Molecular analysis of a functional subtype of HLA-B27. A possible evolutionary pathway for HLA-B27 polymorphism

The structure of a new HLA-B27 subtype antigen B27.4(B27D), distinguishable from the HLA-B27.1, B27.2, and B27.3 subtypes by cytolytic T lymphocytes and isoelectric focusing, has been established by comparative peptide mapping and sequence analysis. HLA-B27.4 differs from the main B27.1 subtype in the same two changes of aspartate-77 to serine-77 and valine-152 to glutamate-152, which distinguish the B27.1 and B27.3 subtypes. In addition, there are two other amino acid changes of histidine-114 to aspartate-114 and of aspartate-116 to tyrosine-116, which are unique to B27.4. The close structural relationship between B27.3 and B27.4 explains the similarity of these two subtypes in terms of T cell recognition. The presence of the two single amino acid differences between B27.3 and B27.4 within a span of three residues in the linear sequence provides a new example, suggesting that gene conversion-like mechanisms play a major role in the diversification of HLA-B27. A comparison of the structure of HLA-B27.4 with those of B27.1, B27.2, and B27.3 in the context of their ethnic distribution suggests that the diversification of the HLA-B27 antigens is an ongoing process that has continued after the separation of the major ethnic groups. A tentative evolutionary model for HLA-B27 polymorphism is proposed.     

Fine specificity of HLA-B27 cellular allorecognition. HLA-B27f is a functional variant distinguishable by cytolytic T cell clones

Three HLA-B27 allospecific cytolytic T lymphocyte (CTL) clones were isolated by limiting dilution of HLA-B27-negative responder cells stimulated with HLA-B27.1-positive lymphoblastoid cells. These clones displayed three distinct reaction patterns when tested for their lytic ability against target cells expressing various structurally defined HLA-B27 subtypes. One of the clones was specific for HLA-B27.1; a second CTL clone reacted only with B27.1 and, less efficiently, with B27.2; the third clone recognized both B27.1 and B27f targets but not cells expressing any other B27 subtype. These results indicate that HLA-B27f is a functional variant amenable to differential recognition by alloreactive CTL. A correlation of the structure of the HLA-B27 subtypes with the reactivity of these clones revealed that multiple B27-specific alloreactive CTL are activated against epitopes of the HLA-B27.1 molecule sharing common structural features. This illustrates the complexity and fine specificity of the allogeneic CTL response against class I HLA antigens and suggests that their immunodominant regions are those which are capable of eliciting a diverse polyclonal response against each of these regions, rather than inducing the selective expansion of a single T cell clone.     

Structural analysis of an HLA-B27 functional variant, B27d, detected in American blacks

The structure of a new functional variant B27d has been established by comparative peptide mapping and radiochemical sequencing. This analysis completes the structural characterization of the six known histocompatibility leukocyte antigen (HLA)-B27 subtypes. The only detected amino acid change between the main HLA-B27.1 subtype and B27d is that of Tyr59 to His59. Position 59 has not been previously found to vary among class I HLA or H-2 antigens. Such substitution accounts for the reported isoelectric focusing pattern of this variant. HLA-B27d is the only B27 variant found to differ from other subtypes by a single amino acid replacement. The nature of the change is compatible with its origin by a point mutation from HLA-B27.1. Because B27d was found only in American blacks and in no other ethnic groups, it is suggested that this variant originated as a result of a mutation of the B27.1 gene that occurred within the black population.     

HLA-B27 antigenicity: antibodies against the chemically synthesized 63-84 peptide from HLA-B27.1 display alloantigenic specificity and discriminate among HLA-B27 subtypes

A chemically synthesized peptide with an amino acid sequence identical to that of the segment spanning residue 63-84 of the major HLA-B27.1 subtype antigen has been obtained. Specific antibodies were raised in rabbits against this peptide, coupled to keyhole limpet hemocyanin carrier. These antibodies lysed lymphoblastoid cell lines expressing HLA-B27.1 in a complement-mediated cytotoxicity assay. They lysed neither B27-negative target cells, nor B27-positive cells expressing other B27 subtype antigens. Complement-mediated lysis of B27.1-positive targets was inhibited by free peptide and by peptide coupled to an unrelated carrier. In addition, the lytic action of the rabbit antiserum was blocked by a monoclonal antibody with no complement-activating capacity that under the conditions of the assay, was specific for HLA-B27. These results indicate that rabbit antibodies against the 63-84 peptide recognize the native HLA-B27.1 antigen; this antiserum is allospecific in character; and it discriminates among B27 subtypes. Thus the data provide direct evidence on the contribution of the hypervariable region spanning residues 63-84 to the alloantigenic specificity of HLA-B27.     

