Differential expression of the enolase gene under in vivo versus in vitro growth conditions of Aeromonas hydrophila.

Aeromonas hydrophila is an emerging human pathogen that leads to gastroenteritis and other invasive diseases. By using a murine peritoneal culture (MPC) model, we identified via restriction fragment differential display PCR (RFDDPCR) five genes of A. hydrophila that were differentially expressed under in vivo versus in vitro growth conditions. The gene encoding enolase was among those five genes that were differentially up regulated. Enolase is a glycolytic enzyme and its surface expression was recently shown to be important in the pathogenesis of a gram-positive bacterium Streptococcus pyogenes. By Western blot analysis and Immunogold staining, we demonstrated secretion and surface expression of enolase in A. hydrophila. We also showed that the whole cells of A. hydrophila had strong enolase activity. Using an enzyme-linked immunosorbant assay and sandwich Western blot analysis, we demonstrated binding of enolase to human plasminogen, which is involved in the fibrinolytic system of the host. We cloned the A. hydrophila enolase gene, which exhibited 62% homology at the DNA level and 57% homology at the amino acid level when compared to S. pyogenes enolase. This is a first report describing the increased expression of enolase gene in vivo that could potentially contribute to the pathogenesis of A. hydrophila infections.

Group A streptococci bind to mucin and human pharyngeal cells through sialic acid-containing receptors.

The first step in the colonization of group A streptococci (Streptococcus pyogenes) is adherence to pharyngeal epithelial cells. Prior to adherence to their target tissue, the first barrier that the streptococci encounter is the mucous layer of the respiratory tract. The present study was undertaken to characterize the interaction between mucin, the major glycoprotein component of mucus, and streptococci. We report here that S. pyogenes is able to bind to bovine submaxillary mucin in solid-phase microtiter plate assays. Western blots probed with (125)I-labeled mucin and a panel of monoclonal antibodies revealed that the streptococcal M protein is one of two cell wall-associated proteins responsible for this binding. The binding was further localized to the N-terminal portion of the M molecule. Further analysis revealed that the M protein binds to the sialic acid moieties on mucin, and this interaction seems to be based on M-protein conformation rather than specific amino acid sequences. We found that sialic acid also plays a critical role in the adherence of an M6 streptococcal strain to the Detroit 562 human pharyngeal cell line and have identified alpha2-6-linked sialic acid as an important sialylated linkage for M-protein recognition. Western blot analysis of extracted pharyngeal cell membrane proteins identified three potential sialic acid-containing receptors for the M protein. The results are the first to show that sialic acid not only is involved in the binding of the streptococci to mucin but also plays an important role in adherence of group A streptococci to the pharyngeal cell surface.

Multifunctional alpha-enolase: its role in diseases.

Enolase, a key glycolytic enzyme, belongs to a novel class of surface proteins which do not possess classical machinery for surface transport, yet through an unknown mechanism are transported on the cell surface. Enolase is a multifunctional protein, and its ability to serve as a plasminogen receptor on the surface of a variety of hematopoetic, epithelial and endothelial cells suggests that it may play an important role in the intravascular and pericellular fibrinolytic system. Its role in systemic and invasive autoimmune disorders was recognized only very recently. In addition to this property, its ability to function as a heat-shock protein and to bind cytoskeletal and chromatin structures indicate that enolase may play a crucial role in transcription and a variety of pathophysiological processes.

Induction of lysogenic bacteriophage and phage-associated toxin from group a streptococci during coculture with human pharyngeal cells.

We found that when group A streptococci are cocultured with human pharyngeal cells, they upregulate and secrete a 25-kDa toxin, determined to be the bacteriophage-encoded streptococcal pyrogenic exotoxin C (SpeC). This prompted us to determine if the bacteriophage themselves are induced during coculture conditions. We found that bacteriophage induction does occur, resulting in the release of approximately 10(5) phage particles during the 3-h coculture. Furthermore, we show that the bacteriophage induction event is mediated by a pharyngeal cell soluble factor for which we provide an initial characterization.

