Characterization of Serologically Dominant Outer Membrane Proteins of Neisseria gonorrhoeae

The proteins of the outer membrane of Neisseria gonorrhoeae play an important role in the serotyping system defined by K. H. Johnston et al. (J. Exp. Med. 143:741–758, 1976). This study attempted to delineate the molecular arrangement of the major proteins of the outer membrane of the gonococcus by using three approaches. First, natural protein-protein relationships were demonstrated by symmetrical, two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Second, proteins exposed on the surface of outer membrane vesicles were cross-linked by using the bifunctional reagents dimethyl-3,3′-dithiobispropionimidate and dithiobis[succinimidyl propionate]. Third, specific antigen-antibody interactions on the surface of membrane vesicles were analyzed by radioautographic techniques. The major proteins of the outer membrane of the gonococcus were defined, and a nomenclature was devised to take into account the effects of heat and reducing agents on the resolution of these proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Results of cross-linking experiments strongly suggest that two of the major proteins of the gonococcal outer membrane (proteins 1 and 3) form a hydrophobically associated trimeric unit in situ which can be stabilized by selective cross-linking reagents. Results substantiated that these proteins are responsible for imparting serotypic specificity.     

Outer Membrane Proteins and Serosubtyping with Outer Membrane Vesicles from Clinical Isolates of Neisseria meningitidis

The currently practiced protocol for routine serosubtyping of Neisseria meningitidis relies on reactivity of whole cells to monoclonal antibodies against the class 1 outer membrane protein (OMP) in ELISAs or dot-blots. This procedure, however, failed to yield serosubtyping information in 28% (48/174) of clinical isolates (1993–1994) in the province of Québec, Canada. These 48 strains were characterized by OMP profiles and ELISAs with outer membrane vesicles (OMVs). Forty out of the 48 strains expressed class 1 OMP, indicating that the inability to assign a serosubtype was not owing to the absence of the class 1 OMP. Of these, 15 (38%) were serosubtypable in ELISAs with outer membrane vesicles. Thus, 81% (141/174) of all meningococcal strains were serosubtypable with ELISAs using whole-cells or OMVs. Because the routinely used procedure for serosubtyping of meningococci is limited in providing serosubtype information, alternate procedures are proposed to obtain comprehensive information for epidemiological identification of this bacterium. Received: 11 June 1996 / Accepted: 5 July 1996     

Outer Membrane Proteins of Escherichia coli IV. Differences in Outer Membrane Proteins Due To Strain and Cultural Differences

When the 42,000-dalton major outer membrane protein of Escherichia coli O111 is examined on alkaline polyacrylamide gels containing sodium dodecyl sulfate, it is resolved into three distinct bands designated as proteins 1, 2, and 3. Band 3 consists of two distinct polypeptides, proteins 3a and 3b. E. coli K-12 does not make any protein 2, but makes proteins similar to 1, 3a, and 3b as indicated by comparison of cyanogen bromide peptide patterns. Several Shigella species and most other strains of E. coli resemble E. coli K-12 in that they lack protein 2, whereas Salmonella typhimurium is more similar to E. coli O111. In addition to these species and strain differences, cultural differences resulted in differences in the outer membrane protein profiles. Under conditions of catabolite repression, the level of protein 2 in E. coli O111 decreased while the level of protein 1 increased. An enterotoxin-producing strain similar to E. coli O111 produced no protein 1 and an elevated level of protein 2 under conditions of low catabolite repression. The levels of proteins 1 and 3 are also different in different phases of the growth curve, with protein 1 being the major species in the exponential-phase cells and protein 3 being the major species in stationary-phase cells. A multiply phage-resistant mutant of E. coli K-12 with no obvious cell wall defects produced no protein 1 or 2, but made increased amounts of protein 3. Thus, the major outer membrane proteins of E. coli and related species may vary considerably without affecting outer membrane integrity.     

Cag3 Is a Novel Essential Component of the Helicobacter pylori Cag Type IV Secretion System Outer Membrane Subcomplex

