The metal permease ZupT from Escherichia coli is a transporter with a broad substrate spectrum

The Escherichia coli zupT (formerly ygiE) gene encodes a cytoplasmic membrane protein (ZupT) related to members of the eukaryotic ZIP family of divalent metal ion transporters. Previously, ZupT was shown to be responsible for uptake of zinc. In this study, we show that ZupT is a divalent metal cation transporter of broad substrate specificity. An E. coli strain with a disruption in all known iron uptake systems could grow in the presence of chelators only if zupT was expressed. Heterologous expression of Arabidopsis thaliana ZIP1 could also alleviate iron deficiency in this E. coli strain, as could expression of indigenous mntH or feoABC. Transport studies with intact cells showed that ZupT facilitates uptake of 55Fe2+ similarly to uptake of MntH or Feo. Other divalent cations were also taken up by ZupT, as shown using 57Co2+. Expression of zupT rendered E. coli cells hypersensitive to Co2+ and sensitive to Mn2+. ZupT did not appear to be metal regulated: expression of a Phi(zupT-lacZ) operon fusion indicated that zupT is expressed constitutively at a low level.     

The NRAMP proteins of Salmonella typhimurium and Escherichia coli are selective manganese transporters involved in the response to reactive oxygen

NRAMPs (natural resistance-associated macrophage proteins) have been characterized in mammals as divalent transition metal transporters involved in iron metabolism and host resistance to certain pathogens. The mechanism of pathogen resistance is proposed to involve sequestration of Fe2+ and Mn2+, cofactors of both prokaryotic and eukaryotic catalases and superoxide dismutases, not only to protect the macrophage against its own generation of reactive oxygen species, but to deny the cations to the pathogen for synthesis of its protective enzymes. NRAMP homologues are also present in bacteria. We report the cloning and characterization of the single NRAMP genes in Escherichia coli and Salmonella enterica ssp. typhimurium, and the cloning of two distinct NRAMP genes from Pseudomonas aeruginosa and an internal fragment of an NRAMP gene in Burkholderia cepacia. The genes are designated mntH because the two enterobacterial NRAMPs encode H+-stimulated, highly selective manganese(II) transport systems, accounting for all Mn2+ uptake in each species under the conditions tested. For S. typhimurium MntH, the Km for 54Mn2+ ( approximately 0.1 microM) was pH independent, but maximal uptake increased as pH decreased. Monovalent cations, osmotic strength, Mg2+ and Ca2+ did not inhibit 54Mn2+ uptake. Ni2+, Cu2+ and Zn2+ inhibited uptake with Kis greater than 100 microM, Co2+ with a Ki of 20 microM and Fe2+ with a Ki that decreased from 100 microM at pH 7. 6 to 10 microM at pH 5.5. Fe3+ and Pb2+ inhibited weakly, exhibiting Kis of 50 microM, while Cd2+ was a potent inhibitor with a Ki of about 1 microM. E. coli MntH had a similar inhibition profile, except that Kis were three- to 10-fold higher. Both S. typhimurium and E. coli MntH also transport 55Fe2+ however, the Kms are equivalent to the Kis for Fe2+ inhibition of Mn2+ uptake, and are thus too high to be physiologically relevant. In both S. typhimurium and E. coli, mntH:lacZ constructs were strongly induced by hydrogen peroxide, weakly induced by EDTA and unresponsive to paraquat, consistent with the presence of Fur and OxyR binding sites in the promoters. Strains overexpressing mntH were more susceptible to growth inhibition by Mn2+ and Cd2+ than wild type, and strains lacking a functional mntH gene were more susceptible to killing by hydrogen peroxide. In S. typhimurium strain SL1344, mntH mutants showed no defect in invasion of or survival in cultured HeLa or RAW264.7 macrophage cells; however, expression of mntH:lacZ was induced severalfold by 3 h after invasion of the macrophages. S. typhimurium mntH mutants showed only a slight attenuation of virulence in BALB/c mice. Thus, the NRAMP Mn2+ transporter MntH and Mn2+ play a role in bacterial response to reactive oxygen species and possibly have a role in pathogenesis.     

