Transmembrane topology of the mammalian Slc11a2 iron transporter.

The mammalian Slc11a1 and Slc11a2 proteins define a large family of secondary metal transporters. Slc11a1 and Slc11a2 function as pH-dependent divalent cation transporters that play a critical role in host defenses against infections and in Fe2+ homeostasis, respectively. The position and polarity of individual transmembrane domains (TMD) of Slc11a2 were studied by an epitope tagging method based on the insertion of small antigenic hemagglutinin A (HA) peptides (YPYDVPDYAS) in predicted intra- or extracellular loops of the protein. The tagged proteins were expressed in transfected LLC-PK1 kidney cells and tested for transport activity, and the polarity of inserted tags with respect to the plasma membrane was determined by immunofluorescence in intact and permeabilized cells. HA epitope tags were inserted at positions 1, 98, 131, 175, 201, 243, 284, 344, 403, 432, 468, 504, and 561. Insertions at positions 98, 131, 175, 403, and 432 abrogated metal transport by Slc11a2, while insertions at positions 1, 201, 243, 284, 344, 468, 504, and 561 resulted in functional proteins. Topology mapping in functional HA-tagged Slc11a2 proteins indicated that the N-terminus (1), as well as loops delineated by TMD4-5 (201), TMD6-7 (284), and TMD10-11 (468), and C-terminus (561) are intracellular, while loops separating TMD5-6 (243), TMD7-8 (344), and TMD11-12 (504) are extracellular. These results are compatible with a topology of 12 transmembrane domains, with intracellular amino and carboxy termini. Structural models constructed by homology threading support this 12TMD topology and show 2-fold structural symmetry in the arrangement of membrane helices for TM1-5 and TM6-10 (conserved Slc11 hydrophobic core).

Identification of a tyrosine-based motif (YGSI) in the amino terminus of Nramp1 (Slc11a1) that is important for lysosomal targeting.

In macrophages, Nramp1 (Slc11a1) is expressed in lysosomes and restricts replication of intracellular pathogens by removing divalent metals (Mn2+ and Fe2+) from the phagolysosome. Nramp2 (DMT1, Slc11a2) is expressed both at the duodenal brush border where it mediates uptake of dietary iron and ubiquitously at the plasma membrane/recycling endosomes of many cell types where it transports transferrin-associated iron across the endosomal membrane. In Nramp2, a carboxyl-terminal cytoplasmic motif ((555)YLLNT(559)) is critical for internalization and recycling of the transporter from the plasma membrane. Here we studied the subcellular trafficking properties of Nramp1 and investigated the cis-acting sequences responsible for targeting to lysosomes. For this, we constructed and studied Nramp1/Nramp2 chimeric proteins where homologous domains of each protein were exchanged. Chimeras exchanging the amino-(upstream TM1) and carboxyl-terminal (downstream TM12) cytoplasmic segments of both transporters were stably expressed in porcine LLC-PK1 kidney cells and were studied with respect to expression, maturation, stability, cell surface targeting, transport activity, and subcellular localization. An Nramp2 isoform II chimera bearing the amino terminus of Nramp1 was not expressed at the cell surface but was targeted to lysosomes. This lysosomal targeting was abolished by single alanine substitutions at Tyr15 and Ile18 of a (15)YGSI(18) motif present in the amino terminus of Nramp1. These results identify YGSI as a tyrosine-based sorting signal responsible for lysosomal targeting of Nramp1.

A novel R416C mutation in human DMT1 (SLC11A2) displays pleiotropic effects on function and causes microcytic anemia and hepatic iron overload.

A patient suffering from microcytic anemia and hepatic iron overload was found to be compound heterozygote for polymorphisms in the iron transporter DMT1 (Nramp2, SLC11A2), including a 3-bp deletion (DMT1(delCTT)) in intron 4 that partially impairs splicing and an amino acid substitution (DMT1(C1246T), R416C) at a conserved residue in transmembrane domain 9 of the protein. The functional properties and possible contribution to disease of the DMT1 R416C mutation were studied in independent mutants at that position (R416C, R416A, R416K, R416E) expressed in LLC-PK(1) kidney cells. Non-conservative substitutions at R416 (C, A, E) cause multiple functional deficiencies including defective protein processing, loss of transport activity, impaired cell surface targeting, and recycling through endosomes, concomitant with retention of the transporter in the endoplasmic reticulum. Conversely, a conservative isoelectric substitution (R416K) was less vulnerable, resulting in a functional transporter that was properly processed and targeted to the cell surface and to recycling endosomes. We propose that DMT1(C1246T) (R416C) represents a complete loss-of-function, and that a quantitative reduction in DMT1 expression is the cause of the microcytic anemia and iron overload in the patient.

Distinct targeting and recycling properties of two isoforms of the iron transporter DMT1 (NRAMP2, Slc11A2).

