Characterization of nra, a global negative regulator gene in group A streptococci.

During sequencing of an 11.5 kb genomic region of a serotype M49 group A streptococcal (GAS) strain, a series of genes were identified including nra(negative regulator of GAS). Transcriptional analysis of the region revealed that nra was primarily monocistronically transcribed. Polycistronic expression was found for the three open reading frames (ORFs) downstream and for the four ORFs upstream of nra. The deduced Nra protein sequence exhibited 62% homology to the GAS RofA positive regulator. In contrast to RofA, Nra was found to be a negative regulator of its own expression and that of the two adjacent operons by analysis of insertional inactivation mutants. By polymerase chain reaction and hybridization assays of 10 different GAS serotypes, the genomic presence of nra, rofA or both was demonstrated. Nra-regulated genes include the fibronectin-binding protein F2 gene (prtF2) and a novel collagen-binding protein (cpa). The Cpa polypeptide was purified as a recombinant maltose-binding protein fusion and shown to bind type I collagen but not fibronectin. In accordance with nra acting as a negative regulator of prtF2 and cpa, levels of attachment of the nra mutant strain to immobilized collagen and fibronectin was increased above wild-type levels. In addition, nra was also found to regulate negatively (four- to 16-fold) the global positive regulator gene, mga. Using a strain carrying a chromosomally integrated duplication of the nra 3' end and an nra-luciferase reporter gene transcriptional fusion, nra expression was observed to reach its maximum during late logarithmic growth phase, while no significant influence of atmospheric conditions could be distinguished clearly.

The group A streptococcal dipeptide permease (Dpp) is involved in the uptake of essential amino acids and affects the expression of cysteine protease.

The majority of characterized bacterial dipeptide permeases (Dpp) are membrane-associated complexes of five proteins belonging to the ABC-transporter family. They have been found to be involved in the uptake of essential amino acids, haem production, chemotaxis and sporulation. A 5.8 kb genomic DNA fragment of the serotype M49 group A streptococcal (GAS) strain CS101 was sequenced and found to contain five putative GAS Dpp genes (dppA to dppE). Deduced amino acid sequences exhibited 17-54% similarity to corresponding ABC-transporter sequences. The operon organization of the five genes was confirmed by transcriptional analysis, and a shorter, more abundant, dppA-only transcript was detected similar to that found in the GAS oligopeptide permease (Opp) system. Insertional inactivation was used to create serotype M2 and M49 strains that did not express the dppD and dppEATPase genes or nearly the entire operon. In feeding experiments with di- to hexapeptides, the wild-type strain grew with each peptide tested. The dpp mutants were unable to grow on dipeptides, whereas hexapeptides did not sustain the growth of opp mutants. Expression of the dpp operon was induced approximately fourfold in late exponential growth phase. In addition, a striking increase in the dppA to dppA-E ratio from 5:1 to more than 20:1 occurred during late exponential growth phase in complex medium. Growth in chemically defined medium (CDM) supplemented with various dipeptides specifically induced the expression of dpp and reduced both the dppA to dppA-E and oppA to oppA-F mRNA ratios. Expression of the virulence factor SpeB (major cysteine protease) was reduced eightfold in dpp mutants, whereas dpp expression was decreased about fourfold in a Mga virulence regulator mutant. Taken together, these data indicate a correlation between levels of intracellular essential amino acids and the regulation of virulence factor expression.

Production of stabilized virulence factor-negative variants by group A streptococci during stationary phase.

Many of the virulence factors associated with fulminant group A streptococci (GAS) infection are expressed under in vitro exponential growth conditions. However, the survival of GAS in tissue and intracellularly, as well as colonization of asymptomatic carriers, has been reported for GAS. The bacteria associated with these niches may encounter high-density, low-nutrient-flowthrough conditions that may more closely mimic in vitro stationary-phase conditions than exponential growth. Therefore, the behavior of GAS in stationary-phase culture was examined. We observed that after 24 h in stationary phase, GAS serotypes M49 and M2 developed a unstable colony dimorphism of typical large and atypical small colonies. Between days 4 and 5, we isolated stabilized atypical small colonies which remained stable for up to nine passages (approximately 200 generations) on fresh medium before fully reverting to the large-colony phenotype. Upon analysis, the small colonies showed no difference in cell number per colony, growth rate, survival in prolonged stationary-phase culture, or antibiotic sensitivity. However, the small colonies showed decreased transcription of hyaluronic acid capsule, the global positive virulence factor regulator gene mga, the mga-regulated emm mRNA (M-protein structural gene), and speB (cysteine protease). Accordingly, the small colonies were completely sensitive in a traditional phagocytosis assay. The production of virulence factors and phagocytosis resistance of the small-colony isolates was recovered when, after several passages on fresh medium, the colony morphology began to revert.

Analysis of toxicity of streptococcal pyrogenic exotoxin A mutants.