Determination of transmembrane topology of the Escherichia coli natural resistance-associated macrophage protein (Nramp) ortholog

The natural resistance-associated macrophage protein (Nramp) defines a conserved family of secondary metal transporters. Molecular evolutionary analysis of the Nramp family revealed the early duplication of an ancestral eukaryotic Nramp gene, which was likely derived from a bacterial ortholog and characterized as a proton-dependent manganese transporter MntH (Makui, H., Roig, E., Cole, S. T., Helmann, J. D., Gros, P., and Cellier, M. F. (2000) Mol. Microbiol. 35, 1065-1078). Escherichia coli MntH represents a model of choice to study structure function relationship in the Nramp protein family. Here, we report E. coli MntH transmembrane topology using a combination of in silico predictions, genetic fusion with cytoplasmic and periplasmic reporters, and MntH functional assays. Constructs of the secreted form of beta-lactamase (Blam) revealed extra loops between transmembrane domains 1/2, 5/6, 7/8, and 9/10, and placed the C terminus periplasmically; chloramphenicol acetyltransferase constructs indicated cytoplasmic loops 2/3, 6/7, 8/9, and 10/11. Two intra loops for which no data were produced (N terminus, intra loop 4/5) both display composition bias supporting their deduced localization. The extra loops 5/6 and 6/7 and periplasmic exposure of the C terminus were confirmed by targeted reporter insertion. Three of them preserved MntH function as measured by a disk assay of divalent metal uptake and a fluorescence assay of divalent metal-dependent proton transport, whereas a truncated form lacking transmembrane domain 11 was inactive. These results demonstrate that EcoliA is a type III integral membrane protein with 11 transmembrane domains transporting both divalent metal ions and protons.     

Identification of functional amino acids in the Nramp family by a combination of evolutionary analysis and biophysical studies of metal and proton cotransport in vivo

The natural resistance-associated macrophage protein (Nramp) family is functionally conserved in bacteria and eukarya; Nramp homologues function as proton-dependent membrane transporters of divalent metals. Sequence analyses indicate that five phylogenetic groups comprise the Nramp family, three bacterial and two eukaryotic, which are distinct from a more distantly related group of microbial sequences (Nramp outgroup). The Nramp family and outgroup share many conserved residues, suggesting they derived from a common ancestor and raising the possibility that the residues invariant in the Nramp family that correspond to residues which are different but also conserved in the outgroup represent candidate sites of functional divergence of the Nramp family. Four Nramp family-specific residues were identified within transmembrane domains 1, 6, and 11, and replaced by the corresponding invariant outgroup residues in the Escherichia coli Nramp ortholog (the proton-dependent manganese transporter, MntH of group A, EcoliA). The resulting mutants (Asp(34)Gly, Asn(37)Thr, His(211)Tyr, and Asn(401)Gly) were tested for both divalent metal uptake and proton transport; quasi-simultaneous analyses of uptake of metals and protons revealed for the first time protons and metals cotransport by a bacterial Nramp homologue. Additional mutations were studied for comparison (Asp(34)Asn, Asn(37)Asp and Asn(37)Val, Asn(401)Thr, His(211)Ala, His(216)Ala, and His(216)Arg). EcoliA activity was impaired after each of the Nramp/outgroup substitutions, as well as after more conservative replacements, showing that the tested sites are all important for metal uptake and metal-dependent H(+) transport. It is proposed that co-occurrence of these four Nramp-specific transmembrane residues may have contributed to the emergence of this family of metal and proton cotransporters.     

The mntH gene encodes the major Mn2+ transporter in Bradyrhizobium japonicum and is regulated by manganese via the Fur protein

The bacterial Nramp family protein MntH is a divalent metal transporter, but mntH mutants have little or no phenotype in organisms where it has been studied. Here, we identify the mntH homologue of Bradyrhizobium japonicum , and demonstrate that it is essential for Mn²⁺ transport and for maintenance of cellular manganese homeostasis. Transport activity was induced under manganese deficiency, and Fe²⁺ did not compete with ⁵⁴Mn²⁺ for uptake by cells. The steady-state level of mntH mRNA was negatively regulated by manganese, but was unaffected by iron. Control of mntH expression and Mn²⁺ transport by manganese was lost in a fur strain, resulting in constitutively high activity. Fur protected a 35 bp region of the mntH promoter in DNase I footprinting analysis that includes three imperfect direct repeat hexamers that are needed for full occupancy. Mn²⁺ increased the affinity of Fur for the mntH promoter by over 50-fold, with a K _d value of 2.2 nM in the presence of metal. The findings identify MntH as the major Mn²⁺ transporter in B. japonicum , and show that Fur is a manganese-responsive regulator in that organism. Furthermore, Fe²⁺ is neither a substrate for MntH nor a regulator of mntH expression in vivo .     

