Identification of sequences in human transferrin that bind to the bacterial receptor protein, transferrin-binding protein B

Alignment of amino-acid sequences from the N-terminal and C-terminal halves of transferrin-binding protein B revealed an underlying bilobed nature with several regions of identity. Based on this analysis, purified recombinant fusion proteins of maltose-binding protein (Mbp) with intact TbpB, its N-terminal half or C-terminal half from the human pathogens Neisseria meningitidis and Moraxella catarrhalis were produced. Solid-phase binding assays and affinity isolation assays demonstrated that the N-terminal and C-terminal halves of TbpB could bind independently to human transferrin (hTf). A solid-phase overlapping synthetic peptide library representing the amino-acid sequence of hTf was probed with soluble, labelled Mbp-TbpB fusions to localize TbpB-binding regions on hTf. An essentially identical series of peptides from domains within both lobes of hTf was recognized by intact TbpB from both organisms, demonstrating a conserved TbpB-hTf interaction. Both halves of TbpB from N. meningitidis bound the same series of peptides, which included peptides from equivalent regions on the two hTf lobes, indicating that TbpB interacts with each lobe of hTf in a similar manner. Mapping of the peptide-binding regions on a molecular model of hTf revealed a series of nearly adjacent surface regions that nearly encircled each lobe. Binding studies with chimeric hTf/bTf transferrins demonstrated that regions in the C-lobe of hTf were preferentially recognized by the N-terminal half of TbpB. Collectively, these results provide evidence that TbpB consists of two lobes, each with distinct yet homologous Tf-binding regions.     

Identification of a 13-kDa protein associated with the polyhydroxyalkanoic acid granules from Acinetobacter spp.

Abstract Transferrin-binding proteins from Neisseria meningitidis vary among different isolates. We have identified and studied a hypervariable region adjacent to the carboxyl-end of the transferrin-binding domain of the Tbp2 molecule. The tbp2 genes from six strains of N. meningitidis were cloned and sequenced in this particular region. Sequence analysis of these regions along with five other sequences available from pathogenic Neisseria showed a common organisation of seven highly variable nucleotide stretches interspersed with six conserved nucleotide stretches. The variable regions correlated with the location of immunoreactive epitopes in polyclonal antisera raised to transferrin-binding proteins identified by peptide pin technology. Sequence analysis suggested a mosaic-like organisation of the tbp2 genes. Taken together, these data suggest that the antigenic variation in this part of the protein may result from a strong host immune pressure.     

Both the full-length and the N-terminal domain of the meningococcal transferrin-binding protein B discriminate between human iron-loaded and apo-transferrin

We have readdressed the ability of the transferrin-binding protein B (TbpB) from Neisseria meningitidis to discriminate between the iron-loaded and the iron-free human transferrin (hTf) by using the BIAcore technology, a powerful experimental technique for the observation of direct interactions between a receptor and its ligands, without the use of labels. Recombinant full-length TbpB from five N. meningitidis strains were produced and purified from Escherichia coli as fusion proteins. They showed a preference for the binding to iron-loaded hTf. As for the full-length molecule, we have demonstrated that the minimal N-terminal hTf binding domain of meningococcal TbpB from B16B6 and M982 strains was able to discriminate between both hTf forms.     

Identification of human transferrin-binding sites within meningococcal transferrin-binding protein B.