Antibodies to streptococcal surface enolase react with human alpha-enolase: implications in poststreptococcal sequelae.

The pathogenic mechanisms for developing acute rheumatic fever after group A streptococcal pharyngitis are still poorly understood. The glycolytic enzyme enolase is one of the major proteins on the surface of group A streptococci. Herein, significant cross-reactivity was shown between streptococcal enolase and human enolase. Fluorocytometric analysis revealed that antistreptococcal enolase antibodies react with the enolase expressed on the surface of hematopoietic cells. Furthermore, the enolase on the leukocyte surface was found to be up-regulated by inflammatory stimuli. Evaluation of antibody titers indicated that serum samples from patients with acute rheumatic fever have higher levels of antibodies that react with the human and bacterial enolases than do serum samples from patients with streptococcal pharyngitis or healthy control subjects. These results show that streptococcal enolase is a novel cross-reactive antigen that may play an important role in the initiation of the autoimmune diseases related to streptococcal infection.

alpha-enolase, a novel strong plasmin(ogen) binding protein on the surface of pathogenic streptococci.

The plasmin(ogen) binding property of group A streptococci is incriminated in tissue invasion processes. We have characterized a novel 45-kDa protein displaying strong plasmin(ogen) binding activity from the streptococcal surface. Based on its biochemical properties, we confirmed the identity of this protein as alpha-enolase, a key glycolytic enzyme. Dose-dependent alpha-enolase activity, immune electron microscopy of whole streptococci using specific antibodies, and the opsonic nature of polyclonal and monoclonal antibodies concluded the presence of this protein on the streptococcal surface. We, henceforth, termed the 45-kDa protein, SEN (streptococcal surface enolase). SEN is found ubiquitously on the surface of most streptococcal groups and serotypes and showed significantly greater plasmin(ogen) binding affinity compared with previously reported streptococcal plasminogen binding proteins. Both the C-terminal lysine residue of SEN and a region N-terminal to it play a critical role in plasminogen binding. Results from competitive plasminogen binding inhibition assays and cross-linking studies with intact streptococci indicate that SEN contributes significantly to the overall streptococcal ability to bind plasmin(ogen). Our findings, showing both the protected protease activity of SEN-bound plasmin and SEN-specific immune responses, provide evidence for an important role of SEN in the disease process and post-streptococcal autoimmune diseases.

Regulation of the phosphorylation of human pharyngeal cell proteins by group A streptococcal surface dehydrogenase: signal transduction between streptococci and pharyngeal cells.

Whether cell-to-cell communication results when group A streptococci interact with their target cells is unknown. Here, we report that upon contact with cultured human pharyngeal cells, both whole streptococci and purified streptococcal surface dehydrogenase (SDH) activate pharyngeal cell protein tyrosine kinase as well as protein kinase C, thus regulating the phosphorylation of cellular proteins. SDH, a major surface protein of group A streptococci, has both glyceraldehyde-3-phosphate dehydrogenase and ADP-ribosylating enzyme activities that may relate to early stages of streptococcal infection. Intact streptococci and purified SDH induce a similar protein phosphorylation pattern with the de novo tyrosine phosphorylation of a 17-kD protein found in the membrane/particulate fraction of the pharyngeal cells. However, this phosphorylation required the presence of cytosolic components. NH2-terminal amino acid sequence analysis identified the 17-kD protein as nuclear core histone H3. Both phosphotyrosine and phosphoserine-specific monoclonal antibodies reacted with the 17-kD protein by Western blot, suggesting that the binding of SDH to these pharyngeal cells elicits a novel signaling pathway that ultimately leads to activation of histone H3-specific kinases. Genistein-inhibitable phosphorylation of histone H3 indicates that tyrosine kinase plays a key role in this event. Treatment of pharyngeal cells with protein kinase inhibitors such as genistein and staurosporine significantly inhibited streptococcal invasion of pharyngeal cells. Therefore, these data indicated that streptococci/SDH-mediated phosphorylation plays a critical role in bacterial entry into the host cell. To identify the membrane receptor that elicits these signaling events, we found that SDH bound specifically to 30- and 32-kD membrane proteins in a direct ligand-binding assay. These findings clearly suggest that SDH plays an important role in cellular communication between streptococci and pharyngeal cells that may be important in host cell gene transcription, and hence in the pathogenesis of streptococcal infection.

