The outer membrane component of the multidrug efflux pump from Pseudomonas aeruginosa may be a gated channel.

OprM, the outer membrane component of the MexAB-OprM multidrug efflux pump of Pseudomonas aeruginosa, has been assumed to facilitate the export of antibiotics across the outer membrane of this organism. Here we purified to homogeneity the OprM protein, reconstituted it into liposome membranes, and tested its channel activity by using the liposome swelling assay. It was demonstrated that OprM is a channel-forming protein and exhibits the channel property that amino acids diffuse more efficiently than saccharides. However, antibiotics showed no significant diffusion through the OprM channel in the liposome membrane, suggesting that OprM functions as a gated channel. We reasoned that the protease treatment may cause the disturbance of the gate structure of OprM. Hence, we treated OprM reconstituted in the membranes with alpha-chymotrypsin and examined its solute permeability. The results demonstrated that the protease treatment caused the opening of an OprM channel through which antibiotics were able to diffuse. To elucidate which cleavage is intimately related to the opening, we constructed mutant OprM proteins where the amino acid at the cleavage site was replaced with another amino acid. By examining the channel activity of these mutant proteins, it was shown that the proteolysis at tyrosine 185 and tyrosine 196 of OprM caused the channel opening. Furthermore, these residues were shown to face into the periplasmic space and interact with other component(s). We considered the possible opening mechanism of the OprM channel based on the structure of TolC, a homologue of OprM.     

Localization of the outer membrane subunit OprM of resistance-nodulation-cell division family multicomponent efflux pump in Pseudomonas aeruginosa

The outer membrane subunit OprM of the multicomponent efflux pump of Pseudomonas aeruginosa has been assumed to form a transmembrane xenobiotic exit channel across the outer membrane. We challenged this hypothesis to clarify the underlying ambiguity by manipulating the amino-terminal signal sequence of the OprM protein of the MexAB-OprM efflux pump in P. aeruginosa. [(3)H]Palmitate uptake experiments revealed that OprM is a lipoprotein. The following lines of evidence unequivocally established that the OprM protein functioned at the periplasmic space. (i) The OprM protein, in which a signal sequence including Cys-18 was replaced with that of periplasmic azurin, appeared in the periplasmic space but not in the outer membrane fraction, and the protein fully functioned as the pump subunit. (ii) The hybrid OprM containing the N-terminal transmembrane segment of the inner membrane protein, MexF, appeared exclusively in the inner membrane fraction. The hybrid protein containing 186 or 331 amino acid residues of MexF was fully active for the antibiotic extrusion, but a 42-residue protein was totally inactive. (iii) The mutant OprM, in which the N-terminal cysteine residue was replaced with another amino acid, appeared unmodified with fatty acid and was fractionated in both the periplasmic space and the inner membrane fraction but not in the outer membrane fraction. The Cys-18-modified OprM functioned for the antibiotic extrusion indistinguishably from that in the wild-type strain. We concluded, based on these results, that the OprM protein was anchored in the outer membrane via fatty acid(s) attached to the N-terminal cysteine residue and that the entire polypeptide moiety was exposed to the periplasmic space.     

Inner membrane efflux components are responsible for beta-lactam specificity of multidrug efflux pumps in Pseudomonas aeruginosa.

A major feature of the MexAB-OprM multidrug efflux pump which distinguishes it from the MexCD-OprJ and MexEF-OprN multidrug efflux systems in Pseudomonas aeruginosa is its ability to export a wide variety of beta-lactam antibiotics. Given the periplasmic location of their targets it is feasible that beta-lactams exit the cell via the outer membrane OprM without interaction with MexA and MexB, though the latter appear to be necessary for OprM function. To test this, chimeric MexAB-OprJ and MexCD-OprM efflux pumps were reconstituted in delta mexCD delta oprM and delta mexAB delta oprJ strains, respectively, and the influence of the exchange of outer membrane components on substrate (i.e., beta-lactam) specificity was assessed. Both chimeric pumps were active in antibiotic efflux, as evidenced by their contributions to resistance to a variety of antimicrobial agents, although there was no change in resistance profiles relative to the native pumps, indicating that OprM is not the determining factor for the beta-lactam specificity of MexAB-OprM. Thus, one or both of inner membrane-associated proteins MexA and MexB are responsible for drug recognition, including recognition of beta-lactams.     