Streptococcal pyrogenic exotoxin A (SPE A) is secreted by some strains of Streptococcus pyogenes and is strongly associated with streptococcal toxic shock syndrome (STSS), a severe and often fatal illness. SPE A possesses a number of biological properties, some of which are shared with a group of exotoxins of streptococcal and staphylococcal origins, the pyrogenic toxin superantigens (PTSAgs). SPE A's most extensively studied property is superantigenicity. Superantigenic activation of T cells and monocytes stimulates the release of cytokines such as tumor necrosis factors alpha and beta, interleukin 1, and gamma interferon. These endogenous mediators are considered to be the primary cause of capillary leak, hypotension, and shock, the most severe manifestations of STSS. However, several studies have suggested that other properties of SPE A, such as ability to greatly enhance host susceptibility to endotoxin and ability to interact directly with endothelial cells, may play substantial roles in the syndrome. In this work we generated single- and double-site mutations of SPE A at residues K16, N20, C87, C90, C98, K157, S195, N20/C98, and N20/K157. The mutant SPE A's were analyzed in vivo for their lethal activity and in vitro for their superantigenic ability. Our results indicate that SPE A's ability to induce lethality and endotoxin enhancement does not require superantigenicity, and conversely superantigenicity does not necessarily lead to lethality. Thus, these properties and their relative contributions to the onset of hypotension and shock may be separable. Furthermore, evidence is presented that certain mutant toxins may be suitable for use as vaccine toxoids.

Brucella abortus siderophore 2,3-dihydroxybenzoic acid protects brucellae from killing by macrophages.

Addition of 2,3-dihydroxybenzoic acid, a siderophore produced by Brucella abortus, to macrophage cultures prevented intracellular killing of brucellae during the first 12 h after infection and increased the number of intracellular brucellae recovered at 48 h after infection. The protective effect could be demonstrated with inflammatory macrophages, interferon-gamma-activated macrophages and with macrophages supplemented with iron, shown elsewhere to facilitate killing of B abortus.

Cell-cell communication in gram-positive bacteria.

In gram-positive bacteria, many important processes are controlled by cell-to-cell communication, which is mediated by extracellular signal molecules produced by the bacteria. Most of these signaling molecules are peptides or modified peptides. Signal processing, in most cases, involves either transduction across the cytoplasmic membrane or import of the signal and subsequent interaction with intracellular effectors. Concentrations of signal in the nanomolar range or below are frequently sufficient for biological activity. The microbial processes controlled by extracellular signaling include the expression of virulence factors, the expression of gene transfer functions, and the production of antibiotics.

Molecular characterization of group A streptococcal (GAS) oligopeptide permease (opp) and its effect on cysteine protease production.

Bacterial oligopeptide permeases are membrane-associated complexes of five proteins belonging to the ABC-transporter family, which have been found to be involved in obtaining nutrients, cell-wall metabolism, competence, and adherence to host cells. A lambda library of the strain CS101 group A streptococcal (GAS) genome was used to sequence 10,192 bp containing the five genes oppA to oppF of the GAS opp operon. The deduced amino acid sequences exhibited 50-84% homology to pneumococcal AmiA to AmiF sequences. The operon organization of the five genes was confirmed by transcriptional analysis and an additional shorter oppA transcript was detected. Insertional inactivation was used to create serotype M49 strains which did not express either the oppA gene or the ATPase genes, oppD and oppF. The mutation in oppA confirmed that the additional shorter oppA transcript originated from the opp operon and was probably due to an intra-operon transcription terminator site located downstream of oppA. While growth kinetics, binding of serum proteins, and attachment to eukaryotic cells were unaffected, the oppD/F mutants showed reduced production of the cysteine protease, SpeB, and a change in the pattern of secreted proteins. Thus, the GAS opp operon appears to contribute to both protease production and export/processing of secreted proteins.

Enterococcus faecalis pheromone binding protein, PrgZ, recruits a chromosomal oligopeptide permease system to import sex pheromone cCF10 for induction of conjugation.

Conjugative transfer of the plasmid pCF10 by Enterococcus faecalis donor cells occurs in response to a peptide sex pheromone, cCF10, secreted by recipients. The plasmid-encoded cCF10 binding protein, PrgZ, is similar in sequence to binding proteins (OppAs) encoded by oligopeptide permease (opp) operons. Mutation of prgZ decreased the sensitivity of donor cells to pheromone, whereas inactivation of the chromosomal E. faecalis opp operon abolished response at physiological concentrations of pheromone. Affinity chromatography experiments demonstrated the interaction of the pheromone with several putative intracellular regulatory molecules, including an RNA molecule required for positive regulation of conjugation functions. These data suggest that processing of the pheromone signal involves recruitment of a chromosomal Opp system by PrgZ and that signaling occurs by direct interaction of internalized pheromone with intracellular effectors.

Identification and characterization of the genes of Enterococcus faecalis plasmid pCF10 involved in replication and in negative control of pheromone-inducible conjugation.

