T lymphocyte recognition of insolubilized peptide antigen

To study the role of antigen-presenting cells (APC) in T lymphocyte responses, the stimulation requirements of a murine T cell hybridoma specific for the peptide antigen human fibrinopeptide B (hFPB)/I-Ak was examined. The fine specificity of T cell recognition of this peptide was determined by using several hFPB homologs and analogs, which indicated that the intact 14-amino acid peptide must remain intact to preserve the antigenic determinant, and that the carboxyl terminal Arg14 was important for T cell responses. Of particular interest was the finding that APC-associated hFPB failed to stimulate the T cells, and that activation was only observed with soluble peptide or by brief hFPB treatment of the T cells and APC mixed together. In addition, hFPB covalently bound to agarose beads was able to cause T cell activation, provided that I-Ak+ APC were also present in the culture. A number of control experiments were performed that showed that hFPB was not released from the bead and that the antigenic peptide involved in T cell responses remained bound to the beads. These results indicate that the form of the hFPB peptide antigen recognized by this T cell can be provided separately from APC.     

Retrogenic modeling of experimental allergic encephalomyelitis associates T cell frequency but not TCR functional affinity with pathogenicity

The properties of a self-specific T cell's TCR that determine its pathogenicity are not well understood. We developed TCR retroviral transgenic, or retrogenic, models of myelin oligodendroglial glycoprotein (MOG)-induced experimental autoimmune encephalomyelitis (EAE) to compare the pathologic potential of five H-2 Ab/MOG35-55-specific TCRs. The TCRs were cloned and retrovirally transduced into either TCRalphabeta-deficient hybridoma cells or Rag1-/- bone marrow progenitor cells. Comparison of the hybridomas, identical except for TCR sequence, revealed distinct responsiveness, or functionally determined affinity, for cognate Ag. Retrogenic mice were produced by transfer of transduced progenitor cells into Rag1-/- recipients. T cells were detected within 4 wk. Engraftment levels varied considerably among the different TCRs and showed separate variability among individual mice. T cells were predominantly naive and virtually exclusively CD4+ and CD25-. Relative responses of the retrogenic T cells to Ag paralleled those of the hybridoma cells. Induction of EAE through active immunization led to rapid and severe disease in all mice expressing MOG-specific TCR. The mice additionally developed spontaneous disease, the incidence of which varied with the individual receptors. Interestingly, spontaneous disease frequency and intensity could not be correlated with the functional affinity of the respective TCR. Instead, it was associated with engraftment level, even when measured weeks before the onset of disease symptoms. Our results demonstrate the feasibility of using retrogenic modeling to compare TCRs in the EAE system. They further suggest that affinity is not a primary determinant in spontaneous EAE development in mice expressing monotypic TCRs and that autoreactive T cell frequency is of greater significance.     

T cell activation by purified, soluble, class I MHC molecules. Requirement for polyvalency

To examine the nature of the interaction of the TCR with the MHC class I Ag, we have studied the stimulation requirements of an H-2Dd-reactive T cell hybridoma, using a homogeneous, purified preparation of a molecularly engineered soluble counterpart of the class I Ag, H-2Dd/Q10b. We demonstrate that this monovalent, soluble MHC Ag is incapable of stimulating the release of IL-2 from this T cell hybridoma. However, the same preparation of the purified protein can elicit a dose-dependent response when made multivalent either by covalent coupling to soluble, high m.w. dextran or to agarose beads, or by adsorption to polystyrene tissue culture plates.     

