INTRODUCTION

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Pathogenic and commensal bacteria alike obtain iron from human and animal hosts by competing for the metal with eucaryotic proteins, like transferrin, lactoferrin, and ferritin (11, 25, 49, 54). In the wild, the low solubility of iron in aqueous, aerobic conditions further complicates its acquisition: the concentration of available Fe³⁺ at neutrality is 10¹⁸ M (34), whereas bacteria require a minimum of 10⁸ M for growth and 10⁶ M for iron sufficiency (24). A wide variety of microbes synthesize specialized, low-molecular-mass (500 to 1,000 Da) organic chelators called siderophores (5, 16, 17, 18, 33, 37, 38, 40, 41, 46, 52, 66) that solve these problems. Siderophores (32) liberate iron from the sequestering proteins of eucaryotic hosts or solubilize it from precipitates of ferric oxyhydroxide, rendering the metal available for microbial consumption.

Enterobactin, the native siderophore of Escherichia coli and the most avid microbial iron chelator (K_a = 10⁵² [10]) contains three dihydroxybenzoyl serine groups linked in a macrocyclic lactone ring (Fig. 1). Its three identical catechol groups chelate Fe³⁺ in a -cis complex, creating a hexadentate iron center with a net charge of 3. Several species of Enterobacteriaceae, including E. coli (37, 46), Salmonella typhimurium, (42) and Klebsiella pneumoniae (40), produce enterobactin in response to iron stress. Many pathogenic bacteria that do not make enterobactin produce membrane transport systems that recognize and transport ferric enterobactin (FeEnt) (48), so the determinants of siderophore uptake may influence the pathogenicity of enteric bacteria.

View larger version (15K): [in this window] [in a new window]   FIG. 1.   Structures of natural and synthetic catecholate siderophores. (A) Enterobactin; (B) TRENCAM; (C) agrobactin A; (D) TRENCAM-3,2-HOPO; (E) TREN-Me-3,2-HOPO; (F) MeME-Me-3,2-HOPO; (G) K3MECAMS; (H) MeMEEtTAM.

FeEnt binds to FepA, an 81-kDa outer membrane protein that also serves as a receptor for two protein toxins, colicins B and D (19, 28, 39, 44, 62, 69). All three ligands interact with two arginine residues within proposed loop 5 (36) in the central region of FepA. FeEnt transport across the outer membrane requires energy and the participation of TonB (19, 58-60); a complex of proteins (9, 13, 51) mediates uptake through the inner membrane.

Synthetic analogs that mimic enterobactin but change certain aspects of its chemistry were previously used to determine the structural features of the siderophore that are important to its transport. For example, the catechol groups of FeEnt form a right-handed propeller around iron, and experiments with its left-handed analog showed the importance of this chirality: ferric enantioenterobactin (FeEnEnt), the mirror image of the natural siderophore, does not provide iron to E. coli (35). Studies of other analogs with modifications to either the chelating groups or the organic platform from which they arise showed that the iron center contains the primary determinants of the uptake reaction. Replacement of the natural macrocyclic ring had little effect on FeEnt transport (15, 21).

We further analyzed the siderophore transport process by determining the principal features of ferric enterobactin that affect its binding to FepA. Experiments with synthetic siderophores and the natural compound agrobactin A reaffirmed the importance of the iron center in binding: high-affinity adsorption of ferric siderophores to FepA required unadulterated catechol moieties around the central iron atom. Unexpectedly, the chirality of the iron complex did not affect the receptor-ligand interaction: FeEnEnt bound to FepA with affinity comparable to that of FeEnt, indicating that the recognition reaction is not stereospecific. We also studied the biochemical properties of FepA homologs of Bordetella, Pseudomonas, and Salmonella species with regard to FeEnt binding and transport. Although the affinities of the various proteins for the siderophore were comparable, we found differences in their transport rates, especially when they were all expressed and compared in E. coli.

	MATERIALS AND METHODS

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Bacterial strains and plasmids. Bacterial strains, plasmids, and sources are listed in Table 1.

