Syrian hamsters express diverse MHC class I gene products

MHC class I glycoproteins are highly diverse in most species. The Syrian hamster has long been thought to express monomorphic MHC class I molecules and thus be an exception to this rule. Here we show that Syrian hamsters express diverse MHC class I gene products. The nucleotide sequences of the alpha 1 and alpha-2 domains of classical Syrian hamster MHC class I molecules are highly variable and show evidence of having been under selective pressures at their Ag recognition sites. Interestingly, none of the Syrian hamster class I genes was closely related to their counterparts in the mouse. These observations suggest that Syrian hamsters in the wild may express diverse MHC class I molecules.     

Unusually limited nucleotide sequence variation of the expressed major histocompatibility complex class I genes of a New World primate species (Saguinus oedipus)

Although major histocompatibility complex (MHC) class I molecules are, as a rule, highly polymorphic in mammalian species, those of the New World primate Saguinus oedipus (cotton-top tamarin) exhibit limited polymorphism. We have cloned and sequenced twelve MHC class I cDNAs from this species. Since cloned cotton-top tamarin cell lines express three to six MHC class I molecules, this species must have at least three functional MHC class I loci. There was, however, no evidence of locus-specific substitutions in the tamarin cDNAs. Unlike all other species studied, tamarin MHC class I cDNAs displayed limited nucleotide sequence variation. The sequence similarity between the two most divergent tamarin cDNAs was 95%. To ensure that the polymerase chain reaction (PCR) primers employed in these studies had amplified all of the tamarins' expressed MHC class I genes, we used another set of primers to amplify only exons 2 and 3 from RNA and DNA. PCR of genomic DNA resulted in the amplification of six distinct clones, of which only three were well expressed. Two of these nonexpressed genes were pseudogenes and the other was a nonclassical gene. Southern blot analysis demonstrated that the tamarin has 8–11 MHC class I genes, suggesting we had indeed cloned the majority of these genes. Cotton-top tamarins are, therefore, unique among mammalian species studied to date in that they express MHC class I molecules with limited nucleotide sequence variation.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M38403-15.     

Antigen presentation in Syrian hamster cells: substrate selectivity of TAP controlled by polymorphic residues in TAP1 and differential requirements for loading of H2 class I molecules

Expression of mouse major histocompatibility complex (MHC) class I molecules in different cell lines derived from Syrian hamsters has revealed antigen presentation deficiencies of some H2 allelic products in two cell lines (BHK and NIL-2) which were overcome by transient expression of the rat transporter associated with antigen processing (TAP; Lobigs et al. 1995). Here we show that in both cell lines the endogenous MHC class I cell surface expression was completely down-regulated. Lymphokine treatment induced endogenous and recombinant mouse MHC class I cell surface expression to levels similar to that in other Syrian hamster cell lines competent for antigen presentation through transduced H2 molecules. Accordingly, constitutive downregulation of expression of accessory molecules of the MHC class I pathway can reveal differences between H2 class I alleles in antigen presentation not encountered when the expression levels are augmented. In addition to the differential expression of MHC class I pathway genes, two cell lines representing competent (FF) and defective (BHK) antigen presentation phenotypes for mouse class I MHC restriction elements demonstrated substantial sequence polymorphism in Tap1 but not Tap2. Cytokine-treated FF or BHK cells and human TAP-deficient T2 cells transfected with FF or BHK TAP1 in combination with FF TAP2 differed in their preference for C-terminal peptide residues, as shown by an in vitro peptide transport assay. Thus, polymorphic residues in TAP1 can influence the substrate selectivity of the Syrian hamster peptide transporter.     

Viral gene inhibition of class I major histocompatibility antigen expression: not a general mechanism governing the tumorigenicity of adenovirus type 2-, adenovirus type 12-, and simian virus 40-transformed Syrian hamster cells

