In vivo competition between self peptides and foreign antigens in T-cell activation

Cytotoxic and helper T lymphocytes recognize foreign antigen in the form of short peptides associated with class I and class II major histocompatibility complex (MHC) molecules, respectively. A recent study of the three-dimensional structure of a class I MHC molecule revealed a cleft formed by the amino-terminal half of the protein, which could serve as the binding site for these peptides. Because an individual possesses only a limited set of different MHC molecules, each molecule of this set must have the ability to bind a large number of different peptides in order to ensure full immunocompetence. Thus, it can be anticipated that peptides with unrelated sequences compete for binding to the same MHC molecule, and, indeed, this has been shown to occur in vitro. We therefore decided to see whether such competition could also regulate the cell responses in vivo. We have found that a synthetic peptide corresponding to residues 46-62 of mouse lysozyme, although not immunogenic itself, effectively inhibits the priming for T-cell responses when injected into mice together with foreign protein or peptide antigens. The inhibition observed strictly correlates with the capacity of the competitor to bind to the particular MHC molecule presenting the foreign antigen, and its extent depends on the molar ratio between antigen and competitor.     

HLA-A2 peptides can regulate cytolysis by human allogeneic T lymphocytes

The class-I and class-II molecules encoded by the major histocompatibility complex (MHC) are homologous proteins which allow cytotoxic and helper T cells to recognize foreign antigens. Recent studies have shown that the form of the antigen recognized by T cells is generally not a native protein but rather a short peptide fragment and that class-II molecules specifically bind antigenic peptides. Furthermore, the three-dimensional structure of the human MHC class-I molecule, HLA-A2, is consistent with a peptide-binding function for MHC class-I molecules. An outstanding question concerns the molecular nature and involvement of MHC-bound peptides in antigens recognized by alloreactive T cells. In this study the effects of peptides derived from HLA-A2 on cytolysis of alloreactive cytotoxic T cells (TC) cells are presented. Peptides can inhibit lysis by binding to the T cell or sensitize to lysis by binding an HLA-A2-related class-I molecule (HLA-Aw69) on the target cell. Thus, allospecific TC cells can recognize HLA-derived peptides in the context of the MHC.     

Evidence from in vitro studies that tolerance to self antigens is MHC-restricted

Mature T cells respond to foreign antigens in the context of self major histocompatibility complex (MHC)-encoded products: T helper cells recognize antigen in the context of class II molecules, while cytotoxic T cells (CTL) recognize antigen plus class I molecules. Recent evidence suggests that the MHC-restricted T cell is unable to recognize either the foreign antigen or the self-MHC product alone, but only a complex of the two. Unresponsiveness to self antigens--self tolerance--implies the deletion or suppression of clones of T cells having reactivity to self antigens. Here we demonstrate the presence in normal mice of T cells which recognize self antigens together with allogeneic MHC products. This finding suggests the MHC restriction of T-cell recognition during the entire process of T-cell ontogeny, that is, MHC restriction of self tolerance.     

Processing of a minimal antigenic peptide alters its interaction with MHC molecules

Before their recognition by T lymphocytes, protein antigens generally require processing by antigen-presenting cells. In a poorly understood series of events, the protein antigen is internalized, transformed and re-expressed on the surface of the antigen-presenting cell in association with gene products of the major histocompatibility complex (MHC). Small peptides derived from the native protein can be recognized in the absence of antigen processing, suggesting that processing involves proteolytic degradation. These peptides are thought to mimic the naturally produced peptide fragment. We describe here a synthetic peptide antigen of this type which does not require processing but which is nevertheless further processed by splenic antigen-presenting cells. Interestingly, this processing event specifically alters the interaction of the peptide with the class II MHC (Ia) molecule, markedly affecting both its potency as an antigen in vitro and its immunogenicity in vivo (IR gene control).     

Processing pathways for presentation of cytosolic antigen to MHC class II-restricted T cells.