Two roles for Ia in antigen-specific T cell activation. II. Toward a Velcro model of antigen recognition

It has been previously reported that Ia Ag on APC seems to be involved in Ag-specific T cell activation in at least two different ways: one is to associate with foreign Ag to form a neoantigenic determinant (the Ag-specific Ia function), and the second is to interact with T cells in a non-Ag-specific manner. Both Ia functions are required for T cell activation. In the present study we examined whether the T cell structures responsible for the non-Ag-specific Ia interaction were separable from the Ag-specific alpha/beta TCR. Purified protein derivative of tuberculin (PPD)-specific murine hybridoma T cells and polyclonal lymph node T cells were stimulated for IL-2 production by APC pulsed with PPD, glutaraldehyde fixed, and anti-Ia antibody treated, to provide the antigenic PPD/Ia determinant, in the presence of glutaraldehyde-fixed non-Ag-pulsed APC, to provide the non-Ag-specific Ia interactions. However, in several different approaches the T cell structures or activation signals responsible for the Ag-specific recognition and non-Ag-specific Ia interactions seemed to be associated with each other in this experimental system. First, the Ag-specific and non-Ag-specific Ia interactions with T cells were both required simultaneously to initiate T cell activation, and it was not possible to activate T cells by providing either Ia signal subsequent to the other. Second, the T cell structures responsible for the non-Ag-specific Ia interactions appeared to be clonally distributed in PPD-specific lymph node T cells. Third, another T cell hybridoma specific for bovine insulin also showed dual Ia interactions, but the specificity of the non-Ag-specific Ia function was different than that for the PPD-specific T cell response. Fourth, all subclones of PPD-specific T hybridomas that had lost Ag-specific responsiveness also lost functional non-Ag-specific Ia interactions. Taken together, these observations suggest that a single species of TCR may mediate both the Ag-specific and non-Ag-specific Ia interactions. In addition, the non-Ag-specific Ia interaction with T cells augmented the Ag-specific Ia interaction for T cell activation, indicating that both types of interactions may be involved in some T cell responses. Based on these observations, a Velcromodel depicting the synergy between the two Ia functions is proposed in which a matrix of interactions consisting of higher affinity Ag binding and lower affinity Ia-TCR associations provides cooperative sets of signals necessary for cellular activation.     

Molecular recognition of human CD1b antigen complexes: evidence for a common pattern of interaction with alpha beta TCRs

Ag-specific T cell recognition is mediated through direct interaction of clonotypic TCRs with complexes formed between Ag-presenting molecules and their bound ligands. Although characterized in substantial detail for class I and class II MHC encoded molecules, the molecular interactions responsible for TCR recognition of the CD1 lipid and glycolipid Ag-presenting molecules are not yet well understood. Using a panel of epitope-specific Abs and site-specific mutants of the CD1b molecule, we showed that TCR interactions occur on the membrane distal aspects of the CD1b molecule over the alpha1 and alpha2 domain helices. The location of residues on CD1b important for this interaction suggested that TCRs bind in a diagonal orientation relative to the longitudinal axes of the alpha helices. The data point to a model in which TCR interaction extends over the opening of the putative Ag-binding groove, making multiple direct contacts with both alpha helices and bound Ag. Although reminiscent of TCR interaction with MHC class I, our data also pointed to significant differences between the TCR interactions with CD1 and MHC encoded Ag-presenting molecules, indicating that Ag receptor binding must be modified to accommodate the unique molecular structure of the CD1b molecule and the unusual Ags it presents.     

Production of T-T hybrids from T cell clones. Direct comparison between cloned T cells and T hybridoma cells derived from them

It has been assumed, without direct evidence, that T cell hybridomas and non-transformed T cell clones are both good models of normal Ag-specific T cells. To compare directly the difference in activation of cloned normal T cells and T hybridoma cells with the same TCR, cloned T hybridoma cells were obtained by fusing pre-established, myoglobin-specific, Iad-restricted T cell clones (14.5 and 9.27) with BW5147 cells. T cell clones were pre-activated with IL-2 as well as specific Ag before fusion. Cloned T hybridoma A3.4C6 was derived from Lys 140-specific and I-Ed-restricted clone 14.5. The other cloned T hybridoma, C7R14, was a fusion product of Glu 109-specific and I-Ad-restricted clone 9.27. Both T hybridomas showed the same Ag specificity and Ia restriction as the parental cloned T cells. However, C7R14 showed higher apparent affinity and broader cross-reactivity than 9.27. Clone 14.5, but not hybridoma A3.4C6, appeared to stimulate splenic cells to secrete cytokines inhibiting HT-2A cell proliferation. The most striking difference between the clones and hybridomas was that both clones, but neither of the matched hybridomas, were induced to synthesize IL-1 on stimulation with Ag. Finally, both cloned T cells and T hybridomas killed Ag-pulsed Iad-bearing B lymphoma target cells. This evidence suggests that killing function can be inherited from clones to hybridomas. However, the clones were much more efficient at killing than the hybridomas, and the hybridomas were more efficient at IL-2 production than the clones. Thus, matched pairs of clones and hybridomas differ in their capacity to mediate the two functions or may tend to be selected differently during cloning. Thus, although our results generally support the validity of T cell hybridomas as faithful models of the corresponding T cell clones, a number of subtle and not-so-subtle differences indicate that caution must be used in such an extrapolation.     

