Peptides: the cornerstone of HLA-B27 biology and pathogenetic role in spondyloarthritis.

The association of human leukocyte antigen (HLA)-B27 to ankylosing spondylitis is one of the strongest between a major histocompatibility complex molecule and a disease. Yet, the basis for this association remains unknown. Several hypotheses, each based on a particular feature of HLA-B27, guide much of the current research on the pathogenesis of this disease, but none has yet satisfactorily explained its mechanism and the differential association of B27 subtypes to it. In this review, the pathogenetic role of HLA-B27 will be analyzed from a global perspective of its biology, emphasizing the interdependency of multiple molecular features and the likely influence of disease-modifying gene products. From this perspective, peptide binding emerges as the cornerstone of all other biological properties.

HLA-B27: a registry of constitutive peptide ligands.

The very strong association of human leukocyte antigen (HLA)-B27 with spondyloarthritis might be related to its peptide-presenting properties. The natural polymorphism of this molecule influences both peptide specificity and disease susceptibility. In this study, we present a comprehensive compilation of known natural ligands of HLA-B27 arising from endogenous proteins of human cells, together with a statistical assessment of residue usage among constitutive peptide repertoires of multiple HLA-B27 subtypes. This analysis provides evidence that every peptide position, including "non-anchor" ones, may be subjected to selection on the basis of its contribution to HLA-B27 binding and also allows a quantization of residue preferences at known anchor positions. The present registry is intended as a basis on which to build up reliable criteria to assess the effect of HLA-B27 polymorphism on peptide presentation, for T-cell epitope predictions, and for molecular mimicry studies.

Conserved TCR beta chain usage in reactive arthritis; evidence for selection by a putative HLA-B27-associated autoantigen.

Previous work suggested that expanded CD8+ T-cell clones in the synovial fluid (SF) of HLA-B27+ patients with reactive arthritis (ReA) preferentially use the T-cell receptor variable region (TCRBV) 1, similar CDR3 sequences, and joining region (BJ) 2S3. To determine the range of conservation and disease-specificity of CDR3-sequences, we analyzed the TCRBV1-J2S3 repertoire from 33 healthy HLA-B27+ individuals, patients with various types of spondyloarthropathies (SpA), and with rheumatoid arthritis (RA) by CDR3-spectratyping. After collection and database submission of all available TCRB-CDR3 from HLA-B27-restricted or SpA-derived T cells, we systematically screened the entire human sequence database for sequences similar to the B27/SpA-related CDR3. Spectratyping revealed expanded T cell clones using conserved TCRBV1J2S3 in the SF from 5/6 of the patients with acute ReA but not among the controls. In database searches, 50 HLA-B27 or SpA-related CDR3-sequences generated similar clusters of matched sequences, and matched reciprocally. Identical or closely related sequences were identified in 15 different individuals and a canonical ReA-associated TCRB was defined [BV1-CASSVG(V/I/L)(Y/F)STDTQYF-J2S3]. All but one patient-derived conserved sequences originated from acute stage ReA-patients, and were not present among approximately 3800 other human TCRB sequences in the database. Five of the conserved sequences originated from T cell clones that recognized uninfected cells in an HLA-B27-restricted fashion, implying a role of HLA-B27-restricted CD8+ T cells specific for a ubiquitous self- or cross-reactive microbial determinant in the early phase of ReA. Related sequences were independently identified in four different laboratories. The consensus TCRB motif could be a helpful diagnostic marker in HLA-B27-associated 'undifferentiated arthritis'.

HLA-B27 and the pathogenesis of spondyloarthritis.

The association of HLA-B27 with ankylosing spondylitis and other spondyloarthropathies ranks among the strongest between any HLA antigen and a human disease. Yet, in spite of intense research and advanced knowledge of the biochemistry and biology of major histocompatibility complex molecules, the mechanism of this association remains unknown. This review attempts a critical assessment of current pathogenetic hypotheses from evidence concerning the epidemiology of HLA-B27 association with disease, its peptide-binding specificity, and other aspects of the molecular biology and immunology of this molecule.

