Presentation of a horse cytochrome c peptide by multiple H-2b class I major histocompatibility complex (MHC) molecules to C57BL/6- and bm1-derived cytotoxic T lymphocytes: Presence of a single MHC anchor residue may confer efficient peptide-specific CTL recognition

In this study the immunogenic tryptic fragment from a horse cytochrome c (cyt c) digest recognized by cytotoxic T lymphocytes (CTL), induced by in vitro peptide stimulation from C57BL/6 (B6) and mutant B6.C-H-2^bm1 (bm1) mice is identified. An identical sequence, p40—53, is recognized by CTL from both B6 and bm1 mice. In addition, both B6 and bm1 cloned CTL lines display unusual major histocompatibility complex (MHC) class I-restricted recognition of this peptide in that they respond to it in the context of H-2K^b, H-2D^b, and H-2K^bm1 class I molecules, although the sequence lacks the usual structural K^b and D^b peptide-binding motifs. Truncated analogues which resemble the lengths of naturally processed MHC class I-presented peptides, confer reactivity for B6 and bm1 CTL against EL4 (H-2^b) targets as well as the L cell transfectants, L + K^b, L + D^b, and L + K^bm1. The antigenic peptide with the greatest potency is p41—49, which appears to be generated by angiotensin converting enzyme cleavage of the full-length p40—53 tryptic peptide. The minimum antigenic peptide recognized by both B6 and bm1 CTL, and which targets lysis on each of the transfectants, is the hexamer p43—48 peptide from horse cyt c. Residues Pro⁴⁴ and Thr⁴⁷, which occupy polymorphic positions with respect to other species-variant cyt c molecules, influence recognition of these peptides differently for the B6 and bm1 CTL. The ability of H-2K^b, H-2D^b, and mutant H-2K^bm1 class I molecules to present the same peptide to a single cloned CTL is discussed in the context of current knowledge of peptide anchor residues and side chain-specific binding pockets in the MHC class I peptide-binding site.     

MUC1 peptide epitopes associated with five different H-2 class I molecules

We have previously described the induction of murine CD8⁺ major histocompatibility complex (MHC) class I-restricted cytotoxic T cells (CTL) recognizing the 20-amino acid repeat region of the human mucin 1 (MUC1) variable number of tandem repeats region (VNTR), a mucin greatly increased in expression in breast cancer and proposed as a target for immunotherapy. In that study, CTL could detect MUC1 peptides associated with the MHC of all nine strains examined, and we now report the different epitopes presented by five different MHC class I molecules. The epitopes were defined in CTL assays using peptide-pulsed phytohemagglutinin blasts or MHC class I-transfected L cells as targets; in addition, peptide binding assays and T cell proliferation studies were performed. Within the 20-amino acid VNTR, nine potential epitopes could be defined. The epitopes for the four MHC class I molecules [K^b (three epitopes), D^d, L^d and K^k] were closely related, all containing the amino acids PDTRPAP. For D^b, three epitopes were identified, all containing APGSTAP. Most of the epitopes did not contain a consensus motif for the particular MHC class I allele, and bound with low ‘affinity’, compared with known high-affinity peptides. CD8⁺ T cell proliferation also occurred to the same MHC class I-presented epitopes. Finally, when conventional anchor residues were introduced into the peptides, peptide binding increased, whereas CTL recognition was either retained (K^b) or lost (D^b) depending on the epitope.     

Elongated peptides,not the predicted nonapeptide stimulate a major histocompatibility complex class I-restricted cytotoxic T lymphocyte clone with specificity for a bacterial heat shock protein

