Crystal structure of the outer membrane protein OpdK from Pseudomonas aeruginosa

In Gram-negative bacteria that do not have porins, most water-soluble and small molecules are taken up by substrate-specific channels belonging to the OprD family. We report here the X-ray crystal structure of OpdK, an OprD family member implicated in the uptake of vanillate and related small aromatic acids. The OpdK structure reveals a monomeric, 18-stranded beta barrel with a kidney-shaped central pore. The OpdK pore constriction is relatively wide for a substrate-specific channel (approximately 8 A diameter), and it is lined by a positively charged patch of arginine residues on one side and an electronegative pocket on the opposite side-features likely to be important for substrate selection. Single-channel electrical recordings of OpdK show binding of vanillate to the channel, and they suggest that OpdK forms labile trimers in the outer membrane. Comparison of the OpdK structure with that of Pseudomonas aeruginosa OprD provides the first qualitative insights into the different substrate specificities of these closely related channels.     

Atomistic Molecular-Dynamics Simulations Enable Prediction of the Arginine Permeation Pathway through OccD1/OprD from Pseudomonas?aeruginosa

Pseudomonas aeruginosa is a Gram-negative bacterium that does not contain large, nonspecific porins in its outer membrane. Consequently, the outer membrane is highly impermeable to polar solutes and serves as a barrier against the penetration of antimicrobial agents. This is one of the reasons why such bacteria are intrinsically resistant to antibiotics. Polar molecules that permeate across the outer membrane do so through substrate-specific channels proteins. To design antibiotics that target substrate-channel proteins, it is essential to first identify the permeation pathways of their natural substrates. In P. aeruginosa, the largest family of substrate-specific proteins is the OccD (previously reported under the name OprD) family. Here, we employ equilibrium and steered molecular-dynamics simulations to study OccD1/OprD, the archetypical member of the OccD family. We study the permeation of arginine, one of the natural substrates of OccD1, through the protein. The combination of simulation methods allows us to predict the pathway taken by the amino acid, which is enabled by conformational rearrangements of the extracellular loops of the protein. Furthermore, we show that arginine adopts a specific orientation to form the molecular interactions that facilitate its passage through part of the protein. We predict a three-stage permeation process for arginine.     

Atomistic Molecular-Dynamics Simulations Enable Prediction of the Arginine Permeation Pathway through OccD1/OprD from Pseudomonas aeruginosa

Pseudomonas aeruginosa is a Gram-negative bacterium that does not contain large, nonspecific porins in its outer membrane. Consequently, the outer membrane is highly impermeable to polar solutes and serves as a barrier against the penetration of antimicrobial agents. This is one of the reasons why such bacteria are intrinsically resistant to antibiotics. Polar molecules that permeate across the outer membrane do so through substrate-specific channels proteins. To design antibiotics that target substrate-channel proteins, it is essential to first identify the permeation pathways of their natural substrates. In P. aeruginosa, the largest family of substrate-specific proteins is the OccD (previously reported under the name OprD) family. Here, we employ equilibrium and steered molecular-dynamics simulations to study OccD1/OprD, the archetypical member of the OccD family. We study the permeation of arginine, one of the natural substrates of OccD1, through the protein. The combination of simulation methods allows us to predict the pathway taken by the amino acid, which is enabled by conformational rearrangements of the extracellular loops of the protein. Furthermore, we show that arginine adopts a specific orientation to form the molecular interactions that facilitate its passage through part of the protein. We predict a three-stage permeation process for arginine.     