T cell tumor cure by T cell receptor-mediated activation requires the development of CD8-dependent host immunity

The participation of the host in eliminating Ag-specific T hybridoma cells after their in vivo activation was studied. In our model system, treatment of the cytochrome c-specific T cell hybridoma 2B4.11 in vitro with Ag in the context of histocompatible APC results in cellular activation, as shown by IL-2 release and growth inhibition. In vivo treatment with Ag results in tumor cell elimination as a result both of a direct inhibitory effect of cytochrome c that is mediated through the 2B4.11 TCR and to the induction of host immunity. In vivo lymphocyte-depletion studies showed that CD8-bearing cells were critical to the successful elimination of tumor cells mediated by Ag, whereas depletion of CD4-bearing cells had only minor effects on the outcome. Cytotoxic cells from mice cured by Ag treatment lysed only 2B4.11 among a panel of related tumors, although in vivo cross-protection studies showed that 2B4.11-immune mice were also resistant to the growth of BW5147 and C10.9. Because spleen cells from 2B4.11 immune mice did not recognize 2B4.11 or other related tumors in proliferation assays, we concluded that a participant(s) with memory and specificity, not assayed in vitro, was also involved in the mediation of the immune effects observed. For therapies based on the use of less selective agents, i.e. mAb that share the activating properties of Ag but can react with T cell neoplasms of unknown specificity, it would appear that a relatively intact immune system is required for maximal success.     

Functional sites on the A alpha-chain. Polymorphic residues involved in antigen presentation to insulin-specific, Ab alpha:Ak beta-restricted T cells

The interaction between the clonally selected TCR, the processed Ag peptide and the Ia molecule is not fully understood in molecular terms. Our study intended to delineate the residues of Ab alpha molecules that function as contact sites for Ag and for the TCR of a panel of T cells specific for the A chain of insulin in combination with mixed haplotype Ab alpha:Ak beta molecules. Multiple L cell transfectants expressing alpha,beta-heterodimers composed of wild-type A beta- and chimeric or mutant A alpha-chains served as antigen presenting cells. The recombinant A alpha-chains had been generated by an exchange of allelically hypervariable regions (ahv) or amino acids. The results point out a broad spectrum of b sequence requirements for the bovine insulin-specific activation of the various T cell populations. Activation of some T cells seemed quite permissive, requiring b-haplotype amino acids in any one of the three ahv, while others had strict requirements, demanding b-haplotype sequence in all three ahv. Our data stress the role of ahvII and especially ahvIII in T cell activation. Interestingly, single amino-acid substitutions in ahvII or ahvIII of Ak alpha were sufficient to bring up full stimulation potential for two T cell hybridomas. We also found that some ahv permutations influenced the Ag preference (beef insulin versus pig insulin) of some T cells. These data suggest a critical role for the three-dimensional structure of the complex formed by Ia and the processed Ag peptide. The stability of the trimolecular complex essential for T cell activation is envisioned as being the sum of the interactions between Ag/I-A, TCR/Ag, and TCR/I-A, each variable in strength and compensated for by the others.     

Induction of negative signal through CD2 during antigen-specific T cell activation.

