Deletions or duplications in the BtuB protein affect its level in the outer membrane of Escherichia coli.

The Escherichia coli btuB product is an outer membrane protein that mediates the TonB-coupled active transport of cobalamins and the uptake of the E colicins and bacteriophage BF23. The roles of various segments of the BtuB protein in its function or cellular localization were investigated by analysis of several genetic constructs. Hybrid proteins in which various lengths from the amino terminus of BtuB were linked to alkaline phosphatase (btuB::phoA genes) were all secreted across the cytoplasmic membrane. The BtuB-PhoA proteins that carried up to 327 amino acids of BtuB appeared to reside in the periplasmic space, whereas hybrid proteins containing at least 399 amino acids of BtuB were associated with the outer membrane. Eleven in-frame internal deletion mutations that spanned more than half of the mature sequence were prepared by combining appropriate restriction fragments from btuB variants with 6-bp linker insertions. None of the deleted proteins was able to complement any BtuB functions, and only three of them were detectable in the outer membrane, suggesting that most of the deletions affected sequences needed for stable association with the outer membrane. Duplications covering the same portions of BtuB were prepared in the same manner. All of these partial duplication variants complemented all BtuB functions, although some gave substantially reduced levels of activity. These proteins were found in the outer membrane, although some were subject to proteolytic cleavage within or near the duplicated segment. These results indicate that the insertion of BtuB into the outer membrane requires the presence of several regions of teh BtuB protein and that the presence of extra or redundant segments of the protein can be tolerated during its insertion and function.     

Interdependence of calcium and cobalamin binding by wild-type and mutant BtuB protein in the outer membrane of Escherichia coli.

The binding of calcium and cobalamin to outer membranes from cells of Escherichia coli that contained amplified levels of wild-type or mutant btuB was studied. The mutant (BBam50) had an aspartyl-prolyl dipeptide inserted after the original 50th amino acid residue of the mature BtuB protein, which is within a region that shows extensive homology with the ferric siderophore receptors. This insertion resulted in cleavage of the BtuB in two places. The larger form retained the insertion but had lost 11 amino acid residues from the amino terminus. The smaller form was cut at the insertion site. Both the wild-type protein and the larger form of mutant BtuB showed calcium-dependent cobalamin binding with the same affinity for cobalamin, although the mutant had a much lower affinity for calcium. The smaller form of the mutant BtuB protein had a greatly reduced affinity for cobalamin, which was probably the result of inactivation of the cobalamin-dependent calcium-binding site. Cobalamin-dependent calcium binding was measured in wild-type BtuB preparations and was found to have the same corrinoid specificity and response to various corrinoid concentrations as shown previously for cobalamin binding. The results are consistent with a role for calcium in the cobalamin pump of the outer membrane of E. coli and show that a conserved part of the BtuB protein is required for the cobalamin-dependent binding of calcium.     

Observations on the calcium dependence and reversibility of cobalamin transport across the outer membrane of Escherichia coli

The calcium dependence of cobalamin (Cbl) binding to the BtuB protein of Escherichia coli and the reversibility of its function in the transport of Cbl across the outer membrane have been examined. The results show that the two calcium-binding sites in BtuB that were identified previously by others are responsible for the calcium dependence of high affinity Cbl binding. The affinity of the pure BtuB protein for Cbl was approximately 1000-fold higher in the presence of saturating levels of calcium than in its absence. The affinities of BtuB for both Cbl and calcium were decreased by insertion of alanine residues at position 51 of the mature protein and were increased by several mutations and deletions in the TonB box. Experiments on the uptake of Cbl into the periplasmic space showed that this process is reversible and that the exit of Cbl back into the medium does not require the protonmotive force. Our interpretation of these results is that the role of the TonB-ExbB-ExbD complex, potentiated by the protonmotive force, is to reduce the affinity of the Cbl-binding site, thus increasing the rate of Cbl release into the periplasmic space. The evidence also indicates that access of the Cbl-binding site of BtuB to the periplasmic space does not require removal of the hatch domain from the barrel.     

Point mutations in a conserved region (TonB box) of Escherichia coli outer membrane protein BtuB affect vitamin B12 transport.

