Energy-coupled colicin transport through the outer membrane of Escherichia coli K-12: mutated TonB proteins alter receptor activities and colicin uptake

Abstract The current model of TonB-dependent colicin transport through the outer membrane of Escherichia coli proposes initial binding to receptor proteins, vectorial release from the receptors and uptake into the periplasm from where the colicins, according to their action, insert into the cytoplasmic membrane or enter the cytoplasm. The uptake is energy-dependent and the TonB protein interacts with the receptors as well as with the colicins. In this paper we have studied the uptake of colicins B and Ia, both pore-forming colicins, into various tonB point mutants. Colicin Ia resistance of the tonB mutant (G186D, R204H) was consistent with a defective Cir receptor-TonB interaction while colicin Ia resistance of E. coli expressing TonB of Serratia marcescens , or TonB of E. coli carrying a C-terminal fragment of the S. marcescens TonB, seemed to be caused by an impaired colicin Ia-TonB interaction. In contrast, E. coli tonB (G174R, V178I) was sensitive to colicin Ia and resistant to colicin B unless TonB, ExbB and ExbD were overproduced which resulted in colicin B sensitivity. The differential effects of tonB mutations indicate differences in the interaction of TonB with receptors and colicins.     

Transport of Vitamin B12 in Escherichia coli: Genetic Studies

The chromosomal location of two genetic loci involved in the transport of cyanocobalamin (B(12)) in Escherichia coli K-12 was determined. One gene, btuA, is believed to code for the transport protein in the cytoplasmic membrane, because a mutant with an alteration in this gene has lost the ability to accumulate B(12) within the cell although normal levels of the surface receptors for B(12) are present. The other locus, btuB, apparently codes for the surface receptor on the outer membrane. These mutants have lost the ability to bind B(12) and have greatly reduced transport activity, although growth experiments have shown that they can utilize B(12) for growth, but with decreased efficiency. This surface receptor for B(12) also appears to function as the receptor for the E colicins, because btuB mutants are resistant to the E colicins, and mutants selected for resistance to colicin E1 are defective in B(12) binding and transport. The gene order was determined by transduction analysis to be cyc-argH-btuA-btuB-rif-purD. In addition, mutations in metH, the gene for the B(12)-dependent homocysteine methylating enzyme, were obtained in this study. This gene was localized between metA and malB.     

Transport of vitamin B12 in Escherichia coli: common receptor system for vitamin B12 and bacteriophage BF23 on the outer membrane of the cell envelope.

We showed previously that the outer membrane of the Escherichia coli cell envelope normally contains about 200 to 250 B12 receptors, and that these receptors function both in B12 transport and as receptors for the E colicins. This paper shows that this receptor system is also shared with bacteriophage BF23. A strong positive correlation was observed between the number of B12 receptors per cell and the rate of adsorption of BF23. Cells from mutant strains that lacked B12 receptors did not adsorb BF23 particles. The rate of adsorption of BF23 to cells of a merodiploid strain (RK4151), with about 550 B12 receptors per cell, was approximately double that to cells of a normal, haploid strain. The adsorption of BF23 to hole cells, cell envelopes, outer membrane particles, and solubilized outer membranes was inhibited by vitamin B12, with 50% inhibition at B12 concentrations in the range of 0.5 to 2.0 nM. These values are close to the observed KS for B12 binding to the B12 receptors. Vitamin B12 concentrations as high as 100 nM did not inhibit adsorption of bacteriophages T5, T6, and lambdacI to cells of sensitive strains of E. coli. Bacteriophage BF23 inhibited B12 transport by whole cells and was shown to be a competitive inhibitor of B12 binding to isolated cell envelope particles. The B12/BF23 receptors from E. coli strains KBT069 (btuB69) and RK4104 (btuB69) were fully active, but the number per cell was reduced to an average value of about 0.5.     

Isolation of vitamin B 12 transport mutants of Escherichia coli

Escherichia coli KBT001, a methionine-vitamin B(12) auxotroph, was found to require a minimum of 20 molecules of vitamin B(12) (CN-B(12)) per cell for aerobic growth in the absence of methionine. After mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine and penicillin selection, two kinds of B(12) transport mutant were isolated from this strain. Mutants of class I, such as KBT069, were defective in the initial rapid binding of CN-B(12) to the cell and were unable to grow in the absence of methionine even with CN-B(12) concentrations as high as 100 ng/ml. The class II mutants possessed intact initial phases of CN-B(12) uptake but were defective in the secondary energy-dependent phase. These strains were also unable to convert the CN-B(12) taken up into other cobalamins. In the absence of methionine, some of these strains (e.g., KBT103) were able to grow on media containing 1 ng of CN-B(12)/ml, whereas others (e.g., KBT041) were unable to grow with any of the CN-B(12) concentrations used. Osmotic shock treatment did not affect the initial rate of uptake of CN-B(12) but gave a substantial decrease in the secondary rate. Trace amounts of B(12)-binding macromolecules were released from the cells by the osmotic shock, but only from strains such as KBT001 and KBT041 which possessed an active initial phase of CN-B(12) uptake. These results are interpreted as being consistent with the view that the initial CN-B(12) binding site which functions in this transport system is probably bound to the cell membrane.     

