Interaction between quinolones antibiotics and bacterial outer membrane porin OmpF

In these work, we try to establish a relation between the hydrophobicity of some quinolones and their interaction with OmpF. In order to do that, the values of the binding constant of some quinolones of different "generations" with OmpF were determined by UV-visible spectrophotometry and by fluorimetry. Our results show that there is a strong interaction between all the drugs and the protein and that it becomes larger for the last "generation" fluoroquinolones. These results were compared with previous ones obtained for the interaction of these drugs with simpler biomembrane models (liposomes) and it is possible to conclude that some of the quinolones associate preferably with the protein than with these models. This suggests that an interaction drug/porin is, probably, the preferentially used for the latest fluoroquinolones what makes reasonable to believe that a strong affinity for OmpF means a better capacity to transpose the barrier formed by the outer membrane.     

Isolation and characterization of recombinant OmpF-like porin from the Yersinia pseudotuberculosis outer membrane

The encoding sequence of the pore-forming OmpF-like protein from the Yersinia pseudotuberculosis outer membrane was cloned and expressed in Escherichia coli cells. Conditions were selected for isolation and refolding of recombinant monomer and porin trimer. Their spatial structures were characterized by the intrinsic protein fluorescence and CD spectroscopy. It was shown that the recombinant porins are similar in the composition of secondary structure elements to the isolated porins, but have a considerably less compact tertiary structure. The pore-forming activities of the recombinant proteins are similar to those of Y. pseudotuberculosis native porins. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2008, vol. 34, no. 2; see also http://www.maik.ru.     

Isolation and characterization of recombinant OmpF-like porin from the Yersinia pseudotuberculosis outer membrane

The encoding sequence of the pore-forming OmpF-like protein from the Yersinia pseudotuberculosis outer membrane was cloned and expressed in Escherichia coli cells. Conditions for isolation and refolding of recombinant monomer and porin trimer were selected. Their spatial structures were characterized by the intrinsic protein fluorescence and CD spectroscopy. It was shown that recombinant porins are similar in the composition of secondary structure elements to isolated porins, but have a considerably less compact tertiary structure. The pore-forming activities of the recombinant proteins are similar to those of Y. pseudotuberculosis native porins.     

Expression in Escherichia coli and function of Pseudomonas aeruginosa outer membrane porin protein F

The gene encoding porin protein F of Pseudomonas aeruginosa was cloned onto a cosmid vector into Escherichia coli. Protein F was expressed as the predominant outer membrane protein in a porin-deficient E. coli background and was clearly visible on one-dimensional sodium dodecyl sulfate-polyacrylamide gels in a porin-sufficient background. The identity of the protein F from the E. coli clone and native P. aeruginosa protein F was demonstrated by their identical mobilities on sodium dodecyl sulfate-polyacrylamide gel electrophoretograms, 2-mercaptoethanol modifiabilities, and reactivities with monoclonal antibodies specific of two separate epitopes of protein F. In the course of gene subcloning, a 2-kilobase DNA fragment was isolated, with an apparent truncation of the part of the gene encoding the carboxy terminus of protein F. This subclone produced a 24,000-molecular-weight, outer membrane-associated, truncated protein F derivative which was not 2-mercaptoethanol modifiable and which reacted with only one of the two classes of protein F-specific monoclonal antibodies. The 2-kilobase fragment was used in Southern blot hybridizations to construct a restriction map of the cloned and subcloned fragments and to demonstrate with restriction digests of whole P. aeruginosa DNA that only one copy of the protein F gene was present in the P. aeruginosa chromosome. The protein F produced by the original cosmid clone in a porin-deficient E. coli background was purified. To demonstrate retention of porin function after cloning, the protein F from the E. coli clone was incorporated into black lipid bilayer membranes. Two major classes of channels were revealed. The predominant class of channels had an average conductance of 0.36 nS in 1 M KCl, whereas larger channels (4 to 7 nS) were seen at a lower frequency. Similar channel sizes were observed for porin protein F purified by the same method from P. aeruginosa outer membranes.     

