thalamus, brain stem, and cerebellum. In brain stem ferroportin-labeling was particularly high in neurons of cranial nerve nuclei and reticular formation. Ferroportin was hardly detectable in striatum, pallidum, or hypothalamus. Among non-neuronal cells, ferroportin was detected in oligodendrocytes and choroid plexus epithelial cells. A comparison with previous studies on the distribution of transferrin receptors in neurons shows that many neuronal pools coincide with those expressing ferroportin. The data therefore indicate that neuronal iron homeostasis consists of a delicate balance between transferrin receptor-mediated uptake of iron-transferrin and ferroportin-related iron excretion. The findings also suggest a particular high turnover of iron in neuronal regions, such as habenula, hippocampus, reticular formation and cerebellum, as several neurons in these regions exhibit a prominent co-expression of transferrin receptors and ferroportin.     

Uptake and Distribution of Iron and Transferrin in the Adult Rat Brain

Brain uptake of iron-59 and iodine-125-labelled transferrin from blood in the adult rat has been investigated using graphical analysis to determine the blood-brain barrier permeability to these tracers in experiments that lasted between 5 min and 8 days. The blood-brain barrier permeability (K(in)) to 59Fe was 89 x 10(-5) ml/min/g compared to the value of 7 x 10(-5) ml/min/g for 125I-transferrin, which is similar to that of albumin, a plasma marker. The autoradiographic distribution of these tracers in brain was also studied to determine any regional variation in brain uptake after the tracers had been administered either systemically or applied in vitro. No regional uptake was seen for 125I-transferrin even after 24 h of circulation. In contrast, 59Fe showed selective regional uptake by the choroid plexus and extra-blood-brain barrier structures 4 h after administration. After 24 h of circulation, 59Fe distribution in brain was similar to the transferrin receptor distribution, as determined in vitro, but was unlike the distribution of nonhaem iron determined histochemically. The data suggest that brain iron uptake does not involve any significant transcytotic pathway of transferrin-bound iron into brain. It is proposed that the uptake of iron into brain involves the entry of iron-loaded transferrin to the cerebral capillaries, deposition of iron within the endothelial cells, followed by recycling of apotransferrin to the circulation. The deposited iron is then delivered to brain-derived transferrin for extracellular transport within the brain, and subsequently taken up via transferrin receptors on neurones and glia for usage or storage.     

Iron absorption by Belgrade rat pups during lactation

Divalent metal transporter-1 (DMT1) mediates dietary nonheme iron absorption. Belgrade (b) rats have defective iron metabolism due to a mutation in the DMT1 gene. To examine the role of DMT1 in neonatal iron assimilation, b/b and b/+ pups were cross-fostered to F344 Fischer dams injected with (59)FeCl(3) twice weekly during lactation. Tissue distribution of the radioisotope in the pups was determined at weaning (day 21). The b/b pups had blood (59)Fe levels significantly lower than b/+ controls but significantly higher (59)Fe tissue levels in heart, bone marrow, skeletal muscle, kidney, liver, spleen, stomach, and intestines. To study the pharmacokinetics of nonheme iron absorption at the time of weaning, (59)FeCl(3) was administered to 21-day-old b/b and b/+ rats by intragastric gavage. Blood (59)Fe levels measured 5 min to 4 h postgavage were significantly lower in b/b rats, consistent with impaired DMT1 function in intestinal iron absorption. Tissue (59)Fe levels were also lower in b/b rats postgavage. Combined, these data suggest that DMT1 function is not essential for iron assimilation from milk during early development in the rat.     

Influence of DMT1 and iron status on inflammatory responses in the lung

Divalent metal transporter 1 (DMT1) is the major iron transporter responsible for duodenal dietary iron absorption and is required for erythropoiesis. Recent studies suggest that loss of DMT1 activity could be involved in metal-related lung injury, but little is known about the effects of iron status and DMT1 function on pulmonary inflammation. To better define the role of DMT1 and iron status in pulmonary inflammatory responses, we performed bronchoalveolar lavage (BAL) following intratracheal instillation of lipopolysaccharide (LPS) to the Belgrade rat, an animal model deficient in DMT1 function. In the basal state, the BAL fluid of Belgrade rats had more macrophages and higher lactate dehydrogenase, myeloperoxidase, albumin, and hemoglobin levels compared with heterozygote control rats. Following LPS instillation, the macrophage fraction relative to total BAL cell content and levels of albumin and IgM were increased in Belgrade rats compared with controls. In contrast, heterozygote Belgrade rats made anemic by diet-induced iron deficiency exhibited attenuated inflammatory responses to LPS. These combined results show that pulmonary inflammation can be modified by both DMT1 and iron status. Loss of DMT1 alters pulmonary responses necessary for lung homeostasis in the basal state and enhances LPS-induced inflammation and therefore would contribute to progression of lung injury.     

