Identification of an HLA-DQ2 peptide binding motif and HLA-DPw3-bound self-peptide by pool sequencing

Molecules of the major histocompatibility complex (MHC) present antigenic peptides to T cells. Sequencing peptide pools eluted from MHC class I molecules has established allele-specific peptide binding motifs. We applied pool sequencing to analyze human MHC class II-bound peptides and found that HLA-DQ2-eluted peptides predominantly contained lysine, isoleucine, and phenylalanine at relative position i, i + 3 and i + 8, respectively. These residues putatively represent anchor residues for MHC binding. Analysis of a heterogeneous HLA-DPw3/DPw4-eluted peptide pool yielded a sequence matching an epitope from the endogeneous enzyme glyceraldehyde-3-phosphate dehydrogenase. This self-peptide and a partially identical, known allo-epitope bound specifically to DPw3 and DR13 molecules, suggesting the sharing of a binding motif. In particular, the presence of an arginine at relative position 4 appeared important for binding to these HLA class II specificities. Thus, pool sequencing is applicable for the analysis of MHC class II-eluted peptides.     

Steric recognition of T-cell receptor contact residues is required to map mutant epitopes by immunoinformatical programmes

MHC class I-restricted CD8 T-lymphocyte epitopes comprise anchor motifs, T-cell receptor (TCR) contact residues and the peptide backbone. Serial variant epitopes with substitution of amino acids at either anchor motifs or TCR contact residues have been synthesized for specific interferon-γ responses to clarify the TCR recognition mechanism as well as to assess the epitope prediction capacity of immunoinformatical programmes. CD8 T lymphocytes recognise the steric configuration of functional groups at the TCR contact side chain with a parallel observation that peptide backbones of various epitopes adapt to the conserved conformation upon binding to the same MHC class I molecule. Variant epitopes with amino acid substitutions at the TCR contact site are not recognised by specific CD8 T lymphocytes without compromising their binding capacity to MHC class I molecules, which demonstrates two discrete antigen presentation events for the binding of peptides to MHC class I molecules and for TCR recognition. The predicted outcome of immunoinformatical programmes is not consistent with the results of epitope identification by laboratory experiments in the absence of information on the interaction with TCR contact residues. Immunoinformatical programmes based on the binding affinity to MHC class I molecules are not sufficient for the accurate prediction of CD8 T-lymphocyte epitopes. The predictive capacity is further improved to distinguish mutant epitopes from the non-mutated epitopes if the peptide-TCR interface is integrated into the computing simulation programme.     

Noncanonical peptides in complex with MHC class I

The major histocompatibility complex (MHC) presents canonical medium-high-affinity peptides on the surface of antigen-presenting cells to T-cells. Recognition of peptide MHC by T-cells initiates a cascade of signals which maintains a T-cell-dependent immune response. In the design of vaccines, there is need for an understanding of how peptides bind to MHC class I molecules. Herein, the presentation of canonical anchor motif peptides to MHC class I, noncanonical anchor motif peptides, low-affinity peptides, peptides making use of new pockets, short peptides, long peptides, glycopeptides, retro-inverso peptides and prediction programs for peptides binding to MHC class I molecules is discussed. All this information will aid in the design of new and improved peptide-based vaccines.     

The assembly of functional beta(2)-microglobulin-free MHC class I molecules that interact with peptides and CD8(+) T lymphocytes

Functional MHC class I molecules are expressed on the cell surface in the absence of beta(2)-microglobulin (beta(2)m) light chain that can interact with CD8(+) T lymphocytes. Whether their assembly requires peptide binding and whether their recognition by CD8(+) T lymphocytes involves the presentation of peptide epitopes remains unknown. We show that beta(2)m-free H-2D(b) assembles with short peptides that are approximately 9 amino acid residues in length, akin to ligands associated with completely assembled beta(2)m(+) H-2D(b). Remarkably, a subset of the peptides associated with the beta(2)m-free H-2D(b) has an altered anchor motif. However, they also include peptides that contain a beta(2)m(+)H-2D(b) binding anchor motif. Further, the H-2K(b)- and H-2D(b)-restricted peptide epitopes derived from SV-40 T antigen also assemble with H-2(b) class I in beta(2)m-deficient cells and are recognized by epitope-specific CD8(+) T lymphocytes. Taken together our data reveal that functional MHC class I molecules assemble in the absence of beta(2)m with peptides and form CD8(+) T lymphocyte epitopes.     