Siderophore preparation. Enterobactin was purified from E. coli AN102 (24). Iron complexes of enterobactin and its analogs (Fig. 1) were formed by mixing equimolar amounts of the siderophores and FeCl₃ dissolved in 0.45 ml of methanol and 0.45 ml of 0.001 M HCl, respectively. For radioisotope studies, 0.05 mCi of ⁵⁹FeCl₃ (Amersham) was added to the FeCl₃ solution. The ferric siderophore solution was incubated for 1 to 2 h at room temperature, 100 µl of 0.5 M sodium phosphate was added, and the iron complexes were chromatographically purified on Sephadex LH20 (61). The concentrations of ferric complexes of enterobactin and its analogs were spectrophotometrically determined by using their millimolar extinction coefficients: enterobactin (42), ₄₉₅ = 5.6; K₃MECAMS (64), ₄₈₈ = 0.81; TRENCAM (67), ₄₈₆ = 4.27; TRENCAM-3,2-HOPO (68), ₅₃₈ = 3.1; TREN-Me-3,2-HOPO (67), ₅₃₀ = 3.6; MeME-Me-3,2-HOPO (68), ₅₄₈ = 3.78; MeMEEtTAM (68), ₅₂₄ = 3.2; agrobactin A (38), ₅₁₃ = 3.5.

Siderophore binding and transport experiments. Bacteria harboring fepA⁺ or mutant fepA alleles on pUC plasmids were grown overnight in Luria-Bertani broth (29) containing ampicillin (100 µg/ml), subcultured into MOPS (morpholinepropanesulfonic acid) minimal medium (31) with ampicillin (10 µg/ml), and grown for 5.5 h at 37°C. In some experiments, enterobactin was added to the culture medium at 2 µM. For binding studies, six 10-ml aliquots were collected and incubated on ice for 1 h, and ⁵⁹Fe siderophore at six different concentrations was added (36). One and 6 min after addition of the siderophore, 5-ml aliquots were collected and filtered through glass fiber filters that then were washed with 10 ml of 0.9% LiCl and counted. Transport experiments (15, 48, 36) were performed quantitatively in MOPS medium and qualitatively as siderophore nutrition assays (62). Binding and transport data were analyzed and plotted using Grafit (versions 3 and 4; Erithacus Software Ltd., Middlesex, England).

Outer membranes and gel electrophoresis. A total of 10¹⁰ cells were resuspended in 10 ml of Tris-buffered saline (TBS) with trace amounts of DNase and RNase and lysed by passage through a French pressure cell at 14,000 lb/in². Unbroken cells were removed by centrifugation at 3,000 × g for 15 min, and the supernatant containing the inner and the outer membranes was collected by centrifugation at 100,000 × g for 1 h. The pellet was resuspended in 1 ml of TBS containing 0.5% sodium sarcosinate and incubated for 30 min at room temperature (48). The extract was spun for 45 min at 20,000 × g, and the pellet containing the outer membranes was resuspended in sample buffer, boiled for 5 min, briefly centrifuged to remove insoluble material, and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) (1, 20).

Western blot analysis. Outer membrane proteins separated on polyacrylamide gels were transferred to nitrocellulose membranes by electrophoresis at 10 V overnight (55). The nitrocellulose was blocked with 1% gelatin, incubated with anti-FepA monoclonal antibodies 2, 27, and 45 (30) followed by goat anti-mouse immunoglobulin G-alkaline phosphatase, and developed with a mixture of nitroblue tetrazolium-bromochloroindolyl phosphate (7).