Evidence for a novel domain of bacterial outer membrane ushers

Many pathogenic bacteria possess adhesive surface organelles (called pili), anchored to their outer membrane, which mediate the first step of infection by binding to host tissue. Pilus biogenesis occurs via the "chaperone-usher" pathway: the usher, a large outer membrane protein, binds complexes of a periplasmic chaperone with pilus subunits, unloads the subunits from the chaperone, and assembles them into the pilus, which is extruded into the extracellular space. Ushers comprise an N-terminal periplasmic domain, a large transmembrane beta-barrel central domain, and a C-terminal periplasmic domain. Since structural data are available only for the N-terminal domain, we performed an in-depth bioinformatic analysis of bacterial ushers. Our analysis led us to the conclusion that the transmembrane beta-barrel region of ushers contains a so far unrecognized soluble domain, the "middle domain", which possesses a beta-sandwich fold. Two other bacterial beta-sandwich domains, the TT0351 protein from Thermus thermophilus and the carbohydrate binding module CBM36 from Paenibacillus polymyxa, are possible distant relatives of the usher "middle domain". Several mutations reported to abolish in vivo pilus formation cluster in this region, underlining its functional importance.     

Incorporation of heterologous outer membrane and periplasmic proteins into Escherichia coli outer membrane vesicles

Gram-negative bacteria shed outer membrane vesicles composed of outer membrane and periplasmic components. Since vesicles from pathogenic bacteria contain virulence factors and have been shown to interact with eukaryotic cells, it has been proposed that vesicles behave as delivery vehicles. We wanted to determine whether heterologously expressed proteins would be incorporated into the membrane and lumen of vesicles and whether these altered vesicles would associate with host cells. Ail, an outer membrane adhesin/invasin from Yersinia enterocolitica, was detected in purified outer membrane and in vesicles from Escherichia coli strains DH5alpha, HB101, and MC4100 transformed with plasmid-encoded Ail. In vesicle-host cell co-incubation assays we found that vesicles containing Ail were internalized by eukaryotic cells, unlike vesicles without Ail. To determine whether lumenal vesicle contents could be modified and delivered to host cells, we used periplasmically expressed green fluorescent protein (GFP). GFP fused with the Tat signal sequence was secreted into the periplasm via the twin arginine transporter (Tat) in both the laboratory E. coli strain DH5alpha and the pathogenic enterotoxigenic E. coli ATCC strain 43886. Pronase-resistant fluorescence was detectable in vesicles from Tat-GFP-transformed strains, demonstrating that GFP was inside intact vesicles. Inclusion of GFP cargo increased vesicle density but did not result in morphological changes in vesicles. These studies are the first to demonstrate the incorporation of heterologously expressed outer membrane and periplasmic proteins into bacterial vesicles.     

Structure and functional characterization of the periplasmic N-terminal polypeptide domain of the sugar-specific ion channel protein (ScrY porin)

The structure of the sucrose-specific porin (ScrY) from Salmonella typhimurium has been elucidated by X-ray crystallography to consist of 18 antiparallel beta-strands, associated as a trimer complex similar to ion-transport channels. However, the 71-amino-acid-residue N-terminal periplasmic domain was not determined from the crystal structure due to the absence of sufficient electron density. The N-terminal polypeptide contains a coiled-coil structural motif and has been assumed to play a role in the sugar binding of ScrY porin. In this study the proteolytic stability and a specific proteolytic truncation site at the N-terminal domain were identified by the complete primary structure characterization of ScrY porin, using MALDI mass spectrometry and post-source-decay fragmentation. The secondary structure and supramolecular association of the coiled-coil N-terminal domain were determined by chemical synthesis of the complete N-terminal polypeptide and several partial sequences and their spectroscopic, biophysical, and mass spectrometric characterization. Circular dichroism spectra revealed predominant alpha-helical conformation for the putative coiled-coil domain comprising residues 4-46. Specific association to both dimer and trimer complexes was identified by electrospray ionization mass spectra and was ascertained by dynamic light scattering and electrophoresis data. The role of the N-terminal domain in sugar binding was examined by comparative TR-NOE-NMR spectroscopy of the complete ScrY porin and a recombinant mutant, ScrY(delta1-62), lacking the N-terminal polypeptide. The TR-NOE-NMR data showed a strong influence of ScrY porin on the sugar-binding affinity and suggested a possible function of the periplasmic N terminus for supramolecular stabilization and low-affinity sugar binding.     