Location of the complement factor H binding site on streptococcal M6 protein.

The surface M protein of group A streptococci binds factor H, a regulatory protein of the alternative complement pathway, which may contribute to the antiphagocytic activity of the M molecules. To locate the factor H binding domain in the alpha-helical coiled-coil structure of the M molecule, the M protein was cleaved with pepsin at pH 5.8, which separates the molecule approximately in half. Western blot (immunoblot), amino acid sequence, and mass spectrometric analyses revealed that factor H bound to a 14.6-kDa C-terminal fragment of the M molecule. Competitive inhibition of factor H binding to the 14.6-kDa fragment with M protein peptides localized the binding site to amino acids 256 to 292. This segment is located within the surface-exposed region of the M6 protein, identified as the C-repeat region, whose sequence is conserved among heterologous M and M-like molecules. These studies also identified a second pepsin-susceptible site with the sequence ELAK located within the cell wall-associated region of the M molecule.

Characterization and biological properties of a new staphylococcal exotoxin.

Staphylococcus aureus strain D4508 is a toxic shock syndrome toxin 1-negative clinical isolate from a nonmenstrual case of toxic shock syndrome (TSS). In the present study, we have purified and characterized a new exotoxin from the extracellular products of this strain. This toxin was found to have a molecular mass of 25.14 kD by mass spectrometry and an isoelectric point of 5.65 by isoelectric focusing. We have also cloned and sequenced its corresponding genomic determinant. The DNA sequence encoding the mature protein was found to be 654 base pairs and is predicted to encode a polypeptide of 218 amino acids. The deduced protein contains an NH2-terminal sequence identical to that of the native protein. The calculated molecular weight (25.21 kD) of the recombinant mature protein is also consistent with that of the native molecules. When injected intravenously into rabbits, both the native and recombinant toxins induce an acute TSS-like illness characterized by high fever, hypotension, diarrhea, shock, and in some cases death, with classical histological findings of TSS. Furthermore, the activity of the toxin is specifically enhanced by low quantities of endotoxins. The toxicity can be blocked by rabbit immunoglobulin G antibody specific for the toxin. Western blotting and DNA sequencing data confirm that the protein is a unique staphylococcal exotoxin, yet shares significant sequence homology with known staphylococcal enterotoxins, especially the SEA, SED, and SEE toxins. We conclude therefore that this 25-kD protein belongs to the staphylococcal enterotoxin gene family that is capable of inducing a TSS-like illness in rabbits.

Glyceraldehyde-3-phosphate dehydrogenase on the surface of group A streptococci is also an ADP-ribosylating enzyme.

We recently identified an enzymatically active glyceraldehyde-3-phosphate dehydrogenase (EC 1.2.1.12; GAPDH) as a major protein on the surface of group A streptococci (SDH), which exhibits multiple binding activity to various mammalian proteins. We now report that the SDH molecule also functions as an ADP-ribosylating enzyme, which, in the presence of NAD, is auto-ADP-ribosylated. In a crude cell wall extract of group A streptococci, SDH is the only protein that is ADP-ribosylated. SDH found in the streptococcal cytoplasmic fraction could not be ADP-ribosylated in the presence of NAD. Treatment of ADP-ribosylated SDH with the cytoplasmic fraction removed the ADP-ribose from SDH, suggesting the presence of an ADP-ribosyl hydrolase in the cytoplasmic compartment. The covalent linkage of ADP-ribose to SDH was stable to neutral hydroxylamine, sensitive to HgCl2, and inhibitable by free cysteine, indicating that the modification was at a cysteine residue of SDH. In addition to its auto-ADP-ribosylation activity, purified SDH or streptococcal cell wall extracts were able to transfer the ADP-ribose moiety of NAD specifically to free cysteine, resulting in a true thioglycosidic linkage. Treatment of purified SDH or the crude cell wall extract with sodium nitroprusside, which spontaneously generates nitric oxide, was found to stimulate the ADP-ribosylation of SDH in a time-dependent manner. ADP-ribosylation and nitric oxide treatment inhibited the GAPDH activity of SDH. Since ADP-ribosylation and nitric oxide are involved in signal transduction events, the ADP-ribosylating activity of SDH may enable communication between host and parasite during infection by group A streptococci.

