Genetic Analysis of the Colicin V Secretion Pathway

Colicin V (ColV) is peptide antibiotic secreted by Escherichia coli through a dedicated exporter composed of three proteins, CvaA, CvaB, and TolC. ColV secretion is independent of the E. coli general secretory pathway (Sec) but requires an N-terminal export signal specific for the CvaAB/TolC exporter. ColV secretion was characterized using genetic and biochemical methods. When the ColV N-terminal extension is replaced with the OmpA signal sequence, the Sec system can localize ColV to the periplasm. Periplasmic ColV is lethal to cells lacking the ColV immunity protein, Cvi. Based on this result, a genetic assay was designed to monitor for the presence of periplasmic ColV during normal CvaAB/TolC mediated secretion. Results indicate that low levels of ColV may be present in the periplasm during secretion. Precursor and mature ColV were also characterized from the wild-type system and in various exporter mutant backgrounds using immunoprecipitation. ColV processing is rapid in wild-type cells, and CvaA and CvaB are critical for processing to occur. In contrast, processing occurs normally, albeit more slowly, in a TolC mutant.     

Nucleotide-dependent dimerization of the C-terminal domain of the ABC transporter CvaB in colicin V secretion

The cytoplasmic membrane proteins CvaB and CvaA and the outer membrane protein TolC constitute the bacteriocin colicin V secretion system in Escherichia coli. CvaB functions as an ATP-binding cassette transporter, and its C-terminal domain (CTD) contains typical motifs for the nucleotide-binding and Walker A and B sites and the ABC signature motif. To study the role of the CvaB CTD in the secretion of colicin V, a truncated construct of this domain was made and overexpressed. Different forms of the CvaB CTD were found during purification and identified as monomer, dimer, and oligomer forms by gel filtration and protein cross-linking. Nucleotide binding was shown to be critical for CvaB CTD dimerization. Oligomers could be converted to dimers by nucleotide triphosphate-Mg, and nucleotide release from dimers resulted in transient formation of monomers, followed by oligomerization and aggregation. Site-directed mutagenesis showed that the ABC signature motif was involved in the nucleotide-dependent dimerization. The spatial proximity of the Walker A site and the signature motif was shown by disulfide cross-linking a mixture of the A530C and L630C mutant proteins, while the A530C or L630C mutant protein did not dimerize on its own. Taken together, these results indicate that the CvaB CTD formed a nucleotide-dependent head-to-tail dimer.     

Topology analysis of the colicin V export protein CvaA in Escherichia coli.

The antibacterial protein toxin colicin V is secreted from Escherichia coli cells by a dedicated export system that is a member of the multicomponent ATP-binding cassette (ABC) transporter family. At least three proteins, CvaA, CvaB, and TolC, are required for secretion via this signal sequence-independent pathway. In this study, the subcellular location and transmembrane organization of membrane fusion protein CvaA were investigated. First, a series of CvaA-alkaline phosphatase (AP) protein fusions was constructed. Inner and outer membrane fractionations of cells bearing these fusions indicated that CvaA is inner membrane associated. To localize the fusion junctions, the relative activities of the fusion proteins, i.e., the amounts of phosphatase activity normalized to the rate of synthesis of each protein, as well as the stability of each fusion, were determined. These results indicated that all of the fusion junctions occur on the same side of the inner membrane. In addition, the relative activities were compared with that of native AP, and the protease accessibility of the AP moieties in spheroplasts and whole cells was analyzed. The results of these experiments suggested that the fusion junctions occur within periplasmic regions of CvA. We conclude that CvaA is an inner membrane protein with a single transmembrane domain near its N terminus; the large C-terminal region extends into the periplasm. This study demonstrates the application of AP fusion analysis to elucidate the topology of a membrane-associated protein having only a single transmembrane domain.     

Functional complementation between bacterial MDR-like export systems: colicin V, alpha-hemolysin, and Erwinia protease.