	RESULTS

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Binding and transport of FeEnt analogs. We measured the binding equilibria between enterobactin analogs (Fig. 1) and E. coli FepA by using strain BN1071 (entA) and its derivative KDF541 (entA fepA cir). FeEnEnt, the  analog of natural  FeEnt, bound to FepA with high affinity (K_d = 21 nM) (Table 2). This result was unexpected because it was previously reported (35), and we confirmed, that FeEnEnt does not promote siderophore nutrition activity for E. coli (Table 2). Similarly, FeTRENCAM, a synthetic analog that mainly differs from enterobactin in the substitution of a tertiary amine for the macrocyclic ester ring of the natural product (Fig. 1), avidly bound to FepA (Fig. 2). The FeTRENCAM-FepA interaction had a K_d of 27 nM, experimentally indistinguishable from that of the FeEnt-FepA interaction (17 nM). However, FeTRENCAM adsorbed to FepA at only one-third the capacity of the native E. coli siderophore. In siderophore nutrition tests, FeTRENCAM did not supply iron to KDF541, but did feed BN1071 and KDF541/pITS449. The growth halo it induced was slightly smaller (15 mm) and noticeably fainter than that generated by FeEnt (18 mm). Quantitative transport assays revealed a K_m for FeTRENCAM (Fig. 2) uptake of 0.37 µM, again experimentally indistinguishable from that of FeEnt (K_m = 0.41 µM). The V_max of FeTRENCAM transport was about half that of FeEnt, consistent with the lower binding capacity for the synthetic siderophore and the faint halos it generated in siderophore nutrition assays.

View larger version (13K): [in this window] [in a new window]   FIG. 2.   Binding (A) and transport (B) of FeEnt (), FeEnEnt (), and FeTRENCAM () by E. coli BN1071. Bacteria were cultured in iron-deficient MOPS medium and exposed to 59Fe siderophores at the indicated concentrations.

FeEnt binding and transport by Salmonella, Pseudomonas, and Bordetella. We compared the outer membrane FeEnt transporters of E. coli (EcoFepA), S. typhimurium (StyFepA, StyIroN), Pseudomonas aeruginosa (PaeFepA), Bordetella bronchisepticus (BbrFepA), and Bordetella pertussis (BpeFepA) with regard to ⁵⁹FeEnt binding and uptake (Table 2). As an initial experiment, we tested four of the bacterial species in vivo in iron-deficient MOPS medium. Under these conditions, E. coli and S. typhimurium bound the siderophore with high affinity (K_d < 50 nM). These two strains transported FeEnt at about the same rate, 100 pmol/min/10⁹ cells. In iron-deficient media, P. aeruginosa did not bind or transport FeEnt, while B. bronchisepticus adsorbed and transported it at very low levels. Neither of the latter two strains synthesizes enterobactin, and therefore they do not normally express their FeEnt transport systems at readily detectable levels, even when subjected to iron stress. However, if they were cultured beforehand with enterobactin, then the binding capabilities of Pseudomonas and Bordetella were similar to those of the Enterobacteriaceae (Fig. 3) (Table 2). When induced in this manner, P. aeruginosa and B. bronchisepticus showed a maximal rate of FeEnt uptake of about half that of E. coli and Salmonella, commensurate with the variations in FepA expression seen in immunoblots (Fig. 4) and inferred from FeEnt binding capacities (Table 2). Precise measurements at concentrations near the transport K_m produced sigmoidal (allosteric) uptake curves for E. coli (Fig. 3), S. typhimurium, and P. aeruginosa (data not shown); these data did not fit a hyperbolic (Michaelis-Menten) function. Kinetic analyses of B. bronchisepticus transport data were inconclusive in this respect.

View larger version (33K): [in this window] [in a new window]   FIG. 3.   Binding and transport of FeEnt by FepA homologs. The concentration dependence of FeEnt binding (A) and transport (C) was measured for chromosomally expressed FepA of E. coli () and S. typhimurium () grown in MOPS medium, and P. aeruginosa () and B. bronchisepticus () cultured in MOPS medium with enterobactin (2 µM). Binding (B) and transport (D) of FeEnt was also measured for the individual proteins EcoFepA (), StyFepA (), StyIroN (), PaeFepA (), and BpeFepA (), expressed from plasmids in E. coli. Insets show transport of FeEnt by E. coli FepA at concentrations near the Km. The plotted data represent mean values (with standard deviations) normalized to Vmax from seven experiments. These curves gave Hill coefficients of 2.98 and 3.19 for chromosome- and plasmid-expressed FepA, respectively, with standard errors less than 5%.

