Deletion of the proline-rich region of TonB disrupts formation of a 2:1 complex with FhuA, an outer membrane receptor of Escherichia coli

TonB protein of Escherichia coli couples the electrochemical potential of the cytoplasmic membrane (CM) to active transport of iron-siderophores and vitamin B(12) across the outer membrane (OM). TonB interacts with OM receptors and transduces conformationally stored energy. Energy for transport is provided by the proton motive force through ExbB and ExbD, which form a ternary complex with TonB in the CM. TonB contains three distinct domains: an N-terminal signal/anchor sequence, a C-terminal domain, and a proline-rich region. The proline-rich region was proposed to extend TonB's structure across the periplasm, allowing it to contact spatially distant OM receptors. Having previously identified a 2:1 stoichiometry for the complex of full-length (FL) TonB and the OM receptor FhuA, we now demonstrate that deletion of the proline-rich region of TonB (TonBDelta66-100) prevents formation of the 2:1 complex. Sedimentation velocity analytical ultracentrifugation of TonBDelta66-100 with FhuA revealed that a 1:1 TonB-FhuA complex is formed. Interactions between TonBDelta66-100 and FhuA were assessed by surface plasmon resonance, and their affinities were determined to be similar to those of TonB (FL)-FhuA. Presence of the FhuA-specific siderophore ferricrocin altered neither stoichiometry nor affinity of interaction, leading to our conclusion that the proline-rich region in TonB is important in forming a 2:1 high-affinity TonB-FhuA complex in vitro. Furthermore, TonBDelta66-100-FhuADelta21-128 interactions demonstrated that the cork region of the OM receptor was also important in forming a complex. Together, these results demonstrate a novel function of the proline-rich region of TonB in mediating TonB-TonB interactions within the TonB-FhuA complex.     

Kinetic analyses reveal multiple steps in forming TonB-FhuA complexes from Escherichia coli

FhuA, an outer membrane receptor of Escherichia coli, facilitates transport of hydroxamate siderophores and siderophore-antibiotic conjugates. The cytoplasmic membrane complex TonB-ExbB-ExbD provides energy for transport via the proton motive force. This energy is transduced by protein-protein interactions between TonB and FhuA, but the molecular determinants of these interactions remain uncharacterized. Our analyses of FhuA and two recombinant TonB species by surface plasmon resonance revealed that TonB undergoes a kinetically limiting rearrangement upon initial interaction with FhuA: an intermediate TonB-FhuA complex of 1:1 stoichiometry was detected. The intermediate then recruits a second TonB protein. Addition of ferricrocin, a FhuA-specific ligand, enhanced amounts of the 2:1 complex but was not essential for its formation. To assess the role of the cork domain of FhuA in forming a 2:1 TonB-FhuA complex, we tested a FhuA deletion (residues 21-128) for its ability to interact with TonB. Analytical ultracentrifugation demonstrated that deletion of this region of the cork domain resulted in a 1:1 complex. Furthermore, the high-affinity 2:1 complex requires the N-terminal region of TonB. Together these in vitro experiments establish that TonB-FhuA interactions require sequential steps of kinetically limiting rearrangements. Additionally, domains that contribute to complex formation were identified in TonB and in FhuA.     

