Diverse molecules, from small antibacterial drugs to large protein toxins, are exported directly across both cell membranes of gram-negative bacteria. This export is brought about by the reversible interaction of substrate-specific inner-membrane proteins with an outer-membrane protein of the TolC family, thus bypassing the intervening periplasm. Here we report the 2.1-A crystal structure of TolC from Escherichia coli, revealing a distinctive and previously unknown fold. Three TolC protomers assemble to form a continuous, solvent-accessible conduit--a 'channel-tunnel' over 140 A long that spans both the outer membrane and periplasmic space. The periplasmic or proximal end of the tunnel is sealed by sets of coiled helices. We suggest these could be untwisted by an allosteric mechanism, mediated by protein-protein interactions, to open the tunnel. The structure provides an explanation of how the cell cytosol is connected to the external environment during export, and suggests a general mechanism for the action of bacterial efflux pumps.
Bacteria like Escherichia coli and Pseudomonas aeruginosa expel drugs via tripartite multidrug efflux pumps spanning both inner and outer membranes and the intervening periplasm. In these pumps a periplasmic adaptor protein connects a substrate-binding inner membrane transporter to an outer membrane-anchored TolC-type exit duct. High-resolution structures of all 3 components are available, but a pump model has been precluded by the incomplete adaptor structure, because of the apparent disorder of its N and C termini. We reveal that the adaptor termini assemble a -roll structure forming the final domain adjacent to the inner membrane. The completed structure enabled in vivo cross-linking to map intermolecular contacts between the adaptor AcrA and the transporter AcrB, defining a periplasmic interface between several transporter subdomains and the contiguous -roll, -barrel, and lipoyl domains of the adaptor. With short and long cross-links expressed as distance restraints, the flexible linear topology of the adaptor allowed a multidomain docking approach to model the transporter-adaptor complex, revealing that the adaptor docks to a transporter region of comparative stability distinct from those key to the proposed rotatory pump mechanism, putative drugbinding pockets, and the binding site of inhibitory DARPins. Finally, we combined this docking with our previous resolution of the AcrA hairpin-TolC interaction to develop a model of the assembled tripartite complex, satisfying all of the experimentally-derived distance constraints. This AcrA 3-AcrB3-TolC3 model presents a 610,000-Da, 270-Å-long efflux pump crossing the entire bacterial cell envelope.antibiotic resistance ͉ docked model ͉ membrane complex ͉ TolC exit duct
The toxin HlyA is exported from Escherichia coli, without a periplasmic intermediate, by a type I system comprising an energized inner-membrane (IM) translocase of two proteins, HlyD and the traffic ATPase HlyB, and the outer-membrane (OM) porin-like TolC. These and the toxin substrate were expressed separately to reconstitute export and, via affinity tags on the IM proteins, cross-linked in vivo complexes were isolated before and after substrate engagement. HlyD and HlyB assembled a stable IM complex in the absence of TolC and substrate. Both engaged HlyA, inducing the IM complex to contact TolC, concomitant with conformational change in all three exporter components. The IM-OM bridge was formed primarily by HlyD, which assembled to stable IM trimers, corresponding to the OM trimers of TolC. The bridge was transient, components reverting to IM and OM states after translocation. Mutant HlyB that bound, but did not hydrolyse ATP, supported IM complex assembly, substrate recruitment and bridging, but HlyA stalled in the channel. A similar picture was evident when the HlyD C-terminus was masked. Export thus occurs via a contiguous channel which is formed, without traffic ATPase ATP hydrolysis, by substrate-induced, reversible bridging of the IM translocase to the OM export pore. Keywords: bacterial secretion mechanism/mitochondrial import/in vivo protein translocation/TolC membrane pore/traffic ATPase
Multidrug resistance among Gram-negative bacteria is conferred by three-component membrane pumps that expel diverse antibiotics from the cell. These efflux pumps consist of an inner membrane transporter such as the AcrB proton antiporter, an outer membrane exit duct of the TolC family, and a periplasmic protein known as the adaptor. We present the x-ray structure of the MexA adaptor from the human pathogen Pseudomonas aeruginosa. The elongated molecule contains three linearly arranged subdomains; a 47-Å-long ␣-helical hairpin, a lipoyl domain, and a six-stranded -barrel. In the crystal, hairpins of neighboring MexA monomers pack side-by-side to form twisted arcs. We discuss the implications of the packing of molecules within the crystal. On the basis of the structure and packing, we suggest a model for the key periplasmic interaction between the outer membrane channel and the adaptor protein in the assembled drug efflux pump.
SummaryThe 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.
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.
We have studied the C‐terminal signal which directs the complete export of the 1024‐amino‐acid hemolysin protein (HlyA) of Escherichia coli across both bacterial membranes into the surrounding medium. Isolation and sequencing of homologous hlyA genes from the related bacteria Proteus vulgaris and Morganella morganii revealed high primary sequence divergence in the three HlyA C‐termini and highlighted within the extreme terminal 53 amino acids the conservation of three contiguous sequences, a potential 18‐amino‐acid amphiphilic alpha‐helix, a cluster of charged residues, and a weakly hydrophobic terminal sequence rich in hydroxylated residues. Fusion of the C‐terminal 53 amino acid sequence to non‐exported truncated Hly A directed wild‐type export but export was radically reduced following independent disruption or progressive truncation of the three C‐terminal features by in‐frame deletion and the introduction of translation stop codons within the 3′ hlyA sequence. The data indicate that the HlyA C‐terminal export signal comprises multiple components and suggest possible analogies with the mitochondrial import signal. Hemolysis assays and immunoblotting confirmed the intracellular accumulation of non‐exported HlyA proteins and supported the view that export proceeds without a periplasmic intermediate. Comparison of cytoplasmic and extracellular forms of an independently exported extreme C‐terminal 194 residue peptide showed that the signal was not removed during export.
Bacteria such as Escherichia coli and Pseudomonas aeruginosa expel antibiotics and other inhibitors via tripartite multidrug efflux pumps spanning the inner and outer membranes and the intervening periplasmic space. A key event in pump assembly is the recruitment of an outer membrane-anchored TolC exit duct by the adaptor protein of a cognate inner membrane translocase, establishing a contiguous transenvelope efflux pore. We describe the underlying interaction of juxtaposed periplasmic exit duct and adaptor coiled-coils in the widespread RND-type pump TolC/AcrAB of E. coli, using in vivo cross-linking to map the extent of intermolecular contacts. Cross-linking of site-specific TolC cysteine variants to wild-type AcrA adaptor identified residues on the lower ␣-helical barrel domain of TolC, defining a contiguous cluster close to the entrance aperture of the exit duct. Reciprocally, site-specific cross-linking of AcrA cysteine variants to wild-type TolC identified the interaction surface on the adaptor within the N-terminal ␣-helix of the AcrA coiled-coil. The experimental data allowed a data-driven docking approach to model the interaction surface central to pump assembly. The lowest energy docked model satisfying all of the cross-link distance constraints places the adaptor at the intramolecular groove formed by the TolC entrance helices, aligning the adaptor coiled-coil with the exposed TolC outer helix. A key feature of this positioning is that it allows space for the proposed movement of the inner coil of TolC during transition to its open state.antibiotic resistance ͉ exit duct ͉ membrane proteins ͉ type I export
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