We have investigated the role of CD2 molecules in Ag-specific T cell activation by using a mouse model system in which the function of CD2 can be analyzed without the apparent influence of major accessory molecules, such as CD4 or LFA-1. Transfection of the CD2 gene into a CD2- T cell hybridoma confers the enhancement of IL-2 production upon Ag stimulation. Anti-CD2 mAb inhibits the Ag-specific response of the CD2-transfectant, not only to the level of CD2- cells but to the background. B cells, but not MHC class II-transfected L cells, serve as APC to induce the inhibition of Ag response. The complete abrogation of the response is observed only upon the stimulation through TCR with Ag in the presence of APC but not through either TCR-CD3 or other molecules such as Thy-1. Furthermore, the inhibition can also be observed when anti-CD2 mAb is immobilized on culture plates, suggesting that the inhibition of Ag response results from transducing the negative signal through the CD2 molecule. The experiments on cytoplasmic domain-deleted CD2-transfected T cells reveal that the cytoplasmic portion is responsible for the CD2-mediated abrogation of Ag responses. These results imply that CD2 has important roles in T cell responses not only as an activation and adhesion molecule but also as a regulatory molecule of Ag-specific responses through the TCR.     

Molecular design of the Calphabeta interface favors specific pairing of introduced TCRalphabeta in human T cells

A promising approach to adoptive transfer therapy of tumors is to reprogram autologous T lymphocytes by TCR gene transfer of defined Ag specificity. An obstacle, however, is the undesired pairing of introduced TCRalpha- and TCRbeta-chains with the endogenous TCR chains. These events vary depending on the individual endogenous TCR and they not only may reduce the levels of cell surface-introduced TCR but also may generate hybrid TCR with unknown Ag specificities. We show that such hybrid heterodimers can be generated even by the pairing of human and mouse TCRalpha- and TCRbeta-chains. To overcome this hurdle, we have identified a pair of amino acid residues in the crystal structure of a TCR that lie at the interface of associated TCR Calpha and Cbeta domains and are related to each other by both a complementary steric interaction analogous to a "knob-into-hole" configuration and the electrostatic environment. We mutated the two residues so as to invert the sense of this interaction analogous to a charged "hole-into-knob" configuration. We show that this inversion in the CalphaCbeta interface promotes selective assembly of the introduced TCR while preserving its specificity and avidity for Ag ligand. Noteworthily, this TCR modification was equally efficient on both a Mu and a Hu TCR. Our data suggest that this approach is generally applicable to TCR independently of their Ag specificity and affinity, subset distribution, and species of origin. Thus, this strategy may optimize TCR gene transfer to efficiently and safely reprogram random T cells into tumor-reactive T cells.     

Relationship between T cell receptors and antigen-binding factors. I. Specificity of functional T cell receptors on mouse T cell hybridomas that produce antigen-binding T cell factors

Upon antigenic stimulation with OVA-pulsed syngeneic macrophages, the mouse T cell hybridoma 231F1 produced glycosylation inhibiting factor (GIF) having affinity for OVA and IgE-suppressive factors, whereas another T cell hybridoma, 12H5, cells produced OVA-binding glycosylation enhancing factor (GEF) and IgE-potentiating factor. The OVA-binding GIF from the 231F1 cells is an Ag-specific Ts cell factor, whereas OVA-binding GEF from the 12H5 cells is an Ag-specific augmenting factor. Both hybridomas express CD3 complex and functional TCR-alpha beta. Cross-linking of TCR-alpha beta or CD3 molecules on the hybridomas by anti-TCR-alpha beta mAb or anti-CD3 mAb and protein A resulted in the formation of the same factors as those obtained by the stimulation of the cells with OVA-pulsed syngeneic macrophages. It was also found that both the 231F1 cells and 12H5 cells formed IgE-binding factors upon incubation with H-2d and H-2b APC, respectively, with a synthetic peptide corresponding to residues 307-317 in the OVA molecules (P307-317). Six other synthetic peptides, including those containing the major immunogenic epitope, i.e., P323-339, failed to stimulate the hybridomas in the presence of APC. Indeed, all of the 10 T cell hybridoma clones, which could produce either OVA-binding GIF or OVA-binding GEF, responded to P307-317 and APC for the formation of IgE-binding factors. In contrast, GIF/GEF derived from six other hybridoma clones, whose TCR recognized P323-339 in the context of a MHC product, failed to bind to OVA-coupled Sepharose. The results indicate the correlation between the fine specificity of TCR and the affinity of GIF/GEF to the nominal Ag. The amino acid sequence of P307-317 suggested that TCR on the cell sources of Ag-binding factors are specific for an external structure of the Ag molecules.     