The antibacterial protein Colicin V (ColV) is secreted from gram-negative bacteria by a signal sequence-independent pathway. The proteins that mediate the export of ColV share sequence similarities with components from other signal sequence-independent export systems such as those for alpha-hemolysin (Hly) and Erwinia protease (Prt). We report here that the intact HlyBD export system can export active ColV from Escherichia coli strains lacking the ColV export proteins CvaA and CvaB. The individual Hly export genes complement mutations in their respective ColV homologs, but do so at a lower efficiency. When CvaA or CvaB is expressed along with the intact HlyBD exporter, the Cva export protein interferes with export of ColV through the HlyBD system. Gene fusions and point mutations in the ColV structural gene were used to define signals in ColV recognized by the Hly exporter. An export signal in ColV recognized by HlyBD is localized to the amino-terminal 57 amino acids of the protein. In addition, mutations in the ColV export signal differentially affect export through CvaAB and HlyBD, suggesting differences in signal specificity between the Cva and Hly systems. The three Erwinia protease export proteins can also export active ColV, and interference is seen when CvaA or CvaB is expressed along with the intact Prt exporter. Functional complementation is not reciprocal; alpha-hemolysin is not exported through either the ColV system or the Prt system.     

Characterization of in-frame proteins encoded by cvaA, an essential gene in the colicin V secretion system: CvaA* stabilizes CvaA to enhance secretion.

Colicin V (ColV), an antibacterial peptide toxin, uses a dedicated signal sequence-independent export system for its extracellular secretion in Escherichia coli. The products of at least three genes (a chromosomal tolC gene and two plasmid-born cvaA and cvaB genes) are involved in this process. To characterize the gene products, the cvaA gene was subcloned and expressed under the control of T7 RNA polymerase promoter. Two in-frame proteins, CvaA and CvaA*, were expressed and identified. DNA sequences predicted that both proteins have two potential translational initiation sites. N-terminal peptide sequencing showed that the translation of CvaA starts from a TTG, 11 amino acids upstream of the previously proposed ATG initiation site. CvaA* is translated from an upstream ATG. Expression of both CvaA and CvaA* was induced by the iron chelator 2,2'-dipyridyl, indicating that cvaA is negatively regulated at least partially by Fur. CvaA*-depleted cells were found to secrete less ColV, based on reduced activity in the supernatant, than did wild type, which was recovered by the addition of a plasmid producing CvaA*. Interestingly, CvaA*-depleted and wild-type cells had similar levels of intracellular ColV activity. Translational fusions showed that the syntheses of ColV and CvaA are not affected by CvaA* depletion. However, CvaA in CvaA*-depleted cells was less stable than that in wild-type cells, indicating that CvaA* may directly or indirectly affect the stability of CvaA. We conclude that CvaA* is not essential for ColV secretion but that it enhances the ColV secretion by stabilizing the CvaA protein.     

Genetic analysis of an MDR-like export system: the secretion of colicin V.

The extracellular secretion of the antibacterial toxin colicin V is mediated via a signal sequence independent process which requires the products of two linked genes: cvaA and cvaB. The nucleotide sequence of cvaB reveals that its product is a member of a subfamily of proteins, involved in the export of diverse molecules, found in both eukaryotes and prokaryotes. This group of proteins, here referred to as the 'MDR-like' subfamily, is characterized by the presence of a hydrophobic region followed by a highly conserved ATP binding fold. By constructing fusions between the structural gene for colicin V, cvaC, and a gene for alkaline phosphatase, phoA, lacking its signal sequence, it was determined that 39 codons in the N-terminus of cvaC contained the structural information to allow CvaC-PhoA fusion proteins to be efficiently translocated across the plasma membrane of Escherichia coli in a CvaA/CvaB dependent fashion. This result is consistent with the location of point mutations in the cvaC gene which yielded export deficient colicin V. The presence of the export signal at the N-terminus of CvaC contrasts with the observed C-terminal location of the export signal for hemolysin, which also utilizes an MDR-like protein for its secretion. It was also found that the CvaA component of the colicin V export system shows amino acid sequence similarities with another component involved in hemolysin export, HlyD. The role of the second component in these systems and the possibility that other members of the MDR-like subfamily will also have corresponding second components are discussed. A third component used in both colicin V and hemolysin extracellular secretion is the E. coli host outer membrane protein, TolC.     