The human major histocompatibility complex class Ib molecule HLA-E binds signal sequence-derived peptides with primary anchor residues at positions 2 and 9

Human histocompatibility leukocyte antigen E (HLA-E) and mouse major histocompatibility complex (MHC) class Ib antigen, Qa-1, share the same substitutions at two normally conserved positions 143 and 147, which are likely to affect binding of the C terminus of peptides. Qa-1 is able to bind a peptide derived from the leader sequence of H-2 D and H-2 L molecules. We developed a peptide binding assay in vitro to compare the binding specificity of HLA-E with the mouse MHC class Ib molecule Qa-1. We demonstrate that HLA-E binds, although poorly, the peptide which binds to Qa-1 and that it also binds nonamer signal sequence-derived peptides from human MHC class I molecules. Using alanine and glycine substitutions, we could define primary anchor residues at positions 2 and 9 and secondary anchor residues at position 7 and possibly 3.     

An assay for peptide binding to HLA-Cw*0102

The assembly assay for peptide binding to class I major histocompatibility complex (MHC) molecules is based on the ability of peptides to stabilize MHC class I molecules synthesized by transporter associated with antigen processing (TAP)-deficient cell. The TAP-deficient cell line T2 has previously been used in the assembly assay to analyze peptide binding to HLA-A*0201 and -B*5101. In this study, we have extended this technique to assay for peptides binding to endogenous HLA-Cw*0102 molecules. We have analyzed the peptide binding of 20 peptides with primary anchor motifs for HLA-Cw*0102. One-third of the peptides analyzed bound with high affinity, half of the peptides examined did not bind, whereas the remaining peptides displayed intermediate binding activity. Interest in HLA-C molecules has increased significantly in recent years, since it has been shown that HLA-C molecules both can present peptides to cytotoxic T lymphocytes (CTL) and in addition are able to inhibit natural killer (NK)-mediated lysis.     

Recognition of core and flanking amino acids of MHC class II-bound peptides by the T cell receptor

CD4 T cells recognize peptides bound to major histocompatibility complex (MHC) class II molecules. Most MHC class II molecules have four binding pockets occupied by amino acids 1, 4, 6, and 9 of the minimal peptide epitope, while the residues at positions 2, 3, 5, 7, and 8 are available to interact with the T cell receptor (TCR). In addition MHC class II bound peptides have flanking residues situated outside of this peptide core. Here we demonstrate that the flanking residues of the conalbumin peptide bound to I-A(k) have no effect on recognition by the D10 TCR. To study the role of peptide flanks for recognition by a second TCR, we determined the MHC and TCR contacting amino acids of the I-A(b) bound Ealpha peptide. The Ealpha peptide is shown to bind I-A(b) using four alanines as anchor residues. TCR recognition of Ealpha peptides with altered flanking residues again suggested that, in general, no specific interactions occurred with the peptide flanks. However, using an HLA-DM-mediated technique to measure peptide binding to MHC class II molecules, we found that the peptide flanking residues contribute substantially to MHC binding.     

Preferred size of peptides that bind to H-2 Kb is sequence dependent.

The identification of naturally processed viral peptides reveals that major histocompatibility complex (MHC) class I epitopes are composed of nine or eight amino acid residues. Peptides eluted from H-2 Kb MHC class I molecules have been suggested, as a class, to be eight amino acid residues long. To assay for peptide-class I interactions, a stabilization assay described for surface labeled "empty" class I molecules was employed, but on biosynthetically labeled class I molecules. The Sendai virus nucleoprotein-derived octapeptide APGNYPAL does not bind and stabilize Kb molecules, whereas other octameric Kb-restricted peptides and the nonameric peptide FAPGNYPAL interact stably. We attribute the failure of Sendai octamer binding to the presence of proline in position two: replacement of proline renders the resulting octamers as efficient as FAPGNYPAL for binding and stabilization of H-2 Kb. Substitution of glycine in position three of APGNYPAL slightly improves its Kb stabilizing capacity. Iodination of the tyrosine residue significantly alters the binding properties of the nonamer peptide. We conclude that the length of epitopes as selected by the class I Kb molecule is influenced by their sequence and suggest that proper positioning of the NH2 terminus of peptides is essential for class I stabilizing properties. The ability to stabilize newly synthesized "empty" class I molecules with peptide argues against an involvement of beta 2 microglobulin exchange in the experiments described here.     