The peptides recognized by an H-2D^b-restricted CD8 cytotoxic T lymphocyte (CTL) clone which is specific for the 60-kDa mycobacterial heat shock protein (hsp) and cross-reacts with stressed host cells were characterized. None of the nonapeptides from hsp60 conforming to the H-2D^b binding motif were able to sensitize target cells for lysis by this CTL clone. Sequence analysis of the stimulatory fraction from a trypsin digest of hsp60, together with synthetic peptide studies, defined a cluster of overlapping epitopes. Carboxy-terminal extension by at least one amino acid of the nonamer predicted to bind best to H-2D^b was essential for CTL recognition. Two such elongated peptides, a 10-mer and a 12-mer stimulated the clone at similarly low concentrations in the 100 pM range. We assume that these two peptides comply best with the natural epitope. In contrast, the 11-mer was inactive. The stimulatory 10-mer bound to H-2D^b with an efficacy similar to that of the nonapeptide corresponding to the H-2D^b motif, as revealed by peptide induced major histocompatibility complex (MHC) surface expression on RMA-S cells and competitive blocking of epitope recognition by the nonamer. Binding of these carboxy-terminally extended peptides to the MHC groove can be explained by anchoring through the amino acid residue Asn in position 5 of the peptide and by intrusion of the hydrophobic carboxy-terminal Ala (10-mer) or Leu (12-mer), but not Gly (11-mer), into the hydrophobic pocket of the H-2D^b cleft. Because the carboxy-terminal part is thus larger than predicted this region of the peptide may arch up from the binding groove. We assume that recognition of steric components of the MHC/peptide complex broaden the range of epitope specificity for a single T cell receptor. This flexibility not only promotes recognition of several overlapping peptides from a single antigen, but may also increase the chance of cross-reaction with similar peptides from unrelated proteins, including autoantigens. Consistent with this latter assumption, the T cell clone cross-recognizes mycobacterial hsp60 and stressed host cells.     

Vaccination with cytotoxic T lymphocyte epitope-containing peptide protects against a tumor induced by human papillomavirus type 16-transformed cells

Cytotoxic T lymphocyte (CTL) peptide epitopes can be used for immunization of mice against lethal virus infection. To study whether this approach can be successful against virus-induced tumors we generated a B6 (H-2^b) tumorigenic cell line transformed by human papillomavirus (HPV). This virus is detected in over 90% of all human cervical cancers. To identify vaccine candidates, we generated a set of 240 overlapping peptides derived from the HPV type 16 (HPV16) oncogenes E6 and E7. These peptides were tested for their ability to bind H-2K^b and H-2D^b MHC class I molecules. Binding peptides were compared with the presently known peptide-binding motifs for H-2K^b and H-2D^b and the predictive value of these motifs is shortly discussed. The high-affinity H-2D^b-binding peptide and putative CTL epitope E₇ 49-57 (RAHYNIVTF) was used in vaccination studies against HPV 16-transformed tumor cells. Immunization with peptide E₇ 49-57 rendered mice insensitive to a subsequent challenge with HPV 16-transformed tumor cells in vivo, and induced a CTL response which lysed the tumor cells in vitro.     

Similar as well as distinct MHC class I-binding peptides are generated by exogenous and endogenous processing of hepatitis B virus surface antigen

Murine MHC class I-restricted cytotoxic T lymphocyte (CTL) responses can be primed by exogenous as well as endogenous hepatitis B surface antigen (HBsAg). Immunodominant CTL-defined epitopes of this viral envelope protein are the L^d -binding 12-mer S28 – 39 peptide IPQSLDSWWTSL in H-2 ^d mice, and the K^b -binding 8-mer S208 – 215 peptide ILSPFLPL in H-2^b mice. We tested if CTL recognizing these epitopes can be primed in vivo by HBsAg delivered as either an exogenous antigen (native HBsAg lipoprotein particles), or an endogenous antigen (plasmid DNA encoding HBsAg). Primed T cells were restimulated in vitro prior to the cytotoxicity assay with cells presenting the H-2 class I-binding epitopes generated by either exogenous or endogenous processing of HBsAg. The data indicate that the L^d -binding peptide S28 – 39 is generated during exogenous as well as endogenous processing of HBsAg. In contrast, the K^b -binding peptide S208 – 215 is generated during exogenous but not endogenous processing of HBsAg. Hence, some but not all MHC class I-binding, immunogenic peptides are generated during endogenous and exogenous processing of HBsAg but there also exists a repertoire of immunogenic peptides of viral origin that is only revealed after exogenous processing of viral proteins.     

