Role of polymorphic residues of human leucocyte antigen-DR molecules on the binding of human immunodeficiency virus peptides.

A study was made of the binding properties of 96 human immunodeficiency virus peptides to human leucocyte antigen (HLA)-DR1 and HLA-DR103 molecules, which differ by three amino acids at positions 67, 70 and 71 in the beta chains. The affinity of the peptides was characterized by their inhibitory concentrations in competitive binding assays which displace half of the labelled influenza haemagglutinin peptide HA306-318 (IC50). Among the high-affinity peptides (IC50 < or = 1 microM), seven bound to DR1, three to DR103 and five equally well to both alleles (promiscuous peptides). Thirty-two other peptides showed medium or low affinity for DR molecules. The role of polymorphic residues was analysed using six mutated DR molecules, intermediates between DR1 and DR103 and differing by one or two substitutions at positions 67, 70 or 71. We reached the same conclusions when using DR1-specific or DR103-specific peptides: modification of residue 70 had no effect on peptide affinity, but single substitution at positions 67 or 71 decreased the allele specificity of the peptides while double substitution at 67 and 71 completely reversed the peptide specificity. In functional assays, DR-binding peptides are able to outcompete specific T-cell proliferation. Furthermore, modification at position 67 or 70 significantly affects the T-cell response and mutation at position 71 abolishes completely the T-cell proliferation. Thus, the polymorphic positions 67 and 71 contributed to the peptide binding with direct effects on T-cell receptor (TCR) recognition while position 70 seems to be mostly engaged in TCR interactions. Furthermore, our results suggest that polymorphic residues may select allele-specific peptides and also influence the conformation of promiscuous peptides.

Position 71 in the alpha helix of the DR beta domain is predicted to influence peptide binding and plays a central role in allorecognition.

Despite all the structural and functional data that have been accumulated regarding major histocompatibility complex (MHC) class II molecules during recent years, the relative contribution of putative T cell receptor (TcR)-contacting residues and peptide-binding MHC polymorphisms to MHC-restricted and allospecific T cell responses remains a point of contention. Some authors emphasize the importance of direct interaction between the allospecific TcR and polymorphic MHC residues whereas other emphasize the role of naturally processed MHC-bound peptides. We have previously described a new HLA-DRB1 allele: DR BON (DRB1*0103). This gene differs from DRB1*0101 by six base pairs clustered in the third variable region of the second exon leading to three amino acid changes at positions 67, 70 and 71 of the beta chain of the HLA-DR molecule. To define the respective role of these residues in allorecognition, we have performed site-directed mutagenesis on the DRB1*0103 allele to create six mutants which are intermediary between the DR BON and the DR1 alleles. These mutant cDNA were expressed in mouse fibroblasts and the transfectants with the highest expression of class II molecules were used as stimulators for a panel of ten anti-DR BON and five anti-DR1 alloreactive T cell clones. We demonstrate that the residue at the peptide-binding position 71 is of paramount importance in the alloresponse of these clones. In addition some clones were sensitive to amino acid substitution at the TcR-contacting position 70, while substitution at position 67 affects very few clones. The dominance of residue 71 was also observed with an influenza hemagglutinin-specific HLA-DR BON-restricted T cell line.

Clonality of T lymphocytes expanded with IL-2 from rheumatoid arthritis peripheral blood, synovial fluid and synovial membrane.

The association of rheumatoid arthritis (RA) with particular MHC class II genes suggests that autoantigen-specific T cell clones present in joints could be central to the pathogenesis of the disease. Previous investigations on the clonal diversity of T cells infiltrating the rheumatoid synovial membrane have yielded conflicting results. With the use of Southern blot analysis, we investigated the clonality of rheumatoid T cell lines expanded from peripheral blood, synovial fluid and synovial tissue. From peripheral blood lymphocyte (PBL) of RA patients and healthy normal controls, we also checked the consequences of two different culture conditions on the clonality of these cell lines. From control PBL, we found that in vitro non-specific expansion of non-clonal T cell populations does not create artefactual clonal selection. However, growing T cells in vitro with IL-2 seems to be able to lead to preferential expansion of cells bearing IL-2 receptor (IL-2R). We identified such in vivo activated IL-2-sensitive T cell clones frequently in RA synovial tissue (8/13) and more rarely in synovial fluid and peripheral blood (3/12). One patient presents the same T cell receptor gene rearrangements in synovial membrane of two affected joints. In RA synovial tissue, the frequency of these IL-2-responsive T cells is most prevalent among actively inflamed membranes removed early in the disease process. The role and the relevance to the disease of these IL-2-responsive T cells remain to be elucidated.

Comparison of TCR-alpha beta sequences of cross-reactive anti-DR alloreactive T-cell clones: identification of possible contact residues based on charge complementarity between TCR chains and DR determinants.