A pattern search method for putative anchor residues in T cell epitopes

The binding affinity between an antigenic peptide and its particular major histocompatibility complex (MHC) molecule seems to be largely determined by only a few residues. These residues have been called “anchors” because of their property of fitting into “pockets” inside the groove of the MHC molecule. To predict natural antigenic epitopes within a longer sequence, it therefore appears to be important to know the motif or pattern describing the anchors, i.e. the anchors amino acid residue preference and the distance between anchor residues. A large set of MHC class I-restricted peptides has been described. Peptide sequences vary in length and lack an obvious common sequence motif. For a list of peptides belonging to one type of MHC class I molecule, we describe a method to find the most prominent sequence motif with at least two anchor residues. Briefly, antigenic sequences are aligned, and two anchor positions are searched for, where all anchor residues share a high similarity. The alignments are scored according to the similarity of their anchor residues. We show that the motifs predicted for the MHC alleles A2.1, B27, K^b, K^d, D^b are in substantial agreement with experimental data. We derive binding motifs for the MHC class I alleles HLA-A1, All, B8, B14, H-2L^d and for the MHC class II alleles I-A^b and I-A^s. In some cases, higher scores were obtained by allowing a slight variation in the number of residues between anchors. Therefore, we support the view that the length of epitopes belonging to a particular class I MHC is not uniform. This method can be used to predict the natural short epitope inside longer antigenic peptides and to predict the epitopes anchor residues. Anchor motifs can be used to search for antigenic regions in sequences of infectious viruses, bacteria and parasites.     

Amino acid substitutions at position 97 in HLA-A2 segregate cytolysis from cytokine release in MART-1/Melan-A peptide AAGIGILTV-specific cytotoxic T lymphocytes

CD8⁺ T lymphocytes recognize antigenic peptides presented by major histocompatibility complex (MHC) class I molecules. Individual peptide termini appear to be fixed at the C- and N-terminal ends. In contrast, central peptide side chains residues may point in different directions and exhibit limited flexibility, dependent on the MHC class I structural variation. For instance, position 97 in HLA-A201 has been shown to shift individual peptide species into different coordinations, one oriented towards the peptide N terminus, or more towards the C-terminal end. The conformational shape of such non-anchor peptide residues may affect the affinity of MHC/peptide / TCR interaction, resulting in quantitative, or qualitative different T cell effector functions. To characterize the impact of different amino acid residues occupying position 97 in HLA-A2 on peptide binding and presentation to CTL, we generated a panel of mutated HLA-A2 molecules containing either M, K, T, V, G, Q, W, P or H at position 97. The HLA-A0201 presented melanoma-associated MART-1/Melan-A derived peptide AAGIGILTV was employed to assess the impact of such position-97 mutations on HLA-A2 in peptide binding measured in an HLA-A2 reconstitution assay and presentation to AAGIGILTV-specific polyclonal or clonal T lymphocytes as measured by cytotoxicity, or interferon (IFN)-γ and granulocyte/macrophage colony-stimulating factor (GM-CSF) secretion. The high-affinity AAGIGILTV peptide bound to all position-97 mutants, albeit with differential efficiencies, and elicited specific release of IFN-γ and GM-CSF by CTL. CTL responses were triggered only by the HLA-A2 wild type, by HLA-A2-H97 (histidine position 97 mutant), and HLA-A2-W97. The HLA-A2-M97 presenting molecule elicited enhanced cytokine release and CTL effector functions by polyclonal and by clonal effector T cells. These results indicate that MHC class I-bound peptides can trigger specific cytokine release by effector T cells independently of their ability to induce cytolysis. We conclude that relatively minor changes in the MHC class I peptide binding groove, including substitutions at position 97, can affect recognition by antigen-specific T cells. Mutant MHC class I molecules, such as those described here, may act as partial peptide antagonists and could be usefol for inducing T lymphocytes with qualitatively different effector functions.     