Uptake of cobalamins and iron chelates in Escherichia coli K-12 is dependent on specific outer membrane transport proteins and the energy-coupling function provided by the TonB protein. The btuB product is the outer membrane receptor for cobalamins, bacteriophage BF23, and the E colicins. A short sequence near the amino terminus of mature BtuB, previously called the TonB box, is conserved in all tonB-dependent receptors and colicins and is the site of the btuB451 mutation (Leu-8----Pro), which prevents energy-coupled cobalamin uptake. This phenotype is partially suppressed by certain mutations in tonB. To examine the role of individual amino acids in the TonB box of BtuB, more than 30 amino acid substitutions in residues 6 to 13 were generated by doped oligonucleotide-directed mutagenesis. Many of the mutations affecting each amino acid did not impair transport activity, although some substitutions reduced cobalamin uptake and the Leu-8----Pro and Val-10----Gly alleles were completely inactive. To test whether the btuB451 mutation affects only cobalamin transport, a hybrid gene was constructed which encodes the signal sequence and first 39 residues of BtuB fused to the bulk of the ferrienterobactin receptor FepA (residues 26 to 723). This hybrid protein conferred all FepA functions but no BtuB functions. The presence of the btuB451 mutation in this fusion gene eliminated all of its tonB-coupled reactions, showing that the TonB box of FepA could be replaced by that from BtuB. These results suggest that the TonB-box region of BtuB is involved in active transport in a manner dependent not on the identity of specific side chains but on the local secondary structure.     

The Escherichia coli outer membrane cobalamin transporter BtuB: structural analysis of calcium and substrate binding, and identification of orthologous transporters by sequence/structure conservation

Gram-negative bacteria possess specialized active transport systems that function to transport organometallic cofactors or carriers, such as cobalamins, siderophores, and porphyrins, across their outer membranes. The primary components of each transport system are an outer membrane transporter and the energy-coupling protein TonB. In Escherichiacoli, the TonB-dependent outer membrane transporter BtuB carries out active transport of cobalamin (Cbl) substrates across its outer membrane. Cobalamins bind to BtuB with nanomolar affinity. Previous studies implicated calcium in high-affinity binding of cyanocobalamin (CN-Cbl) to BtuB. We previously solved four structures of BtuB or BtuB complexes: an apo-structure of a methionine-substitution mutant (used to obtain experimental phases by selenomethionine single-wavelength anomalous diffraction studies); an apo-structure of wild-type BtuB; a binary complex of calcium and wild-type BtuB; and a ternary complex of calcium, CN-Cbl and wild-type BtuB. We present an analysis of the binding of calcium in the binary and ternary complexes, and show that calcium coordination changes upon substrate binding. High-affinity CN-Cbl binding and calcium coordination are coupled. We also analyze the binding mode of CN-Cbl to BtuB, and compare and contrast this binding to that observed in other proteins that bind Cbl. BtuB binds CN-Cbl in a manner very different from Cbl-utilizing enzymes and the periplasmic Cbl binding protein BtuF. Homology searches of bacterial genomes, structural annotation based on the presence of conserved Cbl-binding residues identified by analysis of our BtuB structure, and detection of homologs of the periplasmic Cbl-binding binding protein BtuF enable identification of putative BtuB orthologs in enteric and non-enteric bacterial species.     

Molecular analysis of the Escherichia coli ferric enterobactin receptor FepA

In Escherichia coli, the outer membrane protein FepA is a receptor for the siderophore complex ferric enterobactin and for colicins B and D. To identify protein domains important for FepA activity, the effects of deletion and linker insertion mutations on receptor structure and function were examined. In-frame internal deletion mutations removing sequences encoding up to 304 amino acid residues resulted in functionally defective FepA polypeptides, although most were translocated efficiently to the outer membrane. One exception, a derivative lacking 87 internal amino acid residues near the N terminus, showed an inability to transport ferric enterobactin but retained limited colicin receptor function. Analysis of cells carrying 3'-terminal fepA deletion mutations suggested that residues within the C terminus of FepA may be involved in secretion and proper translocation of the protein to the outer membrane. Introduction of the peptide Leu-Glu after FepA residues 55, 142, or 324 severely impaired receptor function for all three ligands, while the same insertion after residues 339 or 359 had virtually no detrimental effect on FepA function. Foreign peptides inserted after residues 204 or 635 restricted colicin B and D function only, leaving ferric enterobactin transport ability at near wild-type levels. The results presented in this study have identified key regions of FepA potentially involved in receptor function and demonstrate the presence of both shared and unique ligand-responsive domains.     