One allogeneic cytolytic T lymphocyte clone distinguishes three different HLA-B27 subtypes: identification of amino acid residues influencing the specificity and avidity of recognition

The HLA-B27 antigen may be divided into at least three subgroups, designated HLA-B27.1, -B27.2, and -B27.3, by specific cytolytic T lymphocytes. In an attempt to explore the functional relevance of HLA polymorphism, an alloimmune cytolytic T cell clone T3+, T8+, T4- has been characterized, which displays a distinct reactivity pattern with each one of the three HLA-B27 subtypes. This cell kills both B27.1- and B27.2- but not B27.3-positive targets. Its lytic efficiency is greater with B27.1 than with B27.2 cells. The clone does not recognize either B7-positive targets or most B27-negative cells. But HLA-B40-bearing cells are lysed, albeit with significantly less efficiency than any B27-positive targets. The differences in killing ability for B27.1, B27.2, and B40 are also evident in cold-target inhibition studies, indicating that a) B27.1 cells can efficiently inhibit lysis of B27.2 and B40 targets, b) B27.2 cells inhibit the lysis of B40 but not of B27.1 targets, and c) B40 cells do not inhibit B27.1 or B27.2 target lysis. In addition, anti-T3 and anti-T8 antibodies are much more effective in inhibiting the lysis of B27.2 targets than that of B27.1-positive cells, suggesting that the observed differences in killing efficiency of the various targets are due to the fact that the tightness of the effector-target interaction is affected by the structural changes between the different HLA antigens. A correlation of the reactivity pattern of this T cell clone with the known amino acid sequences of the HLA-B27, HLA-B40, and HLA-B7 antigens suggests that the clone recognizes a conformational determinant contributed to by residues within the segments 149-156 and 67-83. Those in the former segment appear to be an essential portion of this determinant, whereas polymorphism in the region 67-83 has a modulating effect on the reactivity of the effector but does not abrogate recognition.     

Structure and diversity of HLA-B27-specific T cell epitopes. Analysis with site-directed mutants mimicking HLA-B27 subtype polymorphism.

HLA-B27 subtype polymorphism is amenable to differential recognition by CTL. Site-directed mutagenesis was used to construct a series of HLA-B27 mutants reproducing most of the changes occurring in the natural subtypes. The reactivity of 21 anti-HLA-B27 CTL clones was examined with these mutants to address three issues concerning the alloreactive response against HLA-B27: 1) diversity of clonotypic specificities, 2) structural features of the epitopes recognized by these clones, and 3) role of individual positions in the differential recognition of HLA-B27 subtypes. Virtually all CTL clones displayed unique reaction patterns with the mutants, indicating a corresponding diversity of epitopes. However, these share some molecular features, such as certain amino acid residues and related locations. Individual mutations induced complex effects on multiple B27-specific CTL epitopes, revealing some of their very precise stereochemical constrains. An important feature of HLA-B27 subtype polymorphism is that every individual change was relevant, altering recognition by many CTL clones. Although the specific set affected by each mutation was partially different, the global number of clones affected by most changes was very similar. This suggests that the antigenic profile of any given subtype is not dominated by one particular change but is uniquely defined by its corresponding set of changes. An exception was the change at position 152, which totally abrogated recognition by all 20 anti-B*2705 CTL clones. This effect decisively influences the profound differences in T cell recognition between B*2705 and the two subtypes, B*2704 and B*2706, carrying this change. The results are compatible with the idea that HLA-B27 allorecognition may involve multiple peptides bound to the alloantigen on the cell surface.     

HLA-B27 subtypes differentially associated with disease exhibit subtle structural alterations

The reasons for the association of the human major histocompatibility complex protein HLA-B27 with spondyloarthropathies are unknown. To uncover the underlying molecular causes, we determined the crystal structures of the disease-associated B*2705 and the nonassociated B*2709 subtypes complexed with the same nonapeptide (GRFAAAIAK). Both differ in only one residue (Asp(116) and His(116), respectively) in the F-pocket that accommodates the peptide C terminus. Several different effects of the Asp(116) --> His replacement are observed. The bulkier His(116) induces a movement of peptide C-terminal pLys(9), allowing the formation of a novel salt bridge to Asp(77), whereas the salt bridge between pLys(9) and Asp(116) is converted into a hydrogen bond with His(116). His(116) but not Asp(116) adopts two alternative conformations, one of which leads to breakage of hydrogen bonds. Water molecules near residue 116 differ with regard to number, position, and contacts made. Furthermore, F-pocket atoms exhibit higher B-factors in B*2709 than in B*2705, indicating an increased flexibility of the entire region in the former subtype. These changes induce subtle peptide conformational alterations that may be responsible for the immunobiological differences between these HLA-B27 subtypes.     