Crystal structures of OprN and OprJ,outer membrane factors of multidrug tripartite efflux pumps of Pseudomonas aeruginosa

The genome of Pseudomonas aeruginosa encodes tripartite efflux pumps that extrude functionally and structurally dissimilar antibiotics from the bacterial cell. MexAB‐OprM, MexCD‐OprJ, MexEF‐OprN, and MexXY‐OprM are the main tripartite efflux pumps responsible for multidrug resistance in P. aeruginosa. The outer membrane factors OprN, OprJ, and OprM are essential components of functional tripartite efflux pumps. To elucidate the structural basis of multidrug resistance, we determined the crystal structures of OprN and OprJ. These structures revealed several features, including tri‐acylation of the N‐terminal cysteine, a small pore in the β‐barrel domain, and a tightly sealed gate in the α‐barrel domain. Despite the overall similarity of OprN, OprJ, and OprM, a comparison of their structures and electrostatic distributions revealed subtle differences at the periplasmic end of the α‐barrel domain. These results suggested that the overall structures of these outer membrane factors are specifically optimized for particular tripartite efflux pumps. Proteins 2016; 84:759–769. © 2016 Wiley Periodicals, Inc.     

TolC--the bacterial exit duct for proteins and drugs

The TolC structure has unveiled a common mechanism for the movement of molecules, large and small, from the bacterial cell cytosol, across two membranes and the intervening periplasm, into the environment. Trimeric TolC is a remarkable cell exit duct that differs radically from other membrane proteins, comprising a 100-A long alpha-barrel that projects across the periplasmic space, anchored by a 40-A long beta-barrel spanning the outer membrane. The periplasmic entrance of TolC is closed until recruitment by substrate-specific translocases in the inner membrane triggers its transition to the open state, achieved by an iris-like 'untwisting' of the tunnel alpha-helices. TolC-dependent machineries present ubiquitous exit routes for virulence proteins and antibacterial drugs, and their conserved structure, specifically the electronegative TolC entrance constriction, may present a target for inhibitors of multidrug-resistant pathogens.     

Evaluation of a structural model of Pseudomonas aeruginosa outer membrane protein OprM, an efflux component involved in intrinsic antibiotic resistance

The outer membrane protein OprM of Pseudomonas aeruginosa is involved in intrinsic and mutational multiple-antibiotic resistance as part of two resistance-nodulation-division efflux systems. The crystal structure of TolC, a homologous protein in Escherichia coli, was recently published (V. Koronakis, A. Sharff, E. Koronakis, B. Luisl, and C. Hughes, Nature 405:914-919, 2000), demonstrating a distinctive architecture comprising outer membrane beta-barrel and periplasmic helical-barrel structures, which assemble differently from the common beta-barrel-only conformation of porins. Based on their sequence similarity, a similar content of alpha-helical and beta-sheet structure determined by circular dichroism spectroscopy, and our observation that OprM, like TolC, reconstitutes channels in planar bilayer membranes, OprM and TolC were considered to be structurally homologous, and a model of OprM was constructed by threading its sequence to the TolC crystal structure. Residues thought to be important for the TolC structure were conserved in space in this OprM model. Analyses of deletion mutants and previously isolated insertion mutants of OprM in the context of this model allowed us to propose roles for different protein domains. Our data indicate that the helical barrel of the protein is critical for both the function and the integrity of the protein, while a C-terminal domain localized around the equatorial plane of this helical barrel is dispensable. Extracellular loops appear to play a lesser role in substrate specificity for this efflux protein compared to classical porins, and there appears to be a correlation between the change in antimicrobial activity for OprM mutants and the pore size. Our model and channel formation studies support the "iris" mechanism of action for TolC and permit us now to form more focused hypotheses about the functional domains of OprM and its related family of efflux proteins.     

