Primordial linkage of β2-microglobulin to the MHC

β2-Microglobulin (β2M) is believed to have arisen in a basal jawed vertebrate (gnathostome) and is the essential L chain that associates with most MHC class I molecules. It contains a distinctive molecular structure called a constant-1 Ig superfamily domain, which is shared with other adaptive immune molecules including MHC class I and class II. Despite its structural similarity to class I and class II and its conserved function, β2M is encoded outside the MHC in all examined species from bony fish to mammals, but it is assumed to have translocated from its original location within the MHC early in gnathostome evolution. We screened a nurse shark bacterial artificial chromosome library and isolated clones containing β2M genes. A gene present in the MHC of all other vertebrates (ring3) was found in the bacterial artificial chromosome clone, and the close linkage of ring3 and β2M to MHC class I and class II genes was determined by single-strand conformational polymorphism and allele-specific PCR. This study satisfies the long-held conjecture that β2M was linked to the primordial MHC (Ur MHC); furthermore, the apparent stability of the shark genome may yield other genes predicted to have had a primordial association with the MHC specifically and with immunity in general.     

Does the polymorphism of MHC class II promoters matter?

The promoters of genes of the major histocompatibility complex vary not only because of linkage disequilibrium with their coding sequences but also, we argue, because of natural selection that acts particularly strongly on MHC II gene promoters. Thus, the promoter of H2Eb varies more than that of H2K, to an extent that cannot be accounted for by coding variation, and the same applies to HLA.DRB1 in comparison with H2D. We discuss how transduction by lentivirus vectors followed by adoptive transfer of monoclonal T cells could be used to test the functional activity of variant mouse promoters in vivo, and how homologous recombination in suitable cell lines might provide a short cut to obtaining promoter knock-ins.     

Physical mapping and evolution of the centromeric class I gene-containing region of the rat MHC

We physically mapped the centromeric part of the BN rat MHC (RT1n haplotype) in a contig of overlapping P1-derived artificial chromosome (PAC) clones encompassing about 300 kb. The following genes were identified and ordered as: (Syngap, Hset, Daxx, Bing1)-Tapbp-Rgl2-Ke2-Bing4-B3galt4- Rps18-Sacm2l-RT1-A1-RT1-A2-RT1-A3-Ring1-Ring2-++ +Ke4-Rxrb-Col11a2-RT1-Hb-Ring3-RT1-DMb. Thus, in contrast to other RT1 haplotypes, RT1n contains three class I genes, RT1-A1, RT1-A2, and RT1-A3, mapping between the Sacm2l and Ring1 genes. Comparisons of the sequences flanking the Sacm2L and Ring1 genes in rat, human, and mouse suggest that the class I gene-containing region was inserted between these genes in rat and mouse at a similar position. Thus, this insertion is likely to have occurred in a common ancestor of these rodents, although the presence of a site particularly permissive for insertions cannot be excluded.     

Characterization of the MHC class I region of the Japanese pufferfish (Fugu rubripes)

A BAC map of the Japanese pufferfish (Fugu) MHC class I region was constructed using a mixture of sequence scanning and sequence-tagged site mapping methodologies. The Fugu MHC class Ia genes are linked to genes which are found within the human classical MHC class II and extended class II regions, a situation which has been found in the MHC of all teleosts mapped so far. The 300-kb contig comprises 24 MHC-related genes and is bounded by six non-MHC genes, which are thought to represent an evolutionary breakpoint within the region. Comparative analysis with both human and zebrafish MHC maps indicates two blocks of genes (KNSL2, ZNF297, DAXX, TAPBP, FLOTILLIN; and PSMB8, PSMB10, PSMB9, ABCB3, FABGL, BRD2, COL11A2, RXRB) which have remained linked over 400 million years and may represent an ancestral arrangement of the vertebrate MHC. Zebrafish and Fugu diverged between 100-200 million years ago and differences exist between these two fish species. The position and number of MHC class Ia genes is not conserved between species, there is an inversion of a block of nine genes centering on the PSMB cluster, and additional genes are present in zebrafish coding for a transport-associated protein and a beta proteasome subunit. The extent of these differences has implications for the extrapolation of fish model organism data to commercial aquaculture species. The data presented here represent the most extensive analysis of a fish MHC class Ia region described so far and clearly delimit the extent of this region in Fugu and, potentially, all teleosts.     