A major surface protein on group A streptococci is a glyceraldehyde-3-phosphate-dehydrogenase with multiple binding activity.

The surface of streptococci presents an array of different proteins, each designed to perform a specific function. In an attempt to understand the early events in group A streptococci infection, we have identified and purified a major surface protein from group A type 6 streptococci that has both an enzymatic activity and a binding capacity for a variety of proteins. Mass spectrometric analysis of the purified molecule revealed a monomer of 35.8 kD. Molecular sieve chromatography and sodium dodecyl sulfate (SDS)-gel electrophoresis suggest that the native conformation of the protein is likely to be a tetramer of 156 kD. NH2-terminal amino acid sequence analysis revealed 83% homology in the first 18 residues and about 56% in the first 39 residues with glyceraldehyde-3-phosphate dehydrogenase (GAPDH) of eukaryotic or bacterial origin. This streptococcal surface GAPDH (SDH) exhibits a dose-dependent dehydrogenase activity on glyceraldehyde-3-phosphate in the presence of beta-nicotinamide adenine dinucleotide both in its pure form and on the streptococcal surface. Its sensitivity to trypsin on whole organism and its inability to be removed with 2 M NaCl or 2% SDS support its surface location and tight attachment to the streptococcal cell. Affinity-purified antibodies to SDH detected the presence of this protein on the surface of all M serotypes of group A streptococcal tested. Purified SDH was found to bind to fibronectin, lysozyme, as well as the cytoskeletal proteins myosin and actin. The binding activity to myosin was found to be localized to the globular heavy meromyosin domain. SDH did not bind to streptococcal M protein, tropomyosin, or the coiled-coil domain of myosin. The multiple binding capacity of the SDH in conjunction with its GAPDH activity may play a role in the colonization, internalization, and the subsequent proliferation of group A streptococci.

Conservation of a hexapeptide sequence in the anchor region of surface proteins from gram-positive cocci.

A highly conserved hexapeptide sequence (both at the protein- and DNA level) has been identified within the C-terminal end of all 11 known surface proteins from Gram-positive cocci. The hexapeptide, with the consensus sequence LPXTGE, is located about 9 amino acids N-terminal from the C-terminal hydrophobic domain which is found in all these surface molecules. The conservation of the hexapeptide, despite sequence variation within the regions flanking it, suggests that it is important for the attachment of these proteins within the cell.

Identification of an endogenous membrane anchor-cleaving enzyme for group A streptococcal M protein. Its implication for the attachment of surface proteins in gram-positive bacteria.

How streptococcal M protein or other surface proteins of gram-positive bacteria are anchored to the cell is poorly understood. Previously, we reported that M protein released after cell wall removal with a muralytic enzyme lacked the COOH terminal hydrophobic amino acids and charged tail predicted from DNA sequence. An endogenous membrane anchor-cleaving enzyme has now been identified with the ability to release M protein from isolated streptococcal protoplasts. At pH 5.5 in the presence of 30% raffinose, the streptococcal cell wall may be removed with a muralytic enzyme without releasing M protein from the resulting protoplasts indicating that the M molecule is attached through the bacterial cytoplasmic membrane. Release of M molecules occurs when the M protein-charged protoplasts are placed in raffinose buffer at pH 7.4. Although Zn2+, Cd2+, Ca2+, PHMB, and pHMPS inhibit the activity of the releasing enzyme, the blocking activity of Zn2+, Cd2+, and Ca2+ are reversible while PHMB and pHMPS are irreversible. PHMB-treated protoplasts are unable to release M protein at pH 7.4. However, M protein is liberated from these protoplasts when mixed with those prepared from M- streptococci serving as an enzyme source. The supernatant from M- protoplasts is unable to release M protein from PHMB-inactivated M+ protoplasts, confirming that the anchor-cleaving enzyme is membrane bound. Thus, the M protein releasing activity appears to be the result of a thiol-dependent anchor-cleaving enzyme. Streptococcal membranes treated with sodium carbonate and Triton X-114 still retain the M protein verifying that it is an integral membrane molecule. Evidence also is presented indicating significant sequence similarity between M protein and certain GPI-anchored proteins in the region responsible for protein anchoring.