Interactions between TonB from Escherichia coli and the periplasmic protein FhuD

For uptake of ferrichrome into bacterial cells, FhuA, a TonB-dependent outer membrane receptor of Escherichia coli, is required. The periplasmic protein FhuD binds and transfers ferrichrome to the cytoplasmic membrane-associated permease FhuB/C. We exploited phage display to map protein-protein interactions in the E. coli cell envelope that contribute to ferrichrome transport. By panning random phage libraries against TonB and against FhuD, we identified interaction surfaces on each of these two proteins. Their interactions were detected in vitro by dynamic light scattering and indicated a 1:1 TonB-FhuD complex. FhuD residue Thr-181, located within the siderophorebinding site and mapping to a predicted TonB-interaction surface, was mutated to cysteine. FhuD T181C was reacted with two thiol-specific fluorescent probes; addition of the siderophore ferricrocin quenched fluorescence emissions of these conjugates. Similarly, quenching of fluorescence from both probes confirmed binding of TonB and established an apparent KD of approximately 300 nM. Prior saturation of the siderophorebinding site of FhuD with ferricrocin did not alter affinity of TonB for FhuD. Binding, further characterized with surface plasmon resonance, indicated a higher affinity complex with KD values in the low nanomolar range. Addition of FhuD to a preformed TonB-FhuA complex resulted in formation of a ternary complex. These observations led us to propose a novel mechanism in which TonB acts as a scaffold, directing FhuD to regions within the periplasm where it is poised to accept and deliver siderophore.     

TonB induces conformational changes in surface-exposed loops of FhuA, outer membrane receptor of Escherichia coli

FhuA, outer membrane receptor of Escherichia coli, transports hydroxamate-type siderophores into the periplasm. Cytoplasmic membrane-anchored TonB transduces energy to FhuA to facilitate siderophore transport. Because the N-terminal cork domain of FhuA occludes the C-terminal beta-barrel lumen, conformational changes must occur to enable siderophore passage. To localize conformational changes at an early stage of the siderophore transport cycle, four anti-FhuA monoclonal antibodies (mAbs) were purified to homogeneity, and the epitopes that they recognize were determined by phage display. We mapped continuous and discontinuous epitopes to outer surface-exposed loops 3, 4, and 5 and to beta-barrel strand 14. To probe for conformational changes of FhuA, surface plasmon resonance measured mAb binding to FhuA in its apo- and siderophore-bound states. Changes in binding kinetics were observed for mAbs whose epitopes were mapped to outer surface-exposed loops. Further, we measured mAb binding in the absence and presence of TonB. After forming immobilized FhuA-TonB complexes, changes in kinetics of mAb binding to FhuA were even more pronounced compared with kinetics of binding in the absence of TonB. Measurement of extrinsic fluorescence of the dye MDCC conjugated to residue 336 in outer surface-exposed loop 4 revealed 33% fluorescence quenching upon ferricrocin binding and up to 56% quenching upon TonB binding. Binding of mAbs to apo- and ferricrocin-bound FhuA complemented by fluorescence spectroscopy studies showed that their cognate epitopes on loops 3, 4, and 5 undergo conformational changes upon siderophore binding. Further, our data demonstrate that TonB binding promotes conformational changes in outer surface-exposed loops of FhuA.     

Phage display reveals multiple contact sites between FhuA, an outer membrane receptor of Escherichia coli, and TonB

The ferric hydroxamate uptake receptor FhuA from Escherichia coli transports siderophores across the outer membrane (OM). TonB-ExbB-ExbD transduces energy from the cytoplasmic membrane to the OM by contacts between TonB and OM receptors that contain the Ton box, a consensus sequence near the N terminus. Although the Ton box is a region of known contact between OM receptors and TonB, our biophysical studies established that TonB binds to FhuA through multiple regions of interaction. Panning of phage-displayed random peptide libraries (Ph.D.-12, Ph.D.-C7C) against TonB identified peptide sequences that specifically interact with TonB. Analyses of these sequences using the Receptor Ligand Contacts (RELIC) suite of programs revealed clusters of multiply aligned peptides that mapped to FhuA. These clusters localized to a continuous periplasm-accessible surface: Ton box/switch helix; cork domain/beta1 strand; and periplasmic turn 8. Guided by such matches, synthetic oligonucleotides corresponding to DNA sequences identical to fhuA were fused to malE; peptides corresponding to the above regions were displayed at the N terminus of E.coli maltose-binding protein (MBP). Purified FhuA peptides fused to MBP bound specifically to TonB by ELISA. Furthermore, they competed with ligand-loaded FhuA for binding to TonB. RELIC also identified clusters of multiply aligned peptides corresponding to the Ton box regions in BtuB, FepA, and FecA; to periplasmic turn 8 in BtuB and FecA; and to periplasmic turns 1 and 2 in FepA. These experimental outcomes identify specific molecular contacts made between TonB and OM receptors that extend beyond the well-characterized Ton box.     