View larger version (108K): [in this window] [in a new window]   FIG. 4.   Chromosome- and plasmid-expression of FepA and its homologs. Outer membranes were prepared by Sarkosyl extraction of cell envelopes from bacteria grown in MOPS minimal medium, subjected to SDS-PAGE, and either stained with Coomassie blue (B) or transferred to nitrocellulose and stained with anti-FepA monoclonal antibodies 2, 27, 45, (30), goat anti-mouse immunoglobulin-alkaline phosphatase, and nitroblue tetrazolium-bromochloroindolyl phosphate (7) (A). E. coli KDF541 (lane 1) and BN1071 (lane 2), S. typhimurium Enb7 (lane 3), P. aeruginosa K407 (lane 4) and K201 (lane 5), and B. bronchisepticus 19387 (lane 7) and 19385 (lane 8) were cultured in iron-deficient MOPS medium. Strains K201 and 19385 were also grown in MOPS medium containing enterobactin (2 µM; lanes 6 and 9, respectively). Outer membranes from KDF541, grown in MOPS medium and harboring either pITS449 (EcoFepA; lane 10), pENB5 (StyFepA; lane 11), pTY994 (StyIroN; lane 12), pKP1 (BpeFepA; lane 13), or pCD3 (PaeFepA; lane 14) were also analyzed. Immunoreactive bands in the immunoblot correspond to the indicated stained bands in the SDS-PAGE gel.

FeEnt binding by Salmonella, Pseudomonas, and Bordetella FepA proteins, expressed in E. coli. The differences in the outer membranes of the species under study suggested that expression of all the FeEnt transporters in a common background might provide a more stringent test of the effects of sequence variation on functionality. Thus, we expressed cloned BpeFepA, PaeFepA, StyFepA, StyIroN, and EcoFepA in KDF541. SDS-PAGE and Western immunoblots with crossreactive anti-(E. coli)FepA monoclonal antibodies verified expression of the five proteins (Fig. 4): each foreign gene directed the synthesis of an immunoreactive, approximately 80-kDa outer membrane protein, albeit weakly in the case of BpeFepA.

FeEnt uptake by Salmonella, Pseudomonas, and Bordetella FepA proteins, expressed in E. coli. Uptake assays in E. coli confirmed the differences seen in binding assays of the five FeEnt transporters, with several nuances and exceptions. First, in spite of their avid binding, StyFepA and StyIroN did not efficiently transport FeEnt. Standard uptake assays failed to detect any transport of ⁵⁹FeEnt by StyFepA and detected only a small amount of transport by StyIroN. However, StyFepA in KDF541 consistently produced positive siderophore nutrition assays (Fig. 5; Table 2), which led us to reevaluate the transport assay conditions. An increase in the uptake period from 5 to 60 min revealed the transport reaction (Fig. 6) (V_max = 14 pmol/min/10⁹ cells). StyIroN showed about the same rate in both conditions (V_max = 10 to 20 pmol/min/10⁹ cells), considerably slower than transport through E. coli FepA (V_max = 46 pmol/min/10⁹ cells). Thus in E. coli, both Salmonella outer membrane proteins recognized FeEnt but transported it with reduced efficiency, about one-fifth the maximum rate observed for the native strain.

View larger version (98K): [in this window] [in a new window]   FIG. 5.   Siderophore nutrition tests. KDF541 (A) grown in Luria-Bertani broth and harboring plasmids pITS449 (EcoFepA) (C), pENB5 (StyFepA) (D), pTY994 (StyIroN) (E), or pCD3 (PaeFepA) (F) was plated in nutrient agar containing ampicillin (10 µg/ml), and 10 µl of 50 µM FeEnt was applied to a sterile paper disc on the agar surface. BN1071 (chromosomal EcoFepA) (B) was tested under the same conditions. A 1-cm ruler was embedded in the photograph.

View larger version (21K): [in this window] [in a new window]   FIG. 6.   Transport of FeEnt by Salmonella proteins expressed in E. coli. Uptake of 59FeEnt by EcoFepA (), StyFepA (), and StyIroN () was compared by two procedures, 5-min assays (filled symbols) and 60-min assays (open symbols).

