Characterization of T cell receptors engineered for high affinity against toxic shock syndrome toxin-1

Superantigens, including bacterial enterotoxins, are a family of proteins that bind simultaneously to MHC class II molecules and the Vbeta regions of T cell receptors. This cross-linking results in the activation of a large population of T cells that release massive amounts of inflammatory cytokines, ultimately causing a condition known as toxic shock syndrome. The staphylococcal superantigen toxic shock syndrome toxin-1 (TSST-1) is a causative agent of this disease, but its structure in complex with the cognate T cell receptor (human Vbeta2.1) has not been determined. To understand the molecular details of the interaction and to develop high affinity antagonists to TSST-1, we used directed evolution to generate a panel of high affinity receptors for TSST-1. Yeast display libraries of random and site-directed hVbeta2.1 mutants were selected for improved domain stability and for higher affinity binding to TSST-1. Stability mutations allowed the individual Vbeta domains to be expressed in a bacterial expression system. Affinity mutations were generated in CDR2 and FR3 residues, yielding improvements in affinity of greater than 10,000-fold (a K(D) value of 180 pmol). Alanine scanning mutagenesis of hVbeta2.1 wild-type and mutated residues allowed us to generate a map of the binding site for TSST-1 and to construct a docking model for the hVbeta2.1-TSST-1 complex. Our experiments suggest that the energetic importance of a single hVbeta2.1 wild-type residue likely accounts for the restriction of TSST-1 specificity to only this human Vbeta region. The high affinity mutants described here thus provide critical insight into the molecular basis of TSST-1 specificity and serve as potential leads toward the development of therapeutic agents for superantigen-mediated disease.     

Structure of streptococcal pyrogenic exotoxin A reveals a novel metal cluster

The streptococcal pyrogenic toxins A, B, and C (SPEA, SPEB, and SPEC) are responsible for the fever, rash, and other toxicities associated with scarlet fever and streptococcal toxic shock syndrome. This role, together with the ubiquity of diseases caused by Streptococcus pyogenes, have prompted structural analyses of SPEA by several groups. Papageorgiou et al. (1999) have recently reported the structure of SPEA crystallized in the absence of zinc. Zinc has been shown to be important in the ability of some staphylococcal and streptococcal toxins to stimulate proliferation of CD4+ T-cells. Since cadmium is more electron dense than zinc and typically binds interchangeably, we grew crystals in the presence of 10 mM CdCl2. Crystals have been obtained in three space groups, and the structure in the P2(1)2(1)2(1) crystal form has been refined to 1.9 A resolution. The structural analysis revealed an identical tetramer as well as a novel tetrahedral cluster of cadmium in all three crystal forms on a disulfide loop encompassing residues 87-98. No cadmium was bound at the site homologous to the zinc site in staphylococcal enterotoxins C (SECs) despite the high structural homology between SPEA and SECs. Subsequent soaking of crystals grown in the presence of cadmium in 10 mM ZnCl2 showed that zinc binds in this site (indicating it can discriminate between zinc and cadmium ions) using the three ligands (Asp77, His106, and His110) homologous to the SECs plus a fourth ligand (Glu33).     

Study of the biological activities of toxic shock syndrome toxin-1. I. Proliferative response and interleukin 2 production by T cells stimulated with the toxin

The mitogenic and interleukin 2 (IL 2) production-inducing effects of toxic shock syndrome toxin-1 (TSST-1) on murine lymphocytes were investigated. TSST-1, an exotoxin produced by Staphylococcus aureus recovered from patients with toxic shock syndrome (TSS), is thought to be a causative agent of the syndrome. TSST-1 was mitogenic for splenic T cells and peanut agglutinin (PNA)-negative thymocytes, but not for T cell-depleted spleen cells, PNA-positive thymocytes or IL 2-dependent CTLL 2-cells. A factor mitogenic for CTCC-2 cells with a molecular weight of 30-35 kdaltons was obtained by stimulating spleen cells with TSST-1 and it was absorbed by CTLL-2 cells, indicating that the factor is IL 2. For substantial amounts of IL 2 to be produced, 10 ng or more of TSST-1 per ml and 48 hr or more of incubation were required. Removal of T cells abrogated the IL 2 production by spleen cells. T cells obtained by the nylon wool column method alone produced IL 2 on TSST-1 stimulation in the presence of either macrophages or a macrophage lysate containing interleukin 1. However, T cells obtained by a combination of the nylon wool column method and anti-Ia antibody treatment produced IL 2 in the presence of macrophages but not of the macrophage lysate, indicating that IL 2 production by TSST-1-stimulated T cells is absolutely dependent on the presence of accessory cells.     

