Deletion analyses of the peptidoglycan-associated lipoprotein Pal reveals three independent binding sequences including a TolA box

The Tol-Pal system of the Escherichia coli cell envelope is composed of five proteins. TolQ, TolR and TolA form a complex in the inner membrane, whereas TolB is a periplasmic protein interacting with Pal, the peptidoglycan-associated lipoprotein anchored to the outer membrane. This system is required for outer membrane integrity and has been shown to form a trans-envelope bridge linking inner and outer membranes. The TolA-Pal interaction plays an important role in the function of this system and has been found to depend on the proton motive force and the TolQ and TolR proteins. The Pal lipoprotein interacts with many components, such as TolA, TolB, OmpA, the major lipoprotein and the murein layer. In this study, six pal deletions were constructed. The analyses of the resulting Pal protein functions and interactions defined an N-terminal region of 40 residues, which can be deleted without any cell-damaging effect, and three independent regions required for its interaction with TolA, OmpA and TolB or the peptidoglycan. The analyses of the integrity of the cells producing the various Pal lipoproteins revealed strong outer membrane destabilization only when binding regions were deleted. Furthermore, a conserved polypeptide sequence located downstream of the peptidoglycan binding motif of Pal was required for the TolA-Pal interaction and for the maintenance of outer membrane stability.     

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.     

TolB protein of Escherichia coli K-12 interacts with the outer membrane peptidoglycan-associated proteins Pal, Lpp and OmpA

The Tol–Pal proteins of Escherichia coli are involved in maintaining outer membrane integrity. Transmembrane domains of TolQ, TolR and TolA interact in the cytoplasmic membrane, while TolB and Pal form a complex near the outer membrane. TolB and the central domain of TolA interact in vitro with the outer membrane porins. In this study, both genetic and biochemical analyses were carried out to analyse the links between TolB, Pal and other components of the cell envelope. It was shown that TolB could be cross-linked in vivo with Pal, OmpA and Lpp, while Pal was associated with TolB and OmpA. The isolation of pal and tolB mutants disrupting some interactions between these proteins represents a first approach to characterizing the residues contributing to the interactions. We propose that TolB and Pal are part of a multiprotein complex that links the peptidoglycan to the outer membrane. The Tol–Pal proteins might form transenvelope complexes that bring the two membranes into close proximity and help some outer membrane components to reach their final destination.     

Identification by genetic suppression of Escherichia coli TolB residues important for TolB-Pal interaction

The Tol-Pal system of Escherichia coli is involved in maintaining outer membrane stability. Mutations in tolQ, tolR, tolA, tolB, or pal genes result in sensitivity to bile salts and the leakage of periplasmic proteins. Moreover, some of the tol genes are necessary for the entry of group A colicins and the DNA of filamentous bacteriophages. TolQ, TolR, and TolA are located in the cytoplasmic membrane where they interact with each other via their transmembrane domains. TolB and Pal form a periplasmic complex near the outer membrane. We used suppressor genetics to identify the regions important for the interaction between TolB and Pal. Intragenic suppressor mutations were characterized in a domain of Pal that was shown to be involved in interactions with TolB and peptidoglycan. Extragenic suppressor mutations were located in tolB gene. The C-terminal region of TolB predicted to adopt a beta-propeller structure was shown to be responsible for the interaction of the protein with Pal. Unexpectedly, none of the suppressor mutations was able to restore a correct association between Pal and peptidoglycan, suggesting that interactions between Pal and other components such as TolB may also be important for outer membrane stability.     