Energy-dependent receptor activities of Escherichia coli K-12: mutated TonB proteins alter FhuA receptor activities to phages T5, T1, ⊘80 and to colicin M

Abstract The activity of the FhuA receptor in the outer membrane of Escherichia coli is dependent on the TonB, ExbB and ExbD proteins which are anchored to the cytoplasmic membrane. Only infection by phage T5 occurs independently of TonB, ExbB and ExbD. In this paper we describe mutated FhuA proteins which displayed either an increased or decreased FhuA activity to phage T5 when combined with mutated TonB proteins. These results suggest conformational changes in FhuA by TonB which are recognized by phage T5. Similar results were obtained with colicin M and the phages T1 and ⊘80. It is proposed that the FhuA mutant proteins assume conformations which are either improved or impaired by the TonB derivatives. For the direct interaction of FhuA with TonB regions which are located outside the TonB box of FhuA and the region around residue 160 of TonB are important.     

Transport of iron across the outer membrane

Summary The TonB protein is involved in energy-coupled receptor-dependent transport processes across the outer membrane. The TonB protein is anchored in the cytoplasmic membrane but exposed to the periplasmic space. To fulfill its function, it has to couple the energy-providing metabolism in the cytoplasmic membrane with regulation of outer membrane receptor activity. Ferrichrome and albomycin transport, uptake of colicin M, and infection by the phages T1 and80 occur via the same receptor, the FhuA protein in the outer membrane. Therefore, this receptor is particularly suitable for the study of energy-coupled TonB-dependent transport across the outer membrane. Ferrichrome, albomycin and colicin M bind to the FhuA receptor but are not released into the periplasmic space of unenergized cells, ortonB mutants. In vivo interaction between FhuA and TonB is suggested by the restoration of activity of inactive FhuA proteins, bearing amino acid replacements in the TonB box, by TonB derivatives with single amino acid substitutions. Point mutations in thefhuA gene are suppressed by point mutations in thetonB gene. In addition, naturally occurring degradation of the TonB protein and its derivatives is preferentially prevented in vivo by FhuA and FhuA derivatives where functional interaction takes place. It is proposed that in the energized state, TonB induces a conformation in FhuA which leads to the release of the FhuA-bound compounds into the periplasmic space. Activation of FhuA by TonB depends on the ExbBD proteins in the cytoplasmic membrane. They can be partially replaced by the TolQR proteins which show strong sequence similarity to the ExbBD proteins. A physical interaction of these proteins with the TonB protein is suggested by TonB stabilization through ExbB and TolQR. We propose a permanent or reversible complex in the cytoplasmic membrane composed of the TonB protein and the ExbBD/TolQR proteins through which TonB is energized.     

Mutual inhibition of cobalamin and siderophore uptake systems suggests their competition for TonB function.