Structural basis of T-cell specificity and activation by the bacterial superantigen TSST-1

Superantigens (SAGs) bind simultaneously to major histocompatibility complex (MHC) and T-cell receptor (TCR) molecules, resulting in the massive release of inflammatory cytokines that can lead to toxic shock syndrome (TSS) and death. A major causative agent of TSS is toxic shock syndrome toxin-1 (TSST-1), which is unique relative to other bacterial SAGs owing to its structural divergence and its stringent TCR specificity. Here, we report the crystal structure of TSST-1 in complex with an affinity-matured variant of its wild-type TCR ligand, human T-cell receptor beta chain variable domain 2.1. From this structure and a model of the wild-type complex, we show that TSST-1 engages TCR ligands in a markedly different way than do other SAGs. We provide a structural basis for the high TCR specificity of TSST-1 and present a model of the TSST-1-dependent MHC-SAG-TCR T-cell signaling complex that is structurally and energetically unique relative to those formed by other SAGs. Our data also suggest that protein plasticity plays an exceptionally significant role in this affinity maturation process that results in more than a 3000-fold increase in affinity.     

T-cell response to superantigen restimulation during menstrual toxic shock syndrome

Menstrual toxic shock syndrome (MTSS) is a severe toxin-mediated disease associated with Staphylococcus aureus producing toxic shock syndrome toxin 1 (TSST-1), a superantigen that mediates a potent activation of Vβ-2 T cells. In animal models, superantigen treatment of responsive T cells induces their initial proliferation, followed by unresponsiveness upon further superantigen stimulation. To determine whether T cell unresponsiveness occurs in humans during the acute phase of MTSS, we collected T cells from a patient with MTSS and restimulated them ex vivo with recombinant TSST-1. The expansion of T cells collected during the acute phase of disease was compared with positive controls including basal-state T cells (collected 70 days after MTSS) restimulated with TSST-1, and T cells stimulated with enterotoxin B superantigen. We found that TSST-1-induced expansion of acute phase T cells was not inferior to that observed in positive controls. We conclude that T cells were still reactive to TSST-1 during the acute phase of MTSS in this patient. As the persistence of TSST-1 production could thus be associated with further expansion of TSST-1-reactive T cells and a rapid worsening of symptoms, this study adds further support to the need for immediate eradication of the focus of infection as soon as MTSS is suspected.     

Effect of dilution rate and Mg2+ limitation on toxic shock syndrome toxin-1 production by Staphylococcus aureus grown in defined continuous culture

A toxic shock syndrome isolate of Staphylococcus aureus was grown in a chemostat, in a defined synthetic medium of six amino acids, glucose, two vitamins and salts. Steady states were achieved under limiting and replete Mg2+ conditions and at a range of relative specific growth rates. The biomass and toxic shock syndrome toxin-1 (TSST-1) were estimated at each condition. Under Mg2+ limitation the biomass and TSST-1 production rates were reduced compared to Mg2+ replete conditions. Optimal TSST-1 production occurred at 0.81 relative specific growth rate.     

The Refined Crystal Structure of Toxic Shock Syndrome Toxin-1 at 2.07 Å Resolution

The pyrogenic toxin toxic shock syndrome toxin-1 fromStaphylococcus aureusis a causative agent of the toxic shock syndrome disease. It belongs to a family of proteins known as superantigens that cross-link major histocompatibility class II molecules and T-cell receptors leading to the activation of a substantial number of T cells. The crystal structure of this protein has been refined to 2.07 Å with anR_crystvalue of 20.4% for 51,240 reflections. The final model contains three molecules in the asymmetric unit with good stereochemistry and a root-mean-square deviation of 0.009 Å and 1.63° from ideality for bond lengths and bond angles, respectively. The overall fold is considerably similar to that of other known microbial superantigens (staphylococcal enterotoxins). However, a detailed structural analysis shows that toxic shock syndrome toxin-1 lacks several structural features that affect its specificity for Vβ elements of the T-cell receptor and also its recognition by major histocompatibility class II molecules.     