Antigens presented to CD4+ T cells derive primarily from exogenous proteins that are processed into peptides capable of binding to class II major histocompatibility complex (MHC) molecules in an endocytic compartment. In contrast, antigens presented to CD8+ T cells derive mostly from proteins processed in the cytosol, and peptide loading onto class I MHC molecules in an early exocytic compartment is dependent on a transporter for antigen presentation encoded in the class II MHC region. Endogenous cytosolic antigen can also be presented by class II molecules. Here we show that, unlike class I-restricted recognition of antigen, HLA-DR1-restricted recognition of cytosolic antigen occurs in mutant cells without a transporter for antigen presentation. In contrast, DR1-restricted recognition of a short cytosolic peptide is dependent on such a transporter. Thus helper T-cell epitopes can be generated from cytosolic antigens by several mechanisms, one of which is distinct from the classical class I pathway.     

T cells can distinguish between allogeneic major histocompatibility complex products on different cell types

In the response of T cells to foreign antigens, the ligand for the T cell alpha/beta receptor is presented on a cell surface as a fragment of antigen complexed to one of the membrane molecules encoded in the major histocompatibility complex (MHC). The receptor apparently interacts via its variable elements (V beta, D beta, J beta, V alpha and J alpha) with residues within both the antigen and MHC portion of the ligand. The frequency of T cells responding to a conventional antigen plus self MHC is usually quite low, presumably reflecting the relative rarity of receptors with the particular combination of variable elements to match the antigen/MHC ligand. T cells also respond to allogeneic forms of MHC molecules in the absence of added antigen. In this case the frequency of responding T cells is very high. One hypothesis to explain this observation is that, in the absence of foreign antigen, MHC molecules are complexed to a large array of peptides derived from self-proteins. In this case the combination of the polymorphic MHC amino acid residues and many different self peptides presents so many possible ligands that the likelihood of recognition by a given T cell receptor is quite high. The recent crystallography experiments which revealed a dramatic binding cleft on the face of a human MHC molecule have given impetus to this view, but as yet there is no direct supporting evidence. We have recently described a close association between murine T cell receptors utilizing the V beta 17a element and reactivity to various allogeneic forms of the murine MHC molecule, I-E (ref. 8). In this paper, we show that this I-E ligand is detected on B cells, but not on I-E+ macrophages or fibroblasts expressing a transfected I-E gene. These results strongly suggest a B cell specific product combines with I-E to form the allogeneic ligand for V beta 17a+ receptors and thus support the concept of alloreactivity described above.     

Induction of regulatory T-lymphocyte responses by liposomes carrying major histocompatibility complex molecules and foreign antigen

Regulatory (helper and suppressor) T lymphocytes become activated only when foreign antigen is presented to them on the surface of antigen-presenting cells (APC), together with class II major histocompatibility complex (MHC) molecules (heterodimers of polypeptides of 28,000 and 35,000 relative molecular mass). Once activated by a certain foreign antigen--MHC combination, T cells react to the same antigen only in combination with the same MHC molecule, a phenomenon termed MHC restriction of T-cell recognition (reviewed in refs 1,5). Studies of the mechanisms involved in antigen presentation and MHC restriction have been hampered mainly by the virtual impossibility of inducing T-cell responses in the absence of APC. We describe here the production of synthetic lipid vesicles with inserted class II MHC molecules and a protein antigen coupled covalently to the lipid. These liposomes are shown to stimulate cloned helper T cells and T-cell hybridomas in an antigen-specific, MHC-restricted manner in the absence of APC. Thus, the recognition of foreign antigen together with class II MHC molecules seems to be the only signal required for the activation of antigen-primed regulatory T cells. Furthermore, 'processing' of antigen by APC is not essential for its recognition by T cells.     

Defective processing and presentation of exogenous antigens in mutants with normal HLA class II genes

Presentation of an exogenous protein antigen to helper (CD4+)T-lymphocytes by antigen presenting cells (APC) generally requires that the APCs degrade the native protein antigen into an immunogenic peptide, a process termed 'antigen processing', and that this peptide bind to a major histocompatibility complex (MHC) class II molecule. The complex of peptide and MHC molecule on the APC surface provides the stimulatory ligand for the alpha beta T cell receptor. The intracellular pathways and molecular mechanisms involved in the generation of the peptide-MHC complex are not well understood. Here, we describe several mutant APCs which are altered in their ability to present native exogenous protein antigens but effectively present immunogenic peptides derived from these proteins. The lesions in these mutants are not in the class II structural genes, but they affect the conformation of mature class II dimers.     