Role of the novel OprD family of porins in nutrient uptake in Pseudomonas aeruginosa

To circumvent the permeability barrier of its outer membrane, Pseudomonas aeruginosa has evolved a series of specific porins. These channels have binding sites for related classes of molecules that facilitate uptake under nutrient-limited conditions. Here, we report on the identification of a 19-member family of porins similar to the basic-amino-acid-specific porin OprD. The members of this family fell into one of two phylogenetically distinct clusters, one bearing high similarity to OprD and the other bearing most similarity to the putative phenylacetic acid uptake porin PhaK of Pseudomonas putida. Analysis of the genome context, operon arrangement, and regulation of the PhaK-like porin OpdK indicated that it might be involved in vanillate uptake. This result was confirmed by demonstrating that an opdK mutant had a deficiency in the ability to grow on vanillate as a carbon source. To extrapolate these data to other paralogues within this family, the substrate specificities of 6 of the 17 remaining OprD homologues were inferred using an approach similar to that used with opdK. The specificities determined were as follows: OpdP, glycine-glutamate; OpdC, histidine; OpdB, proline; OpdT, tyrosine; OpdH, cis-aconitate; and OpdO, pyroglutamate. Thus, members of the OprD subfamily took up amino acids and related molecules, and those characterized members most similar to PhaK were responsible for the uptake of a diverse array of organic acids. These results imply that there is a functional basis for the phylogenetic clustering of these proteins and provide a framework for studying OprD homologues in other organisms.     

Molecular dynamics simulation study of the vanillate transport channel of Opdk

Most water-soluble and small molecules are taken up by substrate-specific channels belonging to the Gram-negative bacteria. The protein named OpdK, a member of OprD family, plays an important role in transporting the vanillate as the only carbon source of Pseudomonas aeruginosa. P. aeruginosa infections can be serious due to the high intrinsic antibiotic resistance owing to the present of the OprD family. We applied standard molecular dynamics, steered molecular dynamics and umbrella sampling, to investigate the thermodynamics of vanillate passing through the pore of OpdK protein at physiological temperature. The results indicate that hydrogen bonds of vanillate-L3 (L3: Gly92-Gln111) and hydrophobic interactions of vanillate-L7 (Gly252-Asn278) are crucial to the transport of vanillate. Compared to L7, L3 can hardly change the shape of the pore, but its amino acids can effectively affect the transport process. The important role of charged residues in the barrel of the protein for the substrate transport has been proved in the experiment researches and our simulations also determinate that these residues may prevent the vanillate from entering the cell. These results provide detailed information that will facilitate the development of effective drugs.     

Raising antibodies against OprD, an outer membrane protein of Pseudomonas aeruginosa using translational fusions to MalE.

OprD is an outer membrane porin of Pseudomonas aeruginosa that mediates uptake of basic amino acids, peptides as well as carbapenem antibiotics. Polyclonal antibodies were raised against the OprD porin by creating protein fusions between the Escherichia coli maltose binding protein and four OprD fragments. These were expressed in E. coli and shown to be exported to the periplasm. The fusion proteins were purified by amylose affinity chromatography and used to immunize rabbits intramuscularly. We established that MalE fusions to OprD fragments retain maltose and amylose binding activities in vivo and in vitro, confirming proper folding of the MalE domain of hybrid proteins. Furthermore, we demonstrate that this strategy can be used to obtain specific antibodies against bacterial outer membrane proteins (OMPs).     

The outer membrane protein OmpW forms an eight-stranded beta-barrel with a hydrophobic channel

Escherichia coli OmpW belongs to a family of small outer membrane proteins that are widespread in Gram-negative bacteria. Their functions are unknown, but recent data suggest that they may be involved in the protection of bacteria against various forms of environmental stress. To gain insight into the function of these proteins A we have determined the crystal structure of E. coli OmpW to 2.7-A resolution. The structure shows that OmpW forms an 8-stranded beta-barrel with a long and narrow hydrophobic channel that contains a bound n-dodecyl-N,N-dimethylamine-N-oxide detergent molecule. Single channel conductance experiments show that OmpW functions as an ion channel in planar lipid bilayers. The channel activity can be blocked by the addition of n-dodecyl-N,N-dimethylamine-N-oxide. Taken together, the data suggest that members of the OmpW family could be involved in the transport of small hydrophobic molecules across the bacterial outer membrane.     