The Cys-67 residue of HLA-B27 influences cell surface stability, peptide specificity, and T-cell antigen presentation.

Cys-67 of HLA-B27 is located in the B pocket, which determines peptide-binding specificity. We analyzed effects of the Cys-67 --> Ser mutation on cell surface expression, peptide specificity, and T-cell recognition of HLA-B*2705. Surface expression was assessed with antibodies recognizing either native or unfolded HLA proteins. Whereas native B*2705 molecules predominated over unfolded ones, this ratio was reversed in the mutant, suggesting lower stability. Comparison of B*2705- and Cys-67 --> Ser-bound peptides revealed that the mutant failed to bind approximately 15% of the B*2705 ligands, while binding as many novel ones. Two peptides with Gln-2 found in both B*2705 and Cys-67 --> Ser are the first demonstration of natural B*2705 ligands lacking Arg-2. Other effects of the mutation on peptide specificity were: 1) average molecular mass of natural ligands higher than for B*2705, 2) bias against small residues at peptide position (P) 1, and 3) increased P2 permissiveness. The results suggest that the Cys-67 --> Ser mutation weakens B pocket interactions, leading to decreased stability of the mutant-peptide complexes. This may be partially compensated by interactions involving bulky P1 residues. The effect of the mutation on allorecognition was consistent with that on peptide specificity. Our results may aid understanding of the pathogenetic role of HLA-B27 in spondyloarthropathy.

Major histocompatibility complex class I molecules bind natural peptide ligands lacking the amino-terminal binding residue in vivo.

Major histocompatibility complex (MHC) class I-peptide complexes are stabilized by multiple interactions, including those of the peptidic NH(2)-terminal group in the A pocket of the MHC molecule. In this study, the characterization of four natural HLA-B39 ligands lacking the amino-terminal binding residue is reported. These peptides were found in the endogenous peptide pool of one or more of the B*3901, B*3905, and B*3909 allotypes and sequenced by nanoelectrospray mass spectrometry. Control experiments ruled out that they resulted from exopeptidase trimming of their NH(2)-terminally extended counterparts: NAc-SHVAVENAL, EHGPNPIL, IHEPEPHIL, and EHAGVISVL, also present in the same peptide pools, during purification. HAGVISVL and HVAVENAL behaved similarly to the corresponding NH(2)-terminally extended peptides in their binding to B*3901 and B*3909 at the cell surface in vitro, and in cell surface stabilization of B*3901. This is, to our knowledge, the first demonstration that peptides lacking the amino-terminal binding residue bind in vivo to classical MHC class I molecules. The results indicate that canonical MHC-peptide interactions in the A pocket are not always necessary for endogenous peptide presentation.

Minimal alterations in the HLA-B27-bound peptide repertoire induced upon infection of lymphoid cells with Salmonella typhimurium.

OBJECTIVE: To characterize putative changes in the HLA-B27-bound peptide repertoire following infection of lymphoid cells with Salmonella typhimurium, a bacterium known to trigger reactive arthritis in HLA-B27-positive individuals. METHODS: A protocol was developed for efficient large-scale infection of lymphoblastoid cell transfectants expressing HLA-B*2705. HLA-B27-bound peptide pools were isolated from noninfected and infected B*2705+ cells and comparatively analyzed by high-performance liquid chromatography. Peptide-containing chromatographic fractions from noninfected and infected cells were systematically compared by mass spectrometry (MS) to look for putative differences at the level of individual peptides. RESULTS: The presence of B*2705 did not influence S typhimurium invasion, since this was equally efficient in nontransfected or B27-transfected cells. The chromatographic profiles of B*2705-bound peptides from noninfected and infected cells were virtually identical. A total of 808 molecular species were compared by MS. Of these, 807 were present in both infected and noninfected cells. Only one molecular species from infected cells lacked a detectable counterpart in noninfected cells. CONCLUSION: Intracellular infection of lymphoid cells by S typhimurium induces minimal alterations in the HLA-B27-bound peptide repertoire. Minor changes detectable by cytotoxic T lymphocytes, but not easily amenable to direct biochemical analysis, are not ruled out.