Peptide-dependent recognition of H-2Kb by alloreactive cytotoxic T lymphocytes

Antigen-specific T lymphocytes appear to recognize foreign antigens in the form of peptide fragments presented within the antigen-binding groove of class I or class II molecules encoded by the major histocompatibility complex (MHC). Alloreactive T cells also show specificity for MHC molecules, and various reports suggest that residues of the MHC molecules constitute at least part of the ligand to which alloreactive T-cell receptors bind. The X-ray crystal structure of the human MHC class I molecule, HLA-A2, has provided evidence to strengthen the argument that MHC-bound self-peptide might also contribute to such recognition. We now provide direct evidence for this, showing that at least some alloreactive cytotoxic T lymphocyte clones recognize peptide fragments derived from cytoplasmic proteins. We reasoned that if self-peptides were involved in allorecognition, then the sequence of some of these peptides could vary between species, resulting in species-restricted distribution of the relevant ligand(s). Several alloreactive cytotoxic T lymphocyte clones specific for H-2Kb, expressed by the murine cell line EL4, did not lyse a human-cell transfectant expressing the H-2Kb molecule (Jurkat-Kb cells). However, these clones were able to lyse Jurkat-Kb cells sensitized by preincubation with an EL4 cytoplasmic extract cleaved by cyanogen bromide. The sensitizing activity from this extract was destroyed by protease and appeared to be due to a peptide consisting of 10 to 15 amino acids.     

Specificity of peptide presentation by a set of hybrid mouse class I MHC molecules

The class I molecules of the major histocompatibility complex (H-2 in mouse, HLA in man) are membrane proteins composed of a polymorphic heavy chain associated with beta-2-microglobulin. Recent studies suggest that class I molecules present peptides derived from processed antigens to the receptor of cytolytic T cells. In particular, in the H-2d haplotype, synthetic HLA peptides can be recognized on Kd-bearing target cells by Kd-restricted cytolytic T cells specific for HLA. Here we analyse the specificity of presentation of two HLA peptides by a set of chimaeric Kd/Dd molecules to four different cytolytic T-cell clones. We identify two distinct regions within the second external (alpha 2) domain of Kd that contribute to its specificity as a restriction element. Our results indicate that the binding of an immunogenic peptide by a class I molecule is not always sufficient for its recognition by the T-cell antigen receptor. This suggests that the major histocompatibility complex restriction element either interacts with the T-cell antigen receptor or induces the recognized conformation of the peptide.     

T-cell-mediated association of peptide antigen and major histocompatibility complex protein detected by energy transfer in an evanescent wave-field

Helper T cells recognize foreign antigen displayed on antigenpresenting cells which also express self-molecules of the major histocompatibility complex (MHC). A single T-cell receptor mediates recognition of both MHC and foreign antigen. A proposed ternary complex between T-cell receptor, foreign antigen and MHC antigen has not yet been demonstrated (see ref. 1 for review). Here, we show that a fluorescein-labelled synthetic peptide, together with Texas red-labelled class II MHC antigen, I-Ad, stimulates the production of interleukin-2 by a peptide-specific I-Ad-restricted T-cell hybridoma when reconstituted in a lipid membrane on a glass substrate. Under the same conditions, resonance-energy transfer from donor peptide to acceptor I-A can be stimulated in an evanescent wave-field only in the presence of the specific T-hybrid. Our results show that the T cell stabilizes an association between peptide antigen and class II MHC protein to within a distance of about 40 A.     