Transferrin-binding protein B (TbpB) from Neisseria meningitidis binds human transferrin (hTf) at the surface of the bacterial cell as part of the iron uptake process. To identify hTf binding sites within the meningococcal TbpB, defined regions of the molecule were produced in Escherichia coli by a translational fusion expression system and the ability of the recombinant proteins (rTbpB) to bind peroxidase-conjugated hTf was characterized by Western blot and dot blot assays. Both the N-terminal domain (amino acids [aa] 2 to 351) and the C-terminal domain (aa 352 to 691) were able to bind hTf, and by a peptide spot synthesis approach, two and five hTf binding sites were identified in the N- and C-terminal domains, respectively. The hTf binding activity of three rTbpB deletion variants constructed within the central region (aa 346 to 543) highlighted the importance of a specific peptide (aa 377 to 394) in the ligand interaction. Taken together, the results indicated that the N- and C-terminal domains bound hTf approximately 10 and 1000 times less, respectively, than the full-length rTbpB (aa 2 to 691), while the central region (aa 346 to 543) had a binding avidity in the same order of magnitude as the C-terminal domain. In contrast with the hTf binding in the N-terminal domain, which was mediated by conformational epitopes, linear determinants seemed to be involved in the hTf binding in the C-terminal domain. The host specificity for transferrin appeared to be mediated by the N-terminal domain of the meningococcal rTbpB rather than the C-terminal domain, since we report that murine Tf binds to the C-terminal domain. Antisera raised to both N- and C-terminal domains were bactericidal for the parent strain, indicating that both domains are accessible at the bacterial surface. We have thus identified hTf binding sites within each domain of the TbpB from N. meningitidis and propose that the N- and C-terminal domains together contribute to the efficient binding of TbpB to hTf with their respective affinities and specificities for determinants of their ligand.     

Energy-dependent changes in the gonococcal transferrin receptor

The pathogenic Neisseria spp. are capable of iron utilization from host iron-binding proteins including transferrin and lactoferrin. Transferrin iron utilization is an energy-dependent, receptor-mediated event in which two identified transferrin-binding proteins participate. One of these proteins, TbpA, is homologous to the TonB-dependent family of outer membrane receptors that are required for high-affinity uptake of vitamin B₁₂ and ferric siderophores. The 'TonB box' is a conserved domain near the amino-terminus of these proteins that has been implicated in interaction with TonB. Interaction between a periplasmic domain of TonB and the TonB box allows energy transduction to occur from the cytoplasmic membrane to the energy-dependent receptor in the outer membrane. We created a TonB box mutant of gonococcal TbpA and demonstrated that its binding and protease accessibility characteristics were indistinguishable from those of gonococcal Ton system mutants. The protease exposure of the second transferrin-binding protein, TbpB, was affected by the energization of TbpA, consistent with an interaction between these proteins. TbpB expressed by the de-energized mutants was readily accessible to protease, similar to TbpB expressed in the absence of TbpA. The de-energized mutants exhibited a marked decrease in transferrin diffusion rate, suggesting that receptor energization was necessary for ligand release. We propose a model to explain the observed Ton-dependent changes in the binding parameters and exposures of TbpA and TbpB.     

Binding and surface exposure characteristics of the gonococcal transferrin receptor are dependent on both transferrin-binding proteins.

Neisseria gonorrhoeae is capable of iron utilization from human transferrin in a receptor-mediated event. Transferrin-binding protein 1 (Tbp1) and Tbp2 have been implicated in transferrin receptor function, but their specific roles in transferrin binding and transferrin iron utilization have not yet been defined. We utilized specific gonococcal mutants lacking Tbp1 or Tbp2 to assess the relative transferrin-binding properties of each protein independently of the other. The apparent affinities of the wild-type transferrin receptor and of Tbp1 and Tbp2 individually were much higher than previously estimated for the gonococcal receptor and similar to the estimates for the mammalian transferrin receptor. The binding parameters of both of the mutants were distinct from those of the parent, which expressed two transferrin-binding sites. Tbp2 discriminated between ferrated transferrin and apotransferrin, while Tbp1 did not. Results of transferrin-binding affinity purification, and protease accessibility experiments were consistent with the hypothesis that Tbp1 and Tbp2 interact in the wild-type strain, although both proteins were capable of binding to transferrin independently when separated in the mutants. The presence of Tbp1 partially protected Tbp2 from trypsin proteolysis, and Tbp2 also protected Tbp1 from trypsin exposure. Addition of transferrin to wild-type but not mutant cells protected Tbp1 from trypsin but increased the trypsin susceptibility of Tbp2. These observations indicate that Tbp1 and Tbp2 function together in the wild-type strain to evoke binding conformations that are distinct from those expressed by the mutants lacking either protein.     

A dynamic model of the meningococcal transferrin receptor.