Assembly and channel opening of outer membrane protein in tripartite drug efflux pumps of Gram-negative bacteria

Gram-negative bacteria are capable of expelling diverse xenobiotic substances from within the cell by use of three-component efflux pumps in which the energy-activated inner membrane transporter is connected to the outer membrane channel protein via the membrane fusion protein. In this work, we describe the crystal structure of the membrane fusion protein MexA from the Pseudomonas aeruginosa MexAB-OprM pump in the hexameric ring arrangement. Electron microscopy study on the chimeric complex of MexA and the outer membrane protein OprM reveals that MexA makes a tip-to-tip interaction with OprM, which suggests a docking model for MexA and OprM. This docking model agrees well with genetic results and depicts detailed interactions. Opening of the OprM channel is accompanied by the simultaneous exposure of a protein structure resembling a six-bladed cogwheel, which intermeshes with the complementary cogwheel structure in the MexA hexamer. Taken together, we suggest an assembly and channel opening model for the MexAB-OprM pump. This study provides a better understanding of multidrug resistance in Gram-negative bacteria.     

Crystal structure of the membrane fusion protein, MexA, of the multidrug transporter in Pseudomonas aeruginosa

The MexAB-OprM efflux pump of Pseudomonas aeruginosa is central to multidrug resistance of this organism, which infects immunocompromised hospital patients. The MexA, MexB, and OprM subunits were assumed to function as the membrane fusion protein, the body of the transporter, and the outer membrane channel protein, respectively. For better understanding of this important xenobiotic transporter, we show the x-ray crystallographic structure of MexA at a resolution of 2.40 A. The global MexA structure showed unforeseen new features with a spiral assembly of six and seven protomers that were joined together at one end by a pseudo 2-fold image. The protomer showed a new protein structure with a tandem arrangement consisting of at least three domains and presumably one more. The rod domain had a long hairpin of twisted coiled-coil that extended to one end. The second domain adjacent to the rod alpha-helical domain was globular and constructed by a cluster of eight short beta-sheets. The third domain located distal to the alpha-helical rod was globular and composed of seven short beta-sheets and one short alpha-helix. The 13-mer was shaped like a woven rattan cylinder with a large internal tubular space and widely opened flared ends. The 6-mer and 7-mer had a funnel-like structure consisting of a tubular rod at one side and a widely opened flared funnel top at the other side. Based on these results, we constructed a model of the MexAB-OprM pump assembly. The three pairs of MexA dimers interacted with the periplasmic alpha-barrel domain of OprM via the alpha-helical hairpin, the second domain interacted with both MexB and OprM at their contact site, and the third and disordered domains probably interacted with the distal domain of MexB. In this fashion, the MexA subunit connected MexB and OprM, indicating that MexA is the membrane bridge protein.     

Membrane topology of the xenobiotic-exporting subunit, MexB, of the MexA,B-OprM extrusion pump in Pseudomonas aeruginosa

The MexA,B-OprM efflux pump assembly of Pseudomonas aeruginosa consists of two inner membrane proteins and one outer membrane protein. The cytoplasmic membrane protein, MexB, appears to function as the xenobiotic-exporting subunit, whereas the MexA and OprM proteins are supposed to function as the membrane fusion protein and the outer membrane channel protein, respectively. Computer-aided hydropathy analyses of MexB predicted the presence of up to 17 potential transmembrane segments. To verify the prediction, we analyzed the membrane topology of MexB using the alkaline phosphatase gene fusion method. We obtained the following unique characteristics. MexB bears 12 membrane spanning segments leaving both the amino and carboxyl termini in the cytoplasmic side of the inner membrane. Both the first and fourth periplasmic loops had very long hydrophilic domains containing 311 and 314 amino acid residues, respectively. This fact suggests that these loops may interact with other pump subunits, such as the membrane fusion protein MexA and the outer membrane protein OprM. Alignment of the amino- and the carboxyl-terminal halves of MexB showed a 30% homology and transmembrane segments 1, 2, 3, 4, 5, and 6 could be overlaid with the segments 7, 8, 9, 10, 11, and 12, respectively. This result suggested that the MexB has a 2-fold repeat that strengthen the experimentally determined topology model. This paper reports the structure of the pump subunit, MexB, of the MexA,B-OprM efflux pump assembly. This is the first time to verify the topology of the resistant-nodulation-division efflux pump protein.     

