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Compared with the MHC of typical mammals, the chicken MHC is smaller and simpler, with only two class I genes found in the B12 haplotype. We make five points to show that there is a single-dominantly expressed class I molecule that can have a strong effect on MHC function. First, we find only one cDNA for two MHC haplotypes (B14 and B15) and cDNAs corresponding to two genes for the other six (B2, B4, B6, B12, B19, and B21). Second, we find, for the B4, B12, and B15 haplotypes, that one cDNA is at least 10-fold more abundant than the other. Third, we use 2D gel electrophoresis of class I molecules from pulse-labeled cells to show that there is only one heavy chain spot for the B4 and B15 haplotypes, and one major spot for the B12 haplotype. Fourth, we determine the peptide motifs for B4, B12, and B15 cells in detail, including pool sequences and individual peptides, and show that the motifs are consistent with the peptides binding to models of the class I molecule encoded by the abundant cDNA. Finally, having shown for three haplotypes that there is a single dominantly expressed class I molecule at the level of RNA, protein, and antigenic peptide, we show that the motifs can explain the striking MHC-determined resistance and susceptibility to Rous sarcoma virus. These results are consistent with the concept of a \"minimal essential MHC\" for chickens, in strong contrast to typical mammals.

Defining permissive and non-permissive mismatches for transplantation is a demanding challenge. Single mismatches at amino acid (AA) position 156 of human leucocyte antigen (HLA) class I have been described to alter the peptide motif, repertoire, or mode of peptide loading through differential interaction with the peptide-loading complex. Hence, a single mismatch can tip the balance and trigger an immunological reaction. HLA-B*35 subtypes have been described to evade the loading complex, 156 mismatch distinguishing B*35:01 and B*35:08 changes the binding groove sufficiently to alter the sequence features of the selected peptide repertoire. To understand the functional influences of residue 156 in B*35 variants, we analyzed the peptide binding profiles of HLA-B*35:01 156Leu , B*35:08 156Arg and B*35:62 156Trp . The glycoprotein tapasin represents a target for immune evasions and functions within the multimeric peptide-loading complex to stabilize empty class I molecules and promote acquisition of high-affinity peptides. All three B*35 subtypes showed a tapasin-independent mode of peptide acquisition. HLA-B*35-restricted peptides of low- and high-binding affinities were recovered in the presence and absence of tapasin and subsequently sequenced utilizing mass spectrometry. The peptides derived from B*35 variants differ substantially in their features dependent on their mode of recruitment; all peptides were preferentially anchored by Pro at p2 and Tyr, Phe, Leu, or Lys at pΩ. However, the Trp at residue 156 altered the p2 motif to an Ala and restricted the pΩ to a Trp. Our results highlight the importance of understanding the impact of key micropolymorphism and how a single AA mismatch orchestrates the neighboring AAs.

Chinese rhesus macaques are of particular interest in simian immunodeficiency virus/human immunodeficiency virus (SIV/HIV) research as these animals have prolonged kinetics of disease progression to acquired immunodeficiency syndrome (AIDS), compared to their Indian counterparts, suggesting that they may be a better model for HIV. Nevertheless, the specific mechanism(s) accounting for these kinetics remains unclear. The study of major histocompatibility complex (MHC) molecules, including their MHC/peptide-binding motifs, provides valuable information for measuring cellular immune responses and deciphering outcomes of infection and vaccine efficacy. In this study, we have provided detailed characterization of six prevalent Chinese rhesus macaque MHC class I alleles, yielding a combined phenotypic frequency of 29 %. The peptide-binding specificity of two of these alleles, Mamu-A2*01:02 and Mamu-B*010:01, as well as the previously characterized allele Mamu-B*003:01 (and Indian rhesus Mamu-B*003:01), was found to be analogous to that of alleles in the HLA-B27 supertype family. Specific alleles in the HLA-B27 supertype family, including HLA-B*27:05, have been associated with long-term nonprogression to AIDS in humans. All six alleles characterized in the present study were found to have specificities analogous to HLA supertype alleles. These data contribute to the concept that Chinese rhesus macaque MHC immunogenetics is more similar to HLA than their Indian rhesus macaque counterparts and thereby warrants further studies to decipher the role of these alleles in the context of SIV infection.