Crystal structure of the major periplasmic domain of the bacterial membrane protein assembly facilitator YidC

The essential bacterial membrane protein YidC facilitates insertion and assembly of proteins destined for integration into the inner membrane. It has homologues in both mitochondria and chloroplasts. Here we report the crystal structure of the Escherichia coli YidC major periplasmic domain (YidCECP1) at 2.5A resolution. This domain is present in YidC from Gram-negative bacteria and is more than half the size of the full-length protein. The structure reveals that YidCECP1 is made up of a large twisted beta-sandwich protein fold with a C-terminal alpha-helix that packs against one face of the beta-sandwich. Our structure and sequence analysis reveals that the C-terminal alpha-helix and the beta-sheet that it lays against are the most conserved regions of the domain. The region corresponding to the C-terminal alpha-helix was previously shown to be important for the protein insertase function of YidC and is conserved in other YidC-like proteins. The structure reveals that a region of YidC that was previously shown to be involved in binding to SecF maps to one edge of the beta-sandwich. Electrostatic analysis of the molecular surface for this region of YidC reveals a predominantly charged surface and suggests that the SecF-YidC interaction may be electrostatic in nature. Interestingly, YidCECP1 has significant structural similarity to galactose mutarotase from Lactococcus lactis, suggesting that this domain may have another function besides its role in membrane protein assembly.     

Biochemical and biophysical characterization of in vitro folded outer membrane porin PorA of Neisseria meningitidis

Two subtypes of the outer membrane porin PorA of Neisseria meningitidis, P1.6 and P1.7,16, were folded in vitro after overexpression in, and isolation from Escherichia coli. The PorA porins could be folded efficiently by quick dilution in an appropriate buffer containing the detergent n-dodecyl-N, N-dimethyl-1-ammonio-3-propanesulphonate. Although the two PorA porins are highly homologous, they required different acidities for optimal folding, that is, a pH above the pI was needed for efficient folding. Furthermore, whereas trimers of PorA P1.7,16 were almost completely stable in 2% sodium dodecyl sulphate (SDS), those of P1.6 dissociated in the presence of SDS. The higher electrophoretic mobility of the in vitro folded porins could be explained by the stable association of the RmpM protein to the porins in vivo. This association of RmpM contributes to the stability of the porins. The P1.6 pores were moderately cation-selective and displayed a single-channel conductance of 2.8 nS in 1 M KCl. The PorA P1.6 pores, but not the PorA P1.7,16 pores, showed an unusual non-linear dependence of the single-channel conductance on the salt concentration of the subphase. We hypothesize that a cluster of three negatively charged residues in L5 of P1.6 is responsible for the higher conductance at low salt concentrations.     

The periplasmic folding of a cysteineless autotransporter passenger domain interferes with its outer membrane translocation

Autotransporters are single polypeptides consisting of an outer membrane translocation domain mediating the translocation of a passenger domain. The periplasmic folding state of the passenger domain is controversial. By comparisons of passenger domains differing in their folding properties, our results suggest that periplasmic folding of passenger domains interferes with translocation.     

Structure and flexibility of the complete periplasmic domain of BamA: the protein insertion machine of the outer membrane

Folding and insertion of β-barrel outer membrane proteins (OMPs) is essential for Gram-negative bacteria. This process is mediated by the multiprotein complex BAM, composed of the essential β-barrel OMP BamA and four lipoproteins (BamBCDE). The periplasmic domain of BamA is key for its function and contains five "polypeptide transport-associated" (POTRA) repeats. Here, we report the crystal structure of the POTRA4-5 tandem, containing the essential for BAM complex formation and cell viability POTRA5. The domain orientation observed in the crystal is validated by solution NMR and SAXS. Using previously determined structures of BamA POTRA1-4, we present a spliced model of the entire BamA periplasmic domain validated by SAXS. Solution scattering shows that conformational flexibility between POTRA2 and 3 gives rise to compact and extended conformations. The length of BamA in its extended conformation suggests that the protein may bridge the inner and outer membranes across the periplasmic space.     