Molecular cloning and characterization of the oprQ gene coding for outer membrane protein OprE3 of Pseudomonas aeruginosa.

We cloned and characterized the oprQ gene coding for outer membrane protein OprE3 of Pseudomonas aeruginosa PAO1. The oprQ gene was composed of 1,275 base pairs including a sequence encoding for the signal sequence and a mature protein with a Mr of 44,602. Computer-aided alignment and hydropathy analyses of the predicted amino acid sequences suggested that OprE3 is a transmembrane protein homologous to outer membrane proteins of P. aeruginosa such as OprD2 (OprD) porin and OprE1 (OprE) porin. Susceptibility to several antibiotics of the strains lacking or overproducing OprE3 was indistinguishable from that of the wild-type strain, suggesting that OprE3 is unlikely involved in the diffusion of carbapenems and other beta-lactam antibiotics.     

Significance of composition and structure of the enterobacterial outer membrane to the transport of desired and undesired substances and its inhibition

The enterobacterial outer membrane forms a bilayer. Its outer monolyer consists of lipopolysaccharides and proteins, its inner monolayer of phospholipids and proteins. It thus represents an efficient penetration barrier against hydrophobic and anionic compounds (such as detergents or hydrophobic antibiotics) and against higher molecular substances (such as proteolytic, lipolytic, and murolylic enzymes). Some of the proteins (“porins”) form channels through the outer membrane through which neutral and cationic hydrophylic compounds up to a molecular weight of about 800 can pass. Besides the porins additional transport systems have been described. They play an important part in providing the bacteria with substances necessary for their growth, i.e., phosphate, iron ions, and others. Organic polycations are able to generate more or less severe disorganizations in the outer membrane through which they can pass the bilayer (“self-promoted pathway”). Some of these polycations represent efficient antibiotics (polymyxin B, nourseothricin). Bacteria are able to protect themselves against the harmful action of these substances by changing the composition of the outer membrane.     

The role of specific surface loop regions in determining the function of the imipenem-specific pore protein OprD of Pseudomonas aeruginosa.

Pseudomonas aeruginosa OprD is a specific porin which facilitates the uptake of basic amino acids and imipenem across the outer membrane. In this study, we examined the effects of deletions in six of the proposed eight surface loops of OprD on the in vivo and in vitro functions of this protein. Native OprD formed very small channels in planar lipid bilayers, with an average single-channel conductance in 1.0 M KCl of 20 pS. When large numbers of OprD channels were incorporated into lipid bilayer membranes, addition of increasing concentrations of imipenem to the bathing solutions resulted in a progressive blocking of the membrane conductance of KCl, indicating the presence of a specific binding site(s) for imipenem in the OprD channel. From these experiments, the concentration of imipenem value of resulting in 50% inhibition of the initial conductance was calculated as approximately 0.6 microM. In contrast, no decrease in channel conductance was observed for the OprDdeltaL2 channel upon addition of up to 2.4 microM imipenem, confirming that external loop 2 was involved in imipenem binding. Deletion of four to eight amino acids from loops 1 and 6 had no effect on antibiotic susceptibility, whereas deletion of eight amino acids from loops 5, 7, and 8 resulted in supersusceptibility to beta-lactams, quinolones, chloramphenicol, and tetracycline. Planar lipid bilayer analysis indicated that the OprDdeltaL5 channel had a 33-fold increase in single-channel conductance in 1 M KCl but had retained its imipenem binding site. The disposition of these loop regions in the interior of the OprD channel is discussed.     

