High-affinity binding by the periplasmic iron-binding protein from Haemophilus influenzae is required for acquiring iron from transferrin.

The periplasmic iron-binding protein, FbpA (ferric-ion-binding protein A), performs an essential role in iron acquisition from transferrin in Haemophilus influenzae. A series of site-directed mutants in the metal-binding amino acids of FbpA were prepared to determine their relative contribution to iron binding and transport. Structural studies demonstrated that the mutant proteins crystallized in an open conformation with the iron atom associated with the C-terminal domain. The iron-binding properties of the mutant proteins were assessed by several assays, including a novel competitive iron-binding assay. The relative ability of the proteins to compete for iron was pH dependent, with a rank order at pH 6.5 of wild-type, Q58L, H9Q>H9A, E57A>Y195A, Y196A. The genes encoding the mutant FbpA were introduced into H. influenzae and the resulting strains varied in the level of ferric citrate required to support growth on iron-limited medium, suggesting a rank order for metal-binding affinities under physiological conditions comparable with the competitive binding assay at pH 6.5 (wild-type=Q58L>H9Q>H9A, E57A>Y195A, Y196A). Growth dependence on human transferrin was only obtained with cells expressing wild-type, Q58L or H9Q FbpAs, proteins with stability constants derived from the competition assay >2.0x10(18) M(-1). These results suggest that a relatively high affinity of iron binding by FbpA is required for removal of iron from transferrin and its transport across the outer membrane.

The role of the synergistic phosphate anion in iron transport by the periplasmic iron-binding protein from Haemophilus influenzae.

The acquisition of iron from transferrin by Gram-negative bacterial pathogens is dependent on a periplasmic ferric-ion-binding protein, FbpA. FbpA shuttles iron from the outer membrane to an inner membrane transport complex. A bound phosphate anion completes the iron co-ordination shell of FbpA and kinetic studies demonstrate that the anion plays a critical role in iron binding and release in vitro. The present study was initiated to directly address the hypothesis that the synergistic anion is required for transport of iron in intact cells. A series of site-directed mutants in the anion-binding amino acids of the Haemophilus influenzae FbpA (Gln-58, Asn-175 and Asn-193) were prepared to provide proteins defective in binding of the phosphate anion. Crystal structures of various mutants have revealed that alteration of the C-terminal domain ligands (Asn-175 or Asn-193) but not the N-terminal domain ligand (Gln-58) abrogated binding of the phosphate anion. The mutant proteins were introduced into H. influenzae to evaluate their ability to mediate iron transport. All of the single site-directed mutants (Q58L, N175L and N193L) were capable of mediating iron acquisition from transferrin and from limiting concentrations of ferric citrate. The results suggest that the transport of iron by FbpA is not dependent on binding of phosphate in the synergistic anion-binding site.

Lactoferrin receptors in gram-negative bacteria: insights into the iron acquisition process.

One component of the anti-microbial function of lactoferrin (Lf) is its ability to sequester iron from potential pathogens. To overcome this iron limitation, a number of gram-negative bacterial pathogens have developed a mechanism for acquiring iron directly from this host glycoprotein. This mechanism involves surface receptors capable of specifically binding Lf from the host, removing iron and transporting it across the outer membrane. The iron is then bound by a periplasmic iron-binding protein, FbpA, and transported into the cell via an inner membrane complex comprised of FbpB and FbpC. The receptor has been shown to consist of two proteins, LbpA and LbpB. LbpB is bilobed lipoprotein anchored to the outer membrane via fatty acyl groups attached to the N-terminal cysteine. LbpA is a homologue of siderophore receptors, which consist of an N-terminal plug and a C-terminal beta-barrel region. We propose that the receptor proteins, LbpA and LbpB, induce conformational changes in human Lf (hLf) that lower its affinity for iron that binding by FbpA can drive the transport across the outer membrane, a mechanism shared with transferrin (Tf) receptors. The interaction between the receptor proteins and Lf is quite extensive and has been previously studied by using chimeric proteins comprised of Lf & Tf. In an attempt to evaluate the role of FbpA in the transport process, a series of site-directed mutants of FbpA were prepared and used to replace the wild-type protein in the iron acquisition pathway. The mutations were made in the iron-binding and anion-binding ligands of FbpA and were designed to result in altered binding properties. Protein crystallography of the iron-bound form of the Q58L mutant protein revealed that it was in the open conformation with iron coordinated by Y195 and Y196 from the C-terminal domain but not by the other iron-liganding amino acids from the N-terminal domain, H9 and E57. Replacement of the native FbpA in Neisseria meningitidis with wild-type or mutant Haemophilus influenzae FbpAs resulted in a defect in growth on Tf or Lf, suggesting that there may be a barrier to functional expression of H. influenzae FbpAs in Neisseria meningitidis. Thus mutants of the N. meningitidis FbpA are being prepared to replace wild-type protein in order to test their ability to mediate transport from hLf.