Qa-1 interaction and T cell recognition of the Qa-1 determinant modifier peptide

The peptide-binding properties of the nonclassical major histocompatibility complex (MHC) class 1b molecule Qa-1 were investigated using a transfected hybrid molecule composed of the α1 and α2 domains of Qa-1^b and the α3 domain of H-2D^b. This allowed the use of a monoclonal antibody directed against H-2D^b whilst retaining the peptide-binding groove of Qa-1^b. By comparison with classical MHC class I molecules, intracellular maturation of the chimeric molecule was inefficient with weak intracellular association with β2-microglobulin. However, at the cell surface the hybrid molecules were stably associated with β2-microglobulin and were recognized by cytotoxic T lymphocyte (CTL) clones specific for the Qa-1^b -presented peptide Qdm (AMAPRTLLL). A whole-cell binding assay was used to determine which residues of Qdm were important for binding to Qa-1^b and CTL clones served to identify residues important for T cell recognition. Substitutions at position 1 and 5 did not reduce the efficiency of binding and had little effect on CTL recognition. In contrast, substitutions at position 9 resulted in loss of MHC class I binding. Mass spectrometric analysis of peptides eluted from immunopurified Qa-1^b/D^b molecules indicated that Qdm was the dominant peptide. The closely related peptide, AMVPRTLLL, which is derived from the signal sequence of H-2D^k, was also present, although it was considerably less abundant. The mass profile suggested the presence of additional peptides the majority of which consisted of eight to ten amino acid residues. Finally, the finding that a peptide derived from Klebsiella pneumoniae can bind raises the possibility that this non-classical MHC class I molecule may play a role in the presentation of peptides of microorganisms.     

Crossrecognition by CD8 T cell receptor αβ cytotoxic T lymphocytes of peptides in the self and the mycobacterial hsp60 which share intermediate sequence homology

Immunization of C57BL/6 mice with the mycobacterial heat shock protein (hsp) 60 in immunostimulating complexes caused the in vivo activation of autoreactive major histocompatibility complex class I (H-2D^b)-restricted CD8 T cell receptor (TcR) α/β cells. A CD8 TcR α/β clone with specificity for the mycobacterial hsp60 peptide_499–508 was derived from this immunization, which, in addition, recognized syngeneic macrophages which had been stressed by interferon-γ (IFN-γ) stimulation. The stress-induced, self peptide could be extracted from IFN-γ-stressed macrophages by acid elution, suggesting that the IFN-γ-induced self peptide is derived from an endogenous protein. Based on our observation that lysis of stressed target cells by this cytotoxic T lymphocyte (CTL) clone was specifically inhibited by hsp60-specific antisense oligonucleotides, we used synthetic peptides representing amino acid (aa) sequences of the murine hsp60 for target cell sensitization and identification of the relevant self peptide. Synthetic peptides representing 9-mer to 11-mer aa sequences of the murine hsp60 with asparagine in anchor position 4 or 5 as the minimal requirement for H-2D^b binding were tested in CTL assays. The overlapping murine hsp60 peptides_{162–170/171} were stimulatory at a concentration as low as 10–100 pM. Seven other peptides of the murine hsp60 required intermediate peptide concentrations of 10–100 nM for recognition by the CTL clone. Although the murine and mycobacterial hsp60 peptides recognized by this CTL clone showed only intermediate homology (3 identical and 3 similar aa), our data suggest that endogenous hsp60 itself is the source of self peptide(s) presented by IFN-γ-stressed macrophages to the cross-reactive CTL clone with promiscuous specificity. This notion is consistent with the idea of hsp as a link between infection and autoimmunity.     