The prgB gene of the Enterococcus faecalis pheromone-inducible conjugative plasmid pCF10 encodes the surface protein Asc10. This protein mediates cell aggregation and its expression results in high-frequency transfer of the plasmid from donor to recipient. To identify the minimum region necessary for negative regulation of prgB expression, target plasmids were constructed containing a recently identified positive control region and a prgB::lacZ transcriptional fusion; expression of prgB in cells carrying these plasmids was thus verified by beta-galactosidase assay. The target plasmids were used in genetic studies with compatible plasmids containing cloned pCF10 genes supplying putative negative control functions to define the minimum region of pCF10 required for shutdown of prgB expression in the absence of exogenous pheromone. The minimum segment required for negative control, as indentified by deletion analysis, was a 6.9-kb region extending from the 5' end of a gene called prgN, through a previously identified gene, prgX. The DNA in this region, which had not been previously characterized (2.85 kb), was sequenced, and several potential regulatory genes and plasmid replication genes were identified. Genetic analysis indicated that the prgN, -Y, and -X genes are involved in negative control; prgW may also play a role in negative control, since it appeared to be required for expression of prgY. prgX, or a closely adjacent DNA sequence, acted in cis. The region of pCF10 containing negative control genes was also shown to function as an autonomous replicon in E. faecalis.

Immunobiologic and biochemical properties of mutants of toxic shock syndrome toxin-1.

Toxic shock syndrome (TSS) is a multisystem illness caused mainly by Staphylococcus aureus producing TSS toxin-1 (TSST-1). A variant of TSST-1 has been isolated from ovine mastitis S. aureus. This toxin, TSST-ovine (TSST-O) is only weakly T cell mitogenic, is nonpyrogenic, does not enhance endotoxin shock, and does not cause TSS in the miniosmotic pump model. The sequence of the ovine gene (tstO) differs from the TSST-1 gene (tstH) by 14 nucleotides that change seven amino acids in the mature protein of which two are in the C-terminal half. A gene fusion containing half of both tstH and tstO was made and cloned into S. aureus. The fusion protein contained the two C-terminal amino acid differences that are in TSST-O at residues 132 and 140. The fusion protein was not T cell mitogenic and did not elicit TSS in two rabbit models. Additional experiments used mutagenesis to change the lysine residue at position 132 of TSST-O to glutamate (TSST-OK132E), as exists in TSST-1, and to change the lysine residue of the human-ovine fusion at position 132 to glutamate (TSST-11140T). Both mutants were pyrogenic, enhanced endotoxin shock, and caused TSS in the miniosmotic pump model. However, the proteins were only partially T cell mitogenic. The restoration of lethality of TSST-O and the human-ovine fusion by changing the lysine to glutamate, as exists in TSST-1, indicates that residue 132 is important in lethality. The failure to regenerate complete T cell mitogenicity of the same mutants indicates that residues 132 and 140 are important for that activity.

Immune cell lethality induced by streptococcal pyrogenic exotoxin A and endotoxin.

Streptococcal pyrogenic exotoxin (SPE) A has many effects on the immune system, including immunolethality, which is characterized by a significant decrease in circulating immune cells as well as depletion of the spleen and lymph nodes prior to death of experimental animals. In this report, characterization of the mechanism of immunolethality has been undertaken. Synergistic induction of immunolethality was observed in vitro when human lymphocytes were treated with both SPE A and lipopolysaccharide (LPS). The same effect was demonstrated in the absence of a mitogenic response with the murine T-cell receptor, as well as in the absence of antigen-presenting cells and their secreted cytokines. The addition of antigen-presenting cells did not significantly affect lethality. SPE A directly interacted with LPS through interaction with ketodeoxyoctonate as demonstrated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and iodinated exotoxin overlays. This interaction was demonstrated to be important for immunolethality, since simultaneous addition of SPE A and LPS was required, whereas sequential addition of SPE A and LPS did not result in lethality. LPS appeared to be acting, in part, to enhance the cell-binding ability of SPE A, since SPE A could only be detected in A.E7 cell membrane preparations after simultaneous incubation with SPE A and LPS.

Cell and receptor requirements for streptococcal pyrogenic exotoxin T-cell mitogenicity.

Streptococcal pyrogenic exotoxins (SPEs) A, B, and C, like other members of the pyrogenic toxin family, are able to cause toxic shock-like syndromes. One of the major properties of these toxins is the ability to induce T-cell proliferation. Characterization of T cell mitogenicity associated with SPEs A, B, and C was undertaken. SPEs A, B, and C were mitogenic for C57BL10/SnJ and BALB/cWAT T cells, with activities differing in intensity depending on the mouse strain and toxin employed. SPE-induced, T-cell-proliferative activity was dependent on class II major histocompatibility complex molecules expressed on antigen-presenting cells. The abilities of SPEs A, B, and C to preferentially stimulate murine cells with certain T-cell receptor V beta s were investigated by fluorescence-activated cell sorter analysis. SPE A preferentially activated T cells expressing V beta 8 but not V beta 3, 6, or 11, while SPEs B and C preferentially stimulated T cells which did not express any of the tested V beta s.