HLA-restricted recognition of viral antigens in HLA transgenic mice

Cytotoxic T lymphocytes (CTL) recognize antigen in the context of the class-I products of the major histocompatibility complex (MHC). The extensive polymorphism of class-I molecules is thought to be linked to their capacity to present a large variety of foreign antigens. Whether a single T-cell receptor (TCR) recognizes two separate epitopes (the foreign antigen and an epitope on MHC molecules), or a single epitope resulting from the combination of a foreign antigen and an MHC molecule, has not yet been resolved. In view of the differences between species in primary structure of histocompatibility antigens, it might be predicted that the TCR repertoire would evolve in concert with the diversity of MHC antigens. The mouse and human TCR repertoire would be optimally adapted to engage in productive interactions only with mouse (H-2) and human (HLA) MHC antigens respectively, especially if the more conserved features of histocompatibility antigens, in addition to foreign antigen, were seen by the TCR. Alternatively, only the most variable segments of MHC antigens might be engaged in antigen presentation and thus in interaction with the TCR. In that case, interaction between MHC plus antigen and the TCR might not necessarily be limited by species-specific features. By analysis of the T-cell response against virus-infected cells in HLA-B27/human beta 2-microglobulin double transgenic mice, we report here that the mouse T-cell repertoire is perfectly capable of using the human HLA-B27 antigen as a restriction element.     

The foreign antigen binding site and T cell recognition regions of class I histocompatibility antigens

Most of the polymorphic amino acids of the class I histocompatibility antigen, HLA-A2, are clustered on top of the molecule in a large groove identified as the recognition site for processed foreign antigens. Many residues critical for T-cell recognition of HLA are located in this site, in positions allowing them to serve as ligands to processed antigens. These findings have implications for how the products of the major histocompatibility complex (MHC) recognize foreign antigens.     

Quantitation of antigen-presenting cell MHC class II/peptide complexes necessary for T-cell stimulation

The number of specific complexes formed between peptide and the class II major histocompatibility complex (MHC) molecules expressed by an antigen-presenting cell (APC) after exposure to protein antigens is unknown, as is the number that activates T cells. Presentation of foreign peptides by APC takes place when many class II molecules may be occupied by autologous peptides. We have now estimated the number of specific peptide/class II complexes per APC by quantitative immunoprecipitation of I-Ak after pulsing the APC with stimulatory levels of a radioactive immunogenic peptide derived from hen egg-white lysozyme protein. T cells were activated by APC that expressed as few as 210-340 specific peptide/class II complexes (0.1% of the I-Ak molecules). These figures were confirmed using anti-CD3 antibody bound to latex beads as an alternative activating ligand. This low number explains the simultaneous presentation of multiple foreign antigens, even in the face of peptide competition.     

Killing of antigen-reactive B cells by class II-restricted, soluble antigen-specific CD8+ cytolytic T lymphocytes

Cytolytic T lymphocytes (CTLs) are generally thought to recognize cellular antigens presented by class I MHC molecules. A number of studies, however, have revealed responses of considerable magnitude involving both CD8+ and CD4+ CTLs with class II restriction, suggesting that class II-restricted CTLs recognizing exogeneous protein antigens may exist. As class II antigens are normally expressed on limited types of cells such as B cells and macrophages, such CTLs might be expected to exert a suppressive effect on antibody responses. Here we report that stimulation of mouse lymphocytes with a soluble antigen induced CD8+ and CD4+ CTLs specific for the antigen with class II restriction. The specific lysis was far more efficient when target B cells specifically recognized the antigen than when they did not, indicating that the primary targets for these CTLs are probably B cells expressing immunoglobulin receptors reactive for the same antigen molecule. These results suggest that the natural occurrence of such CTLs during immune responses may explain antigen-specific suppression on antibody responses by T cells.     

Truncation variants of peptides isolated from MHC class II molecules suggest sequence motifs.

T cells recognize foreign protein antigens in the form of peptide fragments bound tightly to the outer aspect of molecules encoded by the major histocompatibility complex (MHC). Most of the amino-acid differences that distinguish MHC allelic variants line the peptide-binding cleft, and different allelic forms of MHC molecules bind distinct peptides. It has been demonstrated that peptide-binding to MHC class I involves anchor residues in certain positions and that antigenic peptides associated with MHC class I exhibit allele-specific structural motifs. We have previously reported an analysis of MHC class II-associated peptide sequences. Here we extend this analysis and show that certain amino-acid residues occur at particular positions in the sequence of peptides binding to a given MHC class II molecule. These sequence motifs require the amino terminus to be shifted one or two positions to obtain alignment; such shifts occur naturally for a single peptide sequence without qualitatively altering CD4 T-cell recognition.     

