Superantigen recognition by gammadelta T cells: SEA recognition site for human Vgamma2 T cell receptors.

Human gammadelta T cells expressing the Vgamma2Vdelta2 antigen receptors recognize nonpeptide prenyl pyrophosphate and alkylamine antigens. We find that they also recognize staphylococcal enterotoxin A superantigens in a manner distinct from the recognition of nonpeptide antigens. Using chimeric and mutant toxins, SEA amino acid residues 20-27 were shown to be required for gammadelta TCR recognition of SEA. Residues at 200-207 that are critical for specific alphabeta TCR recognition of SEA do not affect gammadelta TCR recognition. SEA residues 20-27 are located in an area contiguous with the binding site of V beta chains. This study defines a superantigen recognition site for a gammadelta T cell receptor and demonstrates the differences between Vgamma2Vdelta2+ T cell recognition of superantigens and nonpeptide antigens.

Intercellular adhesion molecule-1 and leukocyte function-associated antigen-3 provide costimulation for superantigen-induced T lymphocyte proliferation in the absence of a specific presenting molecule.

Bacterial superantigens can bind TCR in the absence of MHC class II molecules and activate T lymphocytes when cocultured with certain class II-deficient accessory cells. It has not been determined, however, whether these accessory cells provide direct costimulation to the T cell or serve to present superantigens via a nonconventional ligand. We have identified a human adenocarcinoma cell line, SW480, that assists in the activation of human T cells by the staphylococcal enterotoxins B (SEB), C1 (SEC1), and D (SED), but not SEA, SEC2, SEC3, or SEE. SW480 cells did not express class II molecules, and anti-class II mAbs did not inhibit T cell proliferation, supporting the hypothesis that class II is not absolutely required for enterotoxin-mediated T cell activation. The TCR Vbeta profile of T cells stimulated by SEB plus SW480 cells was similar to that of T cells stimulated by SEB plus class II+ APC, indicating that TCR-SEB interactions were preserved in the absence of class II molecules. Binding studies failed to detect specific association of SEB with SW480 cells, suggesting that SW480 cells do not express receptors for enterotoxin. SEB coupled to beads, however, stimulated T cell proliferation, but only in the presence of SW480 cells. SW480 cells express both ICAM-1 and LFA-3 molecules, and the addition of Abs to these receptors inhibited T cell proliferation. These findings support a model in which certain enterotoxins engage the TCR independent of MHC class II or other specific presenting molecules and induce T cell proliferation with signals provided by nonconventional accessory cells.

Structural dichotomy of staphylococcal enterotoxin C superantigens leading to MHC class II-independent activation of T lymphocytes.

We have recently characterized an MHC class II-deficient human cell line, SW480, that supports the proliferation of purified human T cells in the presence of the staphylococcal enterotoxin and superantigen SEC1, but not the closely related isotypes SEC2 or SEC3. We now investigate the structural basis of this dichotomy and explore possible mechanisms that may account for it. Differences in activity between SEC1 and SEC2 were not attributable to differences in biochemical modification, to differences in Vbeta specificity, or to the potential to induce anergy. SEC2 inhibited SEC1-mediated T cell activation in the presence of SW480 cells, suggesting that SEC2 could compete with SEC1 for binding to the TCR but was unable to productively signal through the TCR. Utilizing a panel of hybrid enterotoxins we identified specific amino acids near the NH2-terminus of SEC1 that abrogated MHC class II-independent T cell activation, yet did not alter potency in the presence of class II+ APC. These residues mapped to the putative TCR binding domain of SEC1, and suggest that subtle differences in TCR binding affinity or the topology of the SEC1-TCR interaction can compensate for the lack of MHC class II and hence promote T cell proliferation.

Altered orientation of streptococcal superantigen (SSA) on HLA-DR1 allows unconventional regions to contribute to SSA Vbeta specificity.

Crystallographic studies reveal even distantly related bacterial superantigens (SAg) to adopt a common structural topology. Mutational analyses confirm that this shared folding pattern often confers a conserved function to analogous residues in different SAg, albeit with specificities for particular TCR or MHC class II molecules. It was thus surprising that the streptococcal SAg SSA differed from related SAg in the location of its Vbeta-determining residues. Because it seemed unlikely that SSA would deviate significantly from an SAg-like topology, we hypothesized that variations in SSA Vbeta-determining regions might result from differences in SSA-MHC class II interactions relative to other SAg during SSA presentation to the TCR. Comparison of the DR1-binding properties of SSA with its closest homologue SEB found different amino acid positions within SAg primary sequences to contribute to SSA-DR1 and SEB-DR1 interactions, and suggested that SSA bound DR1 with an altered orientation relative to SEB. The common involvement of DR1 alpha39K, however, predicted that the two SAg bound overlapping sites on DR1. Nevertheless, SSA and SEB did not effectively cross-compete for DR1 binding and had opposite patterns of DR1-binding affinity in the presence of distinct DR1-expressing cell lines. The data thus suggest that SSA and SEB bind not only with different orientations on DR1, but may bind preferentially to distinct DR1 subsets delineated by cell-specific factors. Differences in orientation of SSA on DR1 and/or interaction of SSA with particular DR1 subsets may explain why unconventional regions influence SSA TCR Vbeta specificity.