The phage shock protein PspA facilitates divalent metal transport and is required for virulence of Salmonella enterica sv. Typhimurium

The phage shock protein (Psp) system is induced by extracytoplasmic stress and thought to be important for the maintenance of proton motive force. We investigated the contribution of PspA to Salmonella virulence. A pspA deletion mutation significantly attenuates the virulence of Salmonella enterica serovar Typhimurium following intraperitoneal inoculation of C3H/HeN (Ity^r) mice. PspA was found to be specifically required for virulence in mice expressing the natural resistance‐associated macrophage protein 1 (Nramp1) (Slc11a1) divalent metal transporter, which restricts microbial growth by limiting the availability of essential divalent metals within the phagosome. Salmonella competes with Nramp1 by expressing multiple metal uptake systems including the Nramp‐homologue MntH, the ABC transporter SitABCD and the ZIP family transporter ZupT. PspA was found to facilitate Mn²⁺ transport by MntH and SitABCD, as well as Zn²⁺ and Mn²⁺ transport by ZupT. In vitro uptake of ⁵⁴Mn²⁺ by MntH and ZupT was reduced in the absence of PspA. Transport‐deficient mutants exhibit reduced viability in the absence of PspA when grown under metal‐limited conditions. Moreover, the ZupT transporter is required for Salmonella enterica serovar Typhimurium virulence in Nramp1‐expressing mice. We propose that PspA promotes Salmonella virulence by maintaining proton motive force, which is required for the function of multiple transporters mediating bacterial divalent metal acquisition during infection.     

Polyphyletic origins of bacterial Nramp transporters.

The redox-active metals iron and manganese are required for energy metabolism, protection against oxidative stress and defense against infections. In eukaryotes, both divalent metals are transported by Nramp transporters. The sequence of these transporters was remarkably conserved during evolution. Several bacterial Nramp homologs (MntH) are also proton-dependent manganese transporters. Here, we present phylogenetic evidence for the polyphyletic origins of three groups of MntH proteins and for possible Nramp horizontal gene transfer with eukaryotes. We propose that the evolution of the MntH/Nramp family is related to adaptation to oxidative environments, including those arising during infection of animals and plants.     

Characterization of an integral protein of the brush border membrane mediating the transport of divalent metal ions

The transport of Fe(2+) and other divalent transition metal ions across the intestinal brush border membrane (BBM) was investigated using brush border membrane vesicles (BBMVs) as a model. This transport is an energy-independent, protein-mediated process. The divalent metal ion transporter of the BBM is a spanning protein, very likely a protein channel, that senses the phase transition of the BBM, as indicated by a break in the Arrhenius plot. The transporter has a broad substrate range that includes Mn(2+), Fe(2+), Co(2+), Ni(2+), Cu(2+), and Zn(2+). Under physiological conditions the transport of divalent metal ions is proton-coupled, leading to the acidification of the internal cavity of BBMVs. The divalent metal ion transporter can be solubilized in excess detergent (30 mM diheptanoylphosphatidylcholine or 1% Triton X-100) and reconstituted into an artificial membrane system by detergent removal. The reconstituted membrane system showed metal ion transport characteristics similar to those of the original BBMVs. The properties of the protein described here closely resemble those of the proton-coupled divalent cation transporter (DCT1, Nramp2) described by, Nature. 388:482-488). We may conclude that a protein of the Nramp family is present in the BBM, facilitating the transport of Fe(2+) and other divalent transition metal ions.     

Inactivation of an iron transporter in Lactococcus lactis results in resistance to tellurite and oxidative stress

In Lactococcus lactis, the interactions between oxidative defense, metal metabolism, and respiratory metabolism are not fully understood. To provide an insight into these processes, we isolated and characterized mutants of L. lactis resistant to the oxidizing agent tellurite (TeO(3)(2-)), which generates superoxide radicals intracellularly. A collection of tellurite-resistant mutants was obtained using random transposon mutagenesis of L. lactis. These contained insertions in genes encoding a proton-coupled Mn(2+)/Fe(2+) transport homolog (mntH), the high-affinity phosphate transport system (pstABCDEF), a putative osmoprotectant uptake system (choQ), and a homolog of the oxidative defense regulator spx (trmA). The tellurite-resistant mutants all had better survival than the wild type following aerated growth. The mntH mutant was found to be impaired in Fe(2+) uptake, suggesting that MntH is a Fe(2+) transporter in L. lactis. This mutant is capable of carrying out respiration but does not generate as high a final pH and does not exhibit the long lag phase in the presence of hemin and oxygen that is characteristic of wild-type L. lactis. This study suggests that tellurite-resistant mutants also have increased resistance to oxidative stress and that intracellular Fe(2+) can heighten tellurite and oxygen toxicity.     