Outer Membrane-Dependent Transport Systems in Escherichia coli: Effect of Repression or Cessation of Colicin Receptor Synthesis on Colicin Receptor Activities

Proteins in the outer membrane of gram-negative bacteria serve as general porins or as receptors for specific nutrient transport systems. Many of these proteins are also used as receptors initiating the processes of colicin or phage binding and uptake. The functional activities of several outer membrane proteins in Escherichia coli K-12 were followed after cessation or repression of their synthesis. Cessation of receptor synthesis was accomplished with a thermolabile suppressor activity acting on amber mutations in btuB (encoding the receptor for vitamin B(12), the E colicins, and phage BF23) and in fepA (encoding the receptor for ferric enterochelin and colicins B and D). After cessation of receptor synthesis, cells rapidly became insensitive to the colicins using that receptor. Treatment with spectinomycin or rifampin blocked appearance of insensitive cells and even increased susceptibility to colicin E1. Insensitivity to phage BF23 appeared only after a lag of about one division time, and the receptors remained functional for B(12) uptake throughout. Therefore, possession of receptor is insufficient for colicin sensitivity, and some interaction of receptor with subsequent uptake components is indicated. Another example of physiological alteration of colicin sensitivity is the protection against many of the tonB-dependent colicins afforded by provision of iron-supplying siderophores. The rate of acquisition of this nonspecific protection was found to be consistent with the repression of receptor synthesis, rather than through direct and immediate effects on the tonB product or other components of colicin uptake or action.     

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.     

Increased production of the outer membrane receptors for colicins B, D and M by Escherichia coli under iron starvation.

Growth of $\text{E. coli}$ K-12 under severe iron stress results in increased production of the outer membrane receptors for colicins B, D, Ib and M. The increase in colicin receptor activity coincides with the appearance of large amounts of two high molecular weight proteins in the outer membrane of the cells. These proteins are identified as the outer membrane receptors for colicins B and D and for colicin M. Mutants lacking a functional outer membrane receptor for colicins B and D are defective in the uptake of iron complexed with the siderochrome enterochelin, and are thus comparable with $\text{tonA}$ mutants which lack a functional receptor for colicin M and are defective in the uptake of iron complexed with ferrichrome (6). The colicin B and D receptor may therefore function in the uptake of ferri-enterochelin.     

Biosynthesis of the outer membrane receptor for vitamin B12, E colicins, and bacteriophage BF23 by Escherichia coli: kinetics of phenotypic expression after the introduction of bfe+ and bfe alleles.

The bfe locus codes for the cell surface receptor for vitamin B12, the E colicins, and bacteriophage BF23 in the Escherichia coli outer membrane. When the bfe+ allele, which is closely linked to the argH locus, was introduced into an argH bfe recipient by conjugation, arg+ recombinant cells rapidly and simultaneously acquired sensitivity to colicin E3 and phage BF23. In the reciprocal experiment introducing bfe into an argH bfe+ recipient, it was found that colicin E3-resistant, arg+ cells began to appear shortly after the arg+ recombinant population began to divide. This was far earlier than would have been predicted on the basis of 220 receptors per haploid cell. Moreover, there was a lag between the appearance of colicin resistance and the appearance of resistance to killing by phage BF23, and hence a period of time during which some arg+ recombinant cells were sensitive to the phage but resistant to the colicin. Colicin E3 added to cells during this period of time protected against phage killing, indicating that the colicin-resistant cells still had receptors capable of binding colicin on their surface. The modification of the phenotypic expression of colicin and phage resistance by inhibitors of deoxyribonucleic acid, ribonucleic acid, and protein synthesis was also investigated. The results obtained indicate that the receptor protein coded for by the bfe locus can exist on the cell surface in several different functional states.     

Nucleotide sequence of the colicin B activity gene cba: consensus pentapeptide among TonB-dependent colicins and receptors.