Altered binding and transport of vitamin B12 resulting from insertion mutations in the Escherichia coli btuB gene

The BtuB protein of Escherichia coli is a multifunctional outer membrane receptor required for the binding and uptake of vitamin B12, bacteriophage BF23, and the E colicins. The btuB gene was mutagenized by the insertion of 6-base pair linkers into each of ten HpaII sites distributed throughout the coding region. Receptor function was measured with the mutated genes present in single or multiple copies. All of the mutant proteins were found in the outer membrane in similar amounts, although two of them were susceptible to cleavage by endogenous proteolytic activity. The vitamin B12 transport activity mediated by five of the mutants was essentially identical to that of the wild type. Four mutations (insertions after amino acids 50, 252, and 412, and a duplication of residues 434-472) reduced uptake activity to less than 2% of parental, whereas insertions at residues 343 and 434 had less severe effect. The insertions at residues 50 and 252 appeared to slow the rate of cobalamin binding to the receptor; the defect in the former mutant was partially corrected by elevated calcium levels. The insertion at residue 412 did not affect the rate of substrate binding but slowed its release from the receptor. Most of the receptors conferred susceptibility to phage BF23 and the E colicins, although several mutants were altered in the degree of their sensitivity to the lethal agents. None of the mutations affected the entry of only one type of ligand. Thus, several receptor domains have been implicated in substrate binding and energy coupling.     

Bacterial Phage Receptors, Versatile Tools for Display of Polypeptides on the Cell Surface

Four outer membrane proteins of Escherichia coli were examined for their capabilities and limitations in displaying heterologous peptide inserts on the bacterial cell surface. The T7 tag or multiple copies of the myc epitope were inserted into loops 4 and 5 of the ferrichrome and phage T5 receptor FhuA. Fluorescence-activated cell sorting analysis showed that peptides of up to 250 amino acids were efficiently displayed on the surface of E. coli as inserts within FhuA. Strains expressing FhuA fusion proteins behaved similarly to those expressing wild-type FhuA, as judged by phage infection and colicin sensitivity. The vitamin B(12) and phage BF23 receptor BtuB could display peptide inserts of at least 86 amino acids containing the T7 tag. In contrast, the receptors of the phages K3 and lambda, OmpA and LamB, accepted only insertions in their respective loop 4 of up to 40 amino acids containing the T7 tag. The insertion of larger fragments resulted in inefficient transport and/or assembly of OmpA and LamB fusion proteins into the outer membrane. Cells displaying a foreign peptide fused to any one of these outer membrane proteins were almost completely recovered by magnetic cell sorting from a large pool of cells expressing the relevant wild-type platform protein only. Thus, this approach offers a fast and simple screening procedure for cells displaying heterologous polypeptides. The combination of FhuA, along with with BtuB and LamB, should provide a comprehensive tool for displaying complex peptide libraries of various insert sizes on the surface of E. coli for diverse applications.     

Substrate-induced transmembrane signaling in the cobalamin transporter BtuB

The outer membranes of Gram-negative bacteria possess transport proteins essential for uptake of scarce nutrients. In TonB-dependent transporters, a conserved sequence of seven residues, the Ton box, faces the periplasm and interacts with the inner membrane TonB protein to energize an active transport cycle. A critical mechanistic step is the structural change in the Ton box of the transporter upon substrate binding; this essential transmembrane signaling event increases the affinity of the transporter for TonB and enables active transport to proceed. We have solved crystal structures of BtuB, the outer membrane cobalamin transporter from Escherichia coli, in the absence and presence of cyanocobalamin (vitamin B(12)). In these structures, the Ton box is ordered and undergoes a conformational change in the presence of bound substrate. Calcium has been implicated as a necessary factor for the high-affinity binding (K(d) approximately 0.3 nM) of cyanocobalamin to BtuB. We observe two bound calcium ions that order three extracellular loops of BtuB, thus providing a direct (and unusual) structural role for calcium.     

