The TolB protein interacts with the porins of Escherichia coli.

TolB is a periplasmic protein of the cell envelope Tol complex. It is partially membrane associated through an interaction with the outer membrane lipoprotein PAL (peptidoglycan-associated lipoprotein), which also belongs to the Tol system. The interaction of TolB with outer membrane porins of Escherichia coli was investigated with a purified TolB derivative harboring a six-histidine tag. TolB interacted with the trimeric porins OmpF, OmpC, PhoE, and LamB but not with their denatured monomeric forms or OmpA. These interactions took place both in the presence and in the absence of lipopolysaccharide. TolA, an inner membrane component of the Tol system, also interacts with the trimeric porins via its central periplasmic domain (R. Dérouiche, M. Gavioli, H. Bénédetti, A. Prilipov, C. Lazdunski, and R. Lloubès, EMBO J. 15:6408-6415, 1996). In the presence of the purified central domain of TolA (TolAIIHis), the TolB-porin complexes disappeared to form TolAIIHis-porin complexes. These results suggest that the interactions of TolA and TolB with porins might take place in vivo and might be concomitant events participating in porin assembly. They also suggest that the Tol system as a whole may be involved in porin assembly in the outer membrane.     

TolA central domain interacts with Escherichia coli porins.

TolA is an inner membrane protein with three domains: a transmembrane N-terminus and periplasmic central and C-terminal domains. The interaction of TolA with outer membrane porins of Escherichia coli was investigated. Western blot analyses of cell extracts with anti-TolA antibodies indicated that TolA forms high molecular weight complexes specifically with trimeric OmpF, OmpC, PhoE and LamB, but not with OmpA. The interaction of purified TolA domains with purified porins was also studied. TolA interacted with OmpF, PhoE and LamB porins via its central domain, but not with either their denatured monomeric forms or OmpA. Moreover, the presence or absence of lipopolysaccharides associated with trimeric porins did not modify the interactions. These results suggest that the specific interaction of TolA with outer membrane porins might be relevant to the function of Tol proteins.     

Colicin N binds to the periphery of its receptor and translocator, outer membrane protein F

Colicins kill Escherichia coli after translocation across the outer membrane. Colicin N displays an unusually simple translocation pathway, using the outer membrane protein F (OmpF) as both receptor and translocator. Studies of this binary complex may therefore reveal a significant component of the translocation pathway. Here we show that, in 2D crystals, colicin is found outside the porin trimer, suggesting that translocation may occur at the protein-lipid interface. The major lipid of the outer leaflet interface is lipopolysaccharide (LPS). It is further shown that colicin N binding displaces OmpF-bound LPS. The N-terminal helix of the pore-forming domain, which is not required for pore formation, rearranges and binds to OmpF. Colicin N also binds artificial OmpF dimers, indicating that trimeric symmetry plays no part in the interaction. The data indicate that colicin is closely associated with the OmpF-lipid interface, providing evidence that this peripheral pathway may play a role in colicin transmembrane transport.     

The unstructured domain of colicin N kills Escherichia coli

Bacteria often produce toxins which kill competing bacteria. Colicins, produced by and toxic to Escherichia coli bacteria are three‐domain proteins so efficient that one molecule can kill a cell. The C‐terminal domain carries the lethal activity and the central domain is required for surface receptor binding. The N‐terminal domain, required for translocation across the outer membrane, is always intrinsically unstructured. It has always been assumed therefore that the C‐terminal cytotoxic domain is required for the bactericidal activity. Here we report the unexpected finding that in isolation, the 90‐residue unstructured N‐terminal domain of colicin N is cytotoxic. Furthermore it causes ion leakage from cells but, unlike known antimicrobial peptides (AMPs) with this property, shows no membrane binding behaviour. Finally, its activity remains strictly dependent upon the same receptor proteins (OmpF and TolA) used by full‐length colicin N. This mechanism of rapid membrane disruption, via receptor mediated binding of a soluble peptide, may reveal a new target for the development of highly specific antibacterials.     

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.     