Bacterial outer membrane constriction

The outer membrane of Gram‐negative bacteria is a crucial permeability barrier allowing the cells to survive a myriad of toxic compounds, including many antibiotics. This innate form of antibiotic resistance is compounded by the evolution of more active mechanisms of resistance such as efflux pumps, reducing the already limited number of clinically relevant treatments for Gram‐negative pathogens. During cell division Gram‐negative bacteria must coordinate constriction of the outer membrane in conjunction with other crucial layers of the cell envelope, the peptidoglycan cell wall and the inner membrane. Coordination is crucial in maintaining structural integrity of the envelope, and represents a highly vulnerable time for the cell as any failure can be fatal, if not least disadvantageous. However, the molecular mechanisms of cell division and how the biogenesis of the three layers is synchronised during constriction remain largely unknown. Perturbations of the outer membrane have been shown to increase the effectiveness of antibiotics in vitro, and so with improved understanding of this process we may be able to exploit this vulnerability and improve the effectiveness of antibiotic treatments. In this review the current knowledge of how Gram‐negative bacteria facilitate constriction of their outer membranes during cell division will be discussed.     

Molecular dynamic study of MlaC protein in Gram‐negative bacteria: conformational flexibility,solvent effect and protein‐phospholipid binding

The composition of the outer membrane in Gram‐negative bacteria is asymmetric, with the lipopolysaccharides found in the outer leaflet and phospholipids in the inner leaflet. The MlaC protein transfers phospholipids from the outer to inner membrane to maintain such lipid asymmetry in the Mla pathway. In this work, we have performed molecular dynamics simulations on apo and phospholipid‐bound systems to study the dynamical properties of MlaC. Our simulations show that the phospholipid forms hydrophobic interactions with the protein. Residues surrounding the entrance of the binding site exhibit correlated motions to control the site opening and closing. Lipid binding leads to increase of the binding pocket volume and precludes entry of the water molecules. However, in the absence of the phospholipid, water molecules can freely move in and out of the binding site when the pocket is open. Dehydration occurs when the pocket closes. This study provides dynamic information of the MlaC protein and may facilitate the design of antibiotics against the Mla pathway of Gram‐negative bacteria.     

Cellular impermeability and uptake of biocides and antibiotics in gram-positive bacteria and mycobacteria

Gram-positive bacteria possess a permeable cell wall that usually does not restrict the penetration of antimicrobials. However, resistance due to restricted penetration can occur, as illustrated by vancomycin-intermediate resistant Staphylococcus aureus strains (VISA) which produce a markedly thickened cell wall. Alterations in these strains include increased amounts of nonamidated glutamine residues in the peptidoglycan and it is suggested that the resistance mechanism involves 'affinity trapping' of vancomycin in the thickened cell wall. VISA strains have reduced doubling times, lower sensitivity to lysostaphin and reduced autolytic activity, which may reflect changes in the D-alanyl ester content of the wall and membrane teichoic acids. Mycobacterial cell walls have a high lipid content, which is assumed to act as a major barrier to the penetration of antimicrobial agents. Relatively hydrophobic antibiotics such as rifampicin and fluoroquinolones may be able to cross the cell wall by diffusion through the hydrophobic bilayer composed of long chain length mycolic acids and glycolipids. Hydrophilic antibiotics and nutrients cannot diffuse across this layer and are thought to use porin channels which have been reported in many species of mycobacteria. The occurrence of porins in a lipid bilayer supports the view that the mycobacterial wall has an outer membrane analogous to that of gram-negative bacteria. However, mycobacterial porins are much less abundant than in the gram-negative outer membrane and allow only low rates of uptake for small hydrophilic nutrients and antibiotics.     

Molecular basis of bacterial outer membrane permeability revisited.

Gram-negative bacteria characteristically are surrounded by an additional membrane layer, the outer membrane. Although outer membrane components often play important roles in the interaction of symbiotic or pathogenic bacteria with their host organisms, the major role of this membrane must usually be to serve as a permeability barrier to prevent the entry of noxious compounds and at the same time to allow the influx of nutrient molecules. This review summarizes the development in the field since our previous review (H. Nikaido and M. Vaara, Microbiol. Rev. 49:1-32, 1985) was published. With the discovery of protein channels, structural knowledge enables us to understand in molecular detail how porins, specific channels, TonB-linked receptors, and other proteins function. We are now beginning to see how the export of large proteins occurs across the outer membrane. With our knowledge of the lipopolysaccharide-phospholipid asymmetric bilayer of the outer membrane, we are finally beginning to understand how this bilayer can retard the entry of lipophilic compounds, owing to our increasing knowledge about the chemistry of lipopolysaccharide from diverse organisms and the way in which lipopolysaccharide structure is modified by environmental conditions.     