Nucleotide sequence of the gene for the ferrienterochelin receptor FepA in Escherichia coli. Homology among outer membrane receptors that interact with TonB

We have determined the nucleotide sequence of the Escherichia coli fepA gene, which codes for the outer membrane receptor for ferrienterochelin and colicins B and D. The predicted FepA polypeptide has a molecular weight of 79,908 and consists of 723 amino acids. A 22-amino acid leader or signal peptide preceded the mature protein. With respect to overall composition, hydropathy, net charge and distribution of nonpolar segments, the FepA polypeptide was typical of other E. coli outer membrane proteins, except that FepA contained 2 cysteine residues. Comparison of the deduced amino acid sequence of FepA with that of three other TonB-dependent receptors (BtuB, FhuA, and IutA) revealed only a few regions of sequence homology; one of these included the amino-termini. An amino acid substitution within the conserved amino-terminal region of BtuB resulted in production of a receptor that had normal binding functions but was incapable of energy-dependent transport of vitamin B12. This result suggests that the amino-terminal end of these four polypeptides is involved in interaction with the TonB protein or another step of energy transduction. Three other regions of homology were shared among the four proteins: one near residues 50 to 70, another at about residue 100 to 140, and the last between 20 and 40 amino acid residues from the carboxyl terminus. The function of these three regions remains speculative.     

Structure of the complex of the colicin E2 R-domain and its BtuB receptor. The outer membrane colicin translocon

The crystal structure of the complex of the BtuB receptor and the 135-residue coiled-coil receptor-binding R-domain of colicin E3 (E3R135) suggested a novel mechanism for import of colicin proteins across the outer membrane. It was proposed that one function of the R-domain, which extends along the outer membrane surface, is to recruit an additional outer membrane protein(s) to form a translocon for passage colicin activity domain. A 3.5-A crystal structure of the complex of E2R135 and BtuB (E2R135-BtuB) was obtained, which revealed E2R135 bound to BtuB in an oblique orientation identical to that previously found for E3R135. The only significant difference between the two structures was that the bound coiled-coil R-domain of colicin E2, compared with that of colicin E3, was extended by two and five residues at the N and C termini, respectively. There was no detectable displacement of the BtuB plug domain in either structure, implying that colicin is not imported through the outer membrane by BtuB alone. It was concluded that the oblique orientation of the R-domain of the nuclease E colicins has a function in the recruitment of another member(s) of an outer membrane translocon. Screening of porin knock-out mutants showed that either OmpF or OmpC can function in such a translocon. Arg(452) at the R/C-domain interface in colicin E2 was found have an essential role at a putative site of protease cleavage, which would liberate the C-terminal activity domain for passage through the outer membrane translocon.     

Sequence changes in the ton box region of BtuB affect its transport activities and interaction with TonB protein

Uptake of cobalamins by the transporter protein BtuB in the outer membrane of Escherichia coli requires the proton motive force and the transperiplasmic protein TonB. The Ton box sequence near the amino terminus of BtuB is conserved among all TonB-dependent transporters and is the only known site of mutations that confer a transport-defective phenotype which can be suppressed by certain substitutions at residue 160 in TonB. The crystallographic structures of the TonB-dependent transporter FhuA revealed that the region near the Ton box, which itself was not resolved, is exposed to the periplasmic space and undergoes an extensive shift in position upon binding of substrate. Site-directed disulfide bonding in intact cells has been used to show that the Ton box of BtuB and residues around position 160 of TonB approach each other in a highly oriented and specific manner to form BtuB-TonB heterodimers that are stimulated by the presence of transport substrate. Here, replacement of Ton box residues with proline or cysteine revealed that residue side chain recognition is not important for function, although replacement with proline at four of the seven Ton box positions impaired cobalamin transport. The defect in cobalamin utilization resulting from the L8P substitution was suppressed by cysteine substitutions in adjacent residues in BtuB or in TonB. This suppression did not restore active transport of cobalamins but may allow each transporter to function at most once. The uncoupled proline substitutions in BtuB markedly affected the pattern of disulfide bonding to TonB, both increasing the extent of cross-linking and shifting the pairs of residues that can be joined. Cross-linking of BtuB and TonB in the presence of the BtuB V10P substitution became independent of the presence of substrate, indicating an additional distortion of the exposure of the Ton box in the periplasmic space. TonB action thus requires a specific orientation for functional contact with the Ton box, and changes in the conformation of this region block transport by preventing substrate release and repeated transport cycles.     

Nature of the regions involved in the insertion of newly synthesized protein into the outer membrane of Escherichia coli.