Helicobacter pylori strains harboring the cag pathogenicity island (PAI) have been associated with more severe gastric disease in infected humans. The cag PAI encodes a type IV secretion (T4S) system required for CagA translocation into host cells as well as induction of proinflammatory cytokines, such as interleukin-8 (IL-8). cag PAI genes sharing sequence similarity with T4S components from other bacteria are essential for Cag T4S function. Other cag PAI-encoded genes are also essential for Cag T4S, but lack of sequence-based or structural similarity with genes in existing databases has precluded a functional assignment for the encoded proteins. We have studied the role of one such protein, Cag3 (HP0522), in Cag T4S and determined Cag3 subcellular localization and protein interactions. Cag3 is membrane associated and copurifies with predicted inner and outer membrane Cag T4S components that are essential for Cag T4S as well as putative accessory factors. Coimmunoprecipitation and cross-linking experiments revealed specific interactions with HpVirB7 and CagM, suggesting Cag3 is a new component of the Cag T4S outer membrane subcomplex. Finally, lack of Cag3 lowers HpVirB7 steady-state levels, further indicating Cag3 makes a subcomplex with this protein.Helicobacter pylori infects 50% of the world population. Stomach infection with this bacterium is associated with the development of several gastric diseases, including chronic active gastritis, peptic ulcers, gastric cancer, and mucosa-associated lymphoid tissue lymphoma. Factors influencing disease outcomes are not completely understood, but bacterial, host, and environmental factors have been identified that affect the dynamics of this bacterium-host interaction (30). A hallmark of H. pylori infection is the induction of mucosal inflammation, which is a risk factor for developing more severe pathology (27).Epidemiological studies have established that infection with strains harboring the cag pathogenicity island (PAI) leads to a higher risk for development of severe disease (27). The cag PAI size varies between 35 and 40 kb and encodes 27 putative proteins (1, 13). Several of the encoded proteins share sequence similarities with components of the prototypical type IV secretion (T4S) system VirB/D4 of Agrobacterium tumefaciens (15, 16). Based on research done in A. tumefaciens, the components of the molecular machinery have been divided into channel or core complex components (VirB6, VirB7, VirB8, VirB9, and VirB10), energetic components (VirB11, VirB4, and VirD4), and extracellular appendage components (VirB2 and VirB5). VirB6, VirB8, and VirB10 are components anchored at the inner membrane with domains spanning the periplasm, while VirB7 and VirB9 are located at the outer membrane. Energetic components are located at the inner membrane, and pilus components include the main subunit VirB2 and accessory components, such as VirB5, which functions as an adhesin (15, 16). The VirB/D4 T4S is thought to be energized by the inner membrane ATPases, and this energy is transduced to VirB10 and the outer membrane complex for protein translocation (11). The lipoprotein VirB7 is critical for the stability of HpVirB9 at the outer membrane (19).While the extent of homology of the H. pylori cag T4S components is often limited, sequence analysis has allowed the identification of the VirB11 (HP0525 and HpVirB11), VirB10 (HP0527 and HpVirB10), VirB9 (HP0528 and HpVirB9), and VirD4 (HP0524 and HpVirD4) homologues as summarized in Table S1 of the supplemental material (1, 13, 28). HpVirB9 and HpVirB10 homologies are not distributed along the entire length of the protein. For example, HpVirB10 is a very large protein with only a short domain similar to VirB10. HpVirB10 is also reported to localize on the external surface of the pilus (31), while VirB10 is tethered in the inner membrane. HP0529 (HpVirB6) and HP0530 (HpVirB8) have been assigned as homologs of VirB6 and VirB8, respectively (28). HP0523 (HpVirB1) has lytic transglycosylase activity, supporting its designation as a VirB1 homolog (38). HP0532 (HpVirB7) has a lipoprotein attachment site, suggesting a role as a VirB7 homolog (1, 28), and has been suggested to stabilize a Cag T4S outer membrane subcomplex containing CagM, HpVirB9, and HpVirB10 (28).The activity of the cag PAI-encoded T4S system is responsible for the translocation of the effector protein CagA and induction of proinflammatory chemokine and cytokine secretion, including the chemokine interleukin-8 (IL-8) (7). CagA T4S-mediated translocation into host cells is followed by tyrosine phosphorylation on specific tyrosine phosphorylation motifs (EPIYA motifs) at the C-terminal region of the protein and both phosphorylation-dependent and -independent interference with host cellular pathways. The induction of proinflammatory chemokine production is mediated by a still-uncharacterized Cag T4S-mediated delivery of peptidoglycan into host cells and subsequent activation of Nod receptors (37), and it has also been reported that CagA itself has proinflammatory properties (9). The molecular mechanisms responsible for Cag T4S system assembly and activity remain unclear.Null alleles of the genes with homology to T4S components (HpVirB11, HpVirB4, HpVirB6, HpVirB7, HpVirB8, HpVirB9, and HpVirB10) abolish both CagA translocation and IL-8 induction, with the exception of HpVirD4, which affects CagA translocation but not IL-8 induction (20). Other genes of the island also essential for Cag T4S function do not share sequence or structural homology with known T4S components. More detailed analysis of these Cag T4S essential genes allowed the recent assignment of several proteins as functional homologs of additional VirB components. HP0546 was suggested as a VirB2 homolog, the main subunit of other T4S system pili (3). Ultrastructural work suggested that HpVirB10 is also a major subunit of the Cag T4S system pilus (31, 35), but clear evidence that either HpVirB2 or HpVirB10 is the main pilus subunit is still lacking. CagL (HP0539) has been identified (29) as an adhesin (functionally similar to VirB5) whose binding to host cell receptors is required for activation of the secretion process, and CagF (HP0543) has been characterized as a CagA chaperone (17). CagD (HP0545) has been recently reported as a multifunctional Cag T4S component essential for CagA translocation and full IL-8 secretion induction (12).We have characterized the biochemical role of an additional essential H. pylori-specific gene, HP0522/cag3, in Cag T4S. A previous yeast two-hybrid screen that investigated interactions among cag PAI proteins suggested Cag3 could interact with HpVirB8, HpVirB7, CagM (HP0537), and CagG (HP0542) (10). To begin to understand the molecular basis of Cag3 function in T4S we investigated the subcellular localization of the Cag3 protein and the protein-protein interactions this protein establishes in H. pylori cells. We found evidence suggesting that Cag3 is an integral part of the Cag T4S outer membrane subcomplex required to maintain HpVirB7 levels.     