Quantitative and qualitative influences of tapasin on the class I peptide repertoire.

Tapasin is critical for efficient loading and surface expression of most HLA class I molecules. The high level surface expression of HLA-B*2705 on tapasin-deficient 721.220 cells allowed the influence of this chaperone on peptide repertoire to be examined. Comparison of peptides bound to HLA-B*2705 expressed on tapasin-deficient and -proficient cells by mass spectrometry revealed an overall reduction in the recovery of B*2705-bound peptides isolated from tapasin-deficient cells despite similar yields of B27 heavy chain and beta(2)-microglobulin. This indicated that a proportion of suboptimal ligands were associated with B27, and they were lost during the purification process. Notwithstanding this failure to recover these suboptimal peptides, there was substantial overlap in the repertoire and biochemical properties of peptides recovered from B27 complexes derived from tapasin-positive and -negative cells. Although many peptides were preferentially or uniquely isolated from B*2705 in tapasin-positive cells, a number of species were preferentially recovered in the absence of tapasin, and some of these peptide ligands have been sequenced. In general, these ligands did not exhibit exceptional binding affinity, and we invoke an argument based on lumenal availability and affinity to explain their tapasin independence. The differential display of peptides in tapasin-negative and -positive cells was also apparent in the reactivity of peptide-sensitive alloreactive CTL raised against tapasin-positive and -negative targets, demonstrating the functional relevance of the biochemical observation of changes in peptide repertoire in the tapasin-deficient APC. Overall, the data reveal that tapasin quantitatively and qualitatively influences ligand selection by class I molecules.

Large sharing of T-cell epitopes and natural ligands between HLA-B27 subtypes (B*2702 and B*2705) associated with spondyloarthritis.

HLA-B*2702 is an ankylosing spondylitis-associated allotype that differs from the more common B*2705 at residues 77, 80, and 81, in the peptide-binding site. The diversity and fine specificity of alloreactive cytolytic T-lymphocyte (CTL) raised against B*2702 were analyzed at the clonal level. Significant crossreaction with B*2705 and B*2709 indicated that the three subtypes share numerous T-cell epitopes. However, some epitopes shared by B*2702 and B*2705 were lost in B*2709, which correlates with weaker association of this subtype to disease. Clonal specificities were donor-dependent, indicating that allo-immunogenicity is variable among individuals. Anti-B*2702 CTL were little affected by single mutations mimicking B*2702/B*2705 polymorphism, but the double mutant at positions 77 and 81 was recognized worse than B*2705, suggesting a compensatory effect of residue 80. Thus, HLA-B27 polymorphism modulated alloreactivity through cooperative and compensatory effects on T-cell epitope structure. Comparison of B*2705- and B*2702-bound peptide repertoires revealed that they overlapped by 73% and 81%, respectively. This was larger than B*2702/B*2705 cross-reaction, indicating that HLA-B27 allospecificity is only partially determined by the nature of peptide repertoires. The large sharing of natural ligands and T-cell epitopes is consistent with a pathogenetic role of B*2702 and B*2705 in spondyloarthritis based on antigen presentation.

HLA-B27 and immunogenetics of spondyloarthropathies.