Identification of MHC class II-associated peptides that promote the presentation of toxic shock syndrome toxin-1 to T cells

Previous studies have shown that the DM-deficient cell line, T2-I-A(b), is very inefficient at presenting toxic shock syndrome toxin 1 (TSST-1) to T cells, suggesting that I-A(b)-associated peptides play an essential role in the presentation of this superantigen. Consistent with this, the loading of an I-A(b)-binding peptide, staphylococcal enterotoxin B 121-136, onto T2-I-A(b) cells enhanced TSST-1 presentation >1000-fold. However, despite extensive screening, no other peptides have been identified that significantly promote TSST-1 presentation. In addition, the peptide effect on TSST-1 presentation has been demonstrated only in the context of the tumor cell line T2-I-A(b). Here we show that peptides that do not promote TSST-1 presentation can be converted into "promoting" peptides by the progressive truncation of C-terminal residues. These studies result in the identification of two peptides derived from IgGV heavy chain and I-Ealpha proteins that are extremely strong promoters of TSST-1 presentation (47,500- and 12,000-fold, respectively). We have also developed a system to examine the role of MHC class II-associated peptides in superantigen presentation using splenic APC taken directly ex vivo. The data confirmed that the length of the MHC class II-bound peptide plays a critical role in the presentation of TSST-1 by splenic APC and showed that different subpopulations of APC are equally peptide dependent in TSST-1 presentation. Finally, we demonstrated that the presentation of staphylococcal enterotoxin A, like TSST-1, is peptide dependent, whereas staphylococcal enterotoxin B presentation is peptide independent.     

Bacterial toxins induce heat shock proteins in human neutrophils

We studied the influence of different bacterial toxins (alveolysin; toxic shock syndrome toxin 1, TSST-1 and erythrogenic toxin A, ETA) on the expression of heat shock proteins (hsps) in isolated human polymorphonuclear granulocytes (PMNs). As was shown by Western blotting (anti-hsp72) ETA and TSST-1 were potent inducers of hsps at low toxin concentrations (10 ng/ml). Alveolysin led to the expression of hsps at hemolytic concentrations (1 HU; 700 ng/ml) whereas at subhemolytic concentrations (7 ng/ml) no heat shock response was observed. The induction of heat shock proteins was also accompanied by increased mRNA levels for hsp70 as was determined by PCR-analysis.     

Crystal structure of a dimeric form of streptococcal pyrogenic exotoxin A (SpeA1)

Streptococcal pyrogenic exotoxin A (SpeA1) is a bacterial superantigen associated with scarlet fever and streptococcal toxic shock syndrome (STSS). SpeA1 is found in both monomeric and dimeric forms, and previous work suggested that the dimer results from an intermolecular disulfide bond between the cysteines at positions 90 of each monomer. Here, we present the crystal structure of the dimeric form of SpeA1. The toxin crystallizes in the orthorhombic space group P212121, with two dimers in the crystallographic asymmetric unit. The final structure has a crystallographic R-factor of 21.52% for 7248 protein atoms, 136 water molecules, and 4 zinc atoms (one zinc atom per molecule). The implications of SpeA1 dimer on MHC class II and T-cell receptor recognition are discussed.     

The T cell receptor beta-chain second complementarity determining region loop (CDR2beta governs T cell activation and Vbeta specificity by bacterial superantigens

Superantigens (SAgs) are microbial toxins defined by their ability to activate T lymphocytes in a T cell receptor (TCR) β-chain variable domain (Vβ)-specific manner. Although existing structural information indicates that diverse bacterial SAgs all uniformly engage the Vβ second complementarity determining region (CDR2β) loop, the molecular rules that dictate SAg-mediated T cell activation and Vβ specificity are not fully understood. Herein we report the crystal structure of human Vβ2.1 (hVβ2.1) in complex with the toxic shock syndrome toxin-1 (TSST-1) SAg, and mutagenesis of hVβ2.1 indicates that the non-canonical length of CDR2β is a critical determinant for recognition by TSST-1 as well as the distantly related SAg streptococcal pyrogenic exotoxin C. Frame work (FR) region 3 is uniquely critical for TSST-1 function explaining the fine Vβ-specificity exhibited by this SAg. Furthermore, domain swapping experiments with SAgs, which use distinct domains to engage both CDR2β and FR3/4β revealed that the CDR2β contacts dictate T lymphocyte Vβ-specificity. These findings demonstrate that the TCR CDR2β loop is the critical determinant for functional recognition and Vβ-specificity by diverse bacterial SAgs.     