Species-dependent post-translational modification and position 2 allelism: effects on streptococcal superantigen SSA structure and V beta specificity.

Epidemiologic and molecular population genetic analyses support a role for superantigens (SAg) in the pathogenesis of severe staphylococcal and streptococcal infections. To investigate how variations in SAg structure influence immunomodulatory activity, we examined the biochemical and functional properties of two allelic variants of streptococcal SAg SSA that differ at position 2. Mass spectrometry revealed both recombinant (Escherichia coli) and native (Streptococcus pyogenes) SSA allelic variants to have significantly larger molecular masses than predicted by primary sequence alone and provided evidence that the proteins were modified by the addition of biochemical moieties, a phenomenon that has not been described for related SAg. Furthermore, the molecular masses of native and recombinant SSA were not the same; SSA was differentially post-translationally modified by the two bacterial genera. The substitution of E. coli-dependent processing for that of S. pyogenes altered both protease digestion and V beta specificity, suggesting that recombinant SAg from E. coli may not accurately represent the native toxin. In addition, the observation that SSA allelic variants differed in V beta specificity supports a role for position 2 in SSA-TCR interactions. That SSA position 2 contributes to V beta specificity could not have been predicted from functional or crystallographic studies of other SAg and suggests that SSA may adopt unique interactions with TCR and/or MHC class II molecules. Determining the structural basis for these differences should offer additional clues to the manner in which SAg exert their effects on the immune system during infection and may allow the designing of SAg mutants with specific quantitative and qualitative immunomodulatory properties.

Binding-protein-dependent arginine transport in Pasteurella haemolytica.

A periplasmic arginine transport system that is a member of the ATP -dependent transport superfamily was identified in Pasteurella haemolytica. The gene encoding the periplasmic binding protein (lapT) was cloned and the protein overexpressed in Escherichia coli. LapT was purified to homogeneity using a modified osmotic shock procedure and anion-exchange column chromatography. Filter-binding assays established that LapT is an L-arginine-binding protein. Various amino acids were tested for their ability to inhibit L-arginine binding to LapT. When present in 100-fold excess, only L-arginine, D-arginine and citrulline competed with L-arginine for binding. Arginine transport in P. haemolytica whole cells was competitively inhibited by the same amino acids, suggesting that the LapT permease specifically transports L-arginine. The dissociation constant for the L-arginine-LapT complex was 170 nM and the stoichiometry of binding was approximately 0.8 mol L-arginine (mol LapT)-1. A polyclonal antibody raised against the purified protein permitted detection of LapT in P. haemolytica periplasmic fractions.

Phylogenetic distribution of streptococcal superantigen SSA allelic variants provides evidence for horizontal transfer of ssa within Streptococcus pyogenes.

Phylogenetic analyses recently found the gene encoding the streptococcal superantigen SSA of Streptococcus pyogenes to occur in several well-differentiated clones comprising 10 (12.5%) of 80 clonal lineages examined. To determine if distinct clonal lineages carried the same ssa coding sequence or harbored a group of allelic variants, ssa was sequenced from 23 S. pyogenes strains representing the 10 clones identified by multilocus enzyme electrophoresis. Three alleles of ssa were found in natural populations of S. pyogenes. ssa-1 and ssa-3 differed by a single synonymous substitution in codon 94; both encoded SSA-1. Each of these alleles was present in phylogenetically diverse clones that had not shared a recent common ancestor. ssa-2 was present in a single clonal lineage. It was identical to ssa-3 at codon 94 but had a nonsynonymous substitution at codon 28 that changed the second amino acid of the mature protein from serine to arginine. This substitution altered the predicted isoelectric point and affected the apparent molecular mass during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Despite sequence variation both upstream of and within the ssa locus, all ssa-positive lineages expressed either SSA-1 or SSA-2. The observed patterns of ssa allele-clone distribution provide evidence for individual incidences of horizontal transfer and recombination of ssa among distinct group A streptococcal lineages. Although the extensive homology of SSA to the staphylococcal superantigen SEB raises the possibility of intergeneric gene transfer, a search for ssa in 68 genetically diverse clones of Staphylococcus aureus did not identify the gene. Moreover, the absence of ssa among 119 representative strains of Lancefield group B, C, or G streptococci suggests that ssa is confined to S. pyogenes.