Brefeldin A implicates egress from endoplasmic reticulum in class I restricted antigen presentation

Most antigens must be processed intracellularly before they can be presented, in association with major histocompatibility complex (MHC) molecules at the cell surface, for recognition by the antigen-specific receptor of T cells. This processing appears to involve cleavage of protein antigens to smaller peptides. Only certain fragments of any protein can serve as T-cell epitopes and this is, at least in part, determined by the requirement that peptides be able to bind the MHC molecules. Class I restricted antigens are derived from proteins, such as viral antigens, that are synthesized within the presenting cell. Many of these antigens are cytosolic proteins and recent evidence suggests that it is in the cytosol that these proteins are processed to produce either the antigenic peptides or processed intermediates. How and where these processed cytosolic antigens cross the membrane of the vacuolar system and bind to the extracellular domain of the class I molecule is not known but one obvious site for this process is the endoplasmic reticulum (ER), because this organelle is specialized to translocate proteins across the membrane from the cytosol into the secretory system. Based on this model, we reasoned that if we could pharmacologically block the movement of proteins out of the ER, endogenous antigen presentation would cease. An agent which causes such an effect is available--the fungal antibiotic Brefeldin A (BFA). Consistent with the above hypothesis, we report that BFA completely abolishes the ability of a cell to present endogenously synthesized antigens to class I restricted cytotoxic T cells.     

Physical association between MHC class I molecules and immunogenic peptides

Antigenic peptides are presented to T lymphocytes by major histocompatibility complex (MHC) molecules. The binding of peptides to MHC class II molecules has been demonstrated directly, and is found to correlate with the ability of specific class II alleles to restrict the T-cell response to specific peptides. By comparison, a direct demonstration of a physical association between antigenic peptides and MHC class I molecules has proved difficult. A recent report shows that it is possible, however, and the three-dimensional structure of a class I MHC molecule illustrates the site where such binding must occur. Here we describe a simple assay which measures the binding of radiolabelled MHC class I molecules to peptides bound to a solid phase support. We find that class I molecules bind specifically to peptides known to be antigenic for class I-restricted cytotoxic T lymphocytes. Peptides which are recognized by cytotoxic T lymphocytes bind not only to the restricting MHC class I molecule but also to other class I molecules. Our results suggest that quantitative differences in the peptide/MHC class I interaction may influence the-pattern of MHC restriction observed in vivo.     

A pentapeptide as minimal antigenic determinant for MHC class I-restricted T lymphocytes

Peptides that are antigenic for T lymphocytes are ligands for two receptors, the class I or II glycoproteins that are encoded by genes in the major histocompatibility complex, and the idiotypic alpha/beta chain T-cell antigen receptor. That a peptide must bind to an MHC molecule to interact with a T-cell antigen receptor is the molecular basis of the MHC restriction of antigen-recognition by T lymphocytes. In such a trimolecular interaction the amino-acid sequence of the peptide must specify the contact with both receptors: agretope residues bind to the MHC receptor and epitope residues bind to the T-cell antigen receptor. From a compilation of known antigenic peptides, two algorithms have been proposed to predict antigenic sites in proteins. One algorithm uses linear motifs in the sequence, whereas the other considers peptide conformation and predicts antigenicity for amphipathic alpha-helices. We report here that a systematic delimitation of an antigenic site precisely identifies a predicted pentapeptide motif as the minimal antigenic determinant presented by a class I MHC molecule and recognized by a cytolytic T lymphocyte clone.     

Sequence analysis of peptides bound to MHC class II molecules.

CD4 T cells recognize peptide fragments of foreign proteins bound to self class II molecules of the major histocompatibility complex (MHC). Naturally processed peptide fragments bound to MHC class II molecules are peptides of 13-17 amino acids which appear to be precessively truncated from the carboxy terminus, perhaps after binding to the MHC class II molecule. The finding of predominant self peptides has interesting implications for antigen processing and self-non-self discrimination.