Functional differentiation in the genetic control of murine T lymphocyte responses to human fibrinopeptide B

The ability to generate proliferative and helper T lymphocyte responses in mice was compared by using the 14 amino acid peptide, human fibrinopeptide B (hFPB). Lymph node or peritoneal exudate T cells from mice immunized with hFPB were assessed for in vitro proliferation to soluble hFPB as determined by the uptake of 3H-thymidine. The T cell proliferative response to hFPB was found to be under MHC-linked Ir gene control; mice possessing the H-2a,k haplotypes were responders, whereas H-2b,d,q,s mice were nonresponders. The influence of non-H-2 genes on these responses was not investigated, so exclusive regulation by H-2 is provisional. The absence of a detectable lymph node and peritoneal exudate T cell proliferative response persisted in H-2b,d,q,s mice after immunization and boosting with several doses of hFPB. In addition, the capacity to produce a T cell proliferative response was inherited in an autosomal dominant manner and gene(s) controlling responsiveness to hFPB mapped to the I-A subregion of the H-2 complex. To measure peptide-specific helper T cell activity, an in vitro microculture assay in which hFPB-primed lymph node T cells and normal spleen B cells and macrophages were used was developed measuring anti-fluorescein isothiocyanate (FITC) IgM and IgG plaque-forming cell (PFC) responses after culture with FITC-conjugated peptide. Immunization of B10.BR, C57BL/10, B10.D2, and B6AF mice with hFPB primed for significant helper T cell activity as assessed by the ability to augment a primary in vitro IgM response to FITC. The normal B cell IgM responses were completely dependent on hFPB-primed T cells and required that hapten (FITC) and carrier (peptide) be linked. In addition, immunization with FITC-conjugated peptide elicited positive in vivo PFC responses to FITC in B10.BR and C57BL/10 mice, indicating similar genetic control of helper activity in both the intact animals and the in vitro microcultures. Thus, B10.BR mice show both T help and T proliferative responses to hFPB, whereas C57BL/10 mice show only T help and no T proliferative responses. In contrast to B10.BR mice, C3H and CBA mice immunized with hFPB were completely unresponsive when assayed for helper T cell activity in vitro despite their ability to generate positive lymph node T cell proliferative responses. These results indicate responsiveness to hFPB by T helper and proliferating cells is different and is under separate genetic control.     

I-Ak polymorphisms define a functionally dominant region for the presentation of hen egg lysozyme peptides

The class II molecules of the MHC not only bind processed antigenic peptides but also interact with the TCR. This latter interaction is thought to be the basis for allele specific "restriction" of Ag presentation to T cells. The specificity of this interaction is likely due to amino acid differences in a small number of polymorphic or "hypervariable" regions located in the amino terminal domains of the alpha- and beta-chains. We have explored the functional significance of these polymorphic regions in an I-Ak-restricted, hen egg lysozyme specific Ag presentation system in which the measurement of IL-2 production by T cell hybridomas was used as the indicator of TCR recognition of the I-A/Ag complex. Chimeric I-A molecules, in which b allelic residues were substituted in one or more of the polymorphic regions of the A alpha k chain or in which d allelic residues were substituted in one or more of the polymorphic regions of the A beta k chain, were used to examine the contribution of each polymorphic region of the molecule to its function. The results obtained demonstrate that the regions between residues 69 to 76 of the A alpha k chain and the regions between residues 63 to 67 and 75 to 78 of the A beta k-chain exert a dominant effect on the presentation of lysozyme peptides by I-Ak to the T cell hybridomas in our panel. These observations were confirmed and extended by the analysis of Ag presentation by seven serologically selected mutants, all of which have amino acid interchanges in or around the dominant polymorphic regions. The results suggest that the serologically selected mutants fail to present Ag not because they fail to bind the peptide Ag but because the amino acid substitutions destabilize the interaction between the Ia/peptide complex and the TCR. Use of the recently published hypothetical model for class II structure to interpret the Ag presentation results suggests that the dominant polymorphic regions lie across from one another near one end of the alpha-helices that form the two walls of the proposed Ag-binding cleft located on the top surface of the class II molecule. Furthermore, the majority of the amino acids which have been changed in the serologically selected mutants have side chains which are postulated to point up toward the exterior of the molecule and would, therefore, be potential contact residues for the TCR.     