Colicin B formed by Escherichia coli kills sensitive bacteria by dissipating the membrane potential through channel formation. The nucleotide sequence of the structural gene (cba) which encodes colicin B and of the upstream region was determined. A polypeptide consisting of 511 amino acids was deduced from the open reading frame. The active colicin had a molecular weight of 54,742. The carboxy-terminal amino acid sequence showed striking homology to the corresponding channel-forming region of colicin A. Of 216 amino acids, 57% were identical and an additional 19% were homologous. In this part 66% of the nucleotides were identical in the colicin A and B genes. This region contained a sequence of 48 hydrophobic amino acids. Sequence homology to the other channel-forming colicins, E1 and I, was less pronounced. A homologous pentapeptide was detected in colicins B, M, and I whose uptake required TonB protein function. The same consensus sequence was found in all outer membrane proteins involved in the TonB-dependent uptake of iron siderophores and of vitamin B12. Upstream of cba a sequence comprising 294 nucleotides was identical to the sequence upstream of the structural gene of colicin E1, with the exception of 43 single-nucleotide replacements, additions, or deletions. Apparently, the region upstream of colicins B and E1 and the channel-forming sequences of colicins A and B have a common origin.     

Uptake across the cell envelope and insertion into the inner membrane of ion channel-forming colicins in E coli.

Pore-forming colicins exert their lethal effect on E coli through formation of a voltage-dependent channel in the inner (cytoplasmic-membrane) thus destroying the energy potential of sensitive cells. Their mode of action appears to involve 3 steps: i) binding to a specific receptor located in the outer membrane; ii) translocation across this membrane; iii) insertion into the inner membrane. Colicin A has been used as a prototype of pore-forming colicins. In this review, the 3 functional domains of colicin A respectively involved in receptor binding, translocation and pore formation, are defined. The components of sensitive cells implicated in colicin uptake and their interactions with the various colicin A domains are described. The 3-dimensional structure of the pore-forming domain of colicin A has been determined recently. This structure suggests a model of insertion into the cytoplasmic membrane which is supported by model membrane studies. The role of the membrane potential in channel functioning is also discussed.     

Studies of colicin action on wall-less stable L-forms of Escherichia coli. I. Degree of attachment and of killing effect on rods and stable L-form cells.

Escherichia coli strains B and K12 W 1655 F+ are able to bind more lethal units of colicins E2, E3, G, H, Ia, and K+ X per one stable L-form cell (of the protoplast type) than per one rod cell; colicin D is bound in a higher amount on E. coli B rods. This pattern remains unchanged, if the same colicins are attached on chloroform-killed cells of both forms. Rods of both E. coli strains are more sensitive to colicins D, E2, E3, K + X (as--in the strain B--to colicin Ia) than cells of the respective L-forms. In the strain W 1655 F+ both cell forms are equally highly sensitive to colicin Ia. The stable L-forms of both strains are much more sensitive to colicins G and H than the rods. Thus the Gram-negative cell wall decreases the probability of a colicin molecule to get attached to its receptor in the cytoplasmic membrane. On the other hand, in E. coli cells the attachment of most colicin molecules to the wall receptors increases the probability of their biological effect. There is no such effect of the wall-attachment on the action of colicins G or H. The strain B is tolerant to colicin E2, while being resistant to E3; thus the cytoplasmic membrane receptor sites for them are not identical.     

Colicin occlusion of OmpF and TolC channels: outer membrane translocons for colicin import

The interaction of colicins with target cells is a paradigm for protein import. To enter cells, bactericidal colicins parasitize Escherichia coli outer membrane receptors whose physiological purpose is the import of essential metabolites. Colicins E1 and E3 initially bind to the BtuB receptor, whose beta-barrel pore is occluded by an N-terminal globular "plug". The x-ray structure of a complex of BtuB with the coiled-coil BtuB-binding domain of colicin E3 did not reveal displacement of the BtuB plug that would allow passage of the colicin (Kurisu, G., S. D. Zakharov, M. V. Zhalnina, S. Bano, V. Y. Eroukova, T. I. Rokitskaya, Y. N. Antonenko, M. C. Wiener, and W. A. Cramer. 2003. Nat. Struct. Biol. 10:948-954). This correlates with the inability of BtuB to form ion channels in planar bilayers, shown in this work, suggesting that an additional outer membrane protein(s) is required for colicin import across the outer membrane. The identity and interaction properties of this OMP were analyzed in planar bilayer experiments.OmpF and TolC channels in planar bilayers were occluded by colicins E3 and E1, respectively, from the trans-side of the membrane. Occlusion was dependent upon a cis-negative transmembrane potential. A positive potential reversibly opened OmpF and TolC channels. Colicin N, which uses only OmpF for entry, occludes OmpF in planar bilayers with the same orientation constraints as colicins E1 and E3. The OmpF recognition sites of colicins E3 and N, and the TolC recognition site of colicin E1, were found to reside in the N-terminal translocation domains. These data are considered in the context of a two-receptor translocon model for colicin entry into cells.     