The metal transporter DMT1 (Slc11a2) plays a vital role in iron metabolism. Alternative splicing of the 3' exon generates two DMT1 isoforms with different C-terminal protein sequences and a 3' untranslated region harboring (isoform I, +IRE) or not (isoform II, -IRE), an iron-responsive element. Isoform I is expressed at the plasma membrane of certain epithelial cells including the duodenum brush border, where it is essential for the absorption of nutritional iron. Isoform II is expressed in many cells and is essential for the acquisiton of transferrin iron from acidified endosomes. The targeting and trafficking properties of DMT1 isoforms I and II were studied in transfected LLC-PK(1) kidney cells, with respect to isoform-specific differences in function, subcellular localization, endocytosis kinetics, and fate upon internalization. Isoform I showed higher surface expression and was internalized from the plasma membrane with slower kinetics than that of isoform II. As opposed to isoform II, which is efficiently sorted to recycling endosomes upon internalization, isoform I was not efficiently recycled and was targeted to lysosomes. Thus, alternative splicing of DMT1 critically regulates the subcellular localization and site of Fe(2+) transport.

Modulation of Iron Availability at the Host-Pathogen Interface in Phagocytic Cells.

This review summarizes recent data on iron metabolism in macrophages, with a special emphasis on possible bacteriostatic and bactericidal consequences for intracellular pathogens. It includes the role of biological chelators and transporters in normal macrophage physiology and antimicrobial defense. Iron is an essential metal cofactor for many biochemical pathways in mammals. However, excess iron promotes the formation of cytotoxic oxygen derivatives so that systemic iron levels must be tightly regulated. The mechanism of iron recycling by macrophages including iron efflux from erythrocyte-containing phagosomes, iron release from macrophages, and entry into the transferrin (Tf) cycle remain poorly understood. Ferroportin expression in the liver, spleen, and bone marrow cells appears to be restricted to macrophages. Mutant mice bearing a conditional deletion of the ferroportin gene in macrophages show retention of iron by hepatic Kupffer cells and splenic macrophages. Hepcidin is induced by lipopolysaccharide (LPS) in mouse spleens and splenic macrophage in vitro and appears to mediate the LPS-induced down-regulation of ferroportin in the intestine and in splenic macrophages, suggesting that inflammatory agents may regulate iron metabolism through modulation of ferroportin expression. The host transporter Nramp1 may compete directly with bacterial divalent-metal transport systems for the acquisition of divalent metals within the phagosomal space. The ultimate outcome of these competing interactions influences the ability of pathogens to survive and replicate intracellularly. This seems particularly relevant to the Salmonella, Leishmania, and Mycobacterium spp., in which inactivating mutations in Nramp1 abrogate the natural resistance of macrophages to these pathogens.

Carboxyl-terminus determinants of the iron transporter DMT1/SLC11A2 isoform II (-IRE/1B) mediate internalization from the plasma membrane into recycling endosomes.

Mutations in DMT1 (Nramp2 and Slc11a2) impair iron metabolism and cause microcytic anemia. DMT1 is expressed at the duodenal brush border where it controls uptake of dietary iron and is present at the plasma membrane and in recycling endosomes of most cells, where it is necessary for acquisition of transferrin-associated iron. The goal of this study was to identify signal(s) in the cytoplasmic segments of DMT1 responsible for its subcellular targeting and internalization from the plasma membrane into recycling endosomes. We introduced mutations in the amino terminus (DeltaNT), carboxyl terminus (DeltaCT), as well as in NPAY28-31, YSCF62-65, and YLLNT555-559 motifs of a DMT1 construct bearing an exofacial epitope tag, which allowed labeling of the transporter at the cell surface for kinetic studies. Mutants were stably expressed in LLC-PK1 kidney cells and were studied for transport activity, subcellular localization, cell-surface and recycling pool distribution, and internalization from the plasma membrane. Kinetic studies showed that carboxyl-terminus mutants (DeltaCT and DeltaYLLNT) had an increased fraction of the "recycling pool" that was expressed at the cell surface because of impaired internalization from the plasma membrane. Further cell-surface-labeling and immunofluorescence studies in intact cells showed that the DeltaYLLNT and DeltaCT mutants were targeted to the lysosomal compartment upon internalization. These results suggest that the major signal for internalization and recycling of DMT1 isoform II (-IRE/1B) resides in its carboxyl terminus and that removal of this signal leads to a default lysosomal targeting.

Functional characterization of the E399D DMT1/NRAMP2/SLC11A2 protein produced by an exon 12 mutation in a patient with microcytic anemia and iron overload.

DMT1 (Nramp2, Slc11a2) mediates iron uptake at the intestinal brush border and across the membrane of acidified endosomes. A single patient with severe microcytic anemia and iron overload was recently reported to carry a mutation in exon 12 of DMT1 (1285G>C). The mutation has two effects: it severely impairs splicing causing skipping of exon 12 and introduces an amino acid polymorphism (E399D) in the protein encoded by the remaining properly spliced transcript found in the patient. The functional properties and possible contribution to disease of the DMT1 E399D mutation are unknown and have been studied in independent mutants at that position (E399D, E399Q, E399A) expressed in LLC-PK1 kidney cells. The 3 mutants are shown to be fully functional with respect to stability, targeting and trafficking to the membrane, and are transport-competent. This indicates that DMT1G1285C is not a complete loss of function but rather that a modest amount of active DMT1 is produced in this patient. This activity may explain the distinguishing iron overload seen in this patient in addition to microcytic anemia that is absent in parallel rodent models of DMT1 deficiency.