Characterization of the MHC class II ��-chain gene in ducks

In humans, classical MHC class II molecules include DQ, DR, and DP, which are similar in structure but consist of distinct α- and β-chains. The genes encoding these molecules are all located in the MHC class II gene region. In non-mammalian vertebrates such as chickens, only a single class II α-chain gene corresponding to the human DRA has been identified. Here, we report a characterization of the duck MHC class II α-chain (Anpl-DRA) encoding gene, which contains four exons encoding a typical signal peptide, a peptide-binding α1 domain, an immunoglobulin-like α2 domain, and Tm/Cyt, respectively. This gene is present in the duck genome as a single copy and is highly expressed in the spleen. Sequencing of cDNA and genomic DNA of the Anpl-DRA of different duck individuals/strains revealed low levels of genetic polymorphism, especially in the same strain, although most duck individuals have two different alleles. Otherwise, we found that the duck gene is located next to class II β genes, which is the same as in humans but different from the situation in chickens.     

Exploiting the Peptide — MHC Water Interface in the Computer-Aided Design of Non-Natural Peptides that Bind to the Class I MHC Molecule HLA-A2

Abstract

Class I major histocompatibility complex (MHC) molecules bind peptides derived from intra-cellular proteins and present them to cytotoxic T cells. Certain human immunological diseases are associated with errors in this process. Here we describe an approach to the design of non-natural peptides that could potentially interfere with peptide presentation associated with autoimmune diseases. We have shown previously that the interaction of the peptide GILGFVFTL with the MHC molecule HLA-A2 is mediated by a network of water molecules. In principle, the addition of hydroxyl groups to the peptide could allow for an enhanced interaction of the modified peptide with this water network. Here we illustrate this approach using a peptide having the non-natural amino acid homoserine at position 3, GIhSGFVFTL, and also peptides in which the Cα(F5)—CO—NH1—Cα(V6) peptide bond is replaced by an ether. Cα(F5)—CH(X)—O—Cα(V6), to give the non-natural peptide GILGF—CH(X)—O—VFTL, where X = CH₂OH or CH₃. In a 200 ps solvated molecular dynamics simulation of the HLA-A2 complexes of each peptide for GIhSGFVFTL and GILGF—CH(CH₂OH)—O—VFTL the peptide conformation remained essentially unchanged from that of GILGFVFTL in the X-ray structure of its complex with HLA-A2. In contrast, for GILGF—CH(CH₃)—O—VFTL the peptide conformation deviated from the X-ray conformation, indicating the importance of the hydroxyl group.     

Why does the immune system of Atlantic cod lack MHC II?

MHC II, a major feature of the adaptive immune system, is lacking in Atlantic cod, and there are different scenarios (metabolic cost hypothesis or functional shift hypothesis) that might explain this loss. The lack of MHC II coincides with an increased number of genes for MHC I and Toll-like receptors (TLRs).     

Characterization of the MHC class I-related MR1 locus in nonhuman primates

We characterized the MHC-related 1 ( MR1) locus in two nonhuman primates species, Pongo pygmaeus and Pan troglodytes. MR1 cDNA sequences encoding several isoforms generated through alternative splicing were observed in both species. Amino acid alignment between the five species in which MR1 has been characterized to date - human, chimpanzee, orangutan, mouse, and rat - reveals a very high degree of conservation specially in the alpha1 and alpha2 domains of the molecule. The main differences concentrate in the transmembrane and cytoplasmic domains. In the three primates species there is a lysine residue inside the putative transmembrane domain which is not present in rodents. Furthermore, the MR1 cytoplasmic region is longer in rodents, with a conserved serine-containing motif that could be involved in endocytosis; remarkably, this motif is absent in the three primate species. We also describe the presence in the chimpanzee of a sequence homologous to the MR1P1 pseudogene previously found in humans.     

