Analyses of gonococcal H8 antigen. Surface location, inter- and intrastrain electrophoretic heterogeneity, and unusual two-dimensional electrophoretic characteristics.

The H8 protein is a surface-exposed antigen that is found, among members of the Neisseria genus, primarily on pathogenic species. In this study, the surface exposure of H8 was reassessed by four techniques. Results of slide agglutination, indirect fluorescent antibody binding, absorption of sera with whole gonococci, and immune electron microscopy all confirmed the presence of H8 in the outer membrane. The degree to which protein A-gold-labeled monoclonal antibodies bound to H8 was marked, and suggested that this antigen was present in abundant amounts in the outer membrane. Also in this study, the electrophoretic heterogeneity of this common surface antigen was examined. Because H8 stains poorly, electrophoretic mobility was assessed using polyclonal antibodies and a monoclonal antibody that recognizes a common H8 epitope. H8 was analyzed with respect to protein I, lipopolysaccharide (LPS), and pilus and opacity phenotypic variation; results confirmed that heterogeneity of Mr was the rule among strains (21 were examined), however, the variability in Mr was independent of protein I or LPS Mr. In one strain (FA1090), the heterogeneity of H8 was examined among 10 piliation/opacity variants; the H8 (and LPS) Mr was identical in all variants; similar data were generated in strains JS3 and JS1. The electrophoretic mobility of H8 was altered in serum-resistant and neutrophil enzyme-resistant gonococci compared to the sensitive gonococci. Some of the unusual electrophoretic migration characteristics of the antigen were also examined. H8 formed a unique mushroom-shaped band in one-dimensional gels; in a two-dimensional electrophoresis system, the antigen migrated aberrantly, very similarly to LPS. Also seen in the two-dimensional electrophoresis profile were multimers of the H8 antigen; in strain JS3 (Mr 23,500), these migrated at 43,600, 86,000, and greater than 150,000. In other strains, the Mr of the multimers differed depending upon the Mr of the monomer. The two-dimensional migration characteristics (as measured by antigenicity) were completely destroyed by proteinase K digestion. Activity of H8 polyclonal antibodies to the antigens in two-dimensional gels was completely removed by adsorption of formalin-fixed whole cells, but was not affected by adsorption with LPS. These electrophoretic characteristics may reflect the close association of some nonprotein constituent, perhaps lipid or carbohydrate or both.

CAP37, a human neutrophil-derived chemotactic factor with monocyte specific activity.

CAP37, an antimicrobial protein of human neutrophil granules, is a specific chemoattractant for monocytes. Purified to homogeneity by sequential chromatography over carboxymethyl Sephadex, G-75 Sephadex, and hydrophobic interaction HPLC, demonstratively endotoxin-free CAP37 was maximally chemotactic over a range of 1.3 X 10(-9)-10(-8) M. Thus it was active in the same molar concentrations as formyl-methionyl-leucyl-phenylalanine. CAP37 lacked chemotactic activity for neutrophils and lymphocytes. In checkerboard assays CAP37 had some chemokinetic activity as well. It was also chemotactic for rabbit mononuclear cells. Higher concentrations (2.7 X 10(-8) M) were required for activity with rabbit cells than with human. Sequence analysis of the first 42 NH2-terminal amino acid residues of CAP37 showed strong homologies with known serine proteases that mediate various functions in inflammation. However, a critical substitution of a serine for a histidine at position 41 suggested that CAP37 lacked serine protease action. This impression was supported by the failure of CAP37 to bind tritiated diisopropyl fluorophosphate. 89% of total CAP37 was released extracellularly from human neutrophils while they phagocytized Staphylococcus aureus. We propose that CAP37 released from neutrophils during phagocytosis and degranulation may mediate recruitment of monocytes in the second wave of inflammation.

Tailoring an antibacterial peptide of human lysosomal cathepsin G to enhance its broad-spectrum action against antibiotic-resistant bacterial pathogens.