Type IV Pilus Proteins Form an Integrated Structure Extending from the Cytoplasm to the Outer Membrane

The bacterial type IV pilus (T4P) is the strongest biological motor known to date as its retraction can generate forces well over 100 pN. Myxococcus xanthus, a δ-proteobacterium, provides a good model for T4P investigations because its social (S) gliding motility is powered by T4P. In this study, the interactions among M. xanthus T4P proteins were investigated using genetics and the yeast two-hybrid (Y2H) system. Our genetic analysis suggests that there is an integrated T4P structure that crosses the inner membrane (IM), periplasm and the outer membrane (OM). Moreover, this structure exists in the absence of the pilus filament. A systematic Y2H survey provided evidence for direct interactions among IM and OM proteins exposed to the periplasm. For example, the IM lipoprotein PilP interacted with its cognate OM protein PilQ. In addition, interactions among T4P proteins from the thermophile Thermus thermophilus were investigated by Y2H. The results indicated similar protein-protein interactions in the T4P system of this non-proteobacterium despite significant sequence divergence between T4P proteins in T. thermophilus and M. xanthus. The observations here support the model of an integrated T4P structure in the absence of a pilus in diverse bacterial species.     

Differentially Expressed Outer Membrane Proteins of Vibrio alginolyticus in Response to Six Types of Antibiotics

Vibrio alginolyticus is an opportunistic pathogen that occasionally causes life-threatening infections in individuals and results in great losses in marine aquacultures of crustaceans and fish. Recently, antibiotic-resistant strains of the bacterium from clinical and environmental sources have been reported with increasing frequency. However, few reports were involved in the antibiotic resistance of this bacterium at molecular levels. In the present study, Western blotting was utilized to investigate altered OM proteins of V. alginolyticus in response to six types of antibiotics: erythromycin, kanamycin, tetracycline, streptomycin, nalidixic acid, and chloromycetin. Seventeen OM proteins have been reported here for the first time to be related to antibiotic resistance. They were porins OmpU, OmpN, putative OmpU and LamB; transport proteins VA0802, VA2212 (FadL) and VPA0860; TolC family TolC and VA1631; lipoprotein VA0449; OmpA family VPA1186 and VA0764; iron-regulated proteins OmpV, VPA1435, and VA2602; and receptor protein OmpK; hypothetical protein VA1475. Importantly, VA2212 was up-regulated in response to the five antibiotics except nalidixic acid, and VPA1186 was down-regulated in response to the six antibiotics in antibiotic-stressed bacteria. They might be potentially universal targets for designing the new drugs that inhibit multi-resistant bacteria. These findings suggested that parallel investigations into a bacterium responding to several types of antibiotics would be helpful not only for the further understanding of antibiotic-resistant mechanisms but also for the screening of valuable targets of new drugs controlling antibiotic-resistant bacteria.     

