Tracking metal ions through a Cu/Ag efflux pump assigns the functional roles of the periplasmic proteins.

Copper is an essential nutrient for all aerobic organisms but is toxic in excess. At the host-pathogen interface, macrophages respond to bacterial infection by copper-dependent killing mechanisms, whereas the invading bacteria are thought to counter with an up-regulation of copper transporters and efflux pumps. The tripartite efflux pump CusCBA and its metallochaperone CusF are vital to the detoxification of copper and silver ions in the periplasm of Escherichia coli. However, the mechanism of efflux by this complex, which requires the activation of the inner membrane pump CusA, is poorly understood. Here, we use selenomethionine (SeM) active site labels in a series of biological X-ray absorption studies at the selenium, copper, and silver edges to establish a "switch" role for the membrane fusion protein CusB. We determine that metal-bound CusB is required for activation of cuprous ion transfer from CusF directly to a site in the CusA antiporter, showing for the first time (to our knowledge) the in vitro activation of the Cus efflux pump. This metal-binding site of CusA is unlike that observed in the crystal structures of the CusA protein and is composed of one oxygen and two sulfur ligands. Our results suggest that metal transfer occurs between CusF and apo-CusB, and that, when metal-loaded, CusB plays a role in the regulation of metal ion transfer from CusF to CusA in the periplasm.

N-terminal region of CusB is sufficient for metal binding and metal transfer with the metallochaperone CusF.

Gram-negative bacteria, such as Escherichia coli, utilize efflux resistance systems in order to expel toxins from their cells. Heavy-metal resistance is mediated by resistance nodulation cell division (RND)-based efflux pumps composed of a tripartite complex that includes an RND-transporter, an outer-membrane factor (OMF), and a membrane fusion protein (MFP) that spans the periplasmic space. MFPs are necessary for complex assembly and have been hypothesized to play an active role in substrate efflux. Crystal structures of MFPs are available, however incomplete, as large portions of the apparently disordered N- and C-termini are unresolved. Such is the case for CusB, the MFP of the E. coli Cu(I)/Ag(I) efflux pump CusCFBA. In this work, we have investigated the structure and function of the N-terminal region of CusB, which includes the metal-binding site and is missing from previously determined crystal structures. Results from mass spectrometry and X-ray absorption spectroscopy show that the isolated N-terminal 61 residues (CusB-NT) bind metal in a 1:1 stoichiometry with a coordination site composed of M21, M36, and M38, consistent with full-length CusB. NMR spectra show that CusB-NT is mostly disordered in the apo state; however, some slight structure is adopted upon metal binding. Much of the intact protein's function is maintained in this fragment as CusB-NT binds metal in vivo and in vitro, and metal is transferred between the metallochaperone CusF and CusB-NT in vitro. Functional analysis in vivo shows that full-length CusB is necessary in an intact polypeptide for full metal resistance, though CusB-NT alone can contribute partial metal resistance. These findings reinforce the theory that the role of CusB is not only to bind metal but also to play an active role in efflux.

Metal export by CusCFBA, the periplasmic Cu(I)/Ag(I) transport system of Escherichia coli.

High levels of metal ions have the potential to cause cellular toxicity through a variety of mechanisms; therefore, cells have developed numerous systems that regulate their intracellular concentrations. The Cus resistance system aids in protection of Escherichia coli from high levels of Cu(I) and Ag(I) by actively transporting these metal ions to the extracellular environment. The Cus system forms a continuous complex, CusCBA, that spans the inner membrane, periplasm, and outer membrane of Gram-negative bacteria, together with a novel fourth component, the periplasmic metallochaperone, CusF. The metal-binding sites of CusA, CusB, and CusF are exquisitely tuned for Cu(I) and Ag(I), and thus effectively discriminate these ions for transport from other metals that may be required in the cell. Furthermore, direct transfer of metal from protein to protein within the Cus system during the transport process is likely to reduce the potential toxicity posed by the free metal ions. Here we review the wealth of structural, biochemical, and genetic information on the Cus system, which demonstrates the many intriguing aspects of function for metal-transporting efflux systems.

Interactions between CusF and CusB identified by NMR spectroscopy and chemical cross-linking coupled to mass spectrometry.

The Escherichia coli periplasmic proteins CusF and CusB, as part of the CusCFBA efflux system, aid in the resistance of elevated levels of copper and silver by direct metal transfer between the metallochaperone CusF and the membrane fusion protein CusB before metal extrusion from the periplasm to the extracellular space. Although previous in vitro experiments have demonstrated highly specific interactions between CusF and CusB that are crucial for metal transfer to occur, the structural details of the interaction have not been determined. Here, the interactions between CusF and CusB are mapped through nuclear magnetic resonance (NMR) spectroscopy and chemical cross-linking coupled with high-resolution mass spectrometry to better understand how recognition and metal transfer occur between these proteins. The NMR (1)H-(15)N correlation spectra reveal that CusB interacts with the metal-binding face of CusF. In vitro chemical cross-linking with a 7.7 Å homobifunctional amine-reactive cross-linker, BS(2)G, was used to capture the CusF/CusB interaction site, and mass spectral data acquired on an LTQ-Orbitrap confirm the following two cross-links: CusF K31 to CusB K29 and CusF K58 to CusB K32, thus revealing that the N-terminal region of CusB interacts with the metal-binding face of CusF. The proteins transiently interact in a metal-dependent fashion, and contacts between CusF and CusB are localized to regions near their respective metal-binding sites.