Remarkable sequence conservation of theHLA-DQB2 locus (DXβ) within the highly polymorphicDQ subregion of the human MHC

TheHLA-D region of the major histocompatibility complex (MHC) is characterized by a remarkable diversity. Most of theHLA class II genes are highly polymorphic, and in addition, the number and organization of individual loci in that region varies in different haplotypes. This extensive allelic polymorphism of immune response genes has well-known functional implications. Within theHLA-D region, two loci,DQA2 andDQB2 (formerly calledDX andDX), represent a very special case: the detailed structure of these two genes is entirely compatible with expression, yet their expression has never been demonstrated in any tissue. Consequently, there exists no known corresponding protein product. Pseudogenes are known to accumulate mutations, as observed for instance in the case ofHLA-DPA2,-DPB2, or-DRB2 genes. We have therefore investigated the extent of DQ2 genes' polymorphism by DNA sequence comparison and by oligonucleotide hybridization across a large number of different haplotypes, and compared it with other genes in theHLA-D region. We show here that, contrary to the adjacentDQ1 genes,DQ2 genes exhibit little and possibly no polymorphism. This conservation ofDQ2 genes in many haplotypes indicates that the DQ 1-DQ2 duplication event must have preceeded the extensive diversification ofDQ1 genes and raises the puzzling question of whyDQ2 genes have remained nonpolymorphic. This suggests that either these genes correspond to an unusually invariant region of the MHC or they are under a strong selective pressure for the conservation of the amino acid sequence of a putative DQ2 gene product. The latter would imply that theHLA-DQ2 genes are expressed into a protein product endowed with essential functional properties.     

Concerted evolution in a segment of the first domain exon of polymorphic MHC class II β loci

Genetic exchange of sequence information between members of a gene family, generally denoted gene conversion, causes a phenomenon called concerted evolution meaning that non-allelic genes do not evolve independently. The possible significance of this phenomenon in the evolution of major histocompatibility complex (MHC) class II genes has been investigated in the present study. The results of a phylogenetic analysis of human, mouse, bovine, and chicken class II sequences were consistent with the occurrence of gene conversion between polymorphic class II genes (i. e. DPB, DQB, and DRB) but not between these genes and the monomorphic DOB gene or between class II genes. Gene conversion between polymorphic genes appears to be restricted to a gene segment between approximately nucleotide positions 94–286 in the first domain exon. Due to this genetic exchange, there is a greater interlocus similarity both at the DNA and protein level in this region than in the rest of the sequence. The region encodes a functionally important part of the class II molecule including more than half of the -chain residues of the antigen binding site and the residues in the helix assumed to form contact with the T-cell receptor. The observed similarity in the -helical region of class II molecules may be functionally significant for the utilization of the T-cell repertoire for antigen recognition in the immune system.     

The β2-microglobulin-free heterodimerization of rhesus monkey MHC class I A with its normally spliced variant reduces the ubiquitin-dependent degradation of MHC class I A

The MHC class I (MHC I) molecules play a pivotal role in the regulation of immune responses by presenting antigenic peptides to CTLs and by regulating cytolytic activities of NK cells. In this article, we show that MHC I A in rhesus macaques can be alternatively spliced, generating a novel MHC I A isoform (termed "MHC I A-sv1") devoid of α(3) domain. Despite the absence of β2-microglobulin (β2m), the MHC I A-sv1 proteins reached the cell surface of K562-transfected cells as endoglycosidase H-sensitive glycoproteins that could form disulfide-bonded homodimers. Cycloheximide-based protein chase experiments showed that the MHC I A-sv1 proteins were more stable than the full-length MHC I A in transiently or stably transfected cell lines. Of particular interest, our studies demonstrated that MHC I A-sv1 could form β2m-free heterodimers with its full-length protein in mammalian cells. The formation of heterodimers was accompanied by a reduction in full-length MHC I A ubiquitination and consequent stabilization of the protein. Taken together, these results demonstrated that MHC I A-sv1 and MHC I A can form a novel heterodimeric complex as a result of the displacement of β2m and illustrated the relevance of regulated MHC I A protein degradation in the β2m-free heterodimerization-dependent control, which may have some implications for the MHC I A splice variant in the fine tuning of classical MHC I A/TCR and MHC I A/killer cell Ig-like receptor interactions.     

Comparative and evolutionary analysis of the rhesus macaque extended MHC class II region

The sequence-based map of a part of the rhesus macaque major histocompatibility complex (MHC) extended class II region is presented. The sequenced region encompasses 67,401 bp and contains the SACM2L, RING1, FABGL and KE4 genes, as well as the HTATSF1-like and ZNF-like pseudogenes. Similar to human, but different from rat and mouse, no class I genes are found in the SACM2L- RING1 interval. The rhesus macaque extended MHC class II region shows a high degree of conservation of exonic as well as intronic and intergenic sequences compared with the respective human region. It is concluded that this particular genomic organization of the extended class II region-i.e., the absence of class I genes and the presence of the HTATSF1-like and ZNF-like pseudogenes-can be traced back to a common ancestor of humans and rhesus macaques about 23 million years ago.     