Vitamin B12 (CN-Cbl) and iron-siderophore complexes are transported into Escherichia coli in two energy-dependent steps. The first step is mediated by substrate-specific outer membrane transport proteins and the energy-coupling TonB protein complex, and the second step uses separate periplasmic permeases for transport across the cytoplasmic membrane. Genetic and biochemical evidence suggests that the TonB-dependent outer membrane transporters contact TonB directly, and thus they might compete for limiting amounts of functional TonB. The transport of iron-siderophore complexes, such as ferrichrome, causes a partial decrease in the rate of CN-Cbl transport. Although CN-Cbl uptake does not inhibit ferrichrome uptake in wild-type cells, in which the amount of the outer membrane ferrichrome transporter FhuA far exceeds that of the cobalamin transporter BtuB, CN-Cbl does inhibit ferrichrome uptake when BtuB is overexpressed from a multicopy plasmid. This inhibition by CN-Cbl is increased when the expression of FhuA and TonB is repressed by growth with excess iron and is eliminated when BtuB synthesis is repressed by CN-Cbl. The mutual inhibition of CN-Cbl and ferrichrome uptake is overcome by increased expression of TonB. Additional evidence for interaction of the Cbl and iron transport systems is provided by the strong stimulation of the BtuB- and TonB-dependent transport of CN-Cbl into a nonexchangeable, presumably cytoplasmic pool by preincubation of cells with the iron(II) chelator 2,2'-dipyridyl. Other metal ion chelators inhibited CN-Cbl uptake across the outer membrane. Although the effects of chelators are multiple and complex, they indicate competition or interaction among TonB-dependent transport systems.     

Structure and function of X-Pro dipeptide repeats in the TonB proteins of Salmonella typhimurium and Escherichia coli

The TonB protein is required for several outer membrane transport processes in bacteria. A short 33-residue peptide segment of TonB has been studied by 1H and 13C nuclear magnetic resonance spectroscopy. The sequence of this peptide segment contains multiple Glu-Pro and Lys-Pro dipeptide repeats that maintain rigid, elongated structures and flank a short connecting segment that adopts a beta-strand configuration. This TonB peptide is shown to interact specifically with the FhuA protein, the outer membrane receptor for ferrichrome-iron, providing the first direct evidence that the TonB protein interacts with outer membrane receptors. Interaction with the FhuA protein involves the extended structural element containing positively charged Lys-Pro repeats, and suggests a functional role for this segment of the TonB protein. As TonB is anchored in the cytoplasmic membrane the protein must, uniquely, span the periplasm. These data, together with studies described in the accompanying paper, suggest a model by which TonB serves to transduce conformational information over extended distances, from the cytoplasmic membrane to the outer membrane.     

TonB protein of Salmonella typhimurium. A model for signal transduction between membranes

The tonB gene product is required for several outer membrane transport processes in bacteria. The tonB gene from Salmonella typhimurium was sequenced and found to be similar to that of Escherichia coli. The TonB protein is highly proline-rich and includes an unusual segment consisting of multiple X-Pro dipeptide repeats. A synthetic peptide corresponding to this segment has been used to raise anti-TonB antibodies. TonB was shown to be associated with the cytoplasmic membrane, apparently anchored via a single hydrophobic N-terminal segment. Protease accessibility studies, and the use of a series of TonB-beta-lactamase fusions, showed that the rest of the TonB protein is periplasmic. Unusually, export of TonB is not accompanied by cleavage of the N-terminal signal peptide. In the accompanying paper, we show that TonB interacts directly with the outer membrane FhuA (TonA) receptor. Thus, TonB must span the periplasm, providing a link between the cytoplasmic membrane and receptors in the outer membrane. On the basis of these data, and those published by other laboratories, we propose a model whereby TonB serves as a "mechanical" linkage that, by transmitting protein conformational changes from the cytoplasmic membrane across the periplasm, acts as a means of coupling energy to outer membrane transport processes. Such a mechanism has general implications for signal transduction within and between proteins.     

Characterization of in vitro interactions between a truncated TonB protein from Escherichia coli and the outer membrane receptors FhuA and FepA