Mechanisms of colicin binding and transport through outer membrane porins

To kill Escherichia coli, toxic proteins, called colicins, pass through the permeability barrier created by the outer membrane (OM) of the bacterial cell envelope. We consider a variety of different colicins, including A, B, D, E1, E3, Ia, M and N, that penetrate through the porins OmpF, FepA, BtuB, Cir and FhuA, to subsequently interact with a few targets in the periplasm, including TolA, TolB, TolC and TonB. We review the mechanisms, demonstrated and postulated, by which such toxins enter bacterial cells, from the initial binding stage on the cell surface to the internalization reaction through the OM bilayer. Our discussions endeavor to answer two main questions: what is the origin of colicin-binding affinity and specificity, and after adsorption to OM porins, do colicin polypeptides translocate through porin channels, or enter by another, currently unknown pathway?     

Colicin import and pore formation: a system for studying protein transport across membranes?

Pore-forming colicins are a family of protein toxins (M_r40–70kDa) produced by Escherichia coli and related bacteria. They are bactericidal by virtue of their ability to form ion channels in the inner membrane of target cells. They provide a useful means of studying questions such as toxin action, polypeptide translocation across and into membranes, voltage-gated channels and receptor function. These colicins bind to a receptor in the outer membrane before being translocated across the cell envelope with the aid of helper proteins that belong to nutrient-uptake systems and the so-called‘Tol’proteins, the function of which has not yet been properly defined. A distinct domain appears to be associated with each of three steps (receptor binding, translocation and formation of voltage-gated channels). The Tol-dependent uptake pathway is described here. The structures and interactions of TolA, B, Q and R have by now been quite clearly defined. Transmembrane α-helix interactions are required for the functional assembly of the E. coli Tol complex, which is preferentially located at contact sites between the inner and outer membranes. The number of colicin translocation sites is about 1000 per cell. The role and the involvement of the OmpF porin (with colicins A and N) have been described in a recent study on the structural and functional interactions of a colicin-resistant mutant of OmpF. The X-ray crystal structure of the channel-forming fragment of colicin A and that of the entire colicin la have provided the basis for biophysical and site-directed muta-genesis studies. Thanks to this powerful combination, it has been established that the interaction with the receptor in the outer membrane leads to a very substantial conformational change, as a result of which the N-terminal domains of colicins interact with the lumen of the OmpF pore and then with the C-terminal domain of TolA. A molten globular conformation of colicins probably constitutes the intermediate translocation/insertion competent state. Once the pore has formed, the polypeptide chain spans the whole cell envelope. Three distinct steps occur in the last stage of the process: (i) fast binding of the C-terminal domain to the outer face of the cytoplasmic membrane; (ii) a slow insertion of the polypeptide chain into the outer face of the inner membrane in the absence of Δψ and (iii) a profound reorganization of the helix association, triggered by the transmembrane potential and resulting in the formation of the colicin channel.     

Discovery of critical Tol A-binding residues in the bactericidal toxin colicin N: a biophysical approach

Colicins translocate across the Escherichia coli outer membrane and periplasm by interacting with several receptors. After first binding to outer membrane surface receptors via their central region, they interact with TolA or TonB proteins via their N-terminal regions. Finally, the toxic C-terminal region is inserted into or across the cytoplasmic membrane. We have measured the binding of colicin N to TolA by isothermal titration microcalorimetry (ITC) and tryptophan fluorescence. The isolated N-terminal domain exhibits a higher affinity for TolA ( K _d = 1 μM) than does the whole colicin (18 μM), and similar behaviour has been observed when the N-terminal domain of the g3p protein of the bacteriophage fd, which also binds TolA, is examined in isolation and in situ . This may indicate a similar mechanism in which a cryptic TolA binding site is revealed after primary receptor binding. The isolated colicin N N-terminal domain appears to be unstructured in circular dichroism and fluorescence studies. We have used mutagenesis and ITC to characterize the TolA binding site and have shown it to be of a different sequence and much further from the N-terminus than previously thought.     