	DISCUSSION

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Recognition of FeEnt by FepA involves noncovalent bonds between atoms of the iron chelate and surface-exposed residues of the outer membrane protein. Binding reactions between analogs of FeEnt and E. coli FepA, or between FeEnt and homologs of FepA from other bacteria, may identify the critical aspects of ligand-receptor specificity. Our results from such experiments lead to the following three conclusions about the FeEnt-FepA binding reaction: (i) it is not stereospecific; (ii) it is intolerant of modifications to the catechol groups surrounding the metal; and (iii) its affinity is relatively invariant among diverse bacterial species.

Siderophore nutrition by the -cis-FeEnt complex is stereospecific in E. coli (35, 45, Table 2), but preference for right-handed chirality does not originate at the stage of binding between the ferric siderophore and FepA. -cis-FeEnEnt bound to FepA with equivalent affinity and capacity, showing that the chiral specificity resides in a subsequent stage of the uptake process, likely after transport through FepA (36a). The preference for  chirality was not absolute: although ⁵⁹Fe-EnEnt transport was not observed, a very faint halo developed around the  iron complex in siderophore nutrition assays after an extended incubation period (36 h).

FepA recognizes the iron center of FeEnt, three catechol groups complexed to Fe⁺⁺⁺, in the initial step of transport through the outer membrane. The efficacy of MECAM in supplying iron to E. coli initially demonstrated the importance of the metal center (15, 21), and the similar ability of TRENCAM underscores this conclusion: both compounds replace the macrocyclic ester ring of FeEnt without changing its catecholate coordination complex and both are recognized and transported by FepA. Experiments that measured the affinity of the cell surface ligand binding reaction confirmed the importance of unsubstituted catecholate moieties around iron in FeEnt. FeTRENCAM bound to FepA with equal affinity and specificity, while analogs that introduced any other substituents on the rings did not bind to FepA. Although these results suggest that the size and shape of the iron center are crucial to the binding reaction, charge, which was implicated by another approach (36), may also play a role in the failure of the synthetic iron chelates to bind. In most of the compounds that did not specifically adsorb, the net charge of the iron center was different.

Nevertheless, the failure of FeAgroA to bind or to supply iron confirms the importance of the shape of the iron center in recognition by the receptor. Like FeEnt, FeAgroA is negatively charged (2.5 [34]) and contains three catechol groups in a right-handed complex. However, one of these, which provides only a single ligand to iron, projects off the iron center and distorts its size and symmetry (34). Its spermidine backbone also distinguishes FeAgroA, but MECAM and TRENCAM established the relative unimportance of this part of the siderophore in binding, intimating that the different shape of the FeAgroA iron center prevents its adsorption to FepA. The face of the FeEnt iron complex is relatively flat (23), and this feature may be requisite for binding. The lack of siderophore nutrition by FeAgroA concurs with the results of Ong et al. (38), who reported that iron complexes of agrobactin and agrobactin A at concentrations as high as 50 µM did not promote the growth of E. coli.

The different binding capacities of FeEnt and FeTRENCAM must stem from structural variations in the two siderophores that center on the presence of a tertiary amine in the synthetic siderophore. This basic group carries a positive charge at neutrality, while the macrocyclic ring of FeEnt is uncharged. Thus the reduced capacity of FepA for FeTRENCAM may derive from an ionic interaction that reduces its saturation level threefold. One explanation of these data is that, like all the structurally characterized porins (12, 26, 50, 63), FepA exists in vivo as a trimer that accommodates three molecules of FeEnt but only a single molecule of FeTRENCAM. The receptor protein binds the iron center of FeTRENCAM and, although the positive charge on the back of the molecule did not affect the affinity of its adsorption, it may create a charge repulsion barrier that prevents subsequent adsorption of another positively charged chelate, thus reducing binding capacity. An analytical comparison of FeEnt and colicins binding to FepA (39) showed similar results: colicin D bound to FepA at one-third the capacity of colicin B and FeEnt. Furthermore, nondenaturing SDS-PAGE revealed a high-molecular-weight oligomer of FepA with the mass of a trimer (27). Although another ligand-gated porin, the ferrichrome receptor, was purified in monomeric form (8), several independent lines of evidence now support the trimeric structure of FepA in vivo. Relevant to this point, our transport data demonstrate, for the first time, sigmoidal uptake kinetics for FeEnt. When analyzed as allosteric reactions, the transport data yielded Hill coefficients of approximately 3, consistent with a native FepA protein that contains three interacting, cooperative binding sites. These may be equivalent sites on the monomers of a trimer, or three distinct sites on a monomeric protein. In either case, our data indicate that multiple binding sites within FepA function allosterically during FeEnt transport.