High-affinity iron uptake in gram-negative bacteria depends upon TonB, a protein which couples the proton motive force in the cytoplasmic membrane to iron chelate receptors in the outer membrane. To advance studies on TonB structure and function, we expressed a recombinant form of Escherichia coli TonB lacking the N-terminal cytoplasmic membrane anchor. This protein (H(6)-'TonB; M(r), 24,880) was isolated in a soluble fraction of lysed cells and was purified by virtue of a hexahistidine tag located at its N terminus. Sedimentation experiments indicated that the H(6)-'TonB preparation was almost monodisperse and the protein was essentially monomeric. The value found for the Stokes radius (3.8 nm) is in good agreement with the value calculated by size exclusion chromatography. The frictional ratio (2.0) suggested that H(6)-'TonB adopts a highly asymmetrical form with an axial ratio of 15. H(6)-'TonB captured both the ferrichrome-iron receptor FhuA and the ferric enterobactin receptor FepA from detergent-solubilized outer membranes in vitro. Capture was enhanced by preincubation of the receptors with their cognate ligands. Cross-linking assays with the purified proteins in vitro demonstrated that there was preferential interaction between TonB and ligand-loaded FhuA. Purified H(6)-'TonB was found to be stable and thus shows promise for high-resolution structural studies.     

Dimerization of TonB is not essential for its binding to the outer membrane siderophore receptor FhuA of Escherichia coli

FhuA belongs to a family of specific siderophore transport systems located in the outer membrane of Escherichia coli. The energy required for the transport process is provided by the proton motive force of the cytoplasmic membrane and is transmitted to FhuA by the protein TonB. Although the structure of full-length TonB is not known, the structure of the last 77 residues of a fragment composed of the 86 C-terminal amino acids was recently solved and shows an intertwined dimer (Chang, C., Mooser, A., Pluckthun, A., and Wlodawer, A. (2001) J. Biol. Chem. 276, 27535-27540). We analyzed the ability of truncated C-terminal TonB fragments of different lengths (77, 86, 96, 106, 116, and 126 amino acid residues, respectively) to bind to the receptor FhuA. Only the shortest TonB fragment, TonB-77, could not effectively interact with FhuA. We have also observed that the fragments TonB-77 and TonB-86 form homodimers in solution, whereas the longer fragments remain monomeric. TonB fragments that bind to FhuA in vitro also inhibit ferrichrome uptake via FhuA in vivo and protect cells against attack by bacteriophage Phi80.     

Role of the TonB amino terminus in energy transduction between membranes.

Escherichia coli TonB protein is an energy transducer, coupling cytoplasmic membrane energy to active transport of vitamin B12 and iron-siderophores across the outer membrane. TonB is anchored in the cytoplasmic membrane by its hydrophobic amino terminus, with the remainder occupying the periplasmic space. In this report we establish several functions for the hydrophobic amino terminus of TonB. A G-26-->D substitution in the amino terminus prevents export of TonB, suggesting that the amino terminus contains an export signal for proper localization of TonB within the cell envelope. Substitution of the first membrane-spanning domain of the cytoplasmic membrane protein TetA for the TonB amino terminus eliminates TonB activity without altering TonB export, suggesting that the amino terminus contains sequence-specific information. Detectable TonB cross-linking to ExbB is also prevented, suggesting that the two proteins interact primarily through their transmembrane domains. In vivo cleavage of the amino terminus of TonB carrying an engineered leader peptidase cleavage site eliminates (i) TonB activity, (ii) detectable interaction with a membrane fraction having a density intermediate to those of the cytoplasmic and outer membranes, and (iii) cross-linking to ExbB. In contrast, the amino terminus is not required for cross-linking to other proteins with which TonB can form complexes, including FepA. Additionally, although the amino terminus clearly is a membrane anchor, it is not the only means by which TonB associates with the cytoplasmic membrane. TonB lacking its amino-terminal membrane anchor still remains largely associated with the cytoplasmic membrane.     