Binding domains of colicins E1, E2 and E3 in the receptor protein btub ofEscherichia coli

Eight reagents specifically modifying amino acids were applied to cells of a standardEscherichia coli colicin indicator strain to followin vivo changes of its binding capacity for colicins E1–E3 and hence the binding domains (epitopes) for them in the outer membrane receptor protein BtuB. The effect of these reagents was also investigated in a mutant strain carrying an extensive BtuB deletion. The following differences of the binding epitopes could be ascertained.Colicin E1: Blockage of OH-groups, just as N-substitution of His and modification of Arg and Trp enhance binding of colicin E1. In the deleted receptor, also abolition of carboxylic anion bonds enhances its affinity for colicin E1. It follows that colicin E1 is bound, most of all, to the hydrophobic domain A (loops 1+2) of BtuB.Colicins E2 and E3: both exert rather analogous binding parameters. In contrast to E1, O-substitution of Ser and Thr dramatically decreases the E2 and E3 binding, similarly to modification of Lys. There is also a clear difference in the binding affinity of the domain for E2 and/or E3 and for E1 following modifications of their Arg and His. Colicins E2 and E3 are rather bound to the hydrophilic domain B (loops 5–7) of the receptor. In this respect, interactions of colicins E2 and E3 with deeper parts of A and B domains (Trp, several Arg, Lys and His residues) exhibited subtle differences. Acidic pH (4.5–6.0) shows a positive, while pH 7.0–8.5 a rather negative impact on the receptor-binding function for the colicins. It was clearly demonstrated that there is just a partial difference between the binding behavior of colicins E1, E2 and/or E3.     

Daring to be different: colicin N finds another way

The mechanisms by which colicins, protein toxins produced by Escherichia coli, kill other E. coli, have become much better understood in recent years. Most colicins initially bind to an outer membrane protein receptor, and then search for a separate nearby outer membrane protein translocator that serves as a pathway into target cells. Many colicins use the outer membrane porin, OmpF, as that translocator, while using a different primary receptor. Colicin N is unique among known colicins in that only OmpF had been identified as being required for uptake of the colicin and it was presumed to somehow serve as both receptor and translocator. Genetic screens also identified a number of genes required for lipopolysaccharide (LPS) synthesis as uniquely required for killing by colicin N, but not by other colicins. Johnson et al. show that the receptor‐binding domain of colicin N binds to LPS, and does not require OmpF for that binding. LPS of a minimal length is required for binding, explaining the requirement for specific elements of the LPS biosynthetic pathway. For colicin N, the receptor‐binding domain does not recognize a protein, but rather the most abundant component of the outer membrane itself, LPS.     

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.     

Effects of Colicins E1 and K on Permeability to Magnesium and Cobaltous Ions

The energy-dependent exchange of intracellular Mg(2+) with extracellular Mg(2+) or Co(2+) is inhibited by colicin E1 and, less strongly, by colicin K. Treatment with either colicin causes a net loss of intracellular Mg(2+). This loss begins immediately in cells treated with colicin E1, but in colicin K-treated cells the onset of Mg(2+) loss is delayed 1 to 10 min, depending upon the temperature and the multiplicity of colicin K. Both colicins differ from chemical inhibitors of energy-yielding metabolism; energy poisons block transport of Mg(2+) and Co(2+), but both colicins increase passive permeability to Mg(2+) and Co(2+). Inhibitors of energy-yielding metabolism (and of Mg(2+) exchange) block the initiation of Mg(2+) loss by either colicin, but do not stop colicin-promoted efflux once it has begun. Colicin E1 added before colicin K prevents the more rapid Mg(2+) efflux characteristic of colicin K-treated cells. Quantitative comparisons of the effects of colicins E1 and K upon permeability to Mg(2+) and Co(2+) lead us to conclude that the two colicins are not identical in their mode of action.     