Pore Size Dependence on Growth Temperature Is a Common Characteristic of the Major Outer Membrane Protein OprF in Psychrotrophic and Mesophilic Pseudomonas Species

Pseudomonas species adapt well to hostile environments, which are often subjected to rapid variations. In these bacteria, the outer membrane plays an important role in the sensing of environmental conditions such as temperature. In previous studies, it has been shown that in the psychrotrophic strain P. fluorescens MF0, the major porin OprF changes its channel size according to the growth conditions and could affect outer membrane permeability. Studies of the channel-forming properties of OprFs from P. putida 01G3 and P. aeruginosa PAO1 in planar lipid bilayers generated similar results. The presence of a cysteine- or proline-rich cluster in the central linker region is not essential for channel size modulations. These findings suggest that OprF could adopt two alternative conformations in the outer membrane and that folding is thermoregulated. In contrast, no difference according to growth temperature was observed for structurally different outer membrane proteins, such as OprE3 from the Pseudomonas OprD family of specific porins. Our results are consistent with the fact that the decrease in channel size observed at low growth temperature is a particular feature of the OprF porin in various psychrotrophic and mesophilic Pseudomonas species isolated from diverse ecological niches. The ability to reduce outer membrane permeability at low growth temperature could provide these bacteria with adaptive advantages.     

Molecular Basis of Bacterial Outer Membrane Permeability Revisited

Gram-negative bacteria characteristically are surrounded by an additional membrane layer, the outer membrane. Although outer membrane components often play important roles in the interaction of symbiotic or pathogenic bacteria with their host organisms, the major role of this membrane must usually be to serve as a permeability barrier to prevent the entry of noxious compounds and at the same time to allow the influx of nutrient molecules. This review summarizes the development in the field since our previous review (H. Nikaido and M. Vaara, Microbiol. Rev. 49:1-32, 1985) was published. With the discovery of protein channels, structural knowledge enables us to understand in molecular detail how porins, specific channels, TonB-linked receptors, and other proteins function. We are now beginning to see how the export of large proteins occurs across the outer membrane. With our knowledge of the lipopolysaccharide-phospholipid asymmetric bilayer of the outer membrane, we are finally beginning to understand how this bilayer can retard the entry of lipophilic compounds, owing to our increasing knowledge about the chemistry of lipopolysaccharide from diverse organisms and the way in which lipopolysaccharide structure is modified by environmental conditions.     

Current mechanistic understanding of intermembrane lipid trafficking important for maintenance of bacterial outer membrane lipid asymmetry

The outer membrane (OM) of Gram-negative bacteria exhibits unique lipid asymmetry that makes it an effective permeability barrier against toxic molecules, including antibiotics. Central to the maintenance of OM lipid asymmetry is the OmpC-Mla (maintenance of lipid asymmetry) system, which mediates the retrograde transport of phospholipids from the outer leaflet of the OM to the inner membrane. The molecular mechanism(s) of this lipid trafficking process is not fully understood; however, recent advances in structural elucidations and biochemical reconstitutions have provided detailed new insights. Here, we present an integrated understanding of how the OmpC-Mla system transports mislocalized phospholipids across the bacterial cell envelope.     