Role of non-anchor residues of D-restricted peptides in class I binding and TCR triggering

To understand better, the role of non-anchor residues of class I restricted T cell epitopes in class I binding and TCR stimulation, a panel of peptides was synthesized in which each of the nonanchor positions of the D^b-restricted influenza peptide, ASNENMETM, was changed to each of the 20 natural amino acids (AAs). The relative affinity of all the peptides for D^b was determined and their ability to stimulate anti-ASNENMETM cytotoxic T cell hybridomas was also assessed. The results illustrated that for D^b binding, the AAs with the most solvent exposure had the smallest effect on binding. Changes at other positions affected binding to different degrees. Results for the recognition by the T cell hybridomas indicated that a peptide-MHC complex represents a multitude of epitopes, as each hybridoma recognized a different subset of peptides. Most changes in the highly solvent-exposed exposed residues negatively affected recognition by all hybridomas while changes in other positions affected each hybridoma differently, independent of the direction of the side chain of the AA at that position. Furthermore, the use of saturating concentrations of low and high binding peptides showed that, as long as the class I-peptide complex is formed, the T-cell receptor does not differentiate between high and low binding peptides. This indicates that, although the stability of the class I-peptide complex is highly dependent on peptide affinity, the class I MHC conformation induced by low affinity peptides does not necessarily differ significantly from that induced by high affinity peptides. The results of peptide-class I recognition by one ASNENMETM-specific hybridoma was used to construct a peptide that differed from ASNENMETM at four of the nine residues, yet stimulated the hybridoma to a level comparable to ASNENMETM. In addition, peptides bearing the canonical D^b-binding motif but unable to bind to the class I molecule with high affinity could be made to bind D^b, by changing unfavorable AAs to favorable ones at appropriate positions. The extended motif determined was used to identify more accurately the peptides derived from Coxsakie b3 virus that would bind D^b. It was also shown that some of the canonical characteristics of the peptide motif could be obviated and still obtain high affinity binding, provided optimal AAs were present at secondary anchor positions.     

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.     

Role of anchor residues in peptide binding to three HLA-A26 molecules

To investigate the role of anchor residues in HLA-A26 binding peptides, we analyzed the binding of various peptides to three HLA-A26 molecules using the HLA class I stabilization assay. Of twenty nonamer peptides carrying anchors at P2 and P9, 3, 6 and 3 peptides bound to HLA-A*2601, HLA-A*2602 and HLA-A*2603, respectively The peptide EV-IPMFSAL bound most strongly to these three HLA-A26 molecules. Analysis using mutants of this peptide at P1, P2 or P9 showed that acidic amino acids at P1 and five hydrophobic residues (Val, Thr, Ile, Leu and Phe) at P2 are anchor residues for the three HLA-A26 molecules while with exception of positively charged amino acids, a broad range of amino acids function as P9 anchor residues. These anchors were further evaluated using 38 nonamer peptides carrying anchor residues at P1, P2 and P9. Nineteen of these peptides bound to at least one HLA-A26 molecule. The frequency of HLA-A26 binding peptides was higher for peptides carrying all three anchor residues than for peptides carrying only P2 and P9 anchor residues. These results indicate that in addition to P2 and P9 anchors, the P1 anchor plays an important role in peptide binding to three HLA-A26 molecules.     

Structural requirements for the peptide-induced conformational change of free major histocompatibility complex class I heavy chains.

In an attempt to define the structural features of peptides which are important for inducing the folding of free class I heavy chains in the absence of beta 2-microglobulin, and to determine whether they are the same as those required to form stable major histocompatibility complex (MHC): peptide adducts, we have used a panel of peptides related to the Db-binding nonamer ASNENMDAM (influenza nucleoprotein residues 366-374) with altered primary structures, and a number of other peptides which have the Db-binding "motif". In this way, we have shown that in addition to the "anchor" residues which define this motif, the alpha amino and carboxyl groups at the N and C termini also play a major role in both inducing the conformational change in free heavy chain (HC) and formation of a stable Db:peptide complex. We also show that the importance of the key residues is affected by the primary sequence "context" in which they appear. In addition, we have extended our original finding that naturally processed epitopes induce a conformational change in free HC to the H2Kb HC, and show that the effect does not require the presence of the class I alpha 3 domain.     