Immunization with glycosylated Kb-binding peptides generates carbohydrate-specific,unrestricted cytotoxic T cells

Cytotoxic T cells (CTL) recognize target proteins as short peptides presented by major histocompatibility complex (MHC) class I restriction elements. However, there is also evidence for peptide-independent T cell receptor (TCR) recognition of target proteins and non-protein structures. How such T cell responses are generated is presently unclear. We generated carbohydrate (CHO)-specific, MHC-unrestricted CTL responses by coupling di- and trisaccharides to K^b- or D^b-binding peptides for direct immunization in mice. Four peptides and three CHO have been analyzed with the CHO either in terminal or central positions on the carrier peptide. With two of these glycopeptides, with galabiose (Galα1-4Gal; Gal₂) bound to a homocysteine (via an ethylene spacer arm) in position 4 or 6 in a vesicular stomatitis virus nucleoprotein-derived peptide (RGYVYQGL binding to K^b), CTL were generated which preferentially killed target cells treated with glycopeptide compared to those treated with the core peptide. Polyclonal CTL were also found to kill target cells expressing the same Gal₂ epitope in a glycolipid. By fractionation of CTL, preliminary data indicate that glycopeptide-specific K^b-restricted CTL and unrestricted CHO-specific CTL belong to different T cell populations with regard to TCR expression. The results demonstrate that hapten-specific unrestricted CTL responses can be generated with MHC class I-binding carrier peptides. Different models that might explain the generation of such responses are discussed.     

Identification of an HLA-DQ6-derived peptide recognized by mouse MHC class I H-2Db-restricted CD8+ T cells in HLA-DQ6 transgenic mice

Summary CD8⁺ T cells from C57BL/6(B6) mice show cytotoxicity to B cell blasts prepared from syngeneic transgenic mice expressing HLA-DQ6 molecules in a mouse MHC class I H-2D^b restricted manner. Although these results suggest that CD8⁺ T cells recognize peptides derived from DQ6 molecule bound to H-2D^b on target cells, no direct evidence so far has been obtained. To clarify this, we synthesized 23 peptides corresponding to DQ6α orβ chain and carrying the motifs of D^b-binding peptides, and examined their capacity to induce cytotoxicity in the CD8⁺ T cell line. We show here that DQA1-2, one of these peptides, induced cytotoxicity of the CD8⁺ T cells when this peptide was pulsed to H-2D^b expressing target cells, as efficiently as HLA-DQ6 expressing target cells did. Thus, our results suggest that DQA1-2 can be naturally processed from DQ6 molecules and recognized by the CD8⁺ T cells in the context of H-2D^b molecules. These results suggest that allogeneic HLA class II molecules are involved in the rejection not only as the ligand for T cell receptor of alloreactive CD4⁺ T cells but also as self-peptides bound to HLA class I molecules recognized by CD8⁺ T cells.     

Glycosylphosphatidylinositol-anchored H-2Db molecules are defective in antigen processing and presentation to cytotoxic T lymphocytes

Glycosylphosphatidylinositol-anchored (GPI)-D^b molecules are defective in mediating cytotoxic T lymphocytes (CTL) lysis of transfected lymphoma cells, compared to their transmembrane (TM) counterpart. This defect is manifest when antigenic peptide must be processed and presented through the endogenous pathway. These same transfectants can be lysed by allospecific CTL, or by antigen-specific D^b-restricted CTL when pulsed with appropriate exogenous synthetic peptide, demonstrating that they can bind and present peptide for CTL-mediated lympholysis. The defect apparently results from differences between GPI-D^b and TM-D^b assembly and transport, or from differences in membrane topology that affect CD8⁺ CTL recognition of major histocompatibility complex/peptide complex.     

A protective cytotoxic T cell response to a subdominant epitope is influenced by the stability of the MHC class I/peptide complex and the overall spectrum of viral peptides generated within infected cells

This study identifies instability of MHC class I/peptide complexes and intermolecular competition for MHC class I presentation as factors responsible for the subdominance of cyto toxic T lymphocyte (CTL) epitopes. This evidence is based on the characterization of a new CTL epitope derived from the glycoprotein (GP) of lymphocytic choriomeningitis virus (LCMV). This epitope, peptide GP117-125 (GP117) is presented to T cells by the mouse MHC class I molecule, H-2D^b. In short-term experiments induction of GP117-specific CTL by vaccination rendered C57BL/6 mice only partially resistant to infection with wild-type LCMV (LCMV-WE) but completely resistant to challenge with a previously described LCMV variant. The variant virus, LCMV-8.7B23, bears point mutations within both known LCMV-GP, H-2 D^b-restricted epitopes GP33-41 (GP33) and GP276-286 (GP276) resulting in a valine to leucine change at position 35 in peptide GP33 (V35L) and an asparagine to serine change at position 280 in peptide GP276 (N280S). Although variant peptide GP33/V35L stimulates a weak CTL response, GP276/N280S does not. Elution of peptide GP117 from both LCMV-WE- and LCMV-8.7B23-infected cells revealed that the difference in the capacity of GP117-specific CTL to protect against LCMV-WE and the virus variant LCMV-8.7B23 was due to differences in the level of GP117 presentation on the surface of both types of cells. Thus, it appears that the protective capacity of CTL specific for the subdominant epitope GP117 is influenced by the extent of presentation of other immunodominant peptide epitopes present within infected cells.     