TonB protein and energy transduction between membranes

TonB protein couples cytoplasmic membrane electrochemical potential to active transport of iron-siderophore complexes and vitamin B12 through high-affinity outer membrane receptors of Gram-negative bacteria. The mechanism of energy transduction remains to be determined, but important concepts have already begun to emerge. Consistent with its function, TonB is anchored in the cytoplasmic membrane by its uncleaved amino terminus while largely occupying the periplasm. Both the connection to the cytoplasmic membrane and the amino acid sequences of the anchor are essential for activity. TonB directly associates with a number of envelope proteins, among them the outer membrane receptors and cytoplasmic membrane protein ExbB. ExbB and TonB interact through their respective transmembrane domains. ExbB is proposed to recycle TonB to an active conformation following energy transduction to the outer membrane. TonB most likely associates with the outer membrane receptors through its carboxy terminus, which is required for function. In contrast, the novel prolinerich region of TonB can be deleted without affecting function. A model that incorporates this information, as well as tempered speculation, is presented.     

Transport across the outer membrane of Escherichia coli K12 via the FhuA receptor is regulated by the TonB protein of the cytoplasmic membrane

Summary Point mutations in the “TonB box” offhuA were suppressed by point mutations in thetonB gene, suggesting both a functional and physical interaction between the FhuA receptor protein in the outer membrane and the TonB protein in the cytoplasmic membrane ofEscherichia coli K12. Mutations influA were classified into four types according to the extent by which they impaired mutant cells in their growth on ferrichrome as sole iron source and in their sensitivity to the antibiotic albomycin and to colicin M. ThetonB mutation with a glutamine to leucine replacement at position 165 was less efficient in restoring the FhuA functions than the glutamine to lysine exchange at the same position. The better the coupling between FhuA and TonB the poorer was the inhibition of phage T1 binding to FhuA by ferrichrome. A working model is proposed in which the TonB protein assumes different conformations in response to the energized state of the cytoplasmic membrane and thereby allosterically regulates the activity of the FhuA receptor. This model implies an intermembrane coupling between two proteins in adjacent membranes.     

Conversion of the FhuA transport protein into a diffusion channel through the outer membrane of Escherichia coli.

The FhuA receptor protein is involved in energy-coupled transport of Fe3+ via ferrichrome through the outer membrane of Escherichia coli. Since no energy source is known in the outer membrane it is assumed that energy is provided through the action of the TonB, ExbB and ExbD proteins, which are anchored to the cytoplasmic membrane. By deleting 34 amino acid residues of a putative cell surface exposed loop, FhuA was converted from a ligand specific transport protein into a TonB independent and nonspecific diffusion channel. The FhuA deletion derivative FhuA delta 322-355 formed stable channels in black lipid membranes, in contrast to wild-type FhuA which did not increase membrane conductance. The single-channel conductance of the FhuA mutant channels was at least three times larger than that of the general diffusion porins of E. coli outer membrane. It is proposed that the basic structure of FhuA in the outer membrane is a channel formed by beta-barrels. Since the loop extending from residue 316 to 356 is part of the active site of FhuA, it probably controls the permeability of the channel. The transport-active conformation of FhuA is mediated by a TonB-induced conformational change in response to the energized cytoplasmic membrane. The ferrichrome transport rate into cells expressing FhuA delta 322-355 increased linearly with increasing substrate concentration (from 0.5 to 20 microM), in contrast to FhuA wild-type cells, which displayed saturation at 5 microM. This implies that in wild-type cells ferrichrome transport through the outer membrane is the rate-limiting step and that TonB, ExbB and ExbD are only required for outer membrane transport.     

The solution structure of the C-terminal domain of TonB and interaction studies with TonB box peptides

The TonB protein transduces energy from the proton gradient across the cytoplasmic membrane of Gram-negative bacteria to TonB-dependent outer membrane receptors. It is a critically important protein in iron uptake, and deletion of this protein is known to decrease virulence of bacteria in animal models. This system has been used for Trojan horse antibiotic delivery. Here, we describe the high-resolution solution structure of Escherichia coli TonB residues 103-239 (TonB-CTD). TonB-CTD is monomeric with an unstructured N terminus (103-151) and a well structured C terminus (152-239). The structure contains a four-stranded antiparallel beta-sheet packed against two alpha-helices and an extended strand in a configuration homologous to the C-terminal domain of the TolA protein. Chemical shift perturbations to the TonB-CTD (1)H-(15)N HSCQ spectrum titrated with TonB box peptides modeled from the E.coli FhuA, FepA and BtuB proteins were all equivalent, indicating that all three peptides bind to the same region of TonB. Isothermal titration calorimetry measurements demonstrate that TonB-CTD interacts with the FhuA-derived peptide with a K(D)=36(+/-7) microM. On the basis of chemical shift data, the position of Gln160, and comparison to the TolA gp3 N1 complex crystal structure, we propose that the TonB box binds to TonB-CTD along the beta3-strand.     