Single gene effects in mouse models of host: pathogen interactions.

Inbred mouse strains have been known for many years to vary in their degree of susceptibility to different types of infectious diseases. The genetic basis of these interstrain differences is sometimes simple but often complex. In a few cases, positional cloning has been used successfully to identify single gene effects. The natural resistance-associated macrophage protein 1 (Nramp1) gene (Slc11a1) codes for a metal transporter active at the phagosomal membrane of macrophages, and Nramp1 mutations cause susceptibility to Mycobacterium, Salmonella, and Leishmania. Furthermore, recent advances in gene transfer technologies in transgenic mice have enabled the functional dissection of gene effects mapping to complex, repeated parts of the genome, such as the Lgn1 locus, causing susceptibility to Legionella pneumophila in macrophages. Finally, complex traits such as the genetically determined susceptibility to malaria can sometimes be broken down into multiple single gene effects. One such example is the case of pyruvate kinase, where a loss-of-function mutation was recently shown by our group to be protective against blood-stage infection with Plasmodium chabaudi. In all three cases reviewed, the characterization of the noted gene effect(s) has shed considerable light on the pathophysiology of the infection, including host response mechanisms.

Molecular and cellular mechanisms underlying iron transport deficiency in microcytic anemia.

A mutation of the iron transporter Nramp2 (DMT1, Slc11a2) causes microcytic anemia in mk mice and in Belgrade rats by impairing iron absorption in the duodenum and in erythroid cells, causing severe iron deficiency. Both mk and Belgrade animals display a glycine-to-arginine substitution at position 185 (G185R) in the fourth predicted transmembrane domain of Nramp2. To study the molecular basis for the loss of function of Nramp2(G185R), we established cell lines stably expressing extracellularly tagged versions of wild-type (WT) or mutated transporters. Like WT Nramp2, the G185R mutant was able to reach the plasmalemma and endosomal compartments, but with reduced efficiency. Instead, a large fraction of Nramp2(G185R) was detected in the endoplasmic reticulum, where it was unstable and was rapidly degraded by a proteasome-dependent mechanism. Moreover, the stability of the mutant protein that reached the plasma membrane was greatly reduced, further diminishing its surface density at steady state. Last, the specific metal transport activity of plasmalemmal Nramp2(G185R) was found to be significantly depressed, compared with its WT counterpart. Thus, a singlepoint mutation results in multiple biosynthetic and functional defects that combine to produce the impaired iron deficiency that results in microcytic anemia.

Genetic control of susceptibility to bacterial infections in mouse models.

Historically, the laboratory mouse (Mus musculus) has been the experimental model of choice to study pathophysiology of infection with bacterial pathogens, including natural and acquired host defence mechanisms. Inbred mouse strains differ significantly in their degree of susceptibility to infection with various human pathogens such as Mycobacterium, Salmonella, Legionella and many others. Segregation analyses and linkage studies have indicated that some of these differences are under simple genetic control whereas others behave as complex traits. Major advances in genome technologies have greatly facilitated positional cloning of single gene effects. Thus, a number of genes playing a key role in initial susceptibility, progression and outcome of infection have been uncovered and the functional characterization of the encoded proteins has provided new insight into the molecular basis of antimicrobial defences of polymorphonuclear leukocytes, macrophages, as well as T and B lymphocytes. The multigenic control of susceptibility to infection with certain human pathogens is beginning to be characterized by quantitative trait locus mapping in genome wide scans. This review summarizes recent progress on the mapping, cloning and characterization of genes and proteins that affect susceptibility to infection with major intracellular bacterial pathogens.

Iron transport by Nramp2/DMT1: pH regulation of transport by 2 histidines in transmembrane domain 6.

Mutations at natural resistance-associated macrophage protein 1 (Nramp1) impair phagocyte function and cause susceptibility to infections while mutations at Nramp2 (divalent metal transporter 1 [DMT1]) affect iron homeostasis and cause severe microcytic anemia. Structure-function relationships in the Nramp superfamily were studied by mutagenesis, followed by functional characterization in yeast and in mammalian cells. These studies identify 3 negatively charged and highly conserved residues in transmembrane domains (TM) 1, 4, and 7 as essential for cation transport by Nramp2/DMT1. The introduction of a charged residue (Gly185Arg) in TM4 found in the naturally occurring microcytic anemia mk (mouse) and Belgrade (rat) mutants is shown to cause a partial or complete loss of function in mammalian and yeast cells, respectively. A pair of mutation-sensitive and highly conserved histidines (His267, His272) was identified in TM6. Surprisingly, inactive His267 and His272 mutants could be rescued by lowering the pH of the transport assay. This indicates that His267/His272 are not directly involved in metal binding but, rather, play an important role in pH regulation of metal transport by Nramp proteins.