The colicin E3 outer membrane translocon: immunity protein release allows interaction of the cytotoxic domain with OmpF porin

The crystal structure previously obtained for the complex of BtuB and the receptor binding domain of colicin E3 forms a basis for further analysis of the mechanism of colicin import through the bacterial outer membrane. Together with genetic analysis and studies on colicin occlusion of OmpF channels, this implied a colicin translocon consisting of BtuB and OmpF that would transfer the C-terminal cytotoxic domain (C96) of colicin E3 through the Escherichia coli outer membrane. This model does not, however, explain how the colicin attains the unfolded conformation necessary for transfer. Such a conformation change would require removal of the immunity (Imm) protein, which is bound tightly in a complex with the folded colicin E3. In the present study, it was possible to obtain reversible removal of Imm in vitro in a single column chromatography step without colicin denaturation. This resulted in a mostly unordered secondary structure of the cytotoxic domain and a large decrease in stability, which was also found in the receptor binding domain. These structure changes were documented by near- and far-UV circular dichroism and intrinsic tryptophan fluorescence. Reconstitution of Imm in a complex with C96 or colicin E3 restored the native structure. C96 depleted of Imm, in contrast to the native complex with Imm, efficiently occluded OmpF channels, implying that the presence of tightly bound Imm prevents its unfolding and utilization of the OmpF porin for subsequent import of the cytotoxic domain.     

Porin threading drives receptor disengagement and establishes active colicin transport through Escherichia coli OmpF

Bacteria deploy weapons to kill their neighbours during competition for resources and to aid survival within microbiomes. Colicins were the first such antibacterial system identified, yet how these bacteriocins cross the outer membrane (OM) of Escherichia coli is unknown. Here, by solving the structures of translocation intermediates via cryo‐EM and by imaging toxin import, we uncover the mechanism by which the Tol‐dependent nuclease colicin E9 (ColE9) crosses the bacterial OM. We show that threading of ColE9’s disordered N‐terminal domain through two pores of the trimeric porin OmpF causes the colicin to disengage from its primary receptor, BtuB, and reorganises the translocon either side of the membrane. Subsequent import of ColE9 through the lumen of a single OmpF subunit is driven by the proton‐motive force, which is delivered by the TolQ‐TolR‐TolA‐TolB assembly. Our study answers longstanding questions, such as why OmpF is a better translocator than OmpC, and reconciles the mechanisms by which both Tol‐ and Ton‐dependent bacteriocins cross the bacterial outer membrane.     

OmpF enhances the ability of BtuB to protect susceptible Escherichia coli cells from colicin E9 cytotoxicity

The outer membrane (OM) vitamin B(12) receptor, BtuB, is the primary receptor for E group colicin adsorption to Escherichia coli. Cell death by this family of toxins requires the OM porin OmpF but its role remains elusive. We show that OmpF enhances the ability of purified BtuB to protect bacteria against the endonuclease colicin E9, demonstrating either that the two OM proteins form the functional receptor or that OmpF is recruited for subsequent translocation of the bacteriocin. While stable binary colicin E9-BtuB complexes could be readily shown in vitro, OmpF-containing complexes could not be detected, implying that OmpF association with the BtuB-colicin complex, while necessary, must be weak and/or transient in nature.     

Dynamic aspects of colicin N translocation through the Escherichia coli outer membrane.

Colicin N is a bacteriocin that kills sensitive Escherichia coli cells. After binding to the cell surface-exposed receptor, a short period exists when a significant number of the cell-associated colicin N molecules are sensitive to external enzymes. Two colicin N populations are discriminated by proteases: the susceptible pool bound to OmpF porin on the cell surface and another population corresponding to protease-inaccessible colicin N. During translocation, colicin N reaches the periplasmic space and proteolytic cleavage of the colicin occurs only when the outer membrane barrier is permeabilized.     

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.     