Neutrophils contain several cationic antimicrobial proteins or peptides (CAPs) that exert antibiotic-like action against bacteria. These host-derived antibiotics kill susceptible bacteria by oxygen-independent mechanisms. Considerable interest in their activity has been generated in recent years due not only to their likely important role in innate host defense against infection, but also their possible use as therapeutic agents in treating infections caused by antibiotic-resistant pathogens. We have studied the antibacterial properties of human lysosomal cathepsin G (cat G). This highly cationic serine protease contains at least three antibacterial regions that by themselves can exert antibacterial action against Gram-negative bacteria, such as Pseudomonas aeruginosa. Only one of these peptides, defined by residues 117-136 of full-length cat G, has bactericidal action against Gram-positive pathogens, such as Staphylococcus aureus. Due to the broad-spectrum antibacterial action of this peptide, we have sought to define the amino acids within its primary sequence required for this activity and have developed variants with improved activity. This review emphasizes the importance of both cationicity and hydrophobicity as necessary characteristics for the antibacterial action of CAPs. It also proposes the strategy that naturally occurring large human CAPs can be dissected to smaller CAPs and then modified to enhance their activity in vitro. This approach could prove beneficial to those interested in developing antimicrobial peptides as therapeutic agents.

Generation of antiserum to specific epitopes.

The ability to prevent disease by immunization with subunit vaccines that incorporate specific epitopes was demonstrated by DiMarchi et al. (1), who used a synthetic peptide to protect cattle against foot-and-mouth disease. However, generation of antibody to peptide antigens is often difficult owing to the small molecular mass and limited chemical complexity. We tested the hypothesis that recombinant DNA and synthetic peptide techniques would make it possible to stimulate vigorous immune responses to specific epitopes of an outer membrane protein of Neisseria gonorrhoeae. The MtrC AP1 sequence from the invariant MtrC gonococcal lipoprotein was genetically fused to maltose binding protein. The resultant fusion protein was used as the primary immunogen to stimulate MtrC AP1-specific antiserum. To enhance antibody production specific to MtrC AP1, boosting immunizations were performed with synthetic MtrC AP1 sequence contained in a multiple antigenic peptide system immunogen. The MtrC AP1-specific antiserum strongly recognized the MtrC protein on Western blots and appeared to bind native MtrC protein in situ. The generation of antibody in this fashion provides the technology to produce antibody to defined epitopes of any protein, including those found in the gonococcal outer membrane. The ability of those antibodies to inhibit bacterial growth or to activate complement protein can then be tested.

Porphyrin-based compounds exert antibacterial action against the sexually transmitted pathogens Neisseria gonorrhoeae and Haemophilus ducreyi.

A series of porphyrin based compounds without (nMP) or with (MP) metals were found to have potent bactericidal action in vitro against the sexually transmitted pathogens Neisseria gonorrhoeae and Haemophilus ducreyi. nMP and MP did not show bactericidal activity against five species of lactobacilli. An MP containing gallium had the capacity to block a gonococcal infection in a murine vaginal model, indicating that its development as a topical microbicide to block sexually transmitted bacterial infections is warranted. In contrast to other bacterial species, loss of the gonococcal haemoglobin uptake system encoded by hpuB or energy supplied through the TonB-ExbB-ExbD system did not significantly affect levels of MP-susceptibility in gonococci. In contrast, mutations in gonococci that inactivate the mtrCDE-encoded efflux pump were found to enhance gonococcal susceptibility to nMPs and MPs while over-production of this efflux pump decreased levels of gonococcal susceptibility to these compounds.

Lipopolysaccharide masking of gonococcal outer-membrane proteins modulates binding of bacterial cathepsin G to gonococci.

