Structures of sequential open states in a symmetrical opening transition of the TolC exit duct.

In bacterial drug resistance and virulence pumps, an inner membrane (IM) transporter and periplasmic adaptor recruit an outer membrane (OM) trimeric TolC exit duct that projects an α-helical tunnel across the periplasm. The TolC periplasmic entrance is closed by densely packed α-helical coiled coils, inner H7/H8, and outer H3/H4, constrained by a hydrogen bond network. On recruitment, these coiled coils must undergo transition to the open state.

The assembled structure of a complete tripartite bacterial multidrug efflux pump.

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.

A periplasmic coiled-coil interface underlying TolC recruitment and the assembly of bacterial drug efflux pumps.

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.

Directed evolution of a bacterial efflux pump: adaptation of the E. coli TolC exit duct to the Pseudomonas MexAB translocase.

Bacterial multidrug efflux pumps operate by periplasmic recruitment and opening of TolC family outer membrane exit ducts by cognate inner membrane translocases. Directed evolution of active hybrid pumps was achieved by challenging a library of mutated, shuffled TolC variants to adapt to the non-cognate Pseudomonas MexAB translocase, and confer resistance to the efflux substrate novobiocin. Amino acid substitutions in MexAB-adapted TolC variants that endowed high resistance were recreated independently, and revealed that MexAB-adaptation was conferred only by substitutions located in the lower alpha-helical barrel of TolC, specifically the periplasmic equatorial domain and entrance coiled coils.

Three's company: component structures bring a closer view of tripartite drug efflux pumps.

Bacterial multidrug resistance is a serious clinical problem and is commonly conferred by tripartite efflux 'pumps' in the prokaryotic cell envelope. Crystal structures of the three components of a drug efflux pump have now been solved: the outer membrane TolC exit duct in the year 2000, the inner membrane AcrB antiporter in 2002 and the periplasmic adaptor MexA in 2004. These structures have enhanced our understanding of the principles underlying pump assembly and operation, and present pumps as new drug targets.

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.

Structure of the periplasmic component of a bacterial drug efflux pump.

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.

Transition to the open state of the TolC periplasmic tunnel entrance.

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 tunnel-forming alpha-helices. Recruitment of TolC must trigger opening for substrate transit to occur, but the mechanism underlying transition from the closed to the open state is not known.

An aspartate ring at the TolC tunnel entrance determines ion selectivity and presents a target for blocking by large cations.

The TolC protein of Escherichia coli comprises an outer membrane beta-barrel channel and a contiguous alpha-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.