Expression of Opacity Proteins Interferes with the Transmigration of Neisseria gonorrhoeae across Polarized Epithelial Cells

Neisseria gonorrhoeae (GC) establishes infection at the mucosal surface of the human genital tract, most of which is lined with polarized epithelial cells. GC can cause localized as well as disseminated infections, leading to various complications. GC constantly change their surface structures via phase and antigenic variation, which has been implicated as a means for GC to establish infection at various anatomic locations of male and female genital tracks. However, the exact contribution of each surface molecule to bacterial infectivity remains elusive due to their phase variation. Using a GC derivative that is genetically devoid of all opa genes (MS11∆Opa), this study shows that Opa expression interferes with GC transmigration across polarized human epithelial cells. MS11∆Opa transmigrates across polarized epithelial cells much faster and to a greater extent than MS11Opa+, while adhering at a similar level as MS11Opa+. When MS11Opa+, able to phase vary Opa expression, was inoculated, only those bacteria that turn off Opa expression transmigrate across the polarized epithelial monolayer. Similar to bacteria alone or co-cultured with non-polarized epithelial cells, MS11∆Opa fails to form large microcolonies at the apical surface of polarized epithelial cells. Apical inoculation of MS11Opa+, but not MS11∆Opa, induces the recruitment of the Opa host-cell receptor carcinoembryonic antigen–related cell adhesion molecules (CEACAMs) to the apical junction and the vicinity of bacterial adherent sites. Our results suggest that Opa expression limits gonococcal ability to invade into subepithelial tissues by forming tight interactions with neighboring bacteria and by inducing CEACAM redistribution to cell junctions.     

Involvement of Neisseria meningitidis Lipoprotein GNA2091 in the Assembly of a Subset of Outer Membrane Proteins

GNA2091 of Neisseria meningitidis is a lipoprotein of unknown function that is included in the novel 4CMenB vaccine. Here, we investigated the biological function and the subcellular localization of the protein. We demonstrate that GNA2091 functions in the assembly of outer membrane proteins (OMPs) because its absence resulted in the accumulation of misassembled OMPs. Cell fractionation and protease accessibility experiments showed that the protein is localized at the periplasmic side of the outer membrane. Pulldown experiments revealed that it is not stably associated with the β-barrel assembly machinery, the previously identified complex for OMP assembly. Thus, GNA2091 constitutes a novel outer membrane-based lipoprotein required for OMP assembly. Furthermore, its location at the inner side of the outer membrane indicates that protective immunity elicited by this antigen cannot be due to bactericidal or opsonic activity of antibodies.     

A Peptidomimetic Antibiotic Targets Outer Membrane Proteins and Disrupts Selectively the Outer Membrane in Escherichia coli

Increasing antibacterial resistance presents a major challenge in antibiotic discovery. One attractive target in Gram-negative bacteria is the unique asymmetric outer membrane (OM), which acts as a permeability barrier that protects the cell from external stresses, such as the presence of antibiotics. We describe a novel β-hairpin macrocyclic peptide JB-95 with potent antimicrobial activity against Escherichia coli. This peptide exhibits no cellular lytic activity, but electron microscopy and fluorescence studies reveal an ability to selectively disrupt the OM but not the inner membrane of E. coli. The selective targeting of the OM probably occurs through interactions of JB-95 with selected β-barrel OM proteins, including BamA and LptD as shown by photolabeling experiments. Membrane proteomic studies reveal rapid depletion of many β-barrel OM proteins from JB-95-treated E. coli, consistent with induction of a membrane stress response and/or direct inhibition of the Bam folding machine. The results suggest that lethal disruption of the OM by JB-95 occurs through a novel mechanism of action at key interaction sites within clusters of β-barrel proteins in the OM. These findings open new avenues for developing antibiotics that specifically target β-barrel proteins and the integrity of the Gram-negative OM.     

Expression of Outer Membrane Proteins in Escherichia coli Growing at Acid pH

It is generally accepted for Escherichia coli that (i) the level of OmpC increases with increased osmolarity when cells are growing in neutral and alkaline media, whereas the level of OmpF decreases at high osmolarity, and that (ii) the two-component system composed of OmpR (regulator) and EnvZ (sensor) regulates porin expression. In this study, we found that OmpC was expressed at low osmolarity in medium of pH below 6 and that the expression was repressed when medium osmolarity was increased. In contrast, the expression of ompF at acidic pH was essentially the same as that at alkaline pH. Neither OmpC nor OmpF was detectable in an ompR mutant at both acid and alkaline pH values. However, OmpC and OmpF were well expressed at acid pH in a mutant envZ strain, and their expression was regulated by medium osmolarity. Thus, it appears that E. coli has a different mechanism for porin expression at acid pH. A mutant deficient in ompR grew slower than its parent strain in low-osmolarity medium at acid pH (below 5.5). The same growth diminution was observed when ompC and ompF were deleted, suggesting that both OmpF and OmpC are required for optimal growth under hypoosmosis at acid pH.     