Gating at both ends and breathing in the middle: conformational dynamics of TolC

Drug extrusion via efflux through a tripartite complex (an inner membrane pump, an outer membrane protein, and a periplasmic protein) is a widely used mechanism in Gram-negative bacteria. The outer membrane protein (TolC in Escherichia coli; OprM in Pseudomonas aeruginosa) forms a tunnel-like pore through the periplasmic space and the outer membrane. Molecular dynamics simulations of TolC have been performed, and are compared to simulations of Y362F/R367S mutant, and to simulations of its homolog OprM. The results reveal a complex pattern of conformation dynamics in the TolC protein. Two putative gate regions, located at either end of the protein, can be distinguished. These regions are the extracellular loops and the mouth of the periplasmic domain, respectively. The periplasmic gate has been implicated in the conformational changes leading from the closed x-ray structure to a proposed open state of TolC. Between the two gates, a peristaltic motion of the periplasmic domain is observed, which may facilitate transport of the solutes from one end of the tunnel to the other. The motions observed in the atomistic simulations are also seen in coarse-grained simulations in which the protein tertiary structure is represented by an elastic network model.     

Role of the membrane fusion protein in the assembly of resistance-nodulation-cell division multidrug efflux pump in Pseudomonas aeruginosa

The tripartite xenobiotic-antibiotic transporter of Pseudomonas aeruginosa consists of the inner membrane transporter (e.g., MexB, MexY), the periplasmic membrane-fusion-protein (e.g., MexA, MexX), and the outer membrane channel protein (e.g., OprM). These subunits were assumed to assemble into a transporter unit during export of the substrates. However, subunit interaction and their specificity in native form remained to be elucidated. To address these important questions, we analyzed the role of the individual subunits for the assembly of MexAB-OprM by pull-down assay tagging only one of the subunits. We found stable MexA-MexB-OprM complex without chemical cross-linking that withstand all purification procedures. Results of bi-partite interactions analysis showed tight association between MexA and OprM in the absence of MexB, whereas the expression systems lacking MexA failed to co-purify MexB or OprM. None of the heterologous subunit combinations such as MexA+MexY(his)+OprM and MexX+MexB(his)+OprM showed interaction. These results implied that the membrane fusion protein is central to the tripartite xenobiotic transporter assembly.     

Topology of the outer membrane usher PapC determined by site-directed fluorescence labeling

In contrast to typical membrane proteins that span the lipid bilayer via transmembrane alpha-helices, bacterial outer membrane proteins adopt a beta-barrel architecture composed of antiparallel transmembrane beta-strands. The topology of outer membrane proteins is difficult to predict accurately using computer algorithms, and topology mapping protocols commonly used for alpha-helical membrane proteins do not work for beta-barrel proteins. We present here the topology of the PapC usher, an outer membrane protein required for assembly and secretion of P pili by the chaperone/usher pathway in uropathogenic Escherichia coli. An initial attempt to map PapC topology by insertion of protease cleavage sites was largely unsuccessful due to lack of cleavage at most sites and the requirement to disrupt the outer membrane to identify periplasmic sites. We therefore adapted a site-directed fluorescence labeling technique to permit topology mapping of outer membrane proteins using small molecule probes in intact bacteria. Using this method, we demonstrated that PapC has the potential to encode up to 32 transmembrane beta-strands. Based on experimental evidence, we propose that the usher consists of an N-terminal beta-barrel domain comprised of 26 beta-strands and that a distinct C-terminal domain is not inserted into the membrane but is located instead within the lumen of the N-terminal beta-barrel similar to the plug domains encoded by the outer membrane iron-siderophore uptake proteins.     

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. These changes converge to the native MexAB partner OprM, and indicate an interface key to the function and diversity of efflux pumps.     