The arthritogenic peptide hypothesis has inspired research aimed at defining the peptide-presenting properties of HLA-B27 subtypes and their relation to ankylosing spondylitis. Various studies have shed new light on the influence of HLA-B27 polymorphism in modulating peptide binding and T-cell antigen presentation. Moreover, multiple factors along the antigen processing-loading pathway, including tapasin, contribute to shaping the HLA-B27 repertoire. Other studies have revealed significant peptide-binding similarities between HLA-B27 and subtypes of HLA-B39, supporting a role of this antigen in spondyloarthropathy. A putative pathogenetic role of the HLA-B27 heavy chain, initially suggested from studies in transgenic mice, is claimed on the basis of novel, yet circumstantial, evidence concerning an apparently unusual capacity of the heavy chain to form stable homodimers or misfold after biosynthesis. Finally, it appears that arthritogenic infections might downregulate HLA-B27 expression, favoring bacterial survival. The specificity and mechanism of this phenomenon are yet to be defined.

Limited plasticity in the recognition of peptide epitope variants by an alloreactive CTL clone correlates directly with conservation of critical residues and inversely with peptide length.

Although self-restricted T cells are peptide-specific and can distinguish among closely related ligands, they have some flexibility in the recognition of sequence variants of their natural peptide epitopes. Alloreactive cytotoxic T lymphocytes (CTL) can recognize specific peptides bound to the allo-major histocompatibility complex (MHC) molecule, but their plasticity in the recognition of related peptide variants has not been properly defined. The anti-B*2705 alloreactive CTL 27S69 specifically recognizes a natural octamer ligand of HLA-B*2705. In this study, we tested the recognition of a nested set of epitope variants by this CTL clone. Although none of these peptides was recognized equally as the natural epitope, two of the peptide variants were recognized with only slightly decreased efficiency. Peptide sensitization assays showed that CTL recognition of epitope variants correlated directly with conservation of two non-anchor residues that were critical for recognition of the natural epitope, and inversely with peptide length. Molecular modeling of the peptide variants complexed with B*2705 provided a rational explanation for their differential recognition. Location of the two critical peptide residues at the right three-dimensional space favored efficient recognition by CTL 27S69. The negative effect of increasing peptide length on recognition was due to the bigger bulging surface between the two critical residues, which precluded for optimal interaction with the specific T-cell receptors (TCR). Our results demonstrate that an alloreactive CTL has a degree of plasticity in the recognition of peptide epitope variants that is comparable to that of peptide-specific self-restricted CTL, and define the structural features determining crossreaction among related peptides.

A high incidence of Shigella-induced arthritis in a primate species: major histocompatibility complex class I molecules associated with resistance and susceptibility, and their relationship to HLA-B27.

The human major histocompatibility complex (MHC) class I gene, HLA-B27, is a strong risk factor for susceptibility to a group of disorders termed spondyloarthropathies. Rodents that express HLA-B27 develop spondyloarthropathies, implicating HLA-B27 in the etiology of these disorders. To determine whether an HLA-B27-like molecule was associated with spondyloarthropathies in nonhuman primates, we analyzed the MHC class I cDNAs expressed in a cohort of rhesus macaques that developed reactive arthritis after an outbreak of shigellosis. We identified several cDNAs with only limited sequence similarity to HLA-B27. Interestingly, one of these MHC molecules had a B pocket identical to that of HLA-B39. Pool sequencing of radiolabeled peptides bound by this molecule demonstrated that, like HLA-B27 and HLA-B39, it could bind peptides with arginine at the second position. However, extensive analysis of the MHC class I molecules in this cohort revealed no statistically significant association between any particular MHC class I allele and susceptibility to reactive arthritis. Furthermore, none of the rhesus MHC class I molecules bore a strong resemblance to HLA-B27, indicating that reactive arthritis can develop in this animal model in the absence of an HLA-B27-like molecule. Surprisingly, there was a statistically significant association between the rhesus macaque MHC A locus allele, Mamu-A*12, and the absence of reactive arthritis following Shigella infection.

A post-translational modification of nuclear proteins, N(G),N(G)-dimethyl-Arg, found in a natural HLA class I peptide ligand.