Proteasome inhibitors block Ras/ERK signaling pathway resulting in the downregulation of Fas ligand expression during activation-induced cell death in T cells

Activation-induced cell death (AICD) plays a critical role in the maintenance of homeostasis and peripheral tolerance in the immune system, and is mediated by Fas ligand (FasL) expression and the interaction between Fas and FasL. In the present study, we examined the role of the ubiquitin-proteasome system in AICD using T cell hybridoma N3-6-71 cells. The peptidyl aldehyde proteasome inhibitor carbobenzoxyl-Ile-Glu(O-t-butyl)-Ala-leucinal (PSI) blocked T cell receptor (TCR) stimulation-induced apoptosis in the T cell hybridoma. Fas and FasL gene expression and mouse FasL promoter activity following TCR stimulation were suppressed by PSI pretreatment. Deletion or point mutation of the kappaB site in the FasL promoter region did not suppress inducible FasL promoter activity effectively. PSI blocked extracellular signal-regulated kinase (ERK) activity induced by TCR stimulation, but had no effect on c-jun N-terminal kinase activation. ERK activation was essential for FasL expression and AICD. The initial tyrosine phosphorylation steps following TCR stimulation, i.e., phosphorylation of CD3zeta and Vav, were not altered by PSI. These data suggest that the ubiquitin-proteasome system has some regulatory function at an intermediate step between the initial tyrosine phosphorylation steps and ERK activation in AICD.     

p56lck association with CD4 is required for the interaction between CD4 and the TCR/CD3 complex and for optimal antigen stimulation.

By fluorescence resonance energy transfer, we have previously demonstrated that upon anti-CD3 mAb-mediated activation of a murine T cell hybridoma expressing human CD4, CD4 moves into close association with the TCR/CD3 complex. It was shown that this association between CD4 and the TCR/CD3 complex was dependent upon the presence of an intact CD4 cytoplasmic domain. We have now expressed, in a murine T cell hybridoma, mutated forms of CD4 containing cysteine to serine point mutations at positions 420, 422, or 430. The mutations at positions 420 and 422, but not 430, abolish association with p56lck. By using fluorescence resonance energy transfer, we demonstrate that mutations of CD4 which fail to interact with p56lck are unable to associate with the TCR/CD3 complex under conditions in which wild-type CD4 and the 430 mutant CD4 do associate with the TCR/CD3 complex. In addition, these mutants have a diminished response to CD4-dependent stimuli. We conclude that the association between CD4 and the TCR/CD3 complex during T cell activation plays an important role in CD4-dependent responsiveness and this association requires the interaction of CD4 with p56lck. These results also suggest that a substrate for p56lck may be expressed in the TCR/CD3 complex.     

Epitopic analysis by anti-I-Ak monoclonal antibodies of I-Ak-restricted presentation of lysozyme peptides