Influence of inflammation-related changes on conformational characteristics of HLA-B27 subtypes as detected by IR spectroscopy

Inflammatory processes are accompanied by the post-translational modification of certain arginine residues to yield citrulline, and a pH decrease in the affected tissue, which might influence the protonation of histidine residues within proteins. We employed isotope-edited IR spectroscopy to investigate whether conformational features of two human major histocompatibility antigen class I subtypes, HLA-B*2705 and HLA-B*2709, are affected by these changes. Both differ only in residue 116 (Asp vs. His) within the peptide-binding grooves, but are differentially associated with inflammatory rheumatic disorders. Our analyses of the two HLA-B27 subtypes in complex with a modified self-peptide containing a citrulline RRKWURWHL (U = citrulline) revealed that the heavy chain is more flexible in the HLA-B*2705 subtype than in the HLA-B*2709 subtype. Together with our previous studies of HLA-B27 subtypes complexed with the unmodified self-peptide RRKWRRWHL, these findings support the existence of subtype-specific conformational features of the heavy chains under physiological conditions, which are undetectable by X-ray crystallography and exist irrespective of the sequence of the bound peptide and its binding mode. They might thus influence antigenic properties of the respective HLA-B27 subtype. Furthermore, a decrease in the pH from 7.5 to 5.6 during the analyses had an influence only on HLA-B*2709 complexed with the unmodified self-peptide, where His116 is not contacted by any peptide side chain. This permits us to conclude that histidines, and in particular His116, influence the stability of MHC:peptide complexes. The conditions prevailing in inflammatory environments in vivo might thus also exert an impact on selected conformational features of HLA-B27:peptide complexes.     

HLA-B27 subtypes differentially associated with disease exhibit conformational differences in solution

Human leukocyte antigen (HLA) class I molecules consist of a heavy chain, β₂-microglobulin, and a peptide that are noncovalently bound. Certain HLA-B27 subtypes are associated with ankylosing spondylitis (such as HLA-B*2705), whereas others (such as HLA-B*2709) are not. Both differ in only one residue (Asp116 and His116, respectively) in the F pocket that accommodates the peptide C-terminus. An isotope-edited IR spectroscopy study of these HLA-B27 subtypes complexed with the self-peptide RRKWRRWHL was carried out, revealing that the heavy chain is more flexible in the HLA-B*2705 than in the HLA-B*2709 subtype. In agreement with these experimental data, molecular dynamics simulations showed an increased flexibility of the HLA-B*2705 binding groove in comparison with that of the HLA-B*2709 subtype. This difference correlates with an opening of the HLA-B*2705 binding groove, accompanied by a partial detachment of the C-terminal peptide anchor. These combined results demonstrate how the deeply embedded polymorphic heavy-chain residue 116 influences the flexibility of the peptide binding groove in a subtype-dependent manner, a feature that could also influence the recognition of the HLA-B27 complexes by effector cells.     

Peptide-presenting similarities among functionally distant HLA-B27 subtypes revealed by alloreactive T lymphocytes of unusual specificity.

Functional dissection of HLA-B27 subtypes using alloreactive or B27-restricted CTL has shown that the structurally related B*2704 and B*2706 are the most distant subtypes relative to the prototype B*2705. In particular, previous studies have failed to find anti-B*2705 CTL cross-reacting with B*2704 or B*2706. Such failure can be accounted for by the drastic effect on T cell recognition of the change at residue 152 in both subtypes relative to B*2705, as established with site-directed mutants. B*2704 and B*2706 are also related in ethnic distribution, as they are restricted to Orientals, jointly being the predominant HLA-B27 subtypes in this population. As far as it is known, there are no differences relative to B*2705 in their linkage to ankylosing spondylitis. In our study, 5 of 13 examined anti-B*2705 limiting dilution CTL lines from a particular HLA-B27- individual were shown to crossreact with B*2704, B*2706 or both. The monoclonal nature of this cross-reaction was established by cold target competition analysis. This result demonstrates that the apparent differences in T cell antigenicity among anti-B27 subtypes are strongly influenced by the responder individual, as the spectrum of clonal specificities in anti-B27 responses may show significant differences among unrelated responders. Fine specificity differences among the cross-reactive CTL allowed unambiguous functional distinction between B*2704 and B*2706. The molecular basis of such cross-reactivity was examined by correlating CTL reaction patterns with the structure of both subtypes, which differ only by two residues located in the beta-pleated sheet bottom of the peptide binding site, and with site-directed mutants mimicking HLA-B27 subtype polymorphism. The results suggest that: 1) distinct peptides are involved in the allospecific epitopes recognized by the various crossreactive CTL, and 2) B*2704, B*2706, and B*2705 differ in their peptide-presenting specificity, but can present some identical or structurally similar peptides.     