The Neuroendocrine Proteins Secretogranin II and III Are Regionally Conserved and Coordinately Expressed with Proopiomelanocortin in Xenopus Intermediate Pituitary

Abstract: Chromogranins and secretogranins are acidic secretory proteins of unknown function that represent major constituents of neuroendocrine secretory granules. Using a differential screening strategy designed to identify genes involved in peptide hormone biosynthesis and secretion, we have isolated cDNA clones encoding the first nonmammalian homologues of secretogranin II (SgII) and secretogranin III (SgIII) from a Xenopus intermediate pituitary cDNA library. A comparative analysis of the Xenopus and mammalian proteins revealed a striking regional conservation with an overall sequence identity of 48% for SgII and 61% for SgIII. One of the highly conserved and thus potentially functional domains in SgII corresponds to the bioactive peptide secretoneurin. However, in SgII and especially in SgIII, a substantial portion of the potential dibasic cleavage sites is not conserved, arguing against the idea that these granins serve solely as peptide precursors. Moreover, SgIII contains a conserved and repeated motif (DSTK) that is reminiscent of a repeat present in the trans -Golgi network integral membrane proteins TGN38 and TGN41, a finding more consistent with an intracellular function for this protein. When Xenopus intermediate pituitary cells were stimulated in vivo, the mRNA levels of SgII and SgIII increased dramatically (15- and 35-fold, respectively) and in parallel with that of the prohormone proopiomelanocortin (30-fold increase). Our results indicate that the process of peptide hormone production and release in a neuroendocrine cell involves multiple members of the granin family.     

Essential Role of the ESX-5 Secretion System in Outer Membrane Permeability of Pathogenic Mycobacteria

Mycobacteria possess different type VII secretion (T7S) systems to secrete proteins across their unusual cell envelope. One of these systems, ESX-5, is only present in slow-growing mycobacteria and responsible for the secretion of multiple substrates. However, the role of ESX-5 substrates in growth and/or virulence is largely unknown. In this study, we show that esx-5 is essential for growth of both Mycobacterium marinum and Mycobacterium bovis. Remarkably, this essentiality can be rescued by increasing the permeability of the outer membrane, either by altering its lipid composition or by the introduction of the heterologous porin MspA. Mutagenesis of the first nucleotide-binding domain of the membrane ATPase EccC₅ prevented both ESX-5-dependent secretion and bacterial growth, but did not affect ESX-5 complex assembly. This suggests that the rescuing effect is not due to pores formed by the ESX-5 membrane complex, but caused by ESX-5 activity. Subsequent proteomic analysis to identify crucial ESX-5 substrates confirmed that all detectable PE and PPE proteins in the cell surface and cell envelope fractions were routed through ESX-5. Additionally, saturated transposon-directed insertion-site sequencing (TraDIS) was applied to both wild-type M. marinum cells and cells expressing mspA to identify genes that are not essential anymore in the presence of MspA. This analysis confirmed the importance of esx-5, but we could not identify essential ESX-5 substrates, indicating that multiple of these substrates are together responsible for the essentiality. Finally, examination of phenotypes on defined carbon sources revealed that an esx-5 mutant is strongly impaired in the uptake and utilization of hydrophobic carbon sources. Based on these data, we propose a model in which the ESX-5 system is responsible for the transport of cell envelope proteins that are required for nutrient uptake. These proteins might in this way compensate for the lack of MspA-like porins in slow-growing mycobacteria.     

Outer Membrane Proteins and Lipopolysaccharides in Pathovars of Xanthomonas campestris

Variations in the outer membrane proteins (OMPs) and lipopolysaccharides (LPSs) of 54 isolates belonging to 16 different pathovars of Xanthomonas campestris were characterized. OMP samples prepared by sarcosyl extraction of cell walls and LPS samples prepared by proteinase K treatment of sonicated cells were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of 4 M urea. In general, the OMP and LPS profiles within each pathovar were very similar but different from the profiles of other pathovars. Heterogeneity in OMP and LPS profiles was observed within X. campestris pv. campestris, X. campestris pv. translucens, and X. campestris pv. vesicatoria. LPSs were isolated from six X. campestris pathovars, which fell into two major groups on the basis of O antigenicity. The O antigens of X. campestris pv. begoniae, X. campestris pv. graminis, and X. campestris pv. translucens cross-reacted with each other; the other group consisted of X. campestris pv. campestris, X. campestris pv. pelargonii, and X. campestris pv. vesicatoria. A chemical analysis revealed a significant difference between the compositions of the neutral sugars of the LPSs of those two groups; the LPSs of the first group contained xylose and a 6-deoxy-3-O-methyl hexose, whereas the LPSs of the other group lacked both sugars.