Lung injury after ozone exposure is iron dependent

We tested the hypothesis that oxidative stress and biological effect after ozone (O3) exposure are dependent on changes in iron homeostasis. After O3 exposure, healthy volunteers demonstrated increased lavage concentrations of iron, transferrin, lactoferrin, and ferritin. In normal rats, alterations of iron metabolism after O3 exposure were immediate and preceded the inflammatory influx. To test for participation of this disruption in iron homeostasis in lung injury following O3 inhalation, we exposed Belgrade rats, which are functionally deficient in divalent metal transporter 1 (DMT1) as a means of iron uptake, and controls to O3. Iron homeostasis was disrupted to a greater extent and the extent of injury was greater in Belgrade rats than in control rats. Nonheme iron and ferritin concentrations were higher in human bronchial epithelial (HBE) cells exposed to O3 than in HBE cells exposed to filtered air. Aldehyde generation and IL-8 release by the HBE cells was also elevated following O3 exposure. Human embryonic kidney (HEK 293) cells with elevated expression of a DMT1 construct were exposed to filtered air and O3. With exposure to O3, elevated DMT1 expression diminished oxidative stress (i.e., aldehyde generation) and IL-8 release. We conclude that iron participates critically in the oxidative stress and biological effects after O3 exposure.     

DMT1: which metals does it transport?

DMT1-Divalent Metal (Ion) Transporter 1 or SLC11A2/DCT1/Nramp2 - transports Fe2+ into the duodenum and out of the endosome during the transferrin cycle. DMTI also is important in non-transferrin bound iron uptake. It plays similar roles in Mn2+ trafficking. Voltage clamping showed that six other metals evoked currents, but it is unclear if these metals are substrates for DMT1. This report summarizes progress on which metals DMT1 transports, focusing on results from the authors' labs. We recently cloned 1A/+IRE and 2/-IRE DMT1 isoforms to generate HEK293 cell lines that express them in a tetracycline-inducible fashion, then compared induced expression to uninduced expression and to endogenous DMT1 expression. Induced expression increases approximately 50x over endogenous expression and approximately 10x over uninduced levels. Fe2+, Mn2+, Ni2+ and Cu1+ or Cu2+ are transported. We also explored competition between metal ions using this system because incorporation essentially represents DMT1 transport and find this order for transport affinity: Mn>?Cd>?Fe>Pb-Co-Ni>Zn. The effects of decreased DMT1 also could be examined. The Belgrade rat has diminished DMT1 function and thus provides ways of testing. A series of DNA constructs that generate siRNAs specific for DMT1 or certain DMT1 isoforms yield another way to test DMT1-based transport.     

Divalent metal transporter-1 decreases metal-related injury in the lung

Exposure to airborne particulates makes the detoxification of metals a continuous challenge for the lungs. Based on the fate of iron in airway epithelial cells, we postulated that divalent metal transporter-1 (DMT1) participates in detoxification of metal associated with air pollution particles. Homozygous Belgrade rats, which are functionally deficient in DMT1, exhibited diminished metal transport from the lower respiratory tract and greater lung injury than control littermates when exposed to oil fly ash. Preexposure of normal rats to iron in vivo increased expression of the isoform of DMT1 protein that lacked an iron-response element (-IRE), accelerated metal transport out of the lung, and decreased injury after particle exposure. In contrast, normal rats preexposed to vanadium showed less expression of the -IRE isoform of DMT1, decreased metal transport, and greater pulmonary injury after particle instillation. Respiratory epithelial cells in culture gave similar results. Also, DMT1 mRNA and protein expression for the -IRE isoform increased or decreased in these cells when exposed to iron or vanadium, respectively. These results thus demonstrate for the first time a primary role for DMT1 in lung metal transport and detoxification.