Iron is an essential nutrient for all organisms and consequently, the ability to bind transferrin and sequester iron from his source constitutes a distinct advantage to a blood-borne bacterial pathogen. Levels of free iron are strictly limited in human serum, largely through the action of the iron-binding protein transferrin. The acquisition of trasferrin-iron is coincident with pathogenicity among Neisseria species and a limited number of other pathogens of human and veterinary significance. In Neisseria meningitidis, transferrin binding relies on two co-expressed, outer membrane proteins distinct in aspects of both structure and function. These proteins are independently and simultaneously capable of binding human transferrin and both are required for the optimal uptake of iron from this source. It has been established that transferrin-binding proteins (designated TbpA and TbpB) form a discrete, specific complex which may be composed of a transmembrane species (composed of the TbpA dimer) associated with a single surface-exposed lipoprotein (TbpB). This more exposed protein is capable of selectively binding iron-saturated transferrin and the receptor complex has ligand-binding properties which are distinct from either of its components. Previous in vivo analyses of N. gonorrhoeae, which utilizes a closely related transferrin-iron uptake system, indicated that this receptor exists in several conformations influenced in part by the presence (or absence) of transferrin.Here we propose a dynamic model of the meningococcal transferrin receptor which is fully consistent with the current data concerning this subject. We suggest that TbpB serves as the initial binding site for iron-saturated transferrin and brings this ligand close to the associated transmembrane dimer, enabling additional binding events and orientating transferrin over the dual TbpA pores. The antagonistic association of these receptor proteins with a single ligand molecule may also induce conformational change in transferrin, thereby favouring the release of iron. As, in vivo, transferrin may have iron in one or both lobes, this dynamic molecular arrangement would enable iron uptake from either iron-binding site. In addition, the predicted molecular dimensions of the putative TbpA dimer and hTf are fully consistent with these proposals. Given the diverse data used in the formulation of this model and the consistent characteristics of transferrin binding among several significant Gram-negative pathogens, we speculate that such receptor-ligand interactions may be, at least in part, conserved between species. Consequently, this model may be applicable to bacteria other than N. meningitidis.     

Delineating the regions of human transferrin involved in interactions with transferrin binding protein B from Neisseria meningitidis

Pathogenic bacteria in the Neisseriaceae possess a surface receptor mediating iron acquisition from human transferrin (hTf) that consists of a transmembrane iron transporter (TbpA) and a surface‐exposed lipoprotein (TbpB). In this study, we used hydrogen/deuterium exchange coupled to mass spectrometry (H/DX‐MS) to elucidate the effects on hTf by interaction with TbpB or derivatives of TbpB. An overall conserved interaction was observed between hTf and full‐length or N‐lobe TbpB from Neisseria meningitidis strains B16B6 or M982 that represent two distinct subtypes of TbpB. Changes were observed exclusively in the C‐lobe of hTf and were caused by the interaction with the N‐lobe of TbpB. Regions localized to the ‘lip’ of the C1 and C2 domains that flank the interdomain cleft represent sites of direct contact with TbpB whereas the peptides within the interdomain cleft that encompass iron binding ligands are inaccessible in the closed (holo) conformation. Although substantial domain separation upon binding TbpB cannot be excluded by the H/DX‐MS data, the preferred model of interaction involves binding hTf C‐lobe in the closed conformation. Alternate explanations are provided for the substantial protection from deuteration of the peptides encompassing iron binding ligands within the interdomain cleft but cannot be differentiated by the H/DX‐MS data.     

Anchor peptide of transferrin-binding protein B is required for interaction with transferrin-binding protein A

Gram-negative bacterial pathogens belonging to the Pasteurellaceae, Moraxellaceae, and Neisseriaceae families rely on an iron acquisition system that acquires iron directly from host transferrin (Tf). The process is mediated by a surface receptor composed of transferrin-binding proteins A and B (TbpA and TbpB). TbpA is an integral outer membrane protein that functions as a gated channel for the passage of iron into the periplasm. TbpB is a surface-exposed lipoprotein that facilitates the iron uptake process. In this study, we demonstrate that the region encompassing amino acids 7-40 of Actinobacillus pleuropneumoniae TbpB is required for forming a complex with TbpA and that the formation of the complex requires the presence of porcine Tf. These results are consistent with a model in which TbpB is responsible for the initial capture of iron-loaded Tf and subsequently interacts with TbpA through the anchor peptide. We propose that TonB binding to TbpA initiates the formation of the TbpB-TbpA complex and transfer of Tf to TbpA.     