Structural evidence that colicin A protein binds to a novel binding site of TolA protein in Escherichia coli periplasm

The Tol assembly of proteins is an interacting network of proteins located in the Escherichia coli cell envelope that transduces energy and contributes to cell integrity. TolA is central to this network linking the inner and outer membranes by interactions with TolQ, TolR, TolB, and Pal. Group A colicins, such as ColA, parasitize the Tol network through interactions with TolA and/or TolB to facilitate translocation through the cell envelope to reach their cytotoxic site of action. We have determined the first structure of the C-terminal domain of TolA (TolAIII) bound to an N-terminal ColA polypeptide (TA(53-107)). The interface region of the TA(53-107)-TolAIII complex consists of polar contacts linking residues Arg-92 to Arg-96 of ColA with residues Leu-375-Pro-380 of TolA, which constitutes a β-strand addition commonly seen in more promiscuous protein-protein contacts. The interface region also includes three cation-π interactions (Tyr-58-Lys-368, Tyr-90-Lys-379, Phe-94-Lys-396), which have not been observed in any other colicin-Tol protein complex. Mutagenesis of the interface residues of ColA or TolA revealed that the effect on the interaction was cumulative; single mutations of either partner had no effect on ColA activity, whereas mutations of three or more residues significantly reduced ColA activity. Mutagenesis of the aromatic ring component of the cation-π interacting residues showed Tyr-58 of ColA to be essential for the stability of complex formation. TA(53-107) binds on the opposite side of TolAIII to that used by g3p, ColN, or TolB, illustrating the flexible nature of TolA as a periplasmic hub protein.     

Proton motive force drives the interaction of the inner membrane TolA and outer membrane pal proteins in Escherichia coli

The Tol-Pal system of the Escherichia coli envelope is formed from the inner membrane TolQ, TolR and TolA proteins, the periplasmic TolB protein and the outer membrane Pal lipoprotein. Any defect in the Tol-Pal proteins or in the major lipoprotein (Lpp) results in the loss of outer membrane integrity giving hypersensitivity to drugs and detergents, periplasmic leakage and outer membrane vesicle formation. We found that multicopy plasmid overproduction of TolA was able to complement the membrane defects of an lpp strain but not those of a pal strain. This result indicated that overproduced TolA has an envelope-stabilizing effect when Pal is present. We demonstrate that Pal and TolA formed a complex using in vivo cross-linking and immunoprecipitation experiments. These results, together with in vitro experiments with purified Pal and TolA derivatives, allowed us to show that Pal interacts with the TolA C-terminal domain. We also demonstrate using protonophore, K+ carrier valinomycin, nigericin, arsenate and fermentative conditions that the proton motive force was coupled to this interaction.     

Role of TolR N-Terminal, Central, and C-Terminal Domains in Dimerization and Interaction with TolA and TolQ

The Tol-PAL system of Escherichia coli is a multiprotein system involved in maintaining the cell envelope integrity and is necessary for the import of some colicins and phage DNA into the bacterium. It is organized into two complexes, one near the outer membrane between TolB and PAL and one in the cytoplasmic membrane between TolA, TolQ, and TolR. In the cytoplasmic membrane, all of the Tol proteins have been shown to interact with each other. Cross-linking experiments have shown that the TolA transmembrane domain interacts with TolQ and TolR. Suppressor mutant analyses have localized the TolQ-TolA interaction to the first transmembrane domain of TolQ and have shown that the third transmembrane domain of TolQ interacts with the transmembrane domain of TolR. To get insights on the composition of the cytoplasmic membrane complex and its possible contacts with the outer membrane complex, we focused our attention on TolR. Cross-linking and immunoprecipitation experiments allowed the identification of Tol proteins interacting with TolR. The interactions of TolR with TolA and TolQ were confirmed, TolR was shown to dimerize, and the resulting dimer was shown to interact with TolQ. Deletion mutants of TolR were constructed, and they allowed us to determine the TolR domains involved in each interaction. The TolR transmembrane domain was shown to be involved in the TolA-TolR and TolQ-TolR interactions, while TolR central and C-terminal domains appeared to be involved in TolR dimerization. The role of the TolR C-terminal domain in the TolA-TolR interaction and its association with the membranes was also demonstrated. Furthermore, phenotypic studies clearly showed that the three TolR domains (N terminal, central, and C terminal) and the level of TolR production are important for colicin A import and for the maintenance of cell envelope integrity.     