Outer membrane proteins are synthesized by cytoplasmic membrane-bound polysomes, and inserted at insertion sites which cover about 10% of the total outer membrane when cells grow with a generation time of 1 h. A membrane fraction enriched in outer membrane insertion regions was isolated and partly characterized. The rat at which newly inserted proteins are transferred from such insertion regions into the rest of the outer membrane was found to be very fast; the new protein content of insertion regions and that of the remaining outer membrane equilibrate completely within about 20 s at 25 degrees C. Given the rather rigid structure of the outer membrane and the multiple interactions between outer membrane components and the murein layer, lateral diffusion of newly inserted proteins from insertion sites to the remaining outer membrane is not likely to explain this rapid equilibration. Instead, the data support a model in which insertion regions move along the cell surface, leaving behind stationary, newly inserted outer membrane proteins.     

Nature of the regions involved in the insertion of newly synthesized protein into the outer membrane of Escherichia coli

Outer membrane proteins are synthesized by cytoplasmic membrane-bound polysomes, and inserted at insertion sites which cover about 10% of the total outer membrane when cells grow with a generation time of 1 h. A membrane fraction enriched in outer membrane insertion regions was isolated and partly characterized. The rate at which newly inserted proteins are transferred from such insertion regions into the rest of the outer membrane was found to be very fast; the new protein content of insertion regions and that of the remaining outer membrane equilibrate completely within about 20 s at 25°C.Given the rather rigid structure of the outer membrane and the multiple interactions between outer membane components and the murein layer, lateral diffusion of newly inserted proteins from insertion sites to the remaining outer membrane is not likely to explain this rapid equilibration. Instead, the data support a model in which mobile insertion regions move along the cell surface, leaving behind stationary, newly inserted outer membrane proteins.     

Deletion and substitution analysis of the Escherichia coli TonB Q160 region

The active transport of iron siderophores and vitamin B(12) across the outer membrane (OM) of Escherichia coli requires OM transporters and the potential energy of the cytoplasmic membrane (CM) proton gradient and CM proteins TonB, ExbB, and ExbD. A region at the amino terminus of the transporter, called the TonB box, directly interacts with TonB Q160 region residues. R158 and R166 in the TonB Q160 region were proposed to play important roles in cocrystal structures of the TonB carboxy terminus with OM transporters BtuB and FhuA. In contrast to predictions based on the crystal structures, none of the single, double, or triple alanyl substitutions at arginyl residues significantly decreased TonB activity. Even the quadruple R154A R158A R166A R171A mutant TonB still retained 30% of wild-type activity. Up to five residues centered on TonB Q160 could be deleted without inactivating TonB or preventing its association with the OM. TonB mutant proteins with nested deletions of 7, 9, or 11 residues centered on TonB Q160 were inactive and appeared never to have associated with the OM. Because the 7-residue-deletion mutant protein (TonBDelta7, lacking residues S157 to Y163) could still form disulfide-linked dimers when combined with W213C or F202C in the TonB carboxy terminus, the TonBDelta7 deletion did not prevent necessary energy-dependent conformational changes that occur in the CM. Thus, it appeared that initial contact with the OM is made through TonB residues S157 to Y163. It is hypothesized that the TonB Q160 region may be part of a large disordered region required to span the periplasm and contact an OM transporter.     

Primary events in the colicin translocon: FRET analysis of colicin unfolding initiated by binding to BtuB and OmpF

Cellular import of colicin E3 is initiated by high affinity binding of the colicin receptor-binding (R) domain to the vitamin B(12) (BtuB) receptor in the Escherichia coli outer membrane. The BtuB binding site, at the apex of its extended coiled-coil R-domain, is distant from the C-terminal nuclease domain that must be imported for expression of cytotoxicity. Based on genetic analysis and previously determined crystal structures of the R-domain bound to BtuB, and of an N-terminal disordered segment of the translocation (T) domain inserted into the OmpF porin, a translocon model for colicin import has been inferred. Implicit in the model is the requirement for unfolding of the colicin segments inserted into OmpF. FRET analysis was employed to study colicin unfolding upon interaction with BtuB and OmpF. A novel method of Cys-specific dual labeling of a native polypeptide, which allows precise placement of donor and acceptor fluorescent dyes on the same polypeptide chain, was developed. A decrease in FRET efficiency between the translocation and cytotoxic domains of the colicin E3 was observed upon colicin binding in vitro to BtuB or OmpF. The two events were independent and additive. The colicin interactions with BtuB and OmpF have a major electrostatic component. The R-domain Arg399 is responsible for electrostatic interaction with BtuB. It is concluded that free energy for colicin unfolding is provided by binding of the R- domain to BtuB and binding/insertion of the T-domain to/into OmpF.     

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.     