Minimum length requirement of the flexible N-terminal translocation subdomain of colicin E3

The 315-residue N-terminal T domain of colicin E3 functions in translocation of the colicin across the outer membrane through its interaction with outer membrane proteins including the OmpF porin. The first 83 residues of the T domain are known from structure studies to be disordered. This flexible translocation subdomain contains the TolB box (residues 34 to 46) that must cross the outer membrane in an early translocation event, allowing the colicin to bind to the TolB protein in the periplasm. In the present study, it was found that cytotoxicity of the colicin requires a minimum length of 19 to 23 residues between the C terminus (residue 46) of the TolB box and the end of the flexible subdomain (residue 83). Colicin E3 molecules of sufficient length display normal binding to TolB and occlusion of OmpF channels in vitro. The length of the N-terminal subdomain is critical because it allows the TolB box to cross the outer membrane and interact with TolB. It is proposed that the length constraint is a consequence of ordered structure in the downstream segment of the T domain (residues 84 to 315) that prevents its insertion through the outer membrane via a translocation pore that includes OmpF.     

A genetic engineering approach to study the mode of assembly of the OmpF porin in the envelope of E coli

Inducible hybrid genes encoding two large domains, a periplasmic domain consisting of the PhoS sequence and an outer membrane domain corresponding to various lengths of the OmpF mature sequence were constructed. The synthesized hybrid polypeptides are correctly processed during the early times of induction, their precursor forms being accumulated at later times. These hybrids restore sensitivity toward colicin A to ompF E coli B strain which suggests an outer membrane location. At least 2 of them are indeed localized in the outer membrane after immunogold labelling on ultrathin cryosections. Insertion of a hydrophobic sequence between PhoS and OmpF improves the trimerization and the assembly of the OmpF part. Only the hybrids presenting the last C-terminal 29 residues of OmpF are able to promote the colicin N killing action and to exhibit a trimeric conformation which is recognized by specific antibodies. Moreover, the deletion of the C-terminal region impairs the functional insertion of the OmpF domain; this indicates that the last membrane-spanning region of OmpF is necessary for the correct folding and orientation of the protein in the outer membrane.     

The TolA-recognition site of colicin N. ITC, SPR and stopped-flow fluorescence define a crucial 27-residue segment

Colicins translocate across the Escherichia coli outer membrane and periplasm by interacting with several receptors. After first binding to the outer membrane surface receptors via their central region, they interact with TolA or TonB proteins via their N-terminal region. Colicin N residues critical to TolA binding have been discovered, but the full extent of any colicin TolA site is unknown. We present, for the first time, a fully mapped TolA binding site for a colicin. It was determined through the use of alanine-scanning mutants, glutathione S-transferase fusion peptides and Biacore/fluorescence binding studies. The minimal TolA binding region is 27 residues and of similar size to the TolA binding region of bacteriophage g3p-D1 protein. Stopped-flow kinetic studies show that the binding to TolA follows slow association kinetics. The role of other E. coli Tol proteins in colicin translocation was also investigated. Isothermal titration microcalorimetry (ITC) and in vivo studies conclusively show that colicin N translocation does not require the presence of TolB. ITC also demonstrated colicin A interaction with TolB, and that colicin A in its native state does not interact with TolAII-III. Colicin N does not bind TolR-II. The TolA protein is shown to be unsuitable for direct immobilisation in Biacore analysis.     

Tol-dependent macromolecule import through the Escherichia coli cell envelope requires the presence of an exposed TolA binding motif

The Tol-Pal proteins of the cell envelope of Escherichia coli are required for maintaining outer membrane integrity. This system forms protein complexes in which TolA plays a central role by providing a bridge between the inner and outer membranes via its interaction with the Pal lipoprotein. The Tol proteins are parasitized by filamentous bacteriophages and group A colicins. The N-terminal domain of the Ff phage g3p protein and the translocation domains of colicins interact directly with TolA during the processes of import through the cell envelope. Recently, a four-amino-acid sequence in Pal has been shown to be involved in Pal's interaction with TolA. A similar motif is also present in the sequence of two TolA partners, g3p and colicin A. Here, a mutational study was conducted to define the function of these motifs in the binding activity and import process of TolA. The various domains were produced and exported to the bacterial periplasm, and their cellular effects were analyzed. Cells producing the g3p domain were tolerant to colicins and filamentous phages and had destabilized outer membranes, while g3p deleted of three residues in the motif was affected in TolA binding and had no effect on cell integrity or colicin or phage import. A conserved Tyr residue in the colicin A translocation domain was involved in TolA binding and colicin A import. Furthermore, in vivo and in vitro coprecipitation analyses demonstrated that colicin A and g3p N-terminal domains compete for binding to TolA.     