The objective of this study was to characterize the peptide-binding motif of the major histocompatibility complex (MHC) class II HLA-DR8 molecule included in the type 1 diabetes-associated haplotype DRB1 * 0801-DQA1 * 0401/DQB1 * 0402 (DR8-DQ4), and compare it with that of other diabetes-associated MHC class II alleles; DR8-bound peptides were eluted from an HLA-DR homozygous lymphoblastoid cell line. The repertoire was characterized by peptide sequencing using a LTQ ion trap mass spectrometer coupled to a multidimensional liquid chromatography system. After validation of the spectra identification, the definition of the HLA-DR8 peptide-binding motif was achieved from the analysis of 486 natural ligands, based on serial alignments of all possible HLA-DR-binding cores. The DR8 motif showed a strong similarity with the peptide-binding motifs of other MHC class II diabetes-associated alleles, HLA-DQ8 and H-2 I-A g7 . Similar to HLA-DQ8 and H-2 I-A g7 , HLA-DR8 preferentially binds peptides with an acidic residue at position P9 of the binding core, indicating that DR8 is the susceptibility component of the DR8-DQ4 haplotype. Indeed, some DR8 peptides were identical to peptides previously identified as DQ8- or I-A g7 ligands, and several diabetes-specific peptides associated with DQ8 or I-A g7 could theoretically bind to HLA-DR8. These data further strengthen the association of HLA-DR8 with type I diabetes.

Position 45 represents a highly polymorphic residue within HLA class I alleles, which contacts the p2 position of bound peptides in 85% of the peptide–HLA structures analyzed, while the neighboring residues 41 and 46 are not involved in peptide binding. To investigate the influence of residue 45 at the functional level, we sequenced peptides eluted from recombinant HLA-B*44:08 41Ala/45Met/46Ala molecules and compared their features with known peptides from B*44:02 41Thr/45Lys/46Glu . While HLA-B*44:02 has an anchor motif of E at the p2 anchor position, HLA-B*44:08 exhibits Q and L as anchor motif. The 45 Met/Lys polymorphism contributes to the alteration in the peptide-binding motif and provides further evidence that mismatches at position 45 should be considered as nonpermissive in a transplantation setting.

Knowledge about the magnitude of individual polymorphism is a critical part in understanding the complexity of comprehensive mismatching. HLA-B*44:09 differs from the highly frequent HLA-B*44:02 allele by amino acid exchanges at residues 77, 80, 81, 82 and 83. We aimed to identify the magnitude of these mismatches on the features of HLA-B*44:09 bound peptides since residues 77, 80 and 81 comprise part of the F pocket which determines sequence specificity at the pΩ position of the peptide. Using soluble HLA technology we determined >200 individual (nonduplicate) self-peptides from HLA-B*44:09 and compared their features with that of the published peptide features of HLA-B*44:02. Both alleles illustrate an anchor motif of E at p2. In contrast to the C-terminal peptide binding motif of B*44:02 (W, F, Y or L), B*44:09-derived peptides are restricted predominantly to L or F. The source of peptides for both alleles is identical (LCL 721.221 cells) allowing us to identify 23 shared peptides. The majority of these peptides however contained the restricted B*44:09 anchor motif of F or L at the pΩ position. Molecular modelling based on the B*44:02 structure highlights that the differences of the C-terminal peptide anchor between both alleles can be explained primarily by the B*44:02 81Ala  > B*44:09 81Leu polymorphism which restricts the size of the amino acid that can be accommodated in the F pocket of B*44:09. These results highlight that every amino acid substitution has an impact of certain magnitude on the alleles function and demonstrate how surrounding residues orchestrate peptide specificity.

The Simian immunodeficiency virus (SIV)-infected Indian rhesus macaque ( Macaca mulatta ) is the most established model of HIV infection and AIDS-related research, despite the potential that macaques of Chinese origin is a more relevant model. Ongoing efforts to further characterize the Chinese rhesus macaques’ major histocompatibility complex (MHC) for composition and function should facilitate greater utilization of the species. Previous studies have demonstrated that Chinese-origin M. mulatta (Mamu) class I alleles are more polymorphic than their Indian counterparts, perhaps inferring a model more representative of human MHC, human leukocyte antigen (HLA). Furthermore, the Chinese rhesus macaque class I allele Mamu -A1*02201 , the most frequent allele thus far identified, has recently been characterized and shown to be an HLA-B7 supertype analog, the most frequent supertype in human populations. In this study, we have characterized two additional alleles expressed with high frequency in Chinese rhesus macaques, Mamu -A1*02601 and Mamu -B*08301 . Upon the development of MHC–peptide-binding assays and definition of their associated motifs, we reveal that these Mamu alleles share peptide-binding characteristics with the HLA-A2 and HLA-A3 supertypes, respectively, the next most frequent human supertypes after HLA-B7. These data suggest that Chinese rhesus macaques may indeed be a more representative model of HLA gene diversity and function as compared to the species of Indian origin and therefore a better model for investigating human immune responses.