Presentation of peptides derived from endogenous proteins by class I major histocompatibility complex molecules is essential both for immunological self-tolerance and induction of cytotoxic T-cell responses against intracellular parasites. Despite frequent and diverse post-translational modification of eukaryotic cell proteins, very few class I-bound peptides with post-translationally modified residues are known. Here we describe a natural dodecamer ligand of HLA-B39 (B*3910) derived from an RNA-binding nucleoprotein that carried N(G),N(G)-dimethyl-Arg. Although common among RNA-binding proteins, this modification was not previously known among natural class I ligands. The sequence of this peptide was determined by Edman degradation and electrospray ion trap mass spectrometry. The fragmentation pattern of the dimethyl-Arg side chain observed with this latter technique allowed us to unambiguously assign the isomeric form of the modified residue. The post-translationally modified ligand was a prominent component (1-2%) of the B*3910-bound peptide repertoire. The dimethyl-Arg residue was located in a central position of the peptide, amenable to interacting with T-cell receptors, and most other residues in the middle region of the peptide were Gly. These structural features strongly suggest that the post-translationally modified residue may have a major influence on the antigenic properties of this natural ligand.

Peptide specificity of the Amerindian B*3905 allotype: molecular insight into selection mechanisms driving HLA class I evolution in indigenous populations of the Americas.

HLA-B*3905 is apparently restricted to Amerindian populations and presents a wide geographical distribution, from Mexico to Argentina. It differs from B*3901, one of the founder HLA class I alleles of Central and South Amerindians, by a single nucleotide substitution leading to an Asp74Tyr change in the gene product. The peptide specificity of the B*3905 protein was characterized by pool sequence analysis of B*3905-bound peptides and by sequencing of a set of individual ligands, using electrospray ion trap mass spectrometry. The results indicate a double effect of the B*3905 mutation. First, pocket B specificity was shifted towards an increased preference for His at peptide position 2, which is the main anchor for B39-bound peptides, relative to B*3901. Second, at peptide position 3 acidic residues were favored, and aromatic residues disfavored, relative to B*3901. These features approach the peptide specificity of B*3905 to B*3801 and B*1509, allotypes absent from Central and South Amerindians. Together with B*3909, B*3905 is the second HLA-B39 subtype whose polymorphism results in a shift of peptide specificity towards that of HLA-B allotypes absent from these populations. This suggests that HLA-B39 evolution in Central and South America may be an antigen-driven adaptive response, leading to generate antigen-presenting properties absent from the HLA class I repertoire of the ancestral population.

Limited diversity of peptides related to an alloreactive T cell epitope in the HLA-B27-bound peptide repertoire results from restrictions at multiple steps along the processing-loading pathway.

The influence of various factors along the processing-loading pathway in limiting the diversity of HLA-B27-bound peptides around a core protein sequence was analyzed. The C5 proteasome subunit-derived RRFFPYYV and RRFFPYYVY peptides are natural B*2705 ligands. The octamer is an allospecific CTL epitope. Digestion of a 27-mer fragment of C5 revealed that both ligands are generated from this precursor substrate with the 20S proteasome in vitro in a ratio comparable to that in the B*2705-bound peptide pool. The C5 sequence allowed to derive a nested set of six additional peptides with 8-11 residues containing the core octamer sequence and the Arg2 motif of HLA-B27, none of which was found in the B27-bound pool. Together, low proteasomal yield, disfavored TAP-binding motifs, and low affinity for B*2705 accounted for the absence of four of the six peptides. The two remaining differed from the natural octamer or nonamer ligands only by an additional N-terminal Ser residue. Their stability in complex with B*2705 was lower than the respective natural ligands, raising the possibility that N-terminal trimming might have favored a shift toward the more stable peptides. The results suggest that the B*2705-bound peptide repertoire has a highly restricted diversity around a core alloantigenic sequence. This is not explained by a single bottleneck feature, but by multiple factors, including proteasomal generation, TAP-binding motifs, MHC-binding efficiency, and perhaps optimized stability through N-terminal trimming. Tapasin-dependent restrictions, although not excluded, were not required to explain the absence in vivo of the particular peptide set in this study.