Colicin E2 is still in contact with its receptor and import machinery when its nuclease domain enters the cytoplasm

Colicins reach their targets in susceptible Escherichia coli strains through two envelope protein systems: the Tol system is used by group A colicins and the TonB system by group B colicins. Colicin E2 (ColE2) is a cytotoxic protein that recognizes the outer membrane receptor BtuB. After gaining access to the cytoplasmic membrane of sensitive Escherichia coli cells, ColE2 enters the cytoplasm to cleave DNA. After binding to BtuB, ColE2 interacts with the Tol system to reach its target. However, it is not known if the entire colicin or only the nuclease domain of ColE2 enters the cell. Here I show that preincubation of ColE2 with Escherichia coli cells prevents binding and translocation of pore-forming colicins of group A but not of group B. This inhibition persisted even when cells were incubated with ColE2 for 30 min before the addition of pore-forming colicins, indicating that ColE2 releases neither its receptor nor its translocation machinery when its nuclease domain enters the cells. These competition experiments enabled me to estimate the time required for ColE2 binding to its receptor and translocation.     

Crystal structure of the cytotoxic bacterial protein colicin B at 2.5 A resolution

Colicin B (55 kDa) is a cytotoxic protein that recognizes the outer membrane transporter, FepA, as a receptor and, after gaining access to the cytoplasmic membranes of sensitive Escherichia coli cells, forms a pore that depletes the electrochemical potential of the membrane and ultimately results in cell death. To begin to understand the series of dynamic conformational changes that must occur as colicin B translocates from outer membrane to cytoplasmic membrane, we report here the crystal structure of colicin B at 2.5 A resolution. The crystal belongs to the space group C2221 with unit cell dimensions a = 132.162 A, b = 138.167 A, c = 106.16 A. The overall structure of colicin B is dumbbell shaped. Unlike colicin Ia, the only other TonB-dependent colicin crystallized to date, colicin B does not have clearly structurally delineated receptor-binding and translocation domains. Instead, the unique N-terminal lobe of the dumbbell contains both domains and consists of a large (290 residues), mostly beta-stranded structure with two short alpha-helices. This is followed by a single long ( approximately 74 A) helix that connects the N-terminal domain to the C-terminal pore-forming domain, which is composed of 10 alpha-helices arranged in a bundle-type structure, similar to the pore-forming domains of other colicins. The TonB box sequence at the N-terminus folds back to interact with the N-terminal lobe of the dumbbell and leaves the flanking sequences highly disordered. Comparison of sequences among many colicins has allowed the identification of a putative receptor-binding domain.     

Transport of vitamin B12 in Escherichia coli: energy dependence.

This paper presents some evidence that the osmotic shock-sensitive, energy-dependent transfer of vitamin B12 from outer membrane receptor sites into the interior of cells of Escherichia coli requires an energized inner membrane, without obligatory intermediation of adenosine 5'-triphosphate (ATP). The experiments measured the effects of glucose, D-lactate, anaerobiosis, arsenate, cyanide, and 2,4-dinitrophenol upon the rates of B12 transport by starved cells of E. coli KBT001, which possesses a functional Ca2+, Mg2+-stimulated adenosine triphosphatase (Ca,MgATPase), and of E. coli AN120, which lacks this enzyme. Both strains were able to utilize glucose and D-lactate aerobically to potentiate B12 transport, indicating that the Ca,MgATPase was not essential for this process. When respiratory electron transport was blocked, either by cyanide or by anaerobic conditions, and the primary source of energy for the cells was presumably ATP from glucose fermentation, the rate of B12 transport was much reduced in E. coli AN120 but not in E.coli KBT001. These results support the view that the CaMgATPase can play a role in B12 transport but only when the energy for this process must be derived from ATP. The results of experiments with arsenate also supported the conclusion that the generation of phosphate bond energy was not absolutely required for B12 transport.     

The colicin Ia receptor,Cir, is also the translocator for colicin Ia

Colicin Ia, a channel‐forming bactericidal protein, uses the outer membrane protein, Cir, as its primary receptor. To kill Escherichia coli, it must cross this membrane. The crystal structure of Ia receptor‐binding domain bound to Cir, a 22‐stranded plugged β‐barrel protein, suggests that the plug does not move. Therefore, another pathway is needed for the colicin to cross the outer membrane, but no ‘second receptor’ has ever been identified for TonB‐dependent colicins, such as Ia. We show that if the receptor‐binding domain of colicin Ia is replaced by that of colicin E3, this chimera effectively kills cells, provided they have the E3 receptor (BtuB), Cir, and TonB. This is consistent with wild‐type Ia using one Cir as its primary receptor (BtuB in the chimera) and a second Cir as the translocation pathway for its N‐terminal translocation (T) domain and its channel‐forming C‐terminal domain. Deletion of colicin Ia's receptor‐binding domain results in a protein that kills E. coli, albeit less effectively, provided they have Cir and TonB. We show that purified T domain competes with Ia and protects E. coli from being killed by it. Thus, in addition to binding to colicin Ia's receptor‐binding domain, Cir also binds weakly to its translocation domain.