Molecular typing of HLA-B27 alleles

HLA-B27 represents a family of closely related antigens. Six alleles which differ in a limited number of nucleotide substitutions have been described (B*2701—B*2706). These changes are clustered in 1 and 2 domains. Polymerase chain reaction strategies were designed to amplify specific regions of class I exons 2 and 3. Amplified sequences were tested with eight sequence-specific oligonucleotides to distinguish all B27 subtypes. We also subtyped B27 in 50 healthy Spanish individuals using this procedure. The B*2705 subtype is over-represented in our population (96%). The remaining 4% carried the B*2702 allele. This finding is in agreement with the frequencies described by other techniques (cytotoxic T lymphocytes and isoeletric-focusing) for Caucasian populations. Class I oligotyping is a poorly developed field with significant potential applications. This procedure of genotyping B27 alleles is a reliable method which can be used in transplantation and B27-associated disease studies.     

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.     

Thermodynamic and structural analysis of peptide- and allele-dependent properties of two HLA-B27 subtypes exhibiting differential disease association

Selected HLA-B27 subtypes are associated with spondyloarthropathies, but the underlying mechanism is not understood. To explain this association in molecular terms, a comparison of peptide-dependent dynamic and structural properties of the differentially disease-associated subtypes HLA-B*2705 and HLA-B*2709 was carried out. These molecules differ only by a single amino acid at the floor of the peptide binding groove. The thermostabilities of a series of HLA-B27 molecules complexed with nonameric and decameric peptides were determined and revealed substantial differences depending on the subtype as well as the residues at the termini of the peptides. In addition we present the crystal structure of the B*2709 subtype complexed with a decameric peptide. This structure provides an explanation for the preference of HLA-B27 for a peptide with an N-terminal arginine as secondary anchor and the lack of preference for tyrosine as peptide C terminus in B*2709. The data show that differences in thermodynamic properties between peptide-complexed HLA-B27 subtypes are correlated with a variety of structural properties.     

Identification of novel HLA-B27 ligands derived from polymorphic regions of its own or other class I molecules based on direct generation by 20 S proteasome.

HLA-B27 is strongly associated with ankylosing spondylitis. Natural HLA-B27 ligands derived from polymorphic regions of its own or other class I HLA molecules might be involved in autoimmunity or provide diversity among HLA-B27-bound peptide repertoires from individuals. In particular, an 11-mer spanning HLA-B27 residues 169-179 is a natural HLA-B27 ligand with homology to proteins from Gram-negative bacteria. Proteasomal digestion of synthetic substrates demonstrated direct generation of the B27-(169-179) ligand. Cleavage after residue 181 generated a B27-(169-181) 13-mer that was subsequently found as a natural ligand of B*2705 and B*2704. Its binding to HLA-B27 subtypes in vivo correlated better than B27-(169-179) with association to spondyloarthropathy. Proteasomal cleavage generated also a peptide spanning B*2705 residues 150-158. This region is polymorphic among HLA-B27 subtypes and class I HLA antigens. The peptide was a natural B*2704 ligand. Since this subtype differs from B*2705 at residue 152, it was concluded that the ligand arose from HLA-B*3503, synthesized in the cells used as a source for B*2704-bound peptides. Thus, polymorphic HLA-B27 ligands derived from HLA-B27 or other class I molecules are directly produced by the 20 S proteasome in vitro, and this can be used for identification of such ligands in the constitutive HLA-B27-bound peptide pool.     