Utilization of transferrin-bound iron by Listeria monocytogenes

Abstract It has been demonstrated that under iron-restricted conditions, Listeria monocytogenes can utilize iron-loaded transferrin (Tf) from a range of species as its sole source of iron for growth. Human transferrin conjugated to horseradish-peroxidase (HRP-Tf) bound directly to whole cells of L. monocytogenes . This binding was blocked by apotransferrin indicating that the receptor can bind transferrin in either the iron-bound or iron-free form. Transferrin-binding was not host specific because both bovine and equine transferrin inhibited the binding of HRP-conjugated human transferrin. SDS-PAGE and Western blotting of bacterial surface extracts revealed the presence of a transferrin-binding protein of approximately 126 kDa.     

Molecular characterization of LbpB, the second lactoferrin-binding protein of Neisseria meningitidis

The lbpA gene of Neisseria meningitidis encodes an outer membrane lactoferrin-binding protein and shows homology to the transferrin-binding protein, TbpA. Previously, we have detected part of an open reading frame upstream of lbpA . The putative product of this open reading frame, tentatively designated lbpB showed homology to the transferrin-binding protein TbpB, suggesting that the lactoferrrin receptor, like the transferrin receptor, consists of two proteins. The complete nucleotide sequence of lbpB was determined. The gene encodes a 77.5 kDa protein, probably a lipoprotein, with homology, 33% identity to the TbpB of N . meningitidis . A unique feature of LbpB is the presence of two stretches of negatively charged residues, which might be involved in lactoferrin binding. Antisera were raised against synthetic peptides corresponding to the C-terminal part of the putative protein and used to demonstrate that the gene is indeed expressed. Consistent with the presence of a putative Fur binding site upstream of the lbpB gene, expression of both LbpA and LbpB was proved to be iron regulated in Western blot experiments. The LbpB protein appeared to be less stable than TbpB in SDS-containing sample buffer. Isogenic mutants lacking either LbpA or LbpB exhibited a reduced ability to bind lactoferrin. In contrast to the lbpB mutant, the lbpA mutant was completely unable to use lactoferrin as a sole source of iron.     

Conserved interaction between transferrin and transferrin-binding proteins from porcine pathogens

Gram-negative porcine pathogens from the Pasteurellaceae family possess a surface receptor complex capable of acquiring iron from porcine transferrin (pTf). This receptor consists of transferrin-binding protein A (TbpA), a transmembrane iron transporter, and TbpB, a surface-exposed lipoprotein. Questions remain as to how the receptor complex engages pTf in such a way that iron is positioned for release, and whether divergent strains present distinct recognition sites on Tf. In this study, the TbpB-pTf interface was mapped using a combination of mass shift analysis and molecular docking simulations, localizing binding uniquely to the pTf C lobe for multiple divergent strains of Actinobacillus plueropneumoniae and suis. The interface was further characterized and validated with site-directed mutagenesis. Although targeting a common lobe, variants differ in preference for the two sublobes comprising the iron coordination site. Sublobes C1 and C2 participate in high affinity binding, but sublobe C1 contributes in a minor fashion to the overall affinity. Further, the TbpB-pTf complex does not release iron independent of other mediators, based on competitive iron binding studies. Together, our findings support a model whereby TbpB efficiently captures and presents iron-loaded pTf to other elements of the uptake pathway, even under low iron conditions.     

Transferrin-binding protein B of Neisseria meningitidis: sequence-based identification of the transferrin-Binding site confirmed by site-directed mutagenesis

A sequence-based prediction method was employed to identify three ligand-binding domains in transferrin-binding protein B (TbpB) of Neisseria meningitidis strain B16B6. Site-directed mutagenesis of residues located in these domains has led to the identification of two domains, amino acids 53 to 57 and 240 to 245, which are involved in binding to human transferrin (htf). These two domains are conserved in an alignment of different TbpB sequences from N. meningitidis and Neisseria gonorrhoeae, indicating a general functional role of the domains. Western blot analysis and BIAcore and isothermal titration calorimetry experiments demonstrated that site-directed mutations in both binding domains led to a decrease or abolition of htf binding. Analysis of mutated proteins by circular dichroism did not provide any evidence for structural alterations due to the amino acid replacements. The TbpB mutant R243N was devoid of any htf-binding activity, and antibodies elicited by the mutant showed strong bactericidal activity against the homologous strain, as well as against several heterologous tbpB isotype I strains.     