TonB interacts with nonreceptor proteins in the outer membrane of Escherichia coli

The Escherichia coli TonB protein serves to couple the cytoplasmic membrane proton motive force to active transport of iron-siderophore complexes and vitamin B(12) across the outer membrane. Consistent with this role, TonB has been demonstrated to participate in strong interactions with both the cytoplasmic and outer membranes. The cytoplasmic membrane determinants for that interaction have been previously characterized in some detail. Here we begin to examine the nature of TonB interactions with the outer membrane. Although the presence of the siderophore enterochelin (also known as enterobactin) greatly enhanced detectable cross-linking between TonB and the outer membrane receptor, FepA, the absence of enterochelin did not prevent the localization of TonB to the outer membrane. Furthermore, the absence of FepA or indeed of all the iron-responsive outer membrane receptors did not alter this association of TonB with the outer membrane. This suggested that TonB interactions with the outer membrane were not limited to the TonB-dependent outer membrane receptors. Hydrolysis of the murein layer with lysozyme did not alter the distribution of TonB, suggesting that peptidoglycan was not responsible for the outer membrane association of TonB. Conversely, the interaction of TonB with the outer membrane was disrupted by the addition of 4 M NaCl, suggesting that these interactions were proteinaceous. Subsequently, two additional contacts of TonB with the outer membrane proteins Lpp and, putatively, OmpA were identified by in vivo cross-linking. These contacts corresponded to the 43-kDa and part of the 77-kDa TonB-specific complexes described previously. Surprisingly, mutations in these proteins individually did not appear to affect TonB phenotypes. These results suggest that there may be multiple redundant sites where TonB can interact with the outer membrane prior to transducing energy to the outer membrane receptors.     

Regions of Escherichia coli TonB and FepA proteins essential for in vivo physical interactions.

The transport of Fe(III)-siderophore complexes and vitamin B12 across the outer membrane of Escherichia coli is an active transport process requiring a cognate outer membrane receptor, cytoplasmic membrane-derived proton motive force, and an energy-transducing protein anchored in the cytoplasmic membrane, TonB. This process requires direct physical contact between the outer membrane receptor and TonB. Previous studies have identified an amino-terminally located region (termed the TonB box) conserved in all known TonB-dependent outer membrane receptors as being essential for productive energy transduction. In the present study, a mutation in the TonB box of the ferric enterochelin receptor FepA resulted in the loss of detectable in vivo chemical cross-linking between FepA and TonB. Protease susceptibility studies indicated this effect was due to an alteration of conformation rather than the direct disruption of a specific site of physical contact. This suggested that TonB residue 160, implicated in previous studies as a site of allele-specific suppression of TonB box mutants, also made a conformational rather than a direct contribution to the physical interaction between TonB and the outer membrane receptors. This possibility was supported by the finding that TonB carboxyl-terminal truncations that retained Gln-160 were unable to participate in TonB-FepA complex formation, indicating that this site alone was not sufficient to support the physical interactions involved in energy transduction. These studies indicated that the final 48 residues of TonB were essential to this physical interaction. This region contains a putative amphipathic helix which could facilitate TonB-outer membrane interaction. Amino acid replacements at one site in this region were found to affect energy transduction but did not appear to greatly alter TonB conformation or the formation of a TonB-FepA complex. The effects of amino acid substitutions at several other TonB sites were also examined.