We analysed alloreactive T-cell clones selected for their differential recognition of DR variants differing in the third hypervariable region (hvr) of the DRB1 gene (amino acid positions 67-70-71). This polymorphism leads to two main hvr3 types: a basic form (Leu67-Gln70-Arg/Lys71) and an acidic form (Ile67-Asp70-Glu71) where residue 70 is probably directly accessible to the TCR on DR beta chains. The TCRs have been sequenced. Three DRw13-reactive clones use similar V alpha 2 and V beta 13 gene family members but differ mainly by their cross-reactivity towards acidic or basic DR4 variants and by the sequence of CDR3 on their TCR alpha and/or beta chains. One anti-DRw13 clone cross-reacts with most specificities sharing the DRw13 type of hvr3 and reciprocally one anti-DRBon (DRB1*0103) clone cross-reacts with DRw13. These two clones use similar V beta genes and share negative charges in CDR2 alpha at position 56. They also share these negative charges in CDR2 alpha with two other clones reacting specifically with DRBon, the acidic variant of DR1. We hypothesized that the selective recognition of positively or negatively charged residues on the DR beta chain would necessitate reciprocal charges on the TCR complementarity determining regions (CDRs) responsible for this interaction. This facilitated identification of those residues of the TCR that possibly interact with the hvr3 determinant of HLA-DR. From these observations the mechanisms allowing the recognition of alloantigens by these T-cell clones are discussed.

Extended HLA-DQw2 haplotypes: molecular analysis.

The HLA-DQw2 specificity, homogeneous in serology, is strongly associated to two HLA-DR specificities: DR3 and DR7. These alleles are found mainly on DQw2 bearing extended haplotypes with strong linkage disequilibrium. We describe, with BamHI, HindIII and RsaI, two restriction fragments length polymorphisms (RFLP) for the A gene of DQw2. These two subtypes correlated with the DR3 and DR7 specificities. Interestingly, by non-equilibrium pH gradient electrophoresis (NEPHGE), two DQ alpha chains were also found, respectively correlated with the same DR specificities. In addition, HincII polymorphism allowed us to distinguish several patterns of B genes for (DR7) DQw2 haplotypes but without any detectable association with another HLA marker. However, only one DQ beta chain was found by NEPHGE in the (DR7) DQw2 haplotype. Furthermore, HincII discriminated the B genes of the two extended haplotypes: (B8, DR3) DQw2 and (B18, DR3) DQw2. The same result was found by NEPHGE: two DQ beta chains were described, corresponding to the same extended haplotypes. The use of exon-specific DQB probes showed that the genomic polymorphism in DQw2 haplotypes is located, at least, at the 3' end of the gene. These data add new characteristics to the different DQw2 extended haplotypes.

Evolution of the HLA-DR1 gene family. Structural and functional analysis of the new allele "DR-BON".

The molecules of the MHC are highly polymorphic and involve in Ag presentation; their striking genetic polymorphism allows probable interactions with a large variety of antigenic fragments when these are presented to the TCR. It is therefore of interest to explore the extent of this polymorphism and the mechanisms of its generation. We have studied the class II HLA-DR blank allele DR-BON that has been previously defined by MLR, restriction fragment length polymorphism, and two-dimensional gel electrophoresis. A cDNA library was constructed from a DR-BON homozygous typing cell and cDNA corresponding to DR alpha- and DR beta-chains were sequenced. By comparison with other known alpha- and beta-chain sequences it is shown that the alpha-chain is invariant and the beta-chain differs from DR1 by only six nucleotides, clustered in the third variable region with three amino acid changes at position 67, 70, and 71. The short DNA stretch of sequence encoding the 67-71 region is also present in other DR alleles: DR4/Dw10, DRw13, and some DRw11 specificities. Therefore we propose that a gene conversion-like event has occurred between the DRB1 *0101 (DR1/Dw1) gene and one of these three DRB1 genes. Extensive typing has been performed with a DR-BON-specific 17-mer oligonucleotide. Cross-hybridization with other genes than the ones expected from DNA sequence comparison was not observed. A selected panel of DR-BON reactive T cell clones shows three patterns of reactivity. Some clones are strictly DR-BON specific; some cross-reacted with DRw13 and a few cross-reacted with other haplotypes. The role of different epitopes of the third variable region of HLA-DR beta chain in allo-reaction is discussed.

Nature of polymorphism in HLA-A, -B, and -C molecules.

Diversity in 39 HLA-A, -B, and -C molecules is derived from 20 amino acid positions of high variability and 71 positions of low variability. Variation in the structurally homologous alpha 1 and alpha 2 domains is distinct and may correlate with partial segregation of peptide and T-cell receptor binding functions. Comparison of 15 HLA-A with 20 HLA-B molecules reveals considerable locus-specific character, due primarily to differences at polymorphic residues. The results indicate that genetic exchange between alleles of the same locus has been a more important mechanism in the generation of HLA-A, -B, and -C diversity than genetic exchange events between alleles of different loci.