Isolation and characterization of the cell-associated region of group A streptococcal M6 protein.

DNA sequence analysis of the complete M6 protein gene revealed 19 hydrophobic amino acids at the C terminus which could act as a membrane anchor and an adjacent proline- and glycine-rich region likely to be located in the cell wall. To define this region within the cell wall and its role in attaching the molecule to the cell, we isolated the cell-associated fragment of the M protein. Assuming that the cell-associated region of the M protein would be embedded within the wall and thus protected from trypsin digestion, cells were digested with this enzyme, and the wall-associated M protein fragment was released by phage lysin digestion of the peptidoglycan. With antibody probes prepared to synthetic peptides of C-terminal sequences, a cell wall-associated M protein fragment (molecular weight, 16,000) was identified and purified. Amino acid sequence analysis placed the N terminus of the 16,000-molecular-weight fragment at residue 298 within the M sequence. Amino acid composition of this peptide was consistent with a C-terminal sequence lacking the membrane anchor. Antibody studies of nitrous acid-extracted whole bacteria suggested that, in addition to the peptidoglycan-associated region, a 65-residue helical segment of the C-terminal domain of the M protein is embedded within the carbohydrate moiety of the cell wall. Since no detectable amino sugars were associated with the wall-associated fragment, the C-terminal region of the M6 molecule is likely to be intercalated within the cross-linked peptidoglycan and not covalently linked to it. Because the C-terminal region of the M molecule is highly homologous to the C-terminal end of protein A from staphylococci and protein G from streptococci, it is likely that the mechanism of attachment of these proteins to the cell wall is conserved.

Immune responses to the protein, carbohydrate and lipid antigens of Nocardia asteroides in experimental nocardiosis in mice.

The intravenous injection of Nocardia asteroides into mice produced systemic nocardiosis involving all the vital organs. Infection of the kidneys and adrenals was more persistent and progressive than in other organs as evidenced by increased bacterial counts and histopathological findings. During the course of the experimental infection, no humoral immune response was detected against various protein antigens up to 4 weeks after challenge, but significant cell-mediated immunity (CMI) was found. Phospholipid antigens elicited only a humoral immune response. The increased CMI responses with protein antigens correlated well with the decreasing bacterial load, which suggested that CMI against proteins was important in the pathogenesis of this disease.

Immunological responses to protein, carbohydrate and lipid fractions of Nocardia asteroides in mice.

The protein, polysaccharide and phospholipid constituents of Nocardia asteroides have been partially purified and their immunogenicity studied in mice. Humoral and cellular immune responses were demonstrated against a crude cytoplasmic protein fraction (CPF). Two fractions of CPF were prepared on a Sephadex G-200 column; a high mol. wt fraction, fraction-1(F1) was capable of eliciting both types of immune responses, whereas fraction-2(F2) behaved more like a hapten. Phosphatides elicited only humoral responses whereas polysaccharides were non-immunogenic.

Experimentally induced subcutaneous infection by black pigmented Bacteroides species in rats.

In a rat model of anaerobic subcutaneous abscess developed to study the pathogenicity of pure cultures of black pigmented Bacteroides sp. (Bacteroides melaninogenicus and Bacteroides intermedius) maximum lesions were seen between 7 and 15 days after inoculation. Abscesses were produced by one type strain each of B. melaninogenicus and B. intermedius and by 20 of 25 clinical isolates of black pigmented Bacteroides species.