Peptide presentation to an alloreactive CTL clone is modulated through multiple mechanisms involving polymorphic and conserved residues in HLA-B27.

This study addressed the mechanisms by which HLA class I polymorphism modulates allorecognition. CTL 27S69 is an alloreactive clone raised against HLA-B*2705, with a known peptide epitope. This CTL cross-reacts with B*2702, which differs from B*2705 in the D77N, T80I, and L81A changes, but not with B*2701, which has D74Y, D77N, and L81A changes. To explain this differential recognition, B*2705 mutants mimicking subtype changes were used. The A81 mutant was not recognized, despite binding the natural epitope in vivo, suggesting that, when bound to this mutant, this peptide adopts an inappropriate conformation. The N77 and I80 mutations restored recognition in the N77A81 or I80A81 mutants. These compensatory effects explain the cross-reaction with B*2702. The Y74 and the Y74N77 mutants were weakly recognized or not recognized by CTL 27S69. This correlated with the absence or marginal presence of the peptide epitope in the Y74N77-bound pool. As with B*2701, exogenous addition of the peptide epitope sensitized Y74 and Y74N77 targets for lysis, indicating that failure to cross-react with B*2701 or these mutants was due to poor binding of the peptide in vivo and not to inappropriate presentation. The abrogating effect of Y74 was critically dependent upon the K70 residue, conserved among subtypes, as demonstrated with mutants at this position. Thus, HLA polymorphism affects allorecognition by modulating peptide binding or the conformation of bound peptides. Compensatory mutations and indirect effects of a polymorphic residue on residues conserved play a critical role.

Modulation at multiple anchor positions of the peptide specificity of HLA-B27 subtypes differentially associated with ankylosing spondylitis.

OBJECTIVE: To investigate the rules governing peptide binding to HLA-B*2705, and to B*2704 and B*2706, which are 2 subtypes differentially associated with ankylosing spondylitis. METHODS: Poly-Ala analogs carrying the HLA-B27 motif Arg-2, and substitutions at anchor positions P1, P3, or Pomega, were used to determine a binding score for each residue at each position. Binding was assessed in a quantitative epitope stabilization assay, where the cell surface expression of HLA-B27 was measured by flow cytometry as a function of peptide concentration. RESULTS: Peptide anchor residues contributed additively to B*2705 binding. About 15% of the natural B*2705 ligands used a deficient P3 or Pomega anchor, but never both, indicating that detrimental anchoring at one of these positions is always compensated by a good anchor at the other one. About 50% of the B*2705 ligands used suboptimal P1 residues. However, this was compensated with optimal P3 and/or Pomega anchoring. Peptides that were longer than decamers used good anchor residues at the 3 positions, suggesting more stringent binding requirements. B*2704 and B*2706 differed in their residue specificity at P1, P3, and Pomega. The rules derived for B*2705 also applied to the known ligands of these 2 subtypes. CONCLUSION: The B*2705, B*2704, and B*2706 peptide repertoires are limited by the allowed residue combinations described in this study. The differential association of B*2704 and B*2706 with spondylarthropathy correlates with differences in their peptide specificity at multiple anchor positions. However, it is now possible to predict the peptide features that determine this differential binding to both subtypes.

High T cell epitope sharing between two HLA-B27 subtypes (B*2705 and B*2709) differentially associated to ankylosing spondylitis.