Mechanics of force propagation in TonB-dependent outer membrane transport

For the uptake of scarce yet essential organometallic compounds, outer membrane transporters of Gram-negative bacteria work in concert with an energy-generating inner membrane complex, thus spanning the periplasmic space to drive active transport. Here, we examine the interaction of TonB, an inner membrane protein, with an outer membrane transporter based upon a recent crystal structure of a TonB-transporter complex to characterize two largely unknown steps of the transport cycle: how energy is transmitted from TonB to the transporter and how energy transduction initiates transport. Simulations of TonB in complex with BtuB reveal that force applied to TonB is transmitted to BtuB without disruption of the very small connection between the two, supporting a mechanical mode of coupling. Based on the results of different pulling simulations, we propose that the force transduction instigates a partial unfolding of the pore-occluding luminal domain of the transporter, a potential step in the transport cycle. Furthermore, analysis of the electrostatic potentials and salt bridge interactions between the two proteins during the simulations hints at involvement of electrostatic forces in long-range interaction and binding of TonB and BtuB.     

Multiple extracellular loops contribute to substrate binding and transport by the Escherichia coli cobalamin transporter BtuB

The Escherichia coli outer membrane TonB-dependent transporters for iron complexes and cobalamins recognize their multiple and diverse substrates with high specificity and affinity. The X-ray crystallographic structures of several transporters show that the substrate-binding surfaces are comprised of residues from the internal globular domain and multiple extracellular loops. The extracellular loops on the N-terminal half of the transmembrane beta-barrel of the cobalamin transporter BtuB participate in binding of the cofactor calcium atoms and undergo substantial conformation changes upon substrate binding. The functional relevance of the five C-terminal loops was examined by examining the effects of short in-frame deletions. Each loop contributed in different ways to the binding of BtuB substrates. Deletions in loops 7, 8, 9, and 11 strongly decreased cobalamin binding and transport, whereas deletions in loops 8, 9, and 10 affected binding and entry of phage BF23. None of the loops were essential for the action of colicin E1 or E3, which is consistent with the crystallographic observation that the colicin E3 receptor-binding domain can contact almost all of the loops. A deletion in loop 9 or 11 eliminated the ability of cobalamin to inhibit the action of colicin E1. These phenotypes show that there are multiple independent binding elements and point out similarities and differences in binding properties among the TonB-dependent transporters.     

A 76-residue polypeptide of colicin E9 confers receptor specificity and inhibits the growth of vitamin B12-dependent Escherichia coli 113/3 cells

The mechanism by which E colicins recognize and then bind to BtuB receptors in the outer membrane of Escherichia coli cells is a poorly understood first step in the process that results in cell killing. Using N- and C-terminal deletions of the N-terminal 448 residues of colicin E9, we demonstrated that the smallest polypeptide encoded by one of these constructs that retained receptor-binding activity consisted of residues 343-418. The results of the in vivo receptor-binding assay were supported by an alternative competition assay that we developed using a fusion protein consisting of residues 1-497 of colicin E9 fused to the green fluorescent protein as a fluorescent probe of binding to BtuB in E. coli cells. Using this improved assay, we demonstrated competitive inhibition of the binding of the fluorescent fusion protein by the minimal receptor-binding domain of colicin E9 and by vitamin B12. Mutations located in the minimum R domain that abolished or reduced the biological activity of colicin E9 similarly affected the competitive binding of the mutant colicin protein to BtuB. The sequence of the 76-residue R domain in colicin E9 is identical to that found in colicin E3, an RNase type E colicin. Comparative sequence analysis of colicin E3 and cloacin DF13, which is also an RNase-type colicin but uses the IutA receptor to bind to E. coli cells, revealed significant sequence homology throughout the two proteins, with the exception of a region of 92 residues that included the minimum R domain. We constructed two chimeras between cloacin DF13 and colicin E9 in which (i) the DNase domain of colicin E9 was fused onto the T+R domains of cloacin DF13; and (ii) the R domain and DNase domain of colicin E9 were fused onto the T domain of cloacin DF13. The killing activities of these two chimeric colicins against indicator strains expressing BtuB or IutA receptors support the conclusion that the 76 residues of colicin E9 confer receptor specificity. The minimum receptor-binding domain polypeptide inhibited the growth of the vitamin B12-dependent E. coli 113/3 mutant cells, demonstrating that vitamin B12 and colicin E9 binding is mutually exclusive.