Differential effects of yfgL mutation on Escherichia coli outer membrane proteins and lipopolysaccharide

YfgL together with NlpB, YfiO, and YaeT form a protein complex to facilitate the insertion of proteins into the outer membrane of Escherichia coli. Without YfgL, the levels of OmpA, OmpF, and LamB are significantly reduced, while OmpC levels are slightly reduced. In contrast, the level of TolC significantly increases in a yfgL mutant. When cells are depleted of YaeT or YfiO, levels of all outer membrane proteins examined, including OmpC and TolC, are severely reduced. Thus, while the assembly pathways of various nonlipoprotein outer membrane proteins may vary through the step involving YfgL, all assembly pathways in Escherichia coli converge at the step involving the YaeT/YfiO complex. The negative effect of yfgL mutation on outer membrane proteins may in part be due to elevated sigma E activity, which has been shown to downregulate the synthesis of various outer membrane proteins while upregulating the synthesis of periplasmic chaperones, foldases, and lipopolysaccharide. The data presented here suggest that the yfgL effect on outer membrane proteins also stems from a defective assembly apparatus, leading to aberrant outer membrane protein assembly, except for TolC, which assembles independent of YfgL. Consistent with this view, the simultaneous absence of YfgL and the major periplasmic protease DegP confers a synthetic lethal phenotype, presumably due to the toxic accumulation of unfolded outer membrane proteins. The results support the hypothesis that TolC and major outer membrane proteins compete for the YaeT/YfiO complex, since mutations that adversely affect synthesis or assembly of major outer membrane proteins lead to elevated TolC levels.     

Hsp90 is essential for the synthesis and subsequent membrane association, but not the maintenance, of the Src-kinase p56(lck)

Tyrosine kinases of the Src family are synthesized as cytosolic proteins that subsequently translocate to membranes. Little is known of the mechanisms responsible for targeting these proteins to membranes, although a role for the cytosolic chaperone Hsp90 has been proposed. Here, we have studied the involvement of Hsp90 in the synthesis, membrane binding, and maintenance of the Src-kinase Lck. Using specific inhibitors of Hsp90, geldanamycin and radicicol, we found that functional Hsp90 is essential for the stability of newly synthesized, but not mature, Lck. Similar results were obtained for two other Src-kinases, c-Src and Lyn. In contrast, LckY505F and LckDeltaSH2, constitutively active Lck mutants lacking the C-terminal regulatory tyrosine or the entire Src homology 2 domain, respectively, required Hsp90 activity to stabilize the mature proteins. Lck synthesized in the absence of Hsp90 activity was degraded within 30-45 min. This unstable Lck was myristoylated normally but did not associate with membranes or CD4, interactions that normally start within minutes of the completion of Lck synthesis. A construct composed of the N-terminal unique domain of Lck fused to green fluorescent protein did not require Hsp90 activity during synthesis. In addition, this protein associated with membranes efficiently in the absence of Hsp90 activity. Together these data suggest that interaction with Hsp90 is necessary for the correct synthesis and subsequent membrane binding of Lck. However, Hsp90 does not appear to play a direct role in Lck membrane, or CD4, association.     

Initial steps of colicin E1 import across the outer membrane of Escherichia coli

Data suggest a two-receptor model for colicin E1 (ColE1) translocation across the outer membrane of Escherichia coli. ColE1 initially binds to the vitamin B(12) receptor BtuB and then translocates through the TolC channel-tunnel, presumably in a mostly unfolded state. Here, we studied the early events in the import of ColE1. Using in vivo approaches, we show that ColE1 is cleaved when added to whole cells. This cleavage requires the presence of the receptor BtuB and the protease OmpT, but not that of TolC. Strains expressing OmpT cleaved ColE1 at K84 and K95 in the N-terminal translocation domain, leading to the removal of the TolQA box, which is essential for ColE1's cytotoxicity. Supported by additional in vivo data, this suggests that a function of OmpT is to degrade colicin at the cell surface and thus protect sensitive E. coli cells from infection by E colicins. A genetic strategy for isolating tolC mutations that confer resistance to ColE1, without affecting other TolC functions, is also described. We provide further in vivo evidence of the multistep interaction between TolC and ColE1 by using cross-linking followed by copurification via histidine-tagged TolC. First, secondary binding of ColE1 to TolC is dependent on primary binding to BtuB. Second, alterations to a residue in the TolC channel interfere with the translocation of ColE1 across the TolC pore rather than with the binding of ColE1 to TolC. In contrast, a substitution at a residue exposed on the cell surface abolishes both binding and translocation of ColE1.     