Naturally crystalline porin in the outer membrane of Bordetella pertussis

The Gram-negative bacterium Bordetella pertussis is the agent responsible for whooping-cough, and much interest has focused on the functions, structures and immunological properties of the molecules exposed at its outer surface. We have found by electron microscopy that cells of two strains of B. pertussis are covered with a crystalline surface lattice. This lattice is not an extrinsic layer of high molecular weight glycoproteins, such as occur on many other bacteria, but is a natural crystal of an intrinsic membrane protein of 40,000 Mr. This molecule has been shown to be an anion-selective member of an extensive family of proteins ("porins") that render Gram-negative outer membranes permeable to solutes of up to approximately 650 Mr. Computer image processing reveals a trimeric channel-like structure that closely resembles other porins visualized in artificial arrays after treatment with detergents, but in a novel (p2) crystal form. This correlation provides a "missing link" between earlier structural studies based on artificial arrays of porins (of undefined physiological status), and membrane-permeabilization experiments with solubilized porins (in undefined structural states). For the strains characterized so far, crystallinity of the porin surface lattice shows an intriguing correlation with nonpathogenicity.     

Purification, refolding and characterization of the trimeric Omp2a outer membrane porin from Brucella melitensis

Brucella melitensis is a gram-negative bacteria known to cause brucellosis and to produce severe infections in humans. Whilst brucella's outer membrane proteins have been extensively studied due to their potential role as antigens or virulence factors, their function is still poorly understood at the structural level, as the 3D structure of Brucella β-barrel membrane proteins are still unknown. In this context, the B. melitensis trimeric Omp2a porin has been overexpressed and refolded in n-dodecyl-β-d-maltopyranoside. We here show that this refolding process is insensitive to urea but is temperature- and ionic strength-dependent. Reassembled species were characterized by fluorescence, size-exclusion chromatography and circular dichroism. A refolding mechanism is proposed, suggesting that Omp2a first refolds under a monomeric form and then self-associates into a trimeric state. This first complete in vitro refolding of a membrane protein from B. melitensis shall eventually lead to functional and 3D structure determination.     

Interaction between bacterial outer membrane proteins and periplasmic quality control factors: a kinetic partitioning mechanism

The OMPs (outer membrane proteins) of Gram-negative bacteria have to be translocated through the periplasmic space before reaching their final destination. The aqueous environment of the periplasmic space and high permeability of the outer membrane engender such a translocation process inevitably challenging. In Escherichia coli, although SurA, Skp and DegP have been identified to function in translocating OMPs across the periplasm, their precise roles and their relationship remain to be elucidated. In the present paper, by using fluorescence resonance energy transfer and single-molecule detection, we have studied the interaction between the OMP OmpC and these periplasmic quality control factors. The results of the present study reveal that the binding rate of OmpC to SurA or Skp is much faster than that to DegP, which may lead to sequential interaction between OMPs and different quality control factors. Such a kinetic partitioning mechanism for the chaperone-substrate interaction may be essential for the quality control of the biogenesis of OMPs.     

Expression and characterization of the integral membrane domain of bacterial histidine kinase SCO3062 for structural studies

Bacterial histidine kinases play an important role in the response to external stimuli. Structural studies of the histidine kinase transmembrane domain are challenging due to difficulties in protein expression and sample preparation. After carrying out expression screening of a series of histidine kinases, we investigated sample preparation methods for obtaining high quality samples of the periplasmic and transmembrane domain (PTD) of the bacterial histidine kinase SCO3062. Various sample conditions were tested for their ability to give homogeneous NMR spectra of the SCO3062 PTD with well-resolved resonances. Circular dichroism and 3D ¹⁵N-edited NOESY spectrum results demonstrate that the SCO3062 PTD is predominantly α-helical. This method should be applicable to the NMR analysis of other transmembrane proteins.     