The comparable affinities of the five gram-negative bacterial outer membrane transport proteins for FeEnt was unexpected. Against a background of broad overall genetic diversity, the four species manifested a remarkable preservation of avidity for FeEnt. While the structural genes, regulatory systems, and transport components of these organisms adapted to their individual biological needs, the specificity of their outer membrane receptors persevered essentially unchanged. The overall variation in the proteins themselves, from E. coli to B. pertussis, is dramatic, and yet the surface that accepts FeEnt remains relatively unaltered: only a 10-fold drop in affinity occurred in the most distant FepA homolog, B. pertussis. The evolution of bacterial outer membrane proteins occurs most rapidly in their surface loops (22, 48), and the FeEnt binding site illustrates conservation of a functional domain within an overall framework of high sequence variability.

The retention of a FeEnt transport system in Pseudomonas and Bordetella, with modifications of its regulation, illustrates the importance of iron acquisition in bacterial pathogenesis. In both of these disease-causing organisms, the regulatory system has changed from negative and repressible to positive and inducible. That is, the presence of enterobactin induces synthesis of the receptor for its ferric complex, an advantageous strategy for organisms that infect tissues cohabited by enterobactin-secreting bacteria. Transport of FeEnt into P. aeruginosa and B. bronchisepticus occurred at rates similar to those of the enterobactin producers S. typhimurium and E. coli, about 50 pmol/min/10⁹ cells. Although prior work with a Salmonella model system questioned the relationship between FeEnt-mediated iron acquisition and bacterial pathogenesis (6), an overwhelming amount of data now links iron and virulence. The connection appears in studies of Neisseria (Tbp1/transferrin [11]), Vibrio (IrgA [53]), Yersinia (Psn/yersiniabactin [5]), and Escherichia and Salmonella (IutA/aerobactin [65]; TonB [56]) species. In the context of these examples relating iron to infection, the inducible FeEnt transport systems of Bordetella and Pseudomonas emphasize the value of siderophores to bacteria: FeEnt is such a ubiquitous and potent iron complex that these pathogenic bacteria have evolved to steal it from their competitors.

Although plasmid effects are a potential explanation for the poor function of foreign proteins in E. coli, the reduced efficacy of the Salmonella FeEnt transporters StyFepA and StyIroN did not derive from poor expression or targeting to the E. coli outer membrane. Both Salmonella proteins bound FeEnt with high affinity, providing evidence of properly folded, biologically active conformations. The likely explanation for their inferiority is that additional components of the FeEnt uptake systems of Salmonella and Escherichia are sufficiently different to impair the transport reaction. On the other hand, E. coli FepA itself manifested a lower transport rate when expressed from pUC. The multicopy plasmid effected a two- to threefold higher expression level expression than the chromosomal system, but the increase did not cause a higher rate of FeEnt uptake. In both cases we observed an overall rate of 100 pmol/min/10⁹ cells, which translates to a monomer transport rate for chromosomally produced FepA of 1 mol/20 s and for plasmid-expressed FepA of 1 mol/min. These calculations suggest that the higher expression levels encoded by the plasmid exceeded the overall capabilities of the transport complex. The deficiencies in the plasmid system may ensue from inadequate amounts of one or more of the other required components of the cell envelope, including FepB, TonB, or another as-yet-unidentified molecule. At present, however, we cannot fully explain the lower activity of the plasmid-based FepA proteins.