The TolC channel-tunnel spans the bacterial outer membrane and periplasm, providing a large exit duct for protein export and multidrug efflux when recruited by substrate-engaged inner membrane complexes. The sole constriction in the single pore of the homotrimeric TolC is the periplasmic tunnel entrance, which in its resting configuration is closed by dense packing of the 12 tunnelforming ␣-helices.
LamB, a sugar-specific channel of Escherichia coli outer membrane was reconstituted into lipid bilayer membranes and the current noise was investigated using fast Fourier transformation. The current noise through the open channels had a rather small spectral density, which was a function of the inverse frequency up to about 100 Hz. The spectral density of the noise of the open LamB channels was a quadratic function of the applied voltage. Its magnitude was not correlated to the number of channels in the lipid bilayer membrane. Upon addition of sugars to the aqueous phase the current decreased in a dose-dependent manner. Simultaneously, the spectral density of the current noise increased drastically, which indicated interaction of the sugars with the binding site inside the channel. The frequency dependence of the spectral density was of Lorentzian type, although the power of its frequency dependence was not identical to -2. Analysis of the power density spectra using a previously proposed simple model (Benz, R., A. Schmid, and G. H. Vos-Scheperkeuter. 1987. J. Membr. Biol. 100: 12-29), allowed the evaluation of the on- and the off-rate constants for the maltopentaose binding to the binding site inside the LamB channels. This means also that the maltopentaose flux through the LamB channel could be estimated by assuming a simple one-site, two-barrier model for the sugar transport from the results of the noise analysis.
A B S T R A C T LamB (maltoporin) of Escherichia coli outer membrane was reconstituted into artificial lipid bilayer membranes. The channel contains a binding site for sugars and is blocked for ions when the site is occupied by a sugar. The on and off reactions of sugar binding cause an increase of the noise of the current through the channel. The sugar-induced current noise of maltoporin was used for the evaluation of the sugar-binding kinetics for different sugars of the maltooligosaccharide series and for sucrose. The on rate constant for sugar binding was between 106 and 107 M -j" s -I for the maltooligosaccharides and corresponds to the movement of the sugars from the aqueous phase to the central binding site. The off rate (corresponding to the release of the sugars from the channel) decreased with increasing number of glucose residues in the maltooligosaccharides from ~ 2,000 s-1 for maltotriose to 180 s -l for maltoheptaose. The kinetics for sucrose movement was considerably slower. The activation energies of the stability constant and of the rate constants for sugar binding were evaluated from noise experiments at different temperatures. The role of LamB in the transport of maltooligosaccharides across the outer membrane is discussed.
Borrelia burgdorferi is remarkable for its ability to thrive in widely different environments due to its ability to infect various organisms. In comparison to enteric Gram-negative bacteria, these spirochetes have only a few transmembrane proteins some of which are thought to play a role in solute and nutrient uptake and excretion of toxic substances. Here, we have identified an outer membrane protein, BesC, which is part of a putative export system comprising the components BesA, BesB and BesC. We show that BesC, a TolC homolog, forms channels in planar lipid bilayers and is involved in antibiotic resistance. A besC knockout was unable to establish infection in mice, signifying the importance of this outer membrane channel in the mammalian host. The biophysical properties of BesC could be explained by a model based on the channel-tunnel structure. We have also generated a structural model of the efflux apparatus showing the putative spatial orientation of BesC with respect to the AcrAB homologs BesAB. We believe that our findings will be helpful in unraveling the pathogenic mechanisms of borreliae as well as in developing novel therapeutic agents aiming to block the function of this secretion apparatus.
SummaryThe export of large negatively charged capsular polysaccharides across the outer membrane represents a significant challenge to Gram negative bacteria. In the case of Escherichia coli group 2 capsular polysaccharides, the mechanism of export across the outer membrane was unknown, with no identified candidate outer membrane proteins. In this paper we demonstrate that the KpsD protein, previously believed to be a periplasmic protein, is an outer membrane protein involved in the export of group 2 capsular polysaccharides across the outer membrane. We demonstrate that KpsD and KpsE are located at the poles of the cell and that polysaccharide biosynthesis and export occurs at these polar sites. By in vivo chemical cross-linking and MALDI-TOF-MS analysis we demonstrate the presence of a multi-protein biosynthetic/export complex in which cytoplasmic proteins involved in polysaccharide biosynthesis could be cross-linked to proteins involved in export across the inner and outer membranes. In addition, we show that the RhsA protein, of previously unknown function, could be cross-linked to the complex and that a rhsA mutation reduces K5 biosynthesis suggesting a role for RhsA in coupling biosynthesis and export.
Escherichia coli TolC assembles into the unique channel-tunnel structure spanning the outer membrane and periplasmic space. The structure is constricted only at the periplasmic entrance of the tunnel and this must be opened to allow export of substrates bound by cognate inner membrane complexes. We have investigated the electrophysiological behavior of TolC reconstituted into planar lipid bilayers, in particular the influence of the membrane potential, the electrolyte concentration and pH. TolC inserted in one orientation into the membrane. The resultant pores were stable and showed no voltage-dependent opening or closing. Nevertheless, TolC could adopt up to three conductance substates. The pores were cation-selective with a permeability ratio of potassium to chloride ions of 16.5. The single-channel conductance was higher when the protein was inserted from the side with negative potential. It showed a nonlinear dependence on the concentration of the electrolyte in the bulk solution and decreased as the pH was lowered. The calculated pK of the apparent closing was 4.5. The electrophysiological characterization is discussed in relation to the TolC structure, in particular the periplasmic entrance.
Summary The TolC protein of Escherichia coli comprises an outer membrane β‐barrel channel and a contiguous α‐helical tunnel spanning the periplasm, providing an exit duct for protein export and multidrug efflux. It forms a single transmembrane pore that is open to the outside of the cell but constricted at the peri‐plasmic tunnel entrance. This sole constriction is lined by a ring of six aspartate residues, two in each of the three identical monomers. When these were replaced by alanines, the resulting TolCDADA protein reconstituted normally in black lipid membranes but showed altered electrophysiological characteristics. In particular, it had lost the strong pH dependence of the wild type and had switched ion selectivity from cations to anions. The function of wild‐type TolC as a membrane pore was severely inhibited by divalent and trivalent cations entering the channel tunnel from the channel (‘extracellular’) side. Divalent cations bound reversibly to effect complete blocking of the transmembrane ion flux. Trivalent cations were more potent. Hexamminecobalt bound at nanomolar concentrations allowed visualization of single blocking events, whereas the smaller Cr3+ cation bound irreversibly and could also access the cation binding site via the tunnel entrance. The inhibitory cations had no effect on the mutant TolCDADA, supporting the view that the aspartate ring is the cation binding site. The electronegative entrance is widely conserved throughout the TolC family, which is essential for efflux and export by Gram‐negative bacteria, suggesting that it could present a general target for drugs.
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.
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