Chimeric analysis of the multicomponent multidrug efflux transporters from gram-negative bacteria

Many multidrug transporters from gram-negative bacteria belong to the resistance-nodulation-cell division (RND) superfamily of transporters. RND-type multidrug transporters have an extremely broad substrate specificity and protect bacterial cells from the actions of antibiotics on both sides of the cytoplasmic membrane. They usually function as three-component assemblies spanning the outer and cytoplasmic membranes and the periplasmic space of gram-negative bacteria. The structural determinants of RND transporters responsible for multidrug recognition and complex assembly remain unknown. We constructed chimeric RND transporters composed of N-terminal residues of AcrB and C-terminal residues of MexB, the major RND-type transporters from Escherichia coli and Pseudomonas aeruginosa, respectively. The assembly of complexes and multidrug efflux activities of chimeric transporters were determined by coexpression of hybrid genes either with AcrA, the periplasmic component of the AcrAB transporter from E. coli, or with MexA and OprM, the accessory proteins of the MexAB-OprM pump from P. aeruginosa. We found that the specificity of interaction with the corresponding periplasmic component is encoded in the T60-V612 region of transporters. Our results also suggest that the large periplasmic loops of RND-type transporters are involved in multidrug recognition and efflux.     

Bacterial outer membrane ushers contain distinct targeting and assembly domains for pilus biogenesis

Biogenesis of a superfamily of surface structures by gram-negative bacteria requires the chaperone/usher pathway, a terminal branch of the general secretory pathway. In this pathway a periplasmic chaperone works together with an outer membrane usher to direct substrate folding, assembly, and secretion to the cell surface. We analyzed the structure and function of the PapC usher required for P pilus biogenesis by uropathogenic Escherichia coli. Structural analysis indicated PapC folds as a beta-barrel with short extracellular loops and extensive periplasmic domains. Several periplasmic regions were localized, including two domains containing conserved cysteine pairs. Functional analysis of deletion mutants revealed that the PapC C terminus was not required for insertion of the usher into the outer membrane or for proper folding. The usher C terminus was not necessary for interaction with chaperone-subunit complexes in vitro but was required for pilus biogenesis in vivo. Interestingly, coexpression of PapC C-terminal truncation mutants with the chromosomal fim gene cluster coding for type 1 pili allowed P pilus biogenesis in vivo. These studies suggest that chaperone-subunit complexes target an N-terminal domain of the usher and that subunit assembly into pili depends on a subsequent function provided by the usher C terminus.     

Beta-barrel membrane protein folding and structure viewed through the lens of alpha-hemolysin

The beta-barrel is a transmembrane structural motif commonly encountered in bacterial outer membrane proteins and pore-forming toxins (PFTs). Alpha-hemolysin (alphaHL) is a cytotoxin secreted by Staphylococcus aureus that assembles from a water-soluble monomer to form a membrane-bound heptameric beta-barrel on the surface of susceptible cells, perforating the cell membranes, leading to cell death and lysis. The mechanism of heptamer assembly, which has been studied extensively, occurs in a stepwise manner, and the structures of the initial, monomeric form and final, membrane-embedded pore are known. The toxin's ability to assemble from an aqueous, hydrophilic species to a membrane-inserted oligomer is of interest in understanding the assembly of PFTs in particular and the folding and structure of beta-barrel membrane proteins in general. Here we review the structures of the monomeric and heptamer states of LukF and alphaHL, respectively, the mechanism of toxin assembly, and the relationships between alphaHL and nontoxin beta-barrel membrane proteins.     

The crystal structure of the pyoverdine outer membrane receptor FpvA from Pseudomonas aeruginosa at 3.6 angstroms resolution

The pyoverdine outer membrane receptor FpvA from Pseudomonas aeruginosa translocates ferric-pyoverdine across the outer membrane via an energy consuming mechanism that involves the inner membrane energy transducing complex of TonB-ExbB-ExbD and the proton motive force. We solved the crystal structure of FpvA loaded with iron-free pyoverdine at 3.6 angstroms resolution. The pyoverdine receptor is folded in two domains: a transmembrane 22-stranded beta-barrel domain occluded by an N-terminal domain containing a mixed four-stranded beta-sheet (the plug). The beta-strands of the barrel are connected by long extracellular loops and short periplasmic turns. The iron-free pyoverdine is bound at the surface of the receptor in a pocket lined with aromatic residues while the extracellular loops do not completely cover the pyoverdine binding site. The TonB box, which is involved in intermolecular contacts with the TonB protein of the inner membrane, is observed in an extended conformation. Comparison of this first reported structure of an iron-siderophore transporter from a bacterium other than Escherichia coli with the known structures of the E.coli TonB-dependent transporters reveals a high structural homology and suggests that a common sensing mechanism exists for the iron-loading status in all bacterial iron siderophore transporters.     