Interaction between two major outer membrane proteins of Escherichia coli: the matrix protein and the lipoprotein.

The affinity to the matrix protein, one of the major outer membrane proteins of Escherichia coli, for the peptidoglycan was examined of extracting the cell envelope complex at 55 degrees C and 2% sodium dodecyl sulfate containing different amounts of NaCl. It was found that the matrix protein was extracted from the peptidoglycan of a mutant strain (lpo) that lacks another major membrane protein, the lipoprotein, at a lower NaCl concentration than was the matrix protein of the wild-type cell (lpo+). When the envelope fraction of the wild-type strain was treated with trypsin, which is known to cleave the bound-form lipoprotein from the peptidoglycan, the affinity of the matrix protein for the peptidoglycan decreased to the same level as that of the affinity of the matrix protein for the peptidoglycan of the mutant strain. It was further shown that the free-form lipoprotein was also retained in the matrix protein-peptidoglycan complex, although the extent of retention of the free form of the lipoprotein was less than that of the matrix protein. These results indicate that both the free and the bound forms of the lipoprotein are closely associated with the matrix protein and that the bound form of the lipoprotein plays and important role in the association between the matrix protein and the peptidoglycan.     

The Tol proteins of Escherichia coli and their involvement in the translocation of group A colicins

The Tol proteins are involved in outer membrane stability of Gram-negative bacteria. The TolQRA proteins form a complex in the inner membrane while TolB and Pal interact near the outer membrane. These two complexes are transiently connected by an energy-dependent interaction between Pal and TolA. The Tol proteins have been parasitized by group A colicins for their translocation through the cell envelope. Recent advances in the structure and energetics of the Tol system, as well as the interactions between the N-terminal translocation domain of colicins and the Tol proteins are presented.     

The N-terminal domain of colicin E3 interacts with TolB which is involved in the colicin translocation step

Colicins use two envelope multiprotein systems to reach their cellular target in susceptible cells of Escherichia coli : the Tol system for group A colicins and the TonB system for group B colicins. The N-terminal domain of colicins is involved in the translocation step. To determine whether it interacts in vivo with proteins of the translocation system, constructs were designed to produce and export to the cell periplasm the N-terminal domains of colicin E3 (group A) and colicin B (group B). Producing cells became specifically tolerant to entire extracellular colicins of the same group. The periplasmic N-terminal domains therefore compete with entire colicins for proteins of the translocation system and thus interact in situ with these proteins on the inner side of the outer membrane. In vivo cross-linking and co-immunoprecipitation experiments in cells producing the colicin E3 N-terminal domain demonstrated the existence of a 120 kDa complex containing the colicin domain and TolB. After in vitro cross-linking experiments with these two purified proteins, a 120 kDa complex was also obtained. This suggests that the complex obtained in vivo contains exclusively TolB and the colicin E3 domain. The N-terminal domain of a translocation-defective colicin E3 mutant was found to no longer interact with TolB. Hence, this interaction must play an important role in colicin E3 translocation.     

Timing of TolA and TolQ Recruitment at the Septum Depends on the Functionality of the Tol-Pal System

Efficient cell division of Gram-negative bacteria requires the presence of the Tol-Pal system to coordinate outer membrane (OM) invagination with inner membrane invagination (IM) and peptidoglycan (PG) remodeling. The Tol-Pal system is a trans-envelope complex that connects the three layers of the cell envelope through an energy-dependent process. It is composed of the three IM proteins, TolA, TolQ and TolR, the periplasmic protein TolB and the OM lipoprotein Pal. The proteins of the Tol-Pal system are dynamically recruited to the cell septum during cell division. TolA, the central hub of the Tol-Pal system, has three domains: a transmembrane helix (TolA₁), a long second helical periplasmic domain (TolA₂) and a C-terminal globular domain (TolA₃). The TolQR complex uses the PMF to energize TolA, allowing its cyclic interaction via TolA₃ with the OM TolB-Pal complex. Here, we confirm that TolA₂ is sufficient to address TolA to the site of constriction, whereas TolA₁ is recruited by TolQ. Analysis of the protein localization as function of the bacterial cell age revealed that TolA and TolQ localize earlier at midcell in the absence of the other Tol-Pal proteins. These data suggest that TolA and TolQ are delayed from their septal recruitment by the multiple interactions of TolA with TolB-Pal in the cell envelope providing a new example of temporal regulation of proteins recruitment at the septum.     