Human polymorphonuclear leucocyte (PMN) lysosomal cathepsin G exerts potent bactericidal action against Neisseria gonorrhoeae in vitro, independent of its serine esterase activity. The results presented demonstrate that (1) bactericidal, diisopropylfluorophosphate-treated cathepsin G binds in a specific and saturable manner to the surface of gonococci, (2) loss of carbohydrates in gonococcal LPS due to mutation increases total and specific binding of cathepsin G, and (3) at least three outer-membrane proteins (OMPs) (PIA, PIII, and a 45 kDa OMP) interact with cathepsin G. Taken together, the results suggest that gonococcal susceptibility to the lethal action of cathepsin G, and perhaps susceptibility of gonococci to oxygen-independent killing by PMNs, is controlled by LPS-masking of cathepsin-G-binding OMPs.

Staphylococcal enterotoxin A: a chromosomal gene product.

Physical and genetic analysis of the plasmid make-up of Staphylococcus aureus strains S6 and FRI-100 has shown that staphylococcal enterotoxin A is a chromosomal gene product.

Transcriptional control of the mtr efflux system of Neisseria gonorrhoeae.

The capacity of Neisseria gonorrhoeae to resist structurally diverse hydrophobic agents (HAs) because of the mtr (multiple transferable resistance) efflux system was found to be regulated at the level of transcription by two distinct mechanisms. This was surmised because a deletion that removed > 90% of the coding sequence of the mtrR (multiple transferrable resistance regulator) gene or a single-base-pair deletion within a 13-bp inverted repeat sequence located in its promoter resulted in altered expression of the mtrC gene; mtrC encodes a 44-kDa membrane lipoprotein essential for the efflux of HAs. However, the single-base-pair deletion had the more significant impact on gene expression since it resulted in the loss of expression of mtrR and a threefold increase in the expression of mtrC. Hence, the mtr efflux system in gonococci is subject to both MtrR-dependent and MtrR-independent regulation, and the levels of mtrC mRNA correlate well with HA resistance levels in gonococci.

The farAB-encoded efflux pump mediates resistance of gonococci to long-chained antibacterial fatty acids.

Gonococci often infect mucosal surfaces bathed in antibacterial fatty acids (FAs). Resistance of gonococci to FAs and other antibacterial hydrophobic agents has been attributed to the mtrCDE-encoded efflux pump system and a heretofore undefined mechanism. This alternative resistance mechanism has been suggested to mediate gonococcal resistance to long-chained FAs independently of the mtr efflux pump. We have now identified this alternative FA resistance system in gonococci and report that it bears significant similarity to the emrAB-encoded efflux pump possessed by Escherichia coli and the vceAB-encoded pump of Vibrio cholerae. We termed the gonococcal version of this efflux pump farAB (fatty acid resistance) to signify its involvement in FA resistance expressed by gonococci and to distinguish it from the emrAB- or vceAB-encoded pumps that modulate bacterial susceptibility to uncoupling agents and certain antibiotics. Although the farAB system in gonococci was found to provide resistance to FAs independently of the mtrCDE-encoded efflux pump, its function was dependent on the MtrE outer membrane protein. Moreover, expression of the tandemly linked farA and farB genes was positively associated with the presence of the MtrR transcriptional regulatory protein that normally downregulates the expression of mtrCDE. Thus, the data presented herein suggest that, while the mtrCDE- and farAB-encoded systems act independently to mediate resistance of gonococci to host-derived, hydrophobic antimicrobial agents, their capacity to export these agents is dependent on the same outer membrane protein (MtrE), and their expression may be differentially controlled by the same transcriptional regulatory protein (MtrR).

Transduction of staphylococcal enterotoxin B synthesis: establishment of the toxin gene in a recombination-deficient mutant.

Cotransduction of enterotoxin B synthesis into a recombination deficient mutant only occurred when the donor contained the pEntB plasmid. Enterotoxin B from chromosomal genotypes could not be established in such hosts. These data suggest that the entB gene is not capable of high-frequency translocation.

Genetics of staphylococcal enterotoxin B in methicillin-resistant isolates of Staphylococcus aureus.