Reconstitution of a surface transferrin binding complex in insect form Trypanosoma brucei.

In the bloodstream of the mammalian host, Trypanosoma brucei takes up host transferrin by means of a high-affinity uptake system, presumably a transferrin receptor. Transferrin-binding activity is seen in the flagellar pocket and is absent in insect form trypanosomes. By transfection we have reconstituted a transferrin-binding complex in insect form trypanosomes. Formation of this complex requires the products of two genes that are part of a variant surface glycoprotein expression site, expression site-associated gene (ESAG) 6 (encoding a protein with GPI-anchor) and ESAG 7 (encoding a protein without any obvious membrane attachment). This complex can be precipitated by transferrin-Sepharose and by an antibody directed only against the ESAG 6 protein. Transfection of ESAG 6 or 7 alone did not result in transferrin binding. In the transfected trypanosomes, the products of ESAG 6 alone and the combination of ESAG 6 and 7 did not exclusively localize to the flagellar pocket, but were present all over the surface of the trypanosome. The reconstituted transferrin-binding complex also did not result in the uptake of transferrin. Additional proteins present in bloodstream trypanosomes, but not in sufficient amounts in insect form trypanosomes, may therefore be required for the correct routing of the transferrin-binding complex to the flagellar pocket, and for its rapid internalization after ligand binding.     

Insight into the structure and function of the transferrin receptor from Neisseria meningitidis using microcalorimetric techniques

The transferrin receptor of Neisseria meningitidis is composed of the transmembrane protein TbpA and the outer membrane protein TbpB. Both receptor proteins have the capacity to independently bind their ligand human transferrin (htf). To elucidate the specific role of these proteins in receptor function, isothermal titration calorimetry was used to study the interaction between purified TbpA, TbpB or the entire receptor (TbpA + TbpB) with holo- and apo-htf. The entire receptor was shown to contain a single high affinity htf-binding site on TbpA and approximately two lower affinity binding sites on TbpB. The binding sites appear to be independent. Purified TbpA was shown to have strong ligand preference for apo-htf, whereas TbpA in the receptor complex with TbpB preferentially binds the holo form of htf. The orientation of the ligand specificity of TbpA toward holo-htf is proposed to be the physiological function of TbpB. Furthermore, the thermodynamic mode of htf binding by TbpB of isotypes I and II was shown to be different. A protocol for the generation of active, histidine-tagged TbpB as well as its individual N- and C-terminal domains is presented. Both domains are shown to strongly interact with each other, and isothermal titration calorimetry and circular dichroism experiments provide clear evidence for this interaction causing conformational changes. The N-terminal domain of TbpB was shown to be the site of htf binding, whereas the C-terminal domain is not involved in binding. Furthermore, the interactions between TbpA and the different domains of TbpB have been demonstrated.     

Iron piracy: acquisition of transferrin-bound iron by bacterial pathogens

The mechanism of iron utilization from transferrin has been most extensively characterized in the pathogenic Neisseria species and Haemophilus species. Two transferrin-binding proteins, Tbp1 and Tbp2, have been identified in these pathogens and are thought to be components of the transferrin receptor. Tbp1 appears to be an integral, TonB-dependent outer membrane protein while Tbp2, a lipoprotein, may be peripherally associated with the outer membrane. The relative contribution of each of these proteins to transferrin binding and utilization is discussed and a model of iron uptake from transferrin is presented. Sequence comparisons of the genes encoding neisserial transferrin-binding proteins suggest that they are probably under positive selection for variation and may have resulted from inter-species genetic exchange.     

cDNA cloning of the murine transferrin receptor: sequence of trans-membrane and adjacent regions