Residues near the amino and carboxyl termini of staphylococcal enterotoxin E independently mediate TCR V beta-specific interactions.

Previous studies identified three COOH-terminal residues in staphylococcal enterotoxin E (SEE; Asp200, Pro206, and Asp207) that in part mediate TCR V beta recognition. We have identified an additional three residues near the NH2-terminus of SEE (Arg20, Asn21, and Ser24 that are needed in conjunction with these COOH-terminal residues to fully restore native levels of V beta-specific T cell proliferation. A staphylococcal enterotoxin A SEA-SEE hybrid molecule containing the NH2-terminal V beta determinants of SEE to activate alone exhibited V beta specificities of both SEA and SEE, indicating that these residues of SEE independently contribute to V beta recognition and do not obscure the native V beta determinants of SEA. These findings suggest that the ability of SEE to activate certain V beta-specific T cell subsets may result from multiple interactions with a single TCR beta-chain or perhaps by cross-linking two TCR. High affinity binding to HLA-DR1, a property of native SEA, was not altered in the SEA-SEE hybrid enterotoxins containing amino acid substitutions in regions 20 to 24 and 200 to 207, indicating that residues comprising the V beta determinants of SEE are separate from residues that contribute to HLA-DR1 binding affinity. Computer models of the predicted structure of SEE revealed that the V beta determinants of SEE are located on two adjacent solvent-exposed loops. Thus, the residues of SEE that mediate V beta recognition may coalesce to form a TCR binding site with specificities for multiple TCR beta-chains.

Molecular characterization and phylogenetic distribution of the streptococcal superantigen gene (ssa) from Streptococcus pyogenes.

A striking increase in the frequency and severity of invasive infections caused by Streptococcus pyogenes has occurred in recent years. Among these diseases is streptococcal toxic-shock-like syndrome (TSLS), a condition characterized by fulminant soft-tissue destruction and multiorgan failure. Streptococcal superantigen (SSA), a superantigen isolated from a TSLS-inducing, serotype M3 S. pyogenes strain, has recently been identified. We here describe the cloning, sequencing, and phylogenetic distribution of the SSA structural gene. The 783-bp open reading frame encodes a predicted 260-amino-acid protein that is similar in size to several other bacterial superantigens. The deduced sequence of the mature protein is 60.2% identical to that of staphylococcal enterotoxin B but only 49% identical to that of streptococcal pyrogenic exotoxin A. Southern blot and PCR analysis of 138 group A streptococcal strains representing 65 M protein serotypes and 15 nontypeable isolates identified ssa in 68 strains from 10 distinct clonal lineages. All ssa-positive clones expressed SSA. Of the two clones associated with TSLS, the ET 2-M3 lineage, but not the ET 1-M1 lineage, carried the SSA gene. Further analysis of the ET 2-M3 lineage found evidence for temporal variation in ssa association. Contemporary ET 2-M3 disease isolates had ssa, but two older isolates of this clone recovered in 1910 and 1920 lacked the gene. The clonal and temporal distribution patterns of ssa suggest a relatively recent acquisition of this superantigen-encoding gene by the ET 2-M3 lineage, perhaps by horizontal transfer and recombination.

Dual roles for class II major histocompatibility complex molecules in staphylococcal enterotoxin-induced cytokine production and in vivo toxicity.

The staphylococcal enterotoxins (SE) specifically bind to class II major histocompatibility complex (MHC) proteins, resulting in activation of monocytes and T cells. The SE cause weight loss in mice, which is dependent on T-cell stimulation and tumor necrosis factor alpha (TNF-alpha) production. Here we use a mutant of staphylococcal enterotoxin A that binds class II MHC molecules and activates monocytes but not T cells to evaluate the relative contributions of monocyte- and T-cell-stimulatory activities to in vivo toxicity. The mutant toxin did not cause weight loss in B10. BR mice but did stimulate monocyte TNF-alpha production in vitro, as did the wild-type toxin. Addition of a supernatant from toxin-activated T cells enhanced monocyte-stimulatory activity of both mutant and wild-type toxins fivefold. The effect of the supernatant could be mimicked by recombinant gamma interferon (IFN-gamma) and was inhibited by antibody to IFN-gamma. These results suggest that toxin-induced monocyte TNF-alpha production is upregulated by IFN-gamma, which likely represents the T-cell requirement in SE-mediated weight loss. Our studies thus implicate two distinct class II MHC-dependent signaling pathways for SE, the first involving direct signal transduction through class II MHC molecules mediated by either mutant or wild-type toxin and the second requiring T-cell stimulation by toxin-class II MHC complexes with consequent production of IFN-gamma. We suggest that both pathways are required for optimal monocyte TNF-alpha production in vitro and SE-induced toxicity in vivo.