Biophysical and genetic analysis of staphylococcal enterotoxin B (SEB) synthesis in 16 methicillin-resistant (Mecr) Staphylococcus aureus isolates demonstrated that the toxin gene (entB) can occupy either a plasmid or chromosomal locus. Biophysical analysis of the plasmid deoxyribonucleic acid content of these strains by agarose gel electrophoresis revealed the presence of a 1.15-megadalton plasmid in six isolates that appears to contain the entB gene. Genetic manipulation of SEB synthesis by transduction and elimination procedures demonstrated that this plasmid is critical for enterotoxigenesis. Nevertheless, the majority of the Mecr SEB+ isolates (62.5%) analyzed in this investigation were found to lack the 1.15-megadalton plasmid. In at least two of these strains (COL and 57-dk), transduction and elimination procedures showed that entB was chromosomal. Genetic studies involving strains harboring either a plasmid or chromosomal entB gene demonstrated that toxin synthesis was coeliminated with mec. However, analysis of the entB and mec loci by transformation or transduction showed that the genes are not closely linked. On the other hand, transduction of entB, regardless of the donor, was observed when both mec and the Tcr plasmid were jointly cotransduced. This finding suggests that, during transduction, a transient association between entB, mec, and the Tcr plasmid may exist.

Gonococcal penicillin-binding protein 3 and the surface-exposed 44kDa peptidoglycan-binding protein appear to be the same molecule.

The outer membrane of Neisseria gonorrhoeae contains a 44,000 dalton (44kDa) surface-exposed protein which has the reported ability to form covalent interactions with peptidoglycan (PG). This PG-binding outer-membrane protein (OMP) appears to be highly conserved since it has been detected in all isolates examined. It also appears to be invariant since its primary structure among strains gives evidence of being identical (Judd et al., 1991). While studying the interaction of gonococcal penicillin-binding proteins (PBPs) with human lysosomal cathepsin G, we noticed that the 44kDa PG-binding OMP exhibited certain properties similar to PBP3. In this study we sought to obtain biochemical evidence to ascertain whether these proteins were the same. We found that both proteins fractionated with other sarkosyl-insoluble OMPs and that they exhibited similar susceptibility to cleavage in situ by enzymatically active cathepsin G. Moreover, a purified preparation of the 44kDa OMP was found to covalently bind radiolabelled benzylpenicillin in vitro. Thus, the data presented herein suggest that the 44kDa PG-binding OMP and PBP3 are the same OMP.

Neutrophil killing of bacteria by oxygen-independent mechanisms: a historical summary.

The historical development of the concept of neutrophil killing of bacteria by oxygen-independent mechanisms is traced. The role of oxygen-independent microbicidal mechanisms in relationship to neutrophil management of microbes is critically evaluated. In the ultrastructural sense, oxygen-independent killing of bacteria requires the deposition of a bactericidal component (granule proteins) or the establishment of a hostile, non-physiologic environment in the phagolysosome. Accordingly, this review is concerned with the identification and cellular location of cationic proteins that participate in nonoxidative killing of gram-negative bacteria by human polymorphonucleur neutrophil granulocytes. Studies reviewed support the hypothesis that oxygen-independent mechanisms function in vivo and are important in host defense against infection. The chemistry of antimicrobial proteins, the biologically active site of each protein, and the mechanism by which the proteins trigger bacterial death all need to be determined at the molecular level.

Chromosomal locus for staphylococcal enterotoxin B.

The genetic locus of staphylococcal enterotoxin B (SEB) was investigated in the Staphylococcus aureus food-poisoning isolates, strains S6 and 277. Direct neutral sucrose gradient centrifugation analysis of sodium dodecyl sulfate-sodium chloride-mediated cleared lysates demonstrated that strain S6 contained a single 37S plasmid. Transductional analysis revealed that the 37S plasmid in S6 encoded for cadmium resistance (Cad) but not SEB. Additionally, elimination of cadmium resistance in S6 provided a plasmid-negative derivative that produced SEB at the same level as the parent. Examination of strain 277 showed two plasmids, a 37S species encoding for penicillin resistance (Penr) and a 21S species containing the gene(s) responsible for tetracycline resistance (Tetr). Elimination of the 37S, penr plasmid in 277 had no effect on SEB production, whereas introduction of the 21S tetr plasmid via transformation into strain 8325 (SEB--) did not confer enterotoxigenesis upon the transformants. The data obtained in this investigation suggest that the SEB gene(s) in these food-poisoning isolates of S. aureus is chromosomal.