Structure of reconstituted bacterial membrane efflux pump by cryo-electron tomography

Complexes of OprM and MexA, two proteins of the MexA-MexB-OprM multidrug efflux pump from Pseudomonasaeruginosa, an opportunistic Gram-negative bacterium, were reconstituted into proteoliposomes by detergent removal. Stacks of protein layers with a constant height of 21 nm, separated by lipid bilayers, were obtained at stoichiometry of 1:1 (w/w). Using cryo-electron microscopy and tomography, we showed that these protein layers were composed of MexA-OprM complexes self-assembled into regular arrays. Image processing of extracted sub-tomograms depicted the architecture of the bipartite complex sandwiched between two lipid bilayers, representing an environment close to that of the native whole pump (i.e. anchored between outer and inner membranes of P. aeruginosa). The MexA-OprM complex appeared as a cylindrical structure in which we were able to identify the OprM molecule and the MexA moiety. MexA molecules have a cylindrical shape prolonging the periplasmic helices of OprM, and widening near the lipid bilayer. The flared part is likely composed of two MexA domains adjacent to the lipid bilayer, although their precise organization was not reachable mainly due to their flexibility. Moreover, the intermembrane distance of 21 nm indicated that the height of the bipartite complex is larger than that of the tripartite AcrA-AcrB-TolC built-up model in which TolC and AcrB are docked into contact. We proposed a model of MexA-OprM taking into account features of previous models based on AcrA-AcrB-TolC and our structural results providing clues to a possible mechanism of tripartite system assembly.     

In vivo membrane assembly of split variants of the E.coli outer membrane protein OmpA.

The two-domain, 325 residue outer membrane protein OmpA of Escherichia coli is a well-established model for the study of membrane assembly. The N-terminal domain, consisting of approximately 170 amino acid residues, is embedded in the membrane, presumably in the form of a beta-barrel consisting of eight antiparallel transmembrane beta-strands. A set of 16 gene variants carrying deletions in the membrane-embedded domain of OmpA was constructed. When pairs of these mutant genes were co-expressed in E.coli, it was found that a functional OmpA protein could be assembled efficiently from two complementary protein fragments. Assembly was found when the polypeptide chain was split at the second or third periplasmic turn. All four protein termini were located in the periplasmic space. Interestingly, duplication of transmembrane strands five and six led to a variant with an unusual topology: the N-terminus of one fragment and the C-terminus of the other fragment were exposed at the cell surface. This is the first demonstration of correct membrane assembly of split beta-structured membrane proteins. These findings are important for a better understanding of their folding/assembly pathway and may have implications for the development of artificial outer membrane proteins and for the cell surface display of heterologous peptides or proteins.     

Biogenesis of the protein import channel Tom40 of the mitochondrial outer membrane: intermembrane space components are involved in an early stage of the assembly pathway

Tom40 forms the central channel of the preprotein translocase of the mitochondrial outer membrane (TOM complex). The precursor of Tom40 is encoded in the nucleus, synthesized in the cytosol, and imported into mitochondria via a multi-step assembly pathway that involves the mature TOM complex and the sorting and assembly machinery of the outer membrane (SAM complex). We report that opening of the mitochondrial intermembrane space by swelling blocks the assembly pathway of the beta-barrel protein Tom40. Mitochondria with defects in small Tim proteins of the intermembrane space are impaired in the Tom40 assembly pathway. Swelling as well as defects in the small Tim proteins inhibit an early stage of the Tom40 import pathway that is needed for formation of a Tom40-SAM intermediate. We propose that the biogenesis pathway of beta-barrel proteins of the outer mitochondrial membrane not only requires TOM and SAM components, but also involves components of the intermembrane space.