Outer membrane proteome and its regulation networks in response to glucose concentration changes in Escherichia coli

Escherichia coli growth is a complicated process involved in many factors including the utilization of glucose. It has been reported that E. coli cell growth rate is closely related with glucose concentrations in the cell culture medium. However, the protein regulation networks in response to glucose concentration changes are largely unknown. In the present study, a sub-proteomic methodology has been utilized to characterize alterations of E. coli OM proteins in response to 0.02, 0.2 and 2% concentrations of glucose. In comparison with E. coli cells treated with 0.2% glucose concentration, downregulation of FhuE, FepA, CirA, TolC and OmpX and upregulation of LamB, FadL, OmpF, OmpT and Dps were detected in the E. coli cells treated with 0.02% glucose, and a decrease of TolC, LamB, OmpF, OmpT, OmpX, Dps and elevation of FhuE, FepA, CirA, YncD, FadL and MipA were found in 2% glucose. TolC, LamB and OmpT showed more important roles than other altered OM proteins. Furthermore, the interaction among these altered OM proteins was investigated, and protein interaction networks were characterized. In the networks, all proteins were interacted and regulated by others. TolC, LamB and Dps were the top three proteins that regulated more proteins than others, whereas CirA and OmpT were the top two proteins that were regulated by others. The protein networks could be modified correspondingly with the changes of glucose concentrations. The modifications included the addition of new OM proteins or the change of regulation direction. These findings suggest the important roles of the bacterial OM protein network in E. coli's responses to glucose concentration changes and other environment stresses.     

Expression and biochemical characterization of the periplasmic domain of bacterial outer membrane porin TdeA

TolC is an outer membrane porin protein and an essential component of drug efflux and type-I secretion systems in Gram-negative bacteria. TolC comprises a periplasmic alpha- helical barrel domain and a membrane-embedded beta-barrel domain. TdeA, a functional and structural homolog of TolC, is required for toxin and drug export in the pathogenic oral bacterium Actinobacillus actinomycetemcomitans. Here, we report the expression of the periplasmic domain of TdeA as a soluble protein by substitution of the membraneembedded domain with short linkers, which enabled us to purify the protein in the absence of detergent. We confirmed the structural integrity of the TdeA periplasmic domain by size-exclusion chromatography, circular dichroism spectroscopy, and electron microscopy, which together showed that the periplasmic domain of the TolC protein family can fold correctly on its own. We further demonstrated that the periplasmic domain of TdeA interacts with peptidoglycans of the bacterial cell wall, which supports the idea that completely folded TolC family proteins traverse the peptidoglycan layer to interact with inner membrane transporters.     

Real-time analysis of human immunodeficiency virus type 1 Env-mediated membrane fusion by fluorescence resonance energy transfer

Human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein (Env)-mediated membrane fusion occurs as a sequence of events that is triggered by CD4 binding to the Env gp120 subunit. In this study, we analyzed the dynamics of Env-mediated membrane fusion at the single-cell level using fluorescent fusion proteins and confocal laser fluorescent microscopy. Either enhanced cyan or yellow fluorescent protein (CFP and YFP, respectively) was fused to the end of the cytoplasmic regions of the HIV-1 receptors (CD4 and CCR5) and Env proteins. Real-time imaging of membrane fusion mediated by these recombinant proteins revealed that the kinetics of fusion in our system was faster than that previously reported. Analysis of the receptor interaction by fluorescence resonance energy transfer (FRET) at the single-cell level demonstrated a tendency for oligomerization of CD4-CD4, but not of CD4-CCR5, in the absence of Env-expressing cells. However, when Env-expressing cells attached to the receptor cells, FRET produced by CD4-CCR5 interaction was increased; the FRET intensity began to decline before the formation of the fusion pore. These changes in FRET may represent the temporal association of these receptors, triggered by gp120 binding, and their dissociation during the formation of the fusion pore. In addition, the FRET analysis of receptor interactions in the presence of fusion inhibitors showed that not only inhibitors acting on CCR5 but also the gp41-derived peptide T-20 interfered with CD4-CCR5 interaction during fusion. These data suggest that T-20 could affect the formation of Env-receptors complexes during the membrane fusion.     