We previously purified the murine transferrin receptor from cultured myeloma cells and determined the amino acid sequence of six tryptic peptides. We now report the cloning of cDNA encoding the murine transferrin receptor. A tryptic peptide containing a region of six consecutive amino acids, all encoded by four or fewer codons, was used to design two overlapping oligonucleotide probes, 17 and 14 nucleotides in length. These probes were used to screen a lambda gt10 cDNA library from NS-1 myeloma cells. Of approximately 400,000 plaques screened, two hybridized strongly to both probes. A subfragment of one clone that hybridized with both oligonucleotide probes was found to encode the tryptic peptide from which the probes were derived, as well as another sequenced tryptic peptide. Comparison of the sequence with that of the human transferrin receptor shows a high degree of conservation of the sequences surrounding and penetrating the membrane, including cysteine residues that may be involved in interchain disulfide bonding and/or covalent attachment of lipid. The current data, when combined with the published sequence of the human receptor, allow assignment of all six tryptic peptides to a single chain, supporting the idea that the receptor is a homodimer. A 4.9-kb messenger RNA was found in several cultured murine and human tumor cell lines, but transferrin receptor messenger RNA was not detectable in murine spleen. An additional RNA species of 2.7 kb was present in approximately equal abundance in the murine myelomas NS-1 and C118 but was absent from T lymphomas TIKAUT, ST-1, and ST-4.     

The region of human transferrin involved in binding to bacterial transferrin receptors is iocalized in the C-lobe

Iron-saturated human transferrin was digested with either chymotrypsin or trypsin to produce C-lobe and N-lobe protein fragments. Individual protein fragments were purified by a combination of gel filtration and Concanavalin A affinity chromatographic procedures. The C-lobe and N-lobe fragments of human transferrin were then used in binding assays to assess their ability in binding to the bacterial transferrin receptors. Competitive binding assays demonstrated that the C-lobe fragment of human transferrin binds as well as intact human transferrin to bacterial transterrin receptors from Neisseria meningitidis, Neisseria gonorrhoeae and Haemophlius influenzae. Using isogenic mutants of N. meningitidis deficient in either of the transferrin-binding proteins (Tbps), we demonstrated that both transferrin-binding proteins were able to bind to the C-lobe fragment of human transferrin.     

Affinity-purification of Transferrin-binding protein B under nondenaturing conditions

The commonly used purification procedures for Transferrin-binding protein B (TbpB) are based on an affinity chromatography step using resins onto which human transferrin had been immobilized. These protocols involve protein elution using denaturing buffer solutions. Here we present an improved protocol which permits protein elution under nondenaturing conditions using chelating agents such as phosphate or compounds containing a pyrophosphate group. Furthermore, isothermal titration calorimetry experiments of the purified protein with holotransferrin have been shown to be a reliable method to assess the purity and activity of the purified material.     

Comparative analysis of the transferrin and lactoferrin binding proteins in the family Neisseriaceae

Intact cells of several bacterial species were tested for their ability to bind human transferrin and lactoferrin by a solid-phase binding assay using horseradish peroxidase conjugated transferrin and lactoferrin. The ability to bind lactoferrin was detected in all isolates of Neisseria and Branhamella catarrhalis but not in isolates of Escherichia coli or Pseudomonas aeruginosa. Transferrin-binding activity was similarly detected in most isolates of Neisseria and Branhamella but not in E. coli or P. aeruginosa. The expression of transferrin- and lactoferrin-binding activity was induced by addition of ethylenediamine di-o-phenylacetic acid and reversed by excess FeCl3, indicating regulation by the level of available iron in the medium. The transferrin receptor was specific for human transferrin and the lactoferrin receptor had a high degree of specificity for human lactoferrin in all species tested. The transferrin- and lactoferrin-binding proteins were identified after affinity isolation using biotinylated human transferrin or lactoferrin and streptavidin-agarose. The lactoferrin-binding protein was identified as a 105-kilodalton protein in all species tested. Affinity isolation with biotinylated transferrin yielded two or more proteins in all species tested. A high molecular mass protein was observed in all isolates, and was of similar size (approximately 98 kilodaltons) in all species of Neisseria but was larger (105 kilodaltons) in B. catarrhalis.