Interaction pattern of Arg 62 in the A-pocket of differentially disease-associated HLA-B27 subtypes suggests distinct TCR binding modes

The single amino acid replacement Asp116His distinguishes the two subtypes HLA-B*2705 and HLA-B*2709 which are, respectively, associated and non-associated with Ankylosing Spondylitis, an autoimmune chronic inflammatory disease. The reason for this differential association is so far poorly understood and might be related to subtype-specific HLA:peptide conformations as well as to subtype/peptide-dependent dynamical properties on the nanoscale. Here, we combine functional experiments with extensive molecular dynamics simulations to investigate the molecular dynamics and function of the conserved Arg62 of the α1-helix for both B27 subtypes in complex with the self-peptides pVIPR (RRKWRRWHL) and TIS (RRLPIFSRL), and the viral peptides pLMP2 (RRRWRRLTV) and NPflu (SRYWAIRTR). Simulations of HLA:peptide systems suggest that peptide-stabilizing interactions of the Arg62 residue observed in crystal structures are metastable for both B27 subtypes under physiological conditions, rendering this arginine solvent-exposed and, probably, a key residue for TCR interaction more than peptide-binding. This view is supported by functional experiments with conservative (R62K) and non-conservative (R62A) B*2705 and B*2709 mutants that showed an overall reduction in their capability to present peptides to CD8+ T cells. Moreover, major subtype-dependent differences in the peptide recognition suggest distinct TCR binding modes for the B*2705 versus the B*2709 subtype.     

Allospecific T cell epitope sharing reveals extensive conservation of the antigenic features of peptide ligands among HLA-B27 subtypes differentially associated with spondyloarthritis

HLA-B*2702, B*2704, and B*2705 are strongly associated with spondyloarthritis, whereas B*2706 is not. Subtypes differ among each other by a few amino acid changes and bind overlapping peptide repertoires. In this study we asked whether differential subtype association with disease is related to differentially bound peptides or to altered antigenicity of shared ligands. Alloreactive CTL raised against B*2704 were analyzed for cross-reaction with B*2705, B*2702, B*2706, and mutants mimicking subtype changes. These CTL are directed against many alloantigen-bound peptides and can be used to analyze the antigenicity of HLA-B27 ligands on different subtypes. Cross-reaction of anti-B*2704 CTL with B*2705 and B*2702 correlated with overlap of their peptidic anchor motifs, suggesting that many shared ligands have similar antigenic features on these three subtypes. Moreover, the percent of anti-B*2704 CTL cross-reacting with B*2706 was only slightly lower than the overlap between the corresponding peptide repertoires, suggesting that most shared ligands have similar antigenic features on these two subtypes. Cross-reaction with B*2705 or mutants mimicking changes between B*2704 and B*2705 was donor-dependent. In contrast, cross-reaction with B*2702 or B*2706 was less variable among individuals. Conservation of antigenic properties among subtypes has implications for allorecognition, as it suggests that shared peptides may determine cross-reaction across exposed amino acid differences in the MHC molecules and that the antigenic distinctness of closely related allotypes may differ among donors. Our results also suggest that differential association of HLA-B27 subtypes with spondyloarthritis is more likely related to differentially bound peptides than to altered antigenicity of shared ligands.     

Thermodynamic and structural equivalence of two HLA-B27 subtypes complexed with a self-peptide

The F pocket of major histocompatibility complex (in humans HLA) class I molecules accommodates the C terminus of the bound peptide. Residues forming this pocket exhibit considerable polymorphism, and a single difference (Asp116 in HLA-B*2705 and His116 in HLA-B*2709 heavy chains) confers differential association of these two HLA-B27 subtypes to the autoimmune disease ankylosing spondylitis. As peptide presentation by HLA molecules is of central importance for immune responses, we performed thermodynamic (circular dichroism, differential scanning calorimetry, fluorescence polarization) and X-ray crystallographic analyses of both HLA-B27 subtypes complexed with the epidermal growth factor response factor 1-derived self-peptide TIS (RRLPIFSRL) to understand the impact of the Asp116His exchange on peptide display. This peptide is known to be presented in vivo by both subtypes, and as expected for a self-peptide, TIS-reactive cytotoxic T lymphocytes are absent in the respective individuals. The thermodynamic analyses reveal that both HLA-B27:TIS complexes exhibit comparable, relatively high thermostability (Tm approximately 60 degrees C) and undergo multi-step unfolding reactions, with dissociation of the peptide in the first step. As shown by X-ray crystallography, only subtle structural differences between the subtypes were observed regarding the architecture of their F pockets, including the presence of distinct networks of water molecules. However, no consistent structural differences were found between the peptide presentation modes. In contrast to other peptides displayed by the two HLA-subtypes which show either structural or dynamical differences in their peptide presentation modes, the TIS-complexed HLA-B*2705 and HLA-B*2709 subtypes are an example for thermodynamic and structural equivalence, in agreement with functional data.     