Major histocompatibility complex class I-binding peptides are recycled to the cell surface after internalization

Cytotoxic T lymphocytes (CTL) recognize target antigens as short, processed peptides bound to major histocompatibility complex class I (MHC-I) heavy and light chains (β₂-microglobuhn; β₂ m).The heavy chain, which comprise the actual peptide binding α-1 and α-2 domains, can exist at the cell surface in different forms, either free, bound to β₂m or as a ternary complex with β₂m and peptides. MHC-I chains are also known to internalize, and recycle to the cell surface, and this has been suggested to be important in peptide presentation. Whether MHC-I-bound peptides also can recycle is not known. We have investigated this by using both peptide transporter mutant RMA-S cells and EL4 cells loaded with D^b-binding peptides, by two different approaches. First, peptides were covalently linked with galabiose (Galα4Gal) at a position which did not interfere with D^b binding or immunogenicity, and peptide recycling tested with Gal₂-specific monoclonal antibodies. By flow cytometry, a return of Gal₂ epitopes to the cell surface was found, after cellular internalization and cell surface clearance by pronase treatment. This peptide recycling could be discriminated from free fluid-phase uptake and was inhibited by methylamine, chloroquine and low temperature (18°C) but not by leupeptin. Second, specific CTL were reacted with peptide-loaded target cells after complete removal of surface D^b molecules by pronase, and after different times of incubation at 37C to allow reexpression. By this procedure, reappearance of target cell susceptibility was confirmed. The results are in agreement with a model for optimizing peptide presentation by recycling through an intracellular compartment similar to early endosomes in certain antigen-presenting cells.     

Glycosylphosphatidylinositol-linked Db does not induce an influenza-specific cytotoxic T lymphocyte response or recycle membrane-bound peptides

Major histocompatibility complex (MHC) class I molecules, as well as MHC class I-bound peptides, are known to recycle between the cell surface and an undefined, endosomal-like compartment. Little is known about the functional significance of this process. We have explored this using two different forms of the H-2D^b molecule expressed in transgenic mice, either transmembranous (D^b-tm) or with a glycophosphatidylinositol (GPI)-lipid anchor (D^b-GPI). The recycling capacity of peptides bound to D^b-tm and D^b-GPI was investigated using glycosylated D^b-binding glycopeptides, which were detected by flow cytometry. Only the tm form of D^b was found to readily internalize and recycle glycopeptides to the cell surface. When transgenic mice were immunized with influenza A virus (PR8) strain and tested for cytotoxic T lymphocyte (CTL) responses against an immunedominant nucleoprotein epitope (366–374, ASNENMETM), onyl D^b-tm mice were found to generate specific CTL responses. The results support the idea that membrane recycling of MHC class I-bound peptides on antigen-presenting cells may be important for the generation of certain CTL responses.     

Co‐expression of HLA‐B7 and HLA‐B27 alleles is associated with B7‐restricted immunodominant responses following influenza infection