Absence of polymorphism between HLA-B27 genomic exon sequences isolated from normal donors and ankylosing spondylitis patients.

Ninety percent of individuals with ankylosing spondylitis (AS) express HLA-B27. To determine if HLA-B27 coding sequences from normal vs AS individuals show differences that might relate to the etiology of the disease, the gene coding for this allele was cloned from three different partial genomic libraries. These libraries were made with DNA from three different cell lines expressing HLA-B27: MRWC (HLA-B27, 14), obtained from an AS patient; KCA (HLA-B27, w44), obtained from a known normal individual; and MVL (HLA-B27, 27), a homozygous consanguineous cell line of unknown origin. To increase the number of clones coding for the HLA-B locus, partial libraries were made using a complete Eco RI digestion of genomic DNA in the lambda vector 607. The libraries were screened with two probes; one probe hybridizes to all HLA-A, B, C class I genes, and the other to a small subpopulation of class I genes, including the B locus. DNA from clones hybridizing with both probes was transfected into murine L cells. Cell surface expression of HLA-B27 on murine L cells was detected with a polymorphic monoclonal antibody (ME1) specific for HLA-B27, 7, 22. DNA from those clones positive for HLA-B27 by transfection was subcloned into the Xba I site of M13mp18 and the DNA sequence for exons 2 through 4 (encoding domains alpha 1, alpha 2, and alpha 3) was determined by the dideoxy technique by using synthetic oligonucleotide primers or the M13 primer. The resulting sequences show no difference between HLA-B27 alpha 1, alpha 2, alpha 3 domains from a known AS patient and a known normal individual.

HLA-B locus polymorphism: studies with a specific hybridization probe.

The large number of class I histocompatibility genes (HLA) and their extensive homology has made it difficult to assign bands on genomic Southern blots to known genes. Therefore, we have tried to obtain nucleic acid probes for class I genes that are locus specific or have restricted locus specificity. Computer sequence-homology analysis was used to compare the nucleic acid sequences of two genomic clones, one coding for the HLA-B7 antigen (JY150) and one containing a class I pseudogene (pHLA12.4). A sequence in the 3' untranslated region with very low homology was identified. This sequence from the HLA-B7 gene was subcloned into M13 phage. This fragment, JY150/C5, hybridized with two genomic bands in DNA from human HLA homozygotes--presumably the HLA-B locus gene and a closely related gene. The probe was used to assess restriction fragment polymorphism at the HLA-B locus in homozygous consanguineous cell lines. This analysis permitted the association of certain polymorphic restriction enzyme fragments with some alleles of this locus. However, many HLA-B alleles have identical restriction fragments produced by a number of restriction endonucleases.

The complete primary structure of HLA-Bw58.

Serological studies indicate that HLA-B17 molecules are unusually cross-reactive with products of the HLA-A locus. In particular, a mouse monoclonal antibody MA2.1 defines an epitope that is shared by HLA-A2 and the two subtypes (Bw57 and Bw58) of B17. To investigate these relationships at the structural level, we have isolated a gene coding for Bw58 from the WT49 B cell line. The gene was transfected into mouse L cells and its protein product was characterized with a panel of monoclonal anti-HLA antibodies. The nucleotide sequence of 3520 base pairs of DNA encompassing the seven exons coding for Bw58 and associated introns was determined. The deduced protein sequences for Bw58 and eight other HLA-A,B,C molecules were compared. In the first polymorphic domain (alpha 1), Bw58 is unusual in that it is as homologous to HLA-A locus products as to HLA-B locus products. In the second polymorphic domain (alpha 2), Bw58 has greater homology to B locus products. In the alpha 1 domain of Bw58, small segments of amino acid and nucleotide sequence homology with A2 (residues 62-65) and with Aw24 (residues 75-83) are found in the major region of polymorphic diversity (residues 62-83). These similarities provide structural correlates for the serological relationships between Bw58 and A locus molecules, with residues 62-65 possibly being involved in the MA2.1 epitope. From comparisons of four HLA-A and four HLA-B sequences, there is a difference in the patterns of variation for A and B locus molecules. For B locus molecules there is greater variation in the alpha 1 domain than in the alpha 2 domain. For A locus molecules, variation in the two domains is similar and like that for B locus alpha 2 domains. In comparison to other HLA-A,B,C genes, novel inverted repeat sequences were found in the nucleotide sequence of HLA-Bw58. These sequences flank the putative RNA splicing sites at the 3' end of the exons encoding the alpha 2 and alpha 3 protein domains.