The Tol/Pal system function requires an interaction between the C-terminal domain of TolA and the N-terminal domain of TolB

The Tol/Pal system of Escherichia coli is composed of the YbgC, TolQ, TolA, TolR, TolB, Pal and YbgF proteins. It is involved in maintaining the integrity of the outer membrane, and is required for the uptake of group A colicins and DNA of filamentous bacteriophages. To identify new interactions between the components of the Tol/Pal system and gain insight into the mechanism of colicin import, we performed a yeast two-hybrid screen using the different components of the Tol/Pal system and colicin A. Using this system, we confirmed the already known interactions and identified several new interactions. TolB dimerizes and the periplasmic domain of TolA interacts with YbgF and TolB. Our results indicate that the central domain of TolA (TolAII) is sufficient to interact with YbgF, that the C-terminal domain of TolA (TolAIII) is sufficient to interact with TolB, and that the amino terminal domain of TolB (D1) is sufficient to bind TolAIII. The TolA/TolB interaction was confirmed by cross-linking experiments on purified proteins. Moreover, we show that the interaction between TolA and TolB is required for the uptake of colicin A and for the membrane integrity. These results demonstrate that the TolA/TolB interaction allows the formation of a trans-envelope complex that brings the inner and outer membranes in close proximity.     

Trimeric structure and localization of the major lipoprotein in the cell surface of Escherichia coli

A hybrid gene consisting of the ompF promoter, the coding regions for the signal peptide, and the Ala-Glu residue of the OmpF NH2 terminus and the coding region for the major outer membrane lipoprotein devoid of the NH2-terminal cysteine residue was constructed. Escherichia coli carrying the cloned gene produced the predicted hybrid protein that is the same as the major lipoprotein except that the diacyl glycerylcysteine residue at the NH2 terminus is replaced by the Ala-Glu residue. The hybrid protein was localized in the periplasmic space as a trimer with a noncovalent interaction in addition to the previously known covalent interaction with the peptidoglycan. These results strongly indicate that the major lipoprotein exists as a trimer in the periplasmic space with covalent and noncovalent interactions with the peptidoglycan layer through the protein domain on one side and with the hydrophobic interaction with the outer membrane through the lipid domain on the other side. The trimeric structure of the lipoprotein was directly demonstrated by the chemical cross-linking of the native lipoprotein with both cleavable and uncleavable reagents. The cross-linking study also revealed interaction between the lipoprotein and the OmpA protein, a major outer membrane protein.     

Molecular assembly of the lipoprotein trimer on the peptidoglycan layer of Escherichia coli

The molecular assembly of the major outer membrane lipoprotein on the peptidoglycan layer was studied using two hybrid genes coding for different OmpF-lipoprotein hybrid proteins. One gene codes for a "lipoprotein" in which the diacylglyceryl cysteine residue is replaced with the Ala-Glu residue of the NH2 terminus of the OmpF protein (hybrid protein I). The other gene codes for the lipid-free "lipoprotein" from which the COOH-terminal lysine residue was further deleted (hybrid protein II). Hybrid protein I existed as a trimer. A significant portion of it was found to be composed of only the free form, which was noncovalently associated with the peptidoglycan layer. The purified hybrid protein I trimer was dissociated into the subunit in the presence of guanidine-HCl and reassociated on dialysis. Both the native and reassociated trimers were bound to the lipoprotein-free peptidoglycan layer. No enhancement of the binding was observed when the reassociation reaction was carried out simultaneously. Hybrid protein II, on the other hand, did not exhibit association with peptidoglycan in both the cellular fractionation and in vitro binding experiments, although it existed as a trimer. It is concluded that 1) the protein domain of the lipoprotein exists as a trimer which is noncovalently as well as covalently associated with the peptidoglycan layer and 2) although the deletion of the COOH terminal lysine residue did not interfere with the trimerization, it interfered with the noncovalent interaction with the peptidoglycan layer.     