HLA-B*2705 is strongly associated with ankylosing spondylitis (AS) and reactive arthritis. In contrast, B*2709 has been reported to be more weakly or not associated to AS. These two molecules differ by a single amino acid change: aspartic acid in B*2705 or histidine in B*2709 at position 116. In this study, we analyzed the degree of T cell epitope sharing between the two subtypes. Ten allospecific T cell clones raised against B*2705, 10 clones raised against B*2703 but cross-reactive with B*2705, and 10 clones raised against B*2709 were examined for their capacity to lyse B*2705 and B*2709 target cells. The anti-B*2705 and anti-B*2703 CTL were peptide dependent as demonstrated by their failure to lyse TAP-deficient B*2705-T2 transfectant cells. Eight of the anti-B*2705 and five of the anti-B*2703 CTL clones lysed B*2709 targets. The degree of cross-reaction between B*2705 and B*2709 was donor dependent. In addition, the effect of the B*2709 mutation (D116H) on allorecognition was smaller than the effect of the other naturally occurring subtype change at this position, D116Y. These results demonstrate that B*2705 and B*2709 are the antigenically closest HLA-B27 subtypes. Because allospecific T cell recognition is peptide dependent, our results imply that the B*2705- and B*2709-bound peptide repertoires are largely overlapping. Thus, to the extent to which linkage of HLA-B27 with AS is related to the peptide-presenting properties of this molecule, our results would imply that peptides within a relatively small fraction of the HLA-B27-bound peptide repertoire influence susceptibility to this disease.

Long-range effects in protein--ligand interactions mediate peptide specificity in the human major histocompatibilty antigen HLA-B27 (B*2701).

B*2701 differs from all other HLA-B27 subtypes of known peptide specificity in that, among its natural peptide ligands, arginine is not the only allowed residue at peptide position 2. Indeed, B*2701 is unique in binding many peptides with Gln2 in vivo. However, the mutation (Asp74Tyr) responsible for altered selectivity is far away from the B pocket of the peptide binding site to which Gln/Arg2 binds. Here, we present a model that explains this effect. It is proposed that a new rotameric state of the conserved Lys70 is responsible for the unique B*2701 binding motif. This side chain should be either kept away from pocket B through its interaction with Asp74 in most HLA-B27 subtypes, or switched to this pocket if residue 74 is Tyr as in B*2701. Involvement of Lys70 in pocket B would thus allow binding of peptides with Gln2. Binding of Arg2-containing peptides to B*2701 is also possible because Lys70 could adopt another conformation, H-bonded to Asn97, which preserves the same binding mode of Arg2 as in B*2705. This model was experimentally validated by mutating Lys70 into Ala in B*2701. Edman sequencing of the B*2701(K70A) peptide pool showed only Arg2, characteristic of HLA-B27-bound peptides, and no evidence for Gln2. This supports the computational model and demonstrates that allowance of B*2701 for peptides with Gln2 is due to the long-range effect of the polymorphic residue 74 of HLA-B27, by inducing a conformational switch of the conserved Lys70.

Nonapeptide analogues containing (R)-3-hydroxybutanoate and beta-homoalanine oligomers: synthesis and binding affinity to a class I major histocompatibility complex protein.

Crystal structures of antigenic peptides bound to class I MHC proteins suggest that chemical modifications of the central part of the bound peptide should not alter binding affinity to the MHC restriction protein but could perturb the T-cell response to the parent epitope. In our effort in designing nonpeptidic high-affinity ligands for class I MHC proteins, oligomers of (R)-3-hydroxybutanoate and(or) beta-homoalanine have been substituted for the central part of a HLA-B27-restricted T-cell epitope of viral origin. The affinity of six modified peptides to the B2705 allele was determined by an in vitro stabilization assay. Four out of the six designed analogues presented an affinity similar to that of the parent peptide. Two compounds, sharing the same stereochemistry (R,R,S,S) at the four stereogenic centers of the nonpeptidic spacer, bound to B2705 with a 5-6-fold decreased affinity. Although the chiral spacers do not strongly interact with the protein active site, there are configurations which are not accepted by the MHC binding groove, probably because of improper orientation of some lateral substituents in the bound state and different conformational behavior in the free state. However we demonstrate that beta-amino acids can be incorporated in the sequence of viral T-cell epitopes without impairing MHC binding. The presented structure-activity relationships open the door to the rational design of peptide-based vaccines and of nonnatural T-cell receptor antagonists aimed at blocking peptide-specific T-cell responses in MHC-associated autoimmune diseases.