It is recognized that host response following viral infection is characterized by immunodominance, but deciphering the different factors contributing to immunodominance has proved a challenge due to concurrent expression of multiple MHC class I alleles. To address this, we generated H2‐K^?/?/D^?/? double‐knockout transgenic mice expressing either one or two human MHC‐I alleles. We hypothesized that co‐expression of different allele combinations figures critically in immunodominance and examined this in influenza‐infected, double Tg MHC‐I mice. In A2/B7 or A2/B27 mice, using ELISpot assays with the A2‐restricted matrix I.58–66, the B7‐restricted NP418–426 or the B27‐restricted NP383–391 influenza A (flu) epitopes, we observed the expected recognition of both peptides for both alleles. In contrast, in flu‐infected B7/B27 mice, a significantly reduced level of B27/NP383‐restricted CTL response was detected while there was no change in the B7/NP418‐restricted CTL response. Flu‐specific tetramer studies revealed a partial deletion of Vβ8.1⁺ NP383/B27‐restricted CD8⁺ T cells, and a diminished Vβ12⁺ CD8⁺ T‐cell expansion in B7/B27 Tg mice. Using HLA Tg chimeric mice, we confirmed these findings. These findings shed light on the immune consequences of co‐dominant expression of MHC‐I alleles for host immune response to pathogens.     

Antigenicity and Immunogenicity of Antigenized Antibodies. Studies on B and T Cells

This laboratory has been testing the possibility of using the complementarity-determining region (CDR) loops of the antibody molecule to express oligopeptide epitopes in an immunologically-accessible and conformationally-suitable way. The new process consists in grafting peptides epitopes derived from antigens other than immunoglobulins into antibody CDR loops [1], This process, “antibody antigenization,” utilizes the immunoglobulin fold as a scaffold to immobilize and present oligopeptide epitopes to the immune system as the integral part of the immunoglobulin molecule. Here we describe some of the initial results with antigenized antibodies (^AgAbs).     

Generation of hen egg lysozyme-specific and major histocompatibility complex class I-restricted cytolytic T lymphocytes: recognition of cytosolic and secreted antigen expressed by transfected cells

Syngeneic cells exogenously supplied with hen egg lysozyme (HEL) or endogenously synthesizing HEL were used as antigen-presenting cells to induce major histocompatibility complex class I-restricted cytotoxic T lymphocytes (CTL). Immunization of C57BL/6 mice followed by repeated stimulation of their splenocytes in vitro with trypsinized HEL peptides led to the generation of CTL lines specific for trypsinized HEL peptides and restricted by H-2K^b. Immunization of C3H mice with a mixture of soluble native HEL and irradiated syngeneic spleen cells followed by in vitro stimulation of immune spleen cells with soluble HEL could in a few cases result in HEL-specific CTL able to kill syngeneic transfectant L cells secreting HEL (HELs) or expressing cytosol-targeted HEL (HELc). The use of HELs or HELc transfectant L cells as in vivo and in vitro immunogens was a potent way for eliciting HEL-specific polyclonal CTL. These CTL and two CD8⁺ clones were found to be H-2K^k restricted and specific for the 1-17 N-terminal HEL peptide. In addition, the anti-HEL CTL could also exhibit a significant cross-reactivity against unsensitized and HEL-untransfected targets expressing the K restriction element. This cross-reactivity was likely due to recognition of unidentified HEL mimicking peptides (self-derived ?) presented by the MHC class I (H-2K^b or H-2K^k) molecule used as the restriction element for the specific recognition of HEL. The CTL raised after immunization with HELs or HELc transfectant cells were found to recognize both the HELs and HELc transfectant cells even though HEL was not detected in the latter after a 2- or 5-min radiolabeling pulse. Recognition of both HELs and HELc transfectant cells by a given CTL clone suggests that HEL subjected to two separate processing pathways, each depending on the initial subcellular localization, can ensure the generation of similar MHC class I peptide complexes.     

T cells with dual antigen specificity in T cell receptor transgenic mice rejecting allografts

Allelic exclusion of T cell receptor (TCR) genes is incomplete: a significant percentage (10–30%) of normal human and mouse peripheral T cells express two surface TCR α chains, and a small percentage of peripheral human T cells have been reported to express two surface TCR β chains. A proportion of thymocytes in TCR transgenic mice rearrange endogenous T cell receptor genes, and peripheral T cells with two TCR α chains, transgenic and endogenous, have been reported. T cell clones with more than a single TCR heterodimer on their surface might be expected to show specificity for more than one cognate antigen: we report here a T cell clone with dual antigen specificity, isolated from an F5 TCR influenza nucleoprotein (NP 366–374/D^b)-specific transgenic female mouse which had rejected an H-2-matched male skin graft. It was selected in vitro by stimulation with male H-2^b spleen cells in the absence of the NP366–374 peptide but has specificity for both H-Y/D^b and NP366–374. This contrasted with the single NP366–374/D^b specificity shown by a control clone isolated from a Rag1–/– F5 mouse. The dual antigen specificity was associated with the rearrangement of endogenous TCR genes and cell surface expression of these as well as the TCR transgene.     