Effect of isotypes and allelic polymorphism on the binding of staphylococcal exotoxins to MHC class II molecules

Interaction of staphylococcal exotoxins (SE) with MHC class II molecules plays a central role in the activation of immune cells by SE. We have recently demonstrated directly that toxic shock syndrome toxin-1 (TSST-1) binds to MHC class II molecules with high affinity, and similar results have been reported for SEA and SEB. The ability of T cells to respond to individual SE is associated with the expression of particular TCR-V beta gene elements. In the present study we have examined the effect of polymorphism on the ability of MHC class II molecules to bind SEB and TSST-1. We have used a panel of L cell transfectants that express different allelic forms of each of the three human class II isotypes. Radioligand binding assays detected binding of SEB and TSST-1 to most, but not all of the MHC class II molecules examined. Toxin-driven MHC class II-dependent T cell proliferation occurred with all transfectants examined even in the absence of detectable toxin binding. These results indicate that SE can bind to human MHC class II molecules of diverse phenotypes.     

The nucleotide and partial amino acid sequence of toxic shock syndrome toxin-1

The nucleotide sequence of toxic shock syndrome toxin-1 (TSST-1) has been determined. In addition, one-third of the predicted amino acid sequence was confirmed by amino acid sequence analysis of cyanogen bromide-generated TSST-1 protein fragments. The DNA sequencing results identified a 708-base pair open reading frame starting with an ATG, 7 base pairs downstream from a Shine-Dalgarno sequence, and terminating at a UAA stop codon. Amino acid analysis of the intact protein defined the NH2 terminus of the mature protein and located the cleavage point for the signal peptide (Ala/Ser). The signal peptide contained the first 40 amino acids and had characteristic structural similarities with other bacterial signal peptides. The coding sequence of the mature protein was 585 base pairs (194 amino acids) in length, and the molecular weight of the predicted protein was 22,049. This is in good agreement with the previously reported molecular weight of TSST-1 (22,000), as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. NH2-terminal amino acid sequence analysis performed on isolated TSST-1 CNBr fragments determined the position of the peptides in the TSST-1 sequence and verified the predicted amino acid sequence in those positions. Computer analyses of the amino acid sequence showed that TSST-1 has little or no sequence homology with biologically related toxins, streptococcal pyrogenic exotoxin A, and staphylococcal enterotoxins B and C.     

Staphylococcal toxin of toxic shock syndrome

Literature data on toxic shock syndrome staphylococcal toxin (TSST-1) are summarized; properties of Staphylococcus aureus strains producing TSST-1, nutrient media, and factors influencing on production of TSST-1 are reviewed. Physical and chemical properties of the toxin, its molecular characteristics, genetic regulation of its production, mechanism of action, and diseases which it causes are also discussed. Clinical and histologic signs of toxic shock syndrome (TSS), its diagnostic criteria, susceptibility of people to TSS, antigenic and serologic properties of the toxin, epidemiology of the infection caused by TSST-1-producing strains of staphylococci, methods of TSST-1 extraction and identification are described.     

Toxic shock syndrome toxin-1 induces inositol phospholipid turnover, protein kinase C translocation, and calcium mobilization in human T cells

Toxic shock syndrome toxin-1 (TSST-1) is a 22-kDa exotoxin produced by most Staphylococcus aureus strains responsible for toxic shock syndrome. TSST-1 is a mitogen for human T cells. The mechanism of T cell activation by TSST-1 was investigated. TSST-1 induced IL-2R expression, IL-2 synthesis, and proliferation in T cells in a monocyte-dependent fashion. Neither IL-1 nor IL-2, alone or in combination, substituted for monocytes in supporting TSST-1-induced mitogenesis. We investigated the mechanism by which TSST-1 induces initogenesis. TSST-1 failed to induce ADP-ribosylation of T cell membrane proteins. However, the toxin induced transient translocation of protein kinase C from cytosol to plasma membranes and also induced the mobilization of cellular Ca2+ stores in both PBMC and the Jurkat human tumor T cell line, suggesting that TSST-1 triggered inositol phospholipid turnover. This was directly demonstrated to be the case in both cellular preparations studied. TSST-1 induced the increased synthesis of the inositol phospholipid phosphatidyl inositol, phosphatidyl inositol-4 phosphate, and phosphoinositol inositol-4,5-bisphosphate, and induced the breakdown of inositol phospholipid as evidence by the accumulation of phosphatidic acid and inositol phosphates. We conclude that the action of TSST-1 involves the induction of inositol phospholipid turnover, protein kinase C activation, and mobilization of cellular Ca2+ stores. This effect is similar to that of mitogenic lectins and of anti-CD3 antibodies.     