There have been several attempts over the years to identify positions in the peptide-binding region (PBR) of human leukocyte antigens (HLA) that influence the specificity of bound amino acids (AAs) at each position in the peptide. Originally, six pockets (A-F) were defined by calculating the surface area of the PBR on the crystal structure of HLA-A2 molecules. More recent crystallographic analyses of a variety of HLA alleles have led to broader pocket definitions. In this study, we examined the peptide-binding specificity of HLA-B*41 alleles and compared our results with the available pocket definitions. By generating recombinant HLA-B molecules and studying the eluted peptides by mass spectrometry and pool sequencing, we detected two different PΩ peptide motifs within the B*41 group: Leu vs Val/Pro. Specificity was dependent on the presence of Leu (B*4102, B*4103, and B*4104) vs Trp (B*4101, B*4105, and B*4106) at AA position 95 in the HLA molecule, whose impact on PΩ has been a subject of controversy in current pocket definitions. In contrast, the Arg97Ser mutation did not affect pocket F binding specificity in B*41 subtypes although residue 97 was previously identified as a modulator of peptide binding for several HLA class I alleles. According to most pocket definitions, this study shows that the Asn80Lys substitution in B*4105 impels the peptide's PΩ anchor toward more promiscuity. Our sequencing results of peptides eluted from HLA-B*41 variants demonstrate the limitations of current pocket definitions and underline the need for an extended peptide motif database for improved understanding of peptide-major histocompatibility complex interactions.

Rhesus and pigtail macaques have proven to be valuable animal models for several important human diseases, including HIV, where they exhibit similar pathology and disease progression. Because rhesus macaques have been extensively characterized in terms of their major histocompatibility complex (MHC) class I alleles, their demand has soared, making them increasingly difficult to obtain for research purposes. This problem has been exacerbated by a continued export ban in place since 1978. Pigtail macaques represent a potential alternative animal model. However, because their MHC class I alleles have not been characterized in detail, their use has been hindered. To address this, in the present study, we have characterized the peptide binding specificity of the pigtail macaque class I allele Mane-A1*082:01 (formerly known as Mane A*0301), representative of the second most common MHC class I antigen detected across several cohorts. The motif was defined on the basis of binding studies utilizing purified MHC protein and panels of single amino acid substitution analog peptides, as well as sequences of peptide ligands eluted from Mane-A1*082:01. Based on these analyses, Mane-A1*082:01 was found to recognize a motif with H in position 2 and the aromatic residues F and Y, or the hydrophobic/aliphatic residue M, at the C-terminus. Finally, analysis of the binding of a combinatorial peptide library allowed the generation of a detailed quantitative motif that proved effective in the prediction of a set of high-affinity binders derived from chimeric SIV/HIV, an important model virus for studying HIV infection in humans.

In the chicken, resistance to lymphomas that form following infection with oncogenic strains of Marek's herpesvirus is strongly linked to the major histocompatibility complex (MHC)-B complex. MHC-B21 haplotype is associated with lower tumor-related mortality compared to other haplotypes including MHC-B13. The single, dominantly expressed class I gene (BF2) is postulated as responsible for the MHC-B haplotype association. We used mass spectrometry to identify peptides and structural modeling to define the peptide binding preferences of BF2*2101 and BF2*1301 proteins. Endogenous peptides (8-12 residues long) were eluted from affinity-purified BF2*2101 and BF2*1301 proteins obtained from transduced cDNA expressed in RP9 cells, hence expressed in the presence of heterologous TAP. Sequences of individual peptides were identified by mass spectrometry. BF2*2101 peptides appear to be tethered at the binding groove margins with longer peptides arching out but selected by preferred residues at positions P3, P5, and P8: X-X-[AVILFP]-X₍₁₋₅₎-[AVLFWP]-X₍₂₋₃₎-[VILFM]. BF2*1301 peptides appear selected for residues at P2, P3, P5, and P8: X-[DE]-[AVILFW]-X₍₁₋₂₎-[DE]-X-X-[ED]-X₍₀₋₄₎. Some longer BF2*1301 peptides likely also arch out, but others are apparently accommodated by repositioning of Arg83 so that peptides extend beyond the last preferred residue at P8. Comparisons of these peptides with earlier peptides derived in the presence of homologous TAP transport revealed the same side chain preferences. Scanning of Marek's and other viral proteins with the BF2*2101 motif identified many matches, as did the control human leukocyte antigen A*0201 motif. The BF2*1301 motif is more restricting suggesting that this allele may confer a selective advantage only in infections with a subset of viral pathogens.