Structural and guanosine triphosphate/diphosphate requirements for transit peptide recognition by the cytosolic domain of the chloroplast outer envelope receptor, Toc34

Toc34 is a transmembrane protein located in the outer envelope membrane of chloroplasts and involved in transit peptide recognition. The cytosolic region of Toc34 reveals 34% alpha-helical and 26% beta-strand structure and is stabilized by intramolecular electrostatic interaction. Toc34 binds both chloroplast preproteins and isolated transit peptides in a guanosine triphosphate- (GTP-) dependent mechanism. In this study we demonstrate that the soluble, cytosolic domain of Toc34 (Toc34deltaTM) functions as receptor in vitro and is capable to compete with the import of the preprotein of the small subunit (preSSU) of ribulose-1,5-bisphosphate carboxylase-oxygenase into chloroplasts in a GTP-dependent manner. We have developed a biosensor assay to study the interaction of Toc34deltaTM with purified preproteins and transit peptides. The results are compared with the interactions of both a full-size preprotein and the transit peptide of preSSU with the translocon of the outer envelope of chloroplasts (Toc complex) in situ. Several mutants of the transit peptide of preSSU were evaluated to identify amino acid segments that are specifically recognized by Toc34. We present a model of how Toc34 may recognize the transit peptide and discuss how this interaction may facilitate interaction and translocation of preproteins via the Toc complex in vivo.     

Structure of the Escherichia coli TolB protein determined by MAD methods at 1.95 A resolution.

BACKGROUND: The periplasmic protein TolB from Escherichia coli is part of the Tol-PAL (peptidoglycan-associated lipoprotein) multiprotein complex used by group A colicins to penetrate and kill cells. TolB homologues are found in many gram-negative bacteria and the Tol-PAL system is thought to play a role in bacterial envelope integrity. TolB is required for lethal infection by Salmonella typhimurium in mice. RESULTS: The crystal structure of the selenomethionine-substituted TolB protein from E. coli was solved using multiwavelength anomalous dispersion methods and refined to 1. 95 A. TolB has a two-domain structure. The N-terminal domain consists of two alpha helices, a five-stranded beta-sheet floor and a long loop at the back of this floor. The C-terminal domain is a six-bladed beta propeller. The small, possibly mobile, contact area (430 A(2)) between the two domains involves residues from the two helices and the first and sixth blades of the beta propeller. All available genomic sequences were used to identify new TolB homologues in gram-negative bacteria. The TolB structure was then interpreted using the observed conservation pattern. CONCLUSIONS: The TolB beta-propeller C-terminal domain exhibits sequence similarities to numerous members of the prolyl oligopeptidase family and, to a lesser extent, to class B metallo-beta-lactamases. The alpha/beta N-terminal domain shares a structural similarity with the C-terminal domain of transfer RNA ligases. We suggest that the TolB protein might be part of a multiprotein complex involved in the recycling of peptidoglycan or in its covalent linking with lipoproteins.     

Allosteric β‐propeller signalling in TolB and its manipulation by translocating colicins

The Tol system is a five‐protein assembly parasitized by colicins and bacteriophages that helps stabilize the Gram‐negative outer membrane (OM). We show that allosteric signalling through the six‐bladed β‐propeller protein TolB is central to Tol function in Escherichia coli and that this is subverted by colicins such as ColE9 to initiate their OM translocation. Protein–protein interactions with the TolB β‐propeller govern two conformational states that are adopted by the distal N‐terminal 12 residues of TolB that bind TolA in the inner membrane. ColE9 promotes disorder of this ‘TolA box’ and recruitment of TolA. In contrast to ColE9, binding of the OM lipoprotein Pal to the same site induces conformational changes that sequester the TolA box to the TolB surface in which it exhibits little or no TolA binding. Our data suggest that Pal is an OFF switch for the Tol assembly, whereas colicins promote an ON state even though mimicking Pal. Comparison of the TolB mechanism to that of vertebrate guanine nucleotide exchange factor RCC1 suggests that allosteric signalling may be more prevalent in β‐propeller proteins than currently realized.     