The α-barrel tip region of Escherichia coli TolC homologs of Vibrio vulnificus interacts with the MacA protein to form the functional macrolide-specific efflux pump MacAB-TolC

TolC and its homologous family of proteins are outer membrane factors that are essential for exporting small molecules and toxins across the outer membrane in Gram-negative bacteria. Two open reading frames in the Vibrio vulnificus genome that encode proteins homologous to Escherichia coli TolC, designated TolCV1 and TolCV2, have 51.3% and 29.6% amino acid identity to TolC, respectively. In this study, we show that TolCV1 and TolCV2 functionally and physically interacted with the membrane fusion protein, MacA, a component of the macrolide-specific MacAB-TolC pump of E. coli. We further show that the conserved residues located at the aperture tip region of the α-hairpin of TolCV1 and TolCV2 played an essential role in the formation of the functional MacAB-TolC pump using site-directed mutational analyses. Our findings suggest that these outer membrane factors have conserved tip-to-tip interaction with the MacA membrane fusion protein for action of the drug efflux pump in Gramnegative bacteria.     

Altered antibiotic transport in OmpC mutants isolated from a series of clinical strains of multi-drug resistant E. coli

Antibiotic-resistant bacteria, particularly gram negative species, present significant health care challenges. The permeation of antibiotics through the outer membrane is largely effected by the porin superfamily, changes in which contribute to antibiotic resistance. A series of antibiotic resistant E. coli isolates were obtained from a patient during serial treatment with various antibiotics. The sequence of OmpC changed at three positions during treatment giving rise to a total of four OmpC variants (denoted OmpC20, OmpC26, OmpC28 and OmpC33, in which OmpC20 was derived from the first clinical isolate). We demonstrate that expression of the OmpC K12 porin in the clinical isolates lowers the MIC, consistent with modified porin function contributing to drug resistance. By a range of assays we have established that the three mutations that occur between OmpC20 and OmpC33 modify transport of both small molecules and antibiotics across the outer membrane. This results in the modulation of resistance to antibiotics, particularly cefotaxime. Small ion unitary conductance measurements of the isolated porins do not show significant differences between isolates. Thus, resistance does not appear to arise from major changes in pore size. Crystal structures of all four OmpC clinical mutants and molecular dynamics simulations also show that the pore size is essentially unchanged. Molecular dynamics simulations suggest that perturbation of the transverse electrostatic field at the constriction zone reduces cefotaxime passage through the pore, consistent with laboratory and clinical data. This subtle modification of the transverse electric field is a very different source of resistance than occlusion of the pore or wholesale destruction of the transverse field and points to a new mechanism by which porins may modulate antibiotic passage through the outer membrane.     

Role of porins in iron uptake by Mycobacterium smegmatis

Many bacteria rely on siderophores to extract iron from the environment. However, acquisition of iron-loaded siderophores is dependent on high-affinity uptake systems that are not produced under high-iron conditions. The fact that bacteria are able to maintain iron homeostasis in the absence of siderophores indicates that alternative iron acquisition systems exist. It has been speculated that such low-affinity uptake of iron in Gram-negative bacteria includes diffusion of iron ions or chelates across the outer membrane through porins. The outer membrane of the saprophytic Mycobacterium smegmatis contains the Msp family of porins, which enable the diffusion of small and hydrophilic solutes, such as monosaccharides, amino acids, and phosphate. However, it is unknown how cations cross the outer membrane of mycobacteria. Here, we show that the Msp porins of M. smegmatis are involved in the acquisition of soluble iron under high-iron conditions. Uptake of ferric ions by a triple porin mutant was reduced compared to wild-type (wt) M. smegmatis. An intracellular iron reporter indicated that derepression of iron-responsive genes occurs at higher iron concentrations in the porin mutant. This was consistent with the finding that the porin mutant produced more siderophores under low-iron conditions than wt M. smegmatis. In contrast, uptake of the exochelin MS, the main siderophore of M. smegmatis, was not affected by the lack of porins, indicating that a specific outer membrane siderophore receptor exists. These results provide, to our knowledge, the first experimental evidence that general porins are indeed the outer membrane conduit of low-affinity iron acquisition systems in bacteria.