Dynamics of free versus complexed β2-microglobulin and the evolution of interfaces in MHC class I molecules

In major histocompatibility complex (MHC) class I molecules, monomorphic β₂-microglobulin (β₂m) is non-covalently bound to a heavy chain (HC) exhibiting a variable degree of polymorphism. β₂M can stabilize a wide variety of complexes ranging from classical peptide binding to nonclassical lipid presenting MHC class I molecules as well as to MHC class I-like molecules that do not bind small ligands. Here we aim to assess the dynamics of individual regions in free as well as complexed β₂m and to understand the evolution of the interfaces between β₂m and different HC. Using human β₂m and the HLA–B*27:09 complex as a model system, a comparison of free and HC-bound β₂m by nuclear magnetic resonance spectroscopy was initially carried out. Although some regions retain their flexibility also after complex formation, these studies reveal that most parts of β₂m gain rigidity upon binding to the HC. Sequence analyses demonstrate that some of the residues exhibiting flexibility participate in evolutionarily conserved β₂m–HC contacts which are detectable in diverse vertebrate species or characterize a particular group of MHC class I complexes such as peptide- or lipid-binding molecules. Therefore, the spectroscopic experiments and the interface analyses demonstrate that β₂m fulfills its role of interacting with diverse MHC class I HC as well as effector cell receptors not only by engaging in conserved intermolecular contacts but also by falling back upon key interface residues that exhibit a high degree of flexibility.     

Interferon-γ Induces Immunoproteasomes and the Presentation of MHC I-Associated Peptides on Human Salivary Gland Cells

A prominent histopathological feature of Sjögren''s syndrome, an autoimmune disease, is the presence of lymphocytic infiltrates in the salivary and lachrymal glands. Such infiltrates are comprised of activated lymphocytes and macrophages, and known to produce multiple cytokines including interferon-gamma (IFN-γ). In this study, we have demonstrated that IFN-γ strongly induces the expression of immunoproteasome beta subunits (β1i, β2i and β5i) and immunoproteasome activity but conversely inhibits the expression of proteasome beta subunits (β1, β2 and β5) in human salivary gland (HSG) cells. Mass spectrometric analysis has revealed potential MHC I-associated peptides on the HSG cells, including a tryptic peptide derived from salivary amylase, due to IFN-γ stimulation. These results suggest that IFN-γ induces immunoproteasomes in HSG cells, leading to enhanced presentation of MHC I-associated peptides on cell surface. These peptide-presenting salivary gland cells may be recognized and targeted by auto-reactive T lymphocytes. We have also found that lactacystin, a proteasome inhibitor, inhibits the expression of β1 subunit in HSG cells and blocks the IFN-γ-induced expression of β1i and immunoproteasome activity. However, the expression of β2i and β5i in HSG cells is not affected by lactacystin. These results may add new insight into the mechanism regarding how lactacystin blocks the action of proteasomes or immunoproteasomes.     

Historical and contemporary selection of teleost MHC genes: did we leave the past behind?

The extreme polymorphism of antigen‐presenting genes of the major histocompatibility complex (MHC) has spurred intense research unparalleled for any other gene family. This applies also to teleosts where sequence information is available for 3559 MHC class I and class II allelic variants from 137 species. This review summarizes current knowledge on the origin and maintenance of diversity at classical MHC loci. Most studies identified positive selection (i.e. elevated rates of non‐synonymous over synonymous substitutions, dN/dS) as a sign of balancing selection. A meta‐analysis on nine species with sufficient numbers of class I and class II sequences revealed that recombination rate and intensity of positive selection were positively correlated, suggesting that recombination and gene conversion played a significant role in shaping the allelic repertoire. Processes that create diversity over long timescales need to be complemented by contemporary balancing selection, either through overdominance or frequency‐dependent selection, in order to explain the high allelic diversity observed today. While some evidence for overdominance exists for a few taxa (mainly salmonids) by correlating parasite infection data or survival to MHC genotypes, field or experimental data on negative frequency‐dependent selection are lacking altogether, even though some fish species are particularly suitable as model systems. Theoretical predictions suggest that negative frequency‐dependent selection is necessary to maintain the existing polymorphism. Hence, future empirical studies should focus on detecting signals that differentiate between mechanisms of contemporary selection rather than repeatedly showing historical selection events.