Reconstitution of an ordered structure from major outer membrane constituents and the lipoprotein-bearing peptidoglycan sacculus of Escherichia coli.

An ordered hexagonal lattice structure with a lattice constant of about 7 nm was reconstituted on the entire surface of the lipoprotein-bearing peptidoglycan from outer membrane protein O-8 and lipopolysaccharide. The lattice structure resembled that observed in the cell envelope which had been treated with sodium dodecyl sulfate (Steven et al., J. Cell Biol. 72:292-301, 1977). The omission of either O-8 or lipopolysaccharide resulted in the failure of formation of the lattice structure. No ordered lattice was formed on the peptidoglycan lacking the bound form of the lipoprotein. In the absence of the lipoprotein-bearing peptidoglycan, O-8 and lipopolysaccharide assembled into vesicles with an ordered hexagonal lattice, the lattice constant of which was also about 7 nm. A preliminary experiment indicated that protein O-9 gave the same result as did O-8. These results strongly indicate that O-8 and/or O-9 and lipopolysaccharide provide the ordered framework of the outer membrane and that the bound form of the lipoprotein plays a role in the holding of the framework on the peptidoglycan layer.     

Interactions of outer membrane proteins O-8 and O-9 with peptidoglycan sacculus of Escherichia coli K-12.

The outer membrane proteins O-8 and O-9 were specifically bound to the peptidoglycan sacculus in sodium dodecyl sulfate (SDS) solution. Other cellular proteins failed to interact with the peptidoglycan sacculus under the same conditions. When the outer membrane was preheated in SDS solution, the binding did not take place. Optimum binding was observed at pH 8 in the presence of 5 mM Mg2+. A high concentration of sodium chloride strongly inhibited the binding. The effects of these factors on the bindings of O-8 and O-9 required neither the bound nor the free form of Braun's lipoprotein, nor was the binding of either protein necessary for the binding of the other. Proteins O-8 and O-9 were also found in the peptidoglycan sacculus when it was prepared from cells in SDS solution at 60 degrees. A dilution experiment showed that the complex was not an artifact. The mode of interaction between these proteins and peptidoglycan in the preparation was similar to that in the reassembled O-8-O-9-peptidoglycan complex, as judged from the sensitivity to sodium chloride and temperature. The physiological importance of the complex is discussed in relation to the assembly of the outer membrane on the cell surface.     

A PopZ‐linked apical recruitment assay for studying protein–protein interactions in the bacterial cell envelope

Most bacteria are surrounded by a complex cell envelope. As with many biological processes, studies of envelope assembly have benefited from cell‐based assays for detecting protein–protein interactions. These assays use simple readouts and lack a protein purification requirement, making them ideal for early stage investigations. The most widely used two‐hybrid interaction assay for proteins involved in envelope biogenesis is based on the reconstitution of adenylate cyclase activity from a split enzyme. Because adenylate cyclase is only functional in the cytoplasm, both protein fusions used in the assay must have a terminus located in this compartment. However, many envelope assembly factors are wholly extracytoplasmic. Detecting interactions involving such proteins using two‐hybrid systems has therefore been problematic. To address this issue, we developed a cytological assay in Escherichia coli based on PopZ from Caulobacter crescentus. Here, we demonstrate the utility of this PopZ‐Linked Apical Recruitment (POLAR) method for detecting interactions between proteins located in different cellular compartments. Additionally, we report that recruitment of an active peptidoglycan synthase to the cell pole is detrimental for E. coli and that interactions between proteins in the inner and outer membranes of the Gram‐negative envelope may provide a mechanism for recruiting protein complexes to subpolar sites.