Biological and immunological comparisons of Enterobacter cloacae and Escherichia coli porins

Abstract Bacteriocin susceptibilities indicate that during cloacin DF13 uptake the F porin of Enterobacter cloacae plays a similar role to that reported for the OmpF porin of Escherichia coli during colicin A entry. The translocatory activities of these two porins during the bacteriocin uptake can be substituted by the porins D and OmpC, respectively, under conditions not requiring the receptor binding step. Using anti-peptide antibodies, a peptide located in the internal loop L3 of the Escherichia coli OmpF porin was identified in the D and F porins of Enterobacter cloacae. The results demonstrated the existence of a close relationship between porins in terms of both antigenic determinants and bacteriocin susceptibilities.     

A novel OmpY porin from Yersinia pseudotuberculosis: structure, channel-forming activity and trimer thermal stability

A novel OmpY porin was predicted based on the Yersinia pseudotuberculosis genome analysis. Whereas it has the different genomic annotation such as "outer membrane protein N" (ABS46310.1) in str. IP 31758 or "outer membrane protein C2, porin" (YP_070481.1) in str. IP32953, it might be warranted to rename the OmpN/OmpC2 to OmpY, "outer membrane protein Y", where letter "Y" pertained to Yersinia. Both phylogenetic analysis and genomic localization clearly support that the OmpY porin belongs to a new group of general bacterial porins. The recombinant OmpY protein with its signal sequence was overexpressed in porin-deficient Escherichia coli strain. The mature rOmpY was shown to insert into outer membrane as a trimer. The OmpY porin, isolated from the outer membrane, was studied employing spectroscopic, electrophoretic and bilayer lipid membranes techniques. The far UV CD spectrum of rOmpY was essentially identical to that of Y. pseudotuberculosis OmpF. The near UV CD spectrum of rOmpY was weaker and smoother than that of OmpF. The rOmpY single-channel conductance was 180 ± 20 pS in 0.1 M NaCl and was lower than that of the OmpF porin. As was shown by electrophoretic and bilayer lipid membrane experiments, the rOmpY trimers were less thermostable than the OmpF trimers. The porins differed in the trimer-monomer transition temperature by about 20°C. The three-dimensional structural models of the Y. pseudotuberculosis OmpY and OmpF trimers were generated and the intra- and intermonomeric interactions stabilizing the porins were investigated. The difference in the thermal stability of OmpY and OmpF trimers was established to correlate with the difference in intermonomeric polar contacts.     

Protein import into Escherichia coli: colicins A and E1 interact with a component of their translocation system.

Colicins are antibiotic proteins that kill sensitive Escherichia coli cells. Their mode of action involves three steps: binding to specific receptors located in the outer membrane, translocation across this membrane, and action on their targets. A specific colicin domain can be assigned to each of these steps. Colicins have been subdivided into two groups (A and B) depending on the proteins required for them to cross the external membrane. Plasmids were constructed which led to an overproduction of the Tol proteins involved in the import of group A colicins. In vitro binding of overexpressed Tol proteins to either Tol-dependent (group A) or TonB-dependent (group B) colicins was analyzed. The Tol dependent colicins A and E1 were able to interact with TolA but the TonB dependent colicin B was not. The C-terminal region of TolA, which is necessary for colicin uptake, was also found to be necessary for colicin A and E1 binding to occur. Furthermore, only the isolated N-terminal domain of colicin A, which is involved in the translocation step, was found to bind to TolA. These results demonstrate the existence of a correlation between the ability of group A colicins to translocate and their in vitro binding to TolA protein, suggesting that these interactions might be part of the colicin import process.