Mutational Analysis of CvaA in the Highly Conserved Domain of the Membrane Fusion Protein Family

The antibacterial peptide toxin colicin V (ColV) uses a dedicated signal sequence-independent export system for its secretion in Escherichia coli that involves the products of three genes, cvaA, cvaB, and tolC in this process. As a member of the membrane fusion protein (MFP) family, the CvaA protein has been proposed to interact with an outer membrane protein TolC via its C-terminal hydrophobic domain. The importance of this domain, which is highly conserved throughout the members of MFP family, was analyzed by use of site-directed mutagenesis of missense or nonsense mutations with suppressors. All the nonsense mutations tested resulted in the loss of ColV secretion, indicating the importance of the C-terminus of CvaA, including the last 100 residue–hydrophilic domain. The missense mutations of several conserved amino acids have no drastic effects. On the other hand, when Glu-248, Ala-262, Thr-274, Leu-285, Gly-313, Ala-322, or Val-335 of CvaA protein was mutated, the secretion of ColV was greatly reduced in certain mutants. While some mutations resulted in structural instability, Glu-248 to Lys and Ala-322 to Gly proteins were relatively stable, but were not functional in ColV secretion. The results indicate that these conserved amino acids are important for the structure and functions of CvaA in the secretion of ColV. Received: 6 February 1999 / Accepted: 26 June 1999     

Cell-free synthesis of the torque-generating membrane proteins, PomA and PomB, of the Na+-driven flagellar motor in Vibrio alginolyticus

Flagellar motor proteins, PomA and PomB, are essential for converting the sodium motive force into rotational energy in the Na(+)-driven flagella motor of Vibrio alginolyticus. PomA and PomB, which are cytoplasmic membrane proteins, together comprise the stator complex of the motor and form a Na(+) channel. We tried to synthesize PomA and PomB by using the cell-free protein synthesis system, PURESYSTEM. We succeeded in doing so in the presence of liposomes, and showed an interaction between them using the pull-down assay. It seems likely that the proteins are inserted into liposomes and assembled spontaneously. The N-terminal region of in vitro synthesized PomB appeared to be lost, but this problem was suppressed by fusing GFP to the N-terminus of PomB or by mutagenesis at Pro-11 or Pro-12. A structural change of the N-terminal region of PomB by these modifications may prevent cleavage during protein synthesis in PURESYSTEM. The mutations did not affect the functioning of the motor. Using this system, biochemical analysis of PomA and PomB can be performed easily and efficiently.     

Identification and network of outer membrane proteins regulating streptomysin resistance in Escherichia coli

Bacterial Outer membrane (OM) proteins involved in antibiotic resistance have been reported. However, little is known about the OM proteins and their interaction network regulating streptomycin (SM) resistance. In the present study, a subproteomic approach was utilized to characterize OM proteins of Escherichia coli with SM resistance. TolC, OmpT and LamB were found to be up-regulated, and FadL, OmpW and a location-unknown protein Dps were down-regulated in the SM-resistant E. coli strain. These changes at the level of protein expression were validated using Western blotting. The possible roles of the altered proteins involved in the SM resistance were investigated using genetic modified strains with the deletion of these altered genes. It is found that decreased and elevated minimum inhibitory concentrations and survival capabilities of the gene deleted strains and their resistant strains, Delta tolC, Delta ompT, Delta dps, Delta tolC-R, Delta ompT-R, Delta dps-R and Delta fadL-R, were correlated with the changes of TolC, OmpT, Dps and FadL at the protein expression levels detected by 2-DE gels, respectively. The results may suggest that these proteins are the key OM proteins and play important roles in the regulation of SM resistance in E. coli. Furthermore, an interaction network of altered OM proteins involved in the SM resistance was proposed in this report. Of the six altered proteins, TolC may play a central role in the network. These findings may provide novel insights into mechanisms of SM resistance in E. coli.     

Interactions underlying assembly of the Escherichia coli AcrAB-TolC multidrug efflux system