Evidence that the serum resistance genetic locus sac-3 of Neisseria gonorrhoeae is involved in lipopolysaccharide structure.

The gonococcal chromosome contains a sequence of closely linked genes (for example, sac-1, sac-3, nmp) known or presumed to affect cell envelope structure and which appear to influence susceptibility of gonococci to killing by normal human sera (NHS). Previous work has shown that the serum-resistant isolate FA19, and FA899, a serum-sensitive transformant of FA19, differ in outer membrane protein I (PI) and at the sac-3 genetic locus. However, the sac-3 locus is separable from changes determined by nmp-3, the gene determining PI species. We found that FA19 and FA899 differ in lipopolysaccharide (LPS) molecular size and in reactivity with a monoclonal antibody which recognizes an LPS (L8) epitope. To address the question of whether the changes in LPS were due to the sac-3 locus, we constructed new transformants of FA19 using donor DNA prepared from FA899. The new transformants could be divided into three groups: (1) those identical to FA19 in serum resistance (greater than 90% survival at 120 min), in LPS molecular size and in expression of the L8 epitope; (2) those identical to FA899 in serum sensitivity (100% killed at 30 min), in LPS molecular size and in lack of expression of the L8 epitope; (3) those significantly killed by 50% NHS at 120 min, whose LPS molecular size was greater than that of FA19 but less than that of FA899 and which did not express the L8 epitope. Except for PI there were no differences in other outer-membrane proteins (e.g. PII, PIII, H.8) among these transformants.(ABSTRACT TRUNCATED AT 250 WORDS)

Cleavage of the protein III and major iron-regulated protein of Neisseria gonorrhoeae by lysosomal cathepsin G.

Incubation of either 125I-labelled or unlabelled Neisseria gonorrhoeae with enzymically active preparations of human polymorphonuclear leucocyte lysosomal cathepsin G revealed that surface-exposed outer-membrane proteins were susceptible to proteolytic modification. Electroimmunoblotting experiments confirmed that outer-membrane protein III (PIII) and the major iron-regulated protein (MIRP), two conserved gonococcal proteins, were cleaved by cathepsin G. A direct relationship was observed between susceptibility to the antibacterial properties of cathepsin G and cleavage of PIII among isogenic strains differing in their level of resistance to the bactericidal activity of cathepsin G. Although the antibacterial property of cathepsin G is known to be independent of serine-esterase activity, the data suggest that gonococcal outer-membrane proteins are involved in the binding of cathepsin G, and that variation in the level of resistance reflects the degree to which target outer-membrane proteins such as PIII are exposed.

Mechanism of staphylococcal resistance to non-oxidative antimicrobial action of neutrophils: importance of pH and ionic strength in determining the bactericidal action of cathepsin G.

The staphylococcalcidal action of highly purified, enzymically inactive human lysosomal cathepsin G was studied. The bactericidal action of cathepsin G was optimal at pH 7.5 and was inhibited by NaCl; concentrations greater than 0.15 M NaCl completely inhibited killing of Staphylococcus aureus. Under optimal conditions (pH, temperature and NaCl concentration) the ED50 (effective dose) of cathepsin G against S. aureus strain 8325-4 was about 3.1 micrograms ml-1. Polymeric teichoic acid may serve as a binding site for cathepsin G by promoting electrostatic interactions since a mutant lacking this surface component exhibited enhanced resistance to the lethal action of cathepsin G, compared to the teichoic-acid-positive parental strain. These results suggest that (i) the ability of cathepsin G to kill intraphagosomal staphylococci may be regulated in part by the ionic strength of the environment and the pH of the maturing phagolysosome, and (ii) that strategies which retard acidification of the developing phagolysosome would promote the staphylococcalcidal action of cathepsin G.