Understanding the multiple functions of Nramp1

Nramp1 regulates macrophage activation in infectious and autoimmune diseases. Nramp2 controls anaemia. Both are divalent cation (Fe(2+), Zn(2+), and Mn(2+)) transporters; Nramp2 a symporter of H(+) and metal ions, Nramp1 a H(+)/divalent cation antiporter. This provides a model for metal ion homeostasis in macrophages. Nramp2, localised to early endosomes, delivers extracellularly acquired divalent cations into the cytosol. Nramp1, localised to late endosomes/lysosomes, delivers divalent cations from the cytosol to phagolysosomes. Here, Fe(2+) generates antimicrobial hydroxyl radicals via the Fenton reaction. Zn(2+) and Mn(2+) may also influence endosomal metalloprotease activity and phagolysosome fusion. The many cellular functions dependent on metal ions as cofactors may explain the multiple pleiotropic effects of Nramp1, and its complex roles in infectious and autoimmune disease.     

The ManR specifically binds to the promoter of a Nramp transporter gene in Anabaena sp. PCC 7120: a novel regulatory DNA motif in cyanobacteria

The Anabaena sp. PCC 7120 ManR and a homologous protein of MntH were identified by BLAST search. Recombinant ManR protein was overexpressed in Escherichia coli and purified by an immobilized metal (Ni) affinity chromatography. Electrophoretic mobility shift assays revealed that ManR specifically bound to the promoter region of the mntH gene. Site-directed mutagenesis experiments demonstrated that the specific recognition site for ManR is TATGAAAAGAATATGAGAA, which is composed of two direct repeats of the consensus sequence (T/A)ATGA(G/A)A(A/G). This is a novel regulatory DNA motif in cyanobacteria, indicating that the expression of mntH was regulated by a two-component Mn(2+)-Sensing System containing ManR in Anabaena sp. PCC 7120. To date, this specific pathway of regulating mntH expression has only been found in cyanobacteria.     

Solute carrier 11 cation symport requires distinct residues in transmembrane helices 1 and 6

Ubiquitous solute carriers 11 (SLC11) contribute to metal-ion homeostasis by importing Me(2+) and H(+) into the cytoplasm. To identify residues mediating cation symport, Escherichia coli proton-dependent manganese transporter (MntH) was mutated at five SLC11-specific transmembrane (TM) sites; each mutant activity was compared with wild-type MntH, and the biochemical results were tested by homology threading. Cd(2+) and H(+) uptake kinetics were analyzed in whole cells as a function of pH and temperature, and right-side out membrane vesicles were used to detail energy requirements and to probe site accessibility by Cys replacement and thiol modification. This approach revealed that TM segment 1 (TMS1) residue Asp(34) couples H(+) and Me(2+) symport and contributes to MntH forward transport electrogenicity, whereas the TMS6 His(211) residue mediates pH-dependent Me(2+) uptake; MntH Asn(37), Asn(250), and Asn(401) in TMS1, TMS7, and TMS11 participate in transporter cycling and/or helix packing interactions. These biochemical results fit the LeuT/SLC6 structural fold, which suggests that conserved peptide motifs Asp(34)-Pro-Gly (TMS1) and Met-Pro-His(211) (TMS6) form antiparallel "TM helix/extended peptide" boundaries, lining a "pore" cavity and enabling H(+)-dependent Me(2+) import.     

Nramp2 expression is associated with pH-dependent iron uptake across the apical membrane of human intestinal Caco-2 cells

The absorption of dietary non-heme iron by intestinal enterocytes is crucial to the maintenance of body iron homeostasis. This process must be tightly regulated since there are no distinct mechanisms for the excretion of excess iron from the body. An insight into the cellular mechanisms has recently been provided by expression cloning of a divalent cation transporter (DCT1) from rat duodenum and positional cloning of its human homologue, Nramp2. Here we demonstrate that Nramp2 is expressed in the apical membrane of the human intestinal epithelial cell line, Caco 2 TC7, and is associated with functional iron transport in these cells with a substrate preference for iron over other divalent cations. Iron transport occurs by a proton-dependent mechanism, exhibiting a concurrent intracellular acidification. Taken together, these data suggest that the expression of the Nramp2 transporter in human enterocytes may play an important role in intestinal iron absorption.