The major Escherichia coli multidrug efflux pump AcrAB-TolC expels a wide range of antibacterial agents. Using in vivo cross-linking, we show for the first time that the antiporter AcrB and the adaptor AcrA, which form a translocase in the inner membrane, interact with the outer membrane TolC exit duct to form a contiguous proteinaceous complex spanning the bacterial cell envelope. Assembly of the pump appeared to be constitutive, occurring in the presence and absence of drug efflux substrate. This contrasts with substrate-induced assembly of the closely related TolC-dependent protein export machinery, possibly reflecting different assembly dynamics and degrees of substrate responsiveness in the two systems. TolC could be cross-linked independently to AcrB, showing that their large periplasmic domains are in close proximity. However, isothermal titration calorimetry detected no interaction between the purified AcrB and TolC proteins, suggesting that the adaptor protein is required for their stable association in vivo. Confirming this view, AcrA could be cross-linked independently to AcrB and TolC in vivo, and calorimetry demonstrated energetically favourable interactions of AcrA with both AcrB and TolC proteins. AcrB was bound by a polypeptide spanning the C-terminal half of AcrA, but binding to TolC required interaction of N- and C-terminal polypeptides spanning the lipoyl-like domains predicted to present the intervening coiled-coil to the periplasmic coils of TolC. These in vivo and in vitro analyses establish the central role of the AcrA adaptor in drug-independent assembly of the tripartite drug efflux pump, specifically in coupling the inner membrane transporter and the outer membrane exit duct.     

Importance of the adaptor (membrane fusion) protein hairpin domain for the functionality of multidrug efflux pumps

Drug efflux pumps of Gram-negative bacteria are tripartite export machineries located in the bacterial envelopes contributing to multidrug resistance. Protein structures of all three components have been determined, but the exact interaction sites are still unknown. We could confirm that the hybrid system composed of Pseudomonas aeruginosa channel tunnel OprM and the Escherichia coli inner membrane complex, formed by adaptor protein (membrane fusion protein) AcrA and transporter AcrB of the resistance nodulation cell division (RND) family, is not functional. However, cross-linking experiments show that the hybrid exporter assembles. Exchange of the hairpin domain of AcrA with the corresponding hairpin from adaptor protein MexA of P. aeruginosa restored the functionality. This shows the importance of the MexA hairpin domain for the functional interaction with the OprM channel tunnel. On the basis of these results, we have modeled the interaction of the hairpin domain and the channel tunnel on a molecular level for AcrA and TolC as well as MexA and OprM, respectively. The model of two hairpin docking sites per TolC protomer corresponding with hexameric adaptor proteins was confirmed by disulfide cross-linking experiments. The role of this interaction for functional efflux pumps is discussed.     

Identification and characterization of the TolC protein, an outer membrane protein from Escherichia coli

We used the cloned tolC gene to identify, locate, and purify its gene product. Strains carrying pPR13 or pPR42 overproduced a cell envelope protein (molecular weight, 52,000). A protein of the same molecular weight was identified in radioactively labeled minicells carrying pPR13; this protein was absent in pPR11-carrying minicells. This protein was the tolC gene product, since pPR11 differed from pPR13 in having a Tn10 insertion in the tolC gene. The protein seen in cell envelopes of whole cells (TolC protein) was found to exist in an aggregated state in the outer membrane; under conditions in which OmpC and OmpF were peptidoglycan associated, TolC protein was not likewise associated. Using these properties, we purified the TolC protein and determined the sequence of twelve amino acids from the amino-terminal end. The location of the TolC protein in the outer membrane was consistent with the proposed function for the tolC gene product as a processing protein in the outer membrane.     

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

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

Structure of TolC, the outer membrane component of the bacterial type I efflux system, derived from two-dimensional crystals

TolC is an outer membrane protein required for the export of virulence proteins and toxic compounds without a periplasmic intermediate. We show that TolC is an integral part of the translocator, interacting with inner membrane components, by demonstrating a need for TolC in protein export not only from intact cells but also from sphaeroplasts. To establish the structure of TolC, and thus gain information on how this might be achieved, the protein was purified from the Escherichia coli outer membrane, as a trimer, and crystallized in two-dimensional lattices by reconstitution in phospholipid bilayers. The projection structure at 12 Å resolution showed a threefold symmetric molecule of 58 Å outer diameter, and a single pool of stain filling its centre. Side views parallel to the membrane plane revealed an additional domain outside the membrane. Eighteen membrane-spanning β-strands were predicted for the 51.5 kDa monomer, excluding a 7 kDa C-terminal segment, and this segment was shown to contain a proteinase K-sensitive site that was exposed in reconstituted membranes and sphaeroplasts, but which was protected in intact cells. The combined data suggest that TolC is a trimeric outer membrane protein with each monomer comprising a membrane domain, predicted to be β-barrel, and a C-terminal periplasmic domain. The latter could form part of the bridge to the energized inner membrane component of the translocation complex.