Molecular requirements for T cell activation by the staphylococcal toxic shock syndrome toxin-1

The activation of Ag-specific, Ia molecule-restricted, TCR V beta 3+ T cell clones by staphylococcal toxic shock syndrome toxin-1 (TSST-1), was investigated. The results show that although Ag- and TSST-1-induced activation of T cell clones both require TCR expression and similar biologic activation signals, the Ia molecule requirement for TSST-1 recognition was much less stringent than that observed for antigenic peptide recognition. In addition, T cell clones recognized TSST-1 without processing by APC. These results suggest that the ability of TSST-1 to polyclonally activate T cells is dependent on TCR recognition of the intact toxin molecule bound to a nonpolymorphic region(s) of the Ia molecule resulting in the same activation events induced by Ag recognition.     

The structural basis of the thermostability of SP1, a novel plant (Populus tremula) boiling stable protein

We previously reported on a new boiling stable protein isolated from aspen plants (Populus tremula), which we named SP1. SP1 is a stress-related protein with no significant sequence homology to other stress-related proteins. It is a 108-amino-acid hydrophilic polypeptide with a molecular mass of 12.4 kDa (Wang, W. X., Pelah, D., Alergand, T., Shoseyov, O., and Altman, A. (2002) Plant Physiol. 130, 865-875) and is found in an oligomeric form. Preliminary electron microscopy studies and matrix-assisted laser desorption ionization time-of-flight mass spectrometry experiments showed that SP1 is a dodecamer composed of two stacking hexamers. We performed a SDS-PAGE analysis, a differential scanning calorimetric study, and crystal structure determination to further characterize SP1. SDS-PAGE indicated a spontaneous assembly of SP1 to one stable oligomeric form, a dodecamer. Differential scanning calorimetric showed that SP1 has high thermostability i.e. Tm of 107 degrees C (at pH 7.8). The crystal structure of SP1 was initially determined to 2.4 A resolution by multi-wavelength anomalous dispersion method from a crystal belonging to the space group I422. The phases were extended to 1.8 A resolution using data from a different crystal form (P21). The final refined molecule includes 106 of the 108 residues and 132 water molecules (on average for each chain). The R-free is 20.1%. The crystal structure indicated that the SP1 molecule has a ferredoxin-like fold. Strong interactions between each two molecules create a stable dimer. Six dimers associate to form a ring-like-shaped dodecamer strongly resembling the particle visualized in the electron microscopy studies. No structural similarity was found between the crystal structure of SP1 and the crystal structure of other stress-related proteins such as small heat shock proteins, whose structure has been already determined. This structural study further supports our previous report that SP1 may represent a new family of stress-related proteins with high thermostability and oligomerization.     

Staphylococcal toxins bind to different sites on HLA-DR

Staphylococcal enterotoxins (SE) and toxic shock syndrome toxin 1 (TSST-1) bind to MHC class II molecules and the toxin-class II complexes induce proliferation of T cells bearing specific V beta sequences. We have previously reported that these toxins display varying binding affinities for HLA-DR1. We now investigated whether these differences simply reflected differences in binding affinity for a single class II binding site or, at least in part, the engagement of different binding sites on the HLA-DR complex. Through competitive binding studies we show that SEB and TSST-1, which are not closely related by their amino acid sequences, bind to two different sites on HLA-DR. Both of these sites are also occupied by staphylococcal enterotoxin A (SEA), enterotoxin D (SED), and enterotoxin E (SEE) which exhibit more than 70% amino acid sequence homology. SEB and TSST-1 failed to inhibit SEA binding to HLA-DR. These studies suggest that there may be three distinct, although perhaps overlapping, binding sites on HLA-DR for these toxins. Further, although SED and SEE are similar to SEA in structure, and appear to bind the same sites on HLA-DR as SEA, they displayed significantly lower binding affinities. T cell proliferative responses to SED required a higher concentration of the toxin than SEA, probably reflecting its lower binding affinity. SEE, however, elicited T cell responses at very low concentrations, similar to SEA, despite its much lower binding affinity. Therefore, although the affinities of these toxins to MHC class II molecules appear to significantly influence the T cell responses, the effective recognition of the toxin-class II complex by the TCR may also contribute to such responses.