A disulfide bridge network within the soluble periplasmic domain determines structure and function of the outer membrane protein RCSF

RcsF, a proposed auxiliary regulator of the regulation of capsule synthesis (rcs) phosphorelay system, is a key element for understanding the RcsC-D-A/B signaling cascade, which is responsible for the regulation of more than 100 genes and is involved in cell division, motility, biofilm formation, and virulence. The RcsC-D-A/B system is one of the most complex bacterial signal transduction pathways, consisting of several membrane-bound and soluble proteins. RcsF is a lipoprotein attached to the outer membrane and plays an important role in activating the RcsC-d-A/B pathway. The exact mechanism of activation of the rcs phosphorelay by RcsF, however, remains unknown. We have analyzed the sequence of RcsF and identified three structural elements: 1) an N-terminal membrane-anchored helix (residues 3-13), 2) a loop (residues 14-48), and 3) a C-terminal folded domain (residues 49-134). We have determined the structure of this C-terminal domain and started to investigate its interaction with potential partners. Important features of its structure are two disulfide bridges between Cys-74 and Cys-118 and between Cys-109 and Cys-124. To evaluate the importance of this RcsF disulfide bridge network in vivo, we have examined the ability of the full-length protein and of specific Cys mutants to initiate the rcs signaling cascade. The results indicate that the Cys-74/Cys-118 and the Cys-109/Cys-124 residues correlate pairwise with the activity of RcsF. Interaction studies showed a weak interaction with an RNA hairpin. However, no interaction could be detected with reagents that are believed to activate the rcs phosphorelay, such as lysozyme, glucose, or Zn(2+) ions.     

On the targeting and membrane assembly of the Escherichia coli outer membrane porin, PhoE

Abstract Within gram-negative bacteria such as Escherichia coli , the outer membrane porins provide a relatively non-specific uptake route which is utilised by a wide range of solutes including many antibiotics. Understanding the targeting and membrane assembly of these proteins is therefore of importance and this mini review aims to discuss this process in light of present knowledge.     

Orientation of porin channels in the outer membrane of Bordetella pertussis

We have examined the surface topography and channel connectivity of a naturally crystalline porin that is known to be functional, and whose structure has not been perturbed by detergent extraction, A three-dimensional density map, calculated from two independent tilt series of negatively stained cell envelopes, reveals three separate channels per trimer on one side (the ‘smooth’ side), and a single common opening at the other (‘rough’) side. This arrangement is consistent with the molecular structures recently determined at high resolution by X-ray crystallography for three other porins after detergent solubilization, and implies that the Bordetella pertussis porin may have the same kind of folding. Surface relief maps calculated from electron micrographs of cell envelopes contrasted by unidirectional shadowing clearly show that the side with single opening (i.e. the rough side) represents the external surface.     

Alignment and structure prediction of divergent protein families: periplasmic and outer membrane proteins of bacterial efflux pumps

Broad-specificity efflux pumps have been implicated in multidrug-resistant strains of Pseudomonas aeruginosa and other Gram-negative bacteria. Most Gram-negative pumps of clinical relevance have three components, an inner membrane transporter, an outer membrane channel protein, and a periplasmic protein, which together coordinate efflux from the cytoplasmic membrane across the outer membrane through an unknown mechanism. The periplasmic efflux proteins (PEPs) and outer membrane efflux proteins (OEPs) are not obviously related to proteins of known structure, and understanding the structure and function of these proteins has been hindered by the difficulty of obtaining reasonable multiple alignments. We present a general strategy for the alignment and structure prediction of protein families with low mutual sequence similarity using the PEP and OEP families as detailed examples. Gibbs sampling, hidden Markov models, and other analysis techniques were used to locate motifs, generate multiple alignments, and assign PEP or OEP function to hypothetical proteins in several species. We also developed an automated procedure which combines multiple alignments with structure prediction algorithms in order to identify conserved structural features in protein families. This process was used to identify a probable alpha-helical hairpin in the PEP family and was applied to the detection of transmembrane beta-strands in OEPs. We also show that all OEPs contain a large tandem duplication, and demonstrate that the OEP family is unlikely to adopt a porin fold, in contrast to previous predictions.