Anti-I-A mAb were used as probes of functional epitopes for both the presentation of hen egg lysozyme (HEL) peptides to I-Ak-restricted T cell hybridomas and the direct binding of the HEL (46-61) peptide. When mAb directed to polymorphic regions of I-Ak were used as inhibitors of Ag presentation, several different patterns of inhibition were observed among T cells specific for the same HEL peptide as well as among T cells specific for different fragments of HEL. Although there appears to be a conserved usage of some TCR V beta gene segments among the T cell hybrids specific for the same HEL peptide, no correlation is evident between a single V gene usage and susceptibility to blocking of Ag presentation by a particular anti-I-Ak mAb. Several of the mAb demonstrated T cell "clonotypic blocking" of Ag presentation, whereas others blocked presentation to every T cell hybrid tested, regardless of the peptide specificity. When mAb directed to nonpolymorphic regions of the I-A molecule were tested for their ability to block Ag presentation, little or no inhibition was observed. In addition, Fab' fragments of inhibitory mAb functioned identically to their intact homologous counterparts in their ability to block Ag presentation indicating that "nonspecific" steric hindrance was not playing a major role in the inhibitions observed. When the polymorphic region-directed anti-I-A mAb were tested for their ability to block the direct binding of the lysozyme peptide HEL(46-61) to I-Ak, those mAb that block HEL presentation to all T cell hybrids were found to block the binding of this peptide. However, anti-I-A mAb that demonstrate selective inhibition of T cell hybrid stimulation during Ag presentation, i.e., those directed to polymorphic serologic specificities Ia.15 and Ia.19, do not block the binding of HEL(46-61) to I-Ak. These data indicate that functionally independent epitopes exist on the I-Ak molecule for the binding of antigenic peptides and for interaction with the TCR.     

Immunobiological analysis of TCR single-chain transgenic mice reveals new possibilities for interaction between CDR3alpha and an antigenic peptide bound to MHC class I

The interaction between TCRs and peptides presented by MHC molecules determines the specificity of the T cell-mediated immune response. To elucidate the biologically important structural features of this interaction, we generated TCR beta-chain transgenic mice using a TCR derived from a T cell clone specific for the immunodominant peptide of vesicular stomatitis virus (RGYVYQGL, VSV8) presented by H-2K(b). We immunized these mice with VSV8 or analogs substituted at TCR contact residues (positions 1, 4, and 6) and analyzed the CDR3alpha sequences of the elicited T cells. In VSV8-specific CTLs, we observed a highly conserved residue at position 93 of CDR3alpha and preferred Jalpha usage, indicating that multiple residues of CDR3alpha are critical for recognition of the peptide. Certain substitutions at peptide position 4 induced changes at position 93 and in Jalpha usage, suggesting a potential interaction between CDR3alpha and position 4. Cross-reactivity data revealed the foremost importance of the Jalpha region in determining Ag specificity. Surprisingly, substitution at position 6 of VSV8 to a negatively charged residue induced a change at position 93 of CDR3alpha to a positively charged residue, suggesting that CDR3alpha may interact with position 6 in certain circumstances. Analogous interactions between the TCR alpha-chain and residues in the C-terminal half of the peptide have not yet been revealed by the limited number of TCR/peptide-MHC crystal structures reported to date. The transgenic mouse approach allows hundreds of TCR/peptide-MHC interactions to be examined comparatively easily, thus permitting a wide-ranging analysis of the possibilities for Ag recognition in vivo.     

Antigen-specific T cell repertoire modification of CD4+CD25+ regulatory T cells

T cell immune responses are regulated by the interplay between effector and suppressor T cells. Immunization with Ag leads to the selective expansion and survival of effector CD4(+) T cells with high affinity TCR against the Ag and MHC. However, it is not known if CD4(+)CD25(+) regulatory T cells (T(reg)) recognize the same Ag as effector T cells or whether Ag-specific TCR repertoire modification occurs in T(reg). In this study, we demonstrate that after a primary Ag challenge, T(reg) proliferate and TCR repertoire modification is observed although both of these responses were lower than those in conventional T cells. The repertoire modification of Ag-specific T(reg) after primary Ag challenge augmented the total suppressive function of T(reg) against TCR repertoire modification but not against the proliferation of memory CD4(+) T cells. These results reveal that T cell repertoire modification against a non-self Ag occurs in T(reg), which would be crucial for limiting excess primary and memory CD4(+) T cell responses. In addition, these studies provide evidence that manipulation of Ag-specific T(reg) is an ideal strategy for the clinical use of T(reg).