Regulation of staphylococcal enterotoxin B.

The effect of glucose and the glucose analogues 2-deoxyglucose and alpha-methyl-glucoside on the synthesis and regulation of staphylococcal enterotoxin B was examined. The attenuating effect of glucose on staphylococcal enterotoxin B synthesis was observed. However, when this effect was examined with analogues of glucose, contradictory responses were seen. alpha-Methylglucoside had a slight stimulatory effect on enterotoxin production and other extracellular proteins, whereas 2-deoxyglucose markedly inhibited enterotoxin production. beta-hemolysin and staphylococcal nuclease were also inhibited by 2-deoxy glucose but the synthesis of nuclease could be rescued by the addition of glucose to 2-deoxyglucose-containing cultures. Enterotoxin and beta-hemolysin synthesis were not subject to glucose rescue. The cells used in this study were permeable to cyclic 3',5'-adenosine monophosphate, but the addition of this compound did not reverse glucose repression or 2-deoxyglucose inhibition of enterotoxin B synthesis. We conclude from these data that the regulation of enterotoxin is not under catabolite control as previously reported.

Topographical alterations in proteins I of Neisseria gonorrhoeae correlated with lipooligosaccharide variation.

Four transformant strains of Neisseria gonorrhoeae were generated, two of which (WS3 and WS5) had protein I subclass A (P.IA) and two which (WS2 and WS4) had protein I subclass B (P.IB). Analysis of the strains demonstrated that the two P.IA-bearing strains differed in lipooligosaccharide (LOS) and H.8 antigen, as assessed by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotting. The WS5 strain had slow-migrating LOS and H.8 antigen, and the WS3 strain had fast-migrating LOS and H.8 antigen. The P.IB-bearing strains also had either slow-migrating LOS and H.8 antigen (WS4) or fast-migrating LOS and H.8 antigen (WS2). Structural and exposure analysis revealed that although the P.IAs were identical in the WS3 and WS5 strains, there was a slight alteration of the exposure of the proteins which correlated with altered LOS and/or H.8 antigen. The P.IBs were also shown to be structurally identical, but the LOS and/or H.8 antigen variation in these strains correlated with a more pronounced alteration in the exposure of the P.IB molecules. The differences in protein I (P.I) exposure were generally found in highly negatively charged regions of the molecule, suggesting that the immunogenicity and/or antigenicity of the P.I molecules may vary as a result of LOS and/or H.8 antigen alterations.

Induction of the mtrCDE-encoded efflux pump system of Neisseria gonorrhoeae requires MtrA, an AraC-like protein.

The mtr (multiple transferable resistance) gene complex in Neisseria gonorrhoeae encodes an energy-dependent efflux pump composed of the MtrC-MtrD-MtrE cell envelope proteins that serves to export structurally diverse antimicrobial, hydrophobic agents (HAs). Many of these agents have membrane-acting detergent activity. Using Triton X-100 (TX-100) as a representative HA, we found that the mtrCDE efflux pump operon could be induced to higher levels of expression when an HA-sensitive strain was exposed to sublethal concentrations of this non-ionic detergent and the structurally related spermicide, nonoxynol-9. This induction was at the level of mtrCDE gene transcription and was independent of the MtrR repressor, which normally decreases mtrCDE gene expression. However, the enhanced resistance of gonococci to TX-100 was dependent on the expression of a previously undescribed gonococcal protein that belonged to the AraC/XylS family of transcriptional activators. We have termed this protein MtrA to signify its likely role in the activation of mtrCDE gene expression. Taken together with previous studies dealing with the genetic control of mtrCDE gene expression, we propose that gonococci can modulate their resistance to HAs through both positive and negative transcriptional control processes. The action of these regulatory processes is probably of importance in determining the survival capacity of gonococci at mucosal surfaces that contain detergent-like HAs.