Interaction of In Vitro- and In Vivo-Generated Cytotoxic T Cells with SV40 T Antigen: Analysis with Synthetic Peptides

Virus-specific cytotoxic T cells recognize antigens in the form of peptides (8 or 9 amino acids long) bound to MHC class-I molecules. Exposure of unprimed murine splenocytes to synthetic peptides of viral antigens elicits primary CTL in vitro. The fme specificity of such CTL as well as the correlation between binding affinity of peptides to class-I molecules and CTL induction was analysed using synthetic peptides corresponding to overlapping and distinct amino-acid residues in SV40 T antigen (Tag) D_b-restricted T-cell epitopes I, II-III, and V. The peptides induced cross-reactive CD8₊ primary CTL in spienocytes of naive C57 BL/6 mice. This reactivity was seen regardless of the peptides allelic anchor motifs or their abilities to stabilize empty class-I molecules. However, none of the primary CTL and CTL lines lysed Tag-expressing cells. In contrast, CTL generated in vivo by immunizing mice with Tag-expressing cells recognized endogenously processed Tag as well as synthetic peptides. The peptides recognized by these CTL depended on the intracellular concentration of Tag antigen in the immunizing cells. The reactivity of these CTL was peptide specific as shown by a functional peptide competition assay. Moreover, three peptides bound to and were recognized in the context of both K^b and D^b molecules. These results have revealed a flexible disposition of MHC class-I molecules with regard to peptide binding and also reflected lack of correlation between binding affinity to class-1 molecules and the capacity of peptides to induce primary CTL or to serve as potential targets. The significance of these findings in relation to identifying major T-cell epitopes using allele specific peptide motif and in vitro maintained CTL clones is discussed.     

Machine learning reveals a non‐canonical mode of peptide binding to MHC class II molecules

MHC class II molecules play a fundamental role in the cellular immune system: they load short peptide fragments derived from extracellular proteins and present them on the cell surface. It is currently thought that the peptide binds lying more or less flat in the MHC groove, with a fixed distance of nine amino acids between the first and last residue in contact with the MHCII. While confirming that the great majority of peptides bind to the MHC using this canonical mode, we report evidence for an alternative, less common mode of interaction. A fraction of observed ligands were shown to have an unconventional spacing of the anchor residues that directly interact with the MHC, which could only be accommodated to the canonical MHC motif either by imposing a more stretched out peptide backbone (an 8mer core) or by the peptide bulging out of the MHC groove (a 10mer core). We estimated that on average 2% of peptides bind with a core deletion, and 0·45% with a core insertion, but the frequency of such non‐canonical cores was as high as 10% for certain MHCII molecules. A mutational analysis and experimental validation of a number of these anomalous ligands demonstrated that they could only fit to their MHC binding motif with a non‐canonical binding core of length different from nine. This previously undescribed mode of peptide binding to MHCII molecules gives a more complete picture of peptide presentation by MHCII and allows us to model more accurately this event.     

MHC Class II epitope predictive algorithms

Major histocompatibility complex class II (MHC‐II) molecules sample peptides from the extracellular space, allowing the immune system to detect the presence of foreign microbes from this compartment. To be able to predict the immune response to given pathogens, a number of methods have been developed to predict peptide–MHC binding. However, few methods other than the pioneering TEPITOPE/ProPred method have been developed for MHC‐II. Despite recent progress in method development, the predictive performance for MHC‐II remains significantly lower than what can be obtained for MHC‐I. One reason for this is that the MHC‐II molecule is open at both ends allowing binding of peptides extending out of the groove. The binding core of MHC‐II‐bound peptides is therefore not known a priori and the binding motif is hence not readily discernible. Recent progress has been obtained by including the flanking residues in the predictions. All attempts to make ab initio predictions based on protein structure have failed to reach predictive performances similar to those that can be obtained by data‐driven methods. Thousands of different MHC‐II alleles exist in humans. Recently developed pan‐specific methods have been able to make reasonably accurate predictions for alleles that were not included in the training data. These methods can be used to define supertypes (clusters) of MHC‐II alleles where alleles within each supertype have similar binding specificities. Furthermore, the pan‐specific methods have been used to make a graphical atlas such as the MHCMotifviewer, which allows for visual comparison of specificities of different alleles.