Selection of T-cell receptors with a recurrent CDR3β peptide-contact motif within the repertoire of alloreactive CD8(+) T cells

Peptide/MHC complexes recognized by alloreactive T lymphocytes (TLs) have been identified, but their contribution to in vivo allo‐rejection is not known. We previously characterized the peptide pBM1, highly represented among endogenous H‐2K^b (K^b)‐associated peptides and critically required to induce full activation of H‐2^k monoclonal CD8⁺ TLs expressing the cognate TCR‐BM3.3. Here, we asked whether a pBM1/K^b‐specific TL subset could be detected within a polyclonal TL population rejecting allogeneic cells in vivo. We show that the proportion of pBM1/K^b‐binding CD8⁺ TLs increased from <0.04% in naïve mice to 3% of activated CD44⁺ CD8⁺ TLs in H‐2^k mice rejecting K^b‐expressing cells. Among these, TCR‐Vβ2 usage was greatly enriched, and 75% of them shared a TCR‐Vβ2 CDR3β motif with the prototype TCR‐BM3.3. Fewer than 5% of K^b‐reactive CD44⁺ CD8⁺ TLs not binding pBM1/K^b displayed this CDR3β motif. We found that the recurrent CDR3β motif of pBM1/K^b‐binding TLs was assembled from distinct V/D/J recombination events, suggesting that it is recruited upon immunization for its optimal TCR‐peptide/MHC fit. Thus, a CDR3β motif generated by a process akin to “convergent recombination” accounts for a sizable fraction of the alloreactive anti‐K^b TCR repertoire.     

Inhibition of thymocyte negative selection by T cell receptor antagonist peptides

The T cell receptor (TCR) recognizes antigenic peptide presented by major histocompatibility complex (MHC) molecules. Analogs of antigenic peptides have been shown to inhibit antigen-specific T cell responses, a phenomenon described as TCR antagonism. We have examined the effect of a natural variant of an antigenic peptide and a synthetic peptide analog, on the responses of mature T cells and immature thymocytes from an αβ TCR-transgenic mouse (F5), the TCR of which recognizes a nonamer peptide from the nucleoprotein (NP) of influenza virus in the context of the H-2D^b MHC molecule. Both peptides were shown to antagonize specifically the T cell cytolytic response without being able directly to stimulate mature T cells from these transgenic mice. Furthermore, a negative selection assay in vitro was used to demonstrate for the first time that antagonistic peptides are capable of antagonizing thymocyte deletion induced by antigenic peptides. These data suggest that the final selection of a T cell could be the result of a balance between the positive and negative influences of endogenous peptide ligands.     

Cytotoxic T lymphocytes specific for murine type II collagen do not trigger arthritis in B10 mice

To investigate the role of cytotoxic T lymphocytes (CTL) in arthritis, we set out to induce CTL specific for murine type II collagen (mCII) in a mouse model. The primary protein sequence of the murine pro-α1(II) was screened for fragments bearing H-2 D^b or K^b binding motifs. Six fragments were identified and the corresponding peptides synthesized. One of these peptides, peptide P201 (amino acid 199–208 in the C-propeptide of the murine pro-α1(II)), was found to be a strong binder to H-2 D^b. When used to treat RMA-S cells at 26°C, peptide P201 induced a four-fold increase of surface expression of H-2 D^b. Administration of the P201-treated RMA-S cells into B10 mice (H-2^b) induced strong CTL responses against the immunizing collagen peptide. Despite the high frequencies of mCII-specific CTL precursors in the periphery, however, the immunized mice showed no sign of arthritis up to 16 weeks after immunization. Implications of these data for autoimmunity and arthritis are discussed.