HLA class I-associated diseases with a suspected autoimmune etiology: HLA-B27 subtypes as a model system

Although most autoimmune diseases are connected to major histocompatibility complex (MHC) class II alleles, a small number of these disorders exhibit a variable degree of association with selected MHC class I genes, like certain human HLA-A and HLA-B alleles. The basis for these associations, however, has so far remained elusive. An understanding might be obtained by comparing functional, biochemical, and biophysical properties of alleles that are minimally distinct from each other, but are nevertheless differentially associated to a given disease, like the HLA-B*27:05 and HLA-B*27:09 antigens, which differ only by a single amino acid residue (Asp116His) that is deeply buried within the binding groove. We have employed a number of approaches, including X-ray crystallography and isotope-edited infrared spectroscopy, to investigate biophysical characteristics of the two HLA-B27 subtypes complexed with up to ten different peptides. Our findings demonstrate that the binding of these peptides as well as the conformational flexibility of the subtypes is greatly influenced by interactions of the C-terminal peptide residue. In particular, a basic C-terminal peptide residue is favoured by the disease-associated subtype HLA-B*27:05, but not by HLA-B*27:09. This property appears also as the only common denominator of distinct HLA class I alleles, among them HLA-B*27:05, HLA-A*03:01 or HLA-A*11:01, that are associated with diseases suspected to have an autoimmune etiology. We postulate here that the products of these alleles, due to their unusual ability to bind with high affinity to a particular peptide set during positive T cell selection in the thymus, are involved in shaping an abnormal T cell repertoire which predisposes to the acquisition of autoimmune diseases.     

Natural MHC class I polymorphism controls the pathway of peptide dissociation from HLA-B27 complexes

Analysis of antigen dissociation provides insight into peptide presentation modes of folded human leukocyte antigen (HLA) molecules, which consist of a heavy chain, beta2-microglobulin (beta2m), and an antigenic peptide. Here we have monitored peptide-HLA interactions and peptide dissociation kinetics of two HLA-B27 subtypes by fluorescence depolarization techniques. A single natural amino-acid substitution distinguishes the HLA-B*2705 subtype that is associated with the autoimmune disease ankylosing spondylitis from the non-disease-associated HLA-B*2709 subtype. Peptides with C-terminal Arg or Lys represent 27% of the natural B*2705 ligands. Our results show that dissociation of a model peptide with a C-terminal Lys (GRFAAAIAK) follows a two-step mechanism. Final peptide release occurs in the second step for both HLA-B27 subtypes. However, thermodynamics and kinetics of peptide-HLA interactions reveal different molecular mechanisms underlying the first step, as indicated by different activation energies of 95+/-8 kJ/mol (HLA-B*2705) and 150+/-10 kJ/mol (HLA-B*2709). In HLA-B*2709, partial peptide dissociation probably precedes fast final peptide release, while in HLA-B*2705 an allosteric mechanism based on long-range interactions between beta2m and the peptide binding groove controls the first step. The resulting peptide presentation mode lasts for days at physiological temperature, and determines the peptide-HLA-B*2705 conformation, which is recognized by cellular ligands such as T-cell receptors.     

A Yersinia pseudotuberculosis protein which cross-reacts with HLA-B27

The most-debated question in the investigation of the spondyloarthropathies has been whether there is molecular mimicry between host HLA-B27 antigens and the arthritis-causing pathogens. We have generated a monoclonal anti-HLA-B27 antibody in our laboratory and have used a radioimmunoassay to screen a panel of bacterial species. Two strains of Yersinia pseudotuberculosis were found to be highly reactive. The cross-reactive Yersinia component was identified by Western blot to be a 19,000 component. A preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis chromatography apparatus was constructed to isolate milligram quantities of this component. To verify that the component carried the HLA-B27-specific epitope, rabbits were hyperimmunized with the purified materials. Affinity-purified antibodies from one of the immunized rabbits indeed carried anti-HLA-B27 activity. Last, antibodies generated against synthetic peptides derived from the HLA-B27.1 amino acid sequence were tested against the Yersinia component. Positive reactivity was found with antibodies generated against a peptide spanning residues 69-83 of the HLA-B27.1 protein. Since this resides in the segment responsible for the allotypic specificity of the antigen, these experiments establish the presence of molecular mimicry to a high degree of confidence.