The association between the level of class I major histocompatibility (MHC) antigen expression and the tumorigenic phenotype was determined for cells from a series of 15 lines of adenovirus type 2 (Ad2)-, Ad12-, and simian virus 40 (SV40)-transformed hamster cells and 16 lines of cells established from hamster tumors induced by SV40 mutants. These cells range from nontumorigenic to highly tumorigenic in both syngeneic and allogeneic adult hamsters. The Ad2-transformed cells--cells that were nontumorigenic in syngeneic adult hamsters--expressed either high levels or low levels of class I MHC antigens. The SV40-transformed cells--cells transformed in vitro that produced tumors with equal efficiency in both syngeneic and allogeneic adult hamsters--or cells derived from SV40-induced tumors expressed very high levels of class I MHC antigens. The Ad12-transformed cells uniformly expressed low levels of class I MHC antigens; these cells produced tumors 200- to 1,000-fold less efficiently in allogeneic adult hamsters than in syngeneic adult hamsters and produced tumors with about the same efficiency in immunoimmature newborns and immunocompetent syngeneic adult hamsters. We conclude that the expression of either high levels or low levels of class I MHC antigens is, at most, a minor factor in the differences observed among these adenovirus- and SV40-transformed cells in their tumor-inducing capacity in naive, immunocompetent hamsters.     

Single amino acid residue in the A2 domain of major histocompatibility complex class I is involved in the efficiency of equine herpesvirus-1 entry

Equine herpesvirus-1 (EHV-1), an α-herpesvirus of the family Herpesviridae, causes respiratory disease, abortion, and encephalomyelitis in horses. EHV-1 utilizes equine MHC class I molecules as entry receptors. However, hamster MHC class I molecules on EHV-1-susceptible CHO-K1 cells play no role in EHV-1 entry. To identify the MHC class I molecule region that is responsible for EHV-1 entry, domain exchange and site-directed mutagenesis experiments were performed, in which parts of the extracellular region of hamster MHC class I (clone C5) were replaced with corresponding sequences from equine MHC class I (clone A68). Substitution of alanine for glutamine at position 173 (Q173A) within the α2 domain of the MHC class I molecule enabled hamster MHC class I C5 to mediate EHV-1 entry into cells. Conversely, substitution of glutamine for alanine at position 173 (A173Q) in equine MHC class I A68 resulted in loss of EHV-1 receptor function. Equine MHC class I clone 3.4, which possesses threonine at position 173, was unable to act as an EHV-1 receptor. Substitution of alanine for threonine at position 173 (T173A) enabled MHC class I 3.4 to mediate EHV-1 entry into cells. These results suggest that the amino acid residue at position 173 of the MHC class I molecule is involved in the efficiency of EHV-1 entry.     

Evolutionary origin and diversification of the mammalian CD1 antigen genes.

CD1 antigens are cell-surface glycoproteins which have a molecular structure which is similar (consisting of extracellular domains alpha 1, alpha 2, and alpha 3, a transmembrane portion, and a cytoplasmic tail) to that of class I MHC molecules. Phylogenetic analysis of mammalian CD1 DNA sequences revealed that these genes are more closely related to the class I major histocompatibility complex (MHC) than to the class II MHC and that mammalian genes are more closely related to avian class I MHC genes than they are to mammalian class I MHC genes. The CD1 genes form a multigene family with different numbers of genes in different species (five in human, eight in rabbit, and two in mouse). Known CD1 genes are grouped into the following three families, on the basis of evolutionary relationship: (1) the human HCD1B gene and a partial sequence from the domestic rabbit, (2) the human HCD1A and HCD1C genes, and (3) the human HCD1D and HCD1E genes plus the two mouse genes and a sequence from the cottontail rabbit. The alpha 1 and alpha 2 domains of CD1 are much less conserved at the amino acid level than are the corresponding domains of class I MHC molecules, but the alpha 3 domain of CD1 seems to be still more conserved than the well-conserved alpha 3 domain of class I MHC molecules. Furthermore, in the human CD1 gene family, interlocus exon exchange has homogenized alpha 3 domains of all CD1 genes except HCD1C.     

Molecular cloning of orangutan and gibbon MHC class I cDNA. The HLA-A and -B loci diverged over 30 million years ago.

To investigate whether the classical HLA MHC class I loci have been preserved during evolution of the primates, we have cloned, sequenced, and expressed eight MHC class I cDNA from orangutan and gibbon lymphocytes. Both the HLA-A and -B loci are present in both of these species. In fact, lymphocytes from the orangutan expressed three HLA-B-related gene products, suggesting that the ancestral homologue of the HLA-B locus had undergone a duplication in this species. Interestingly, several amino acid motifs thought to be important in the Ag-presenting function of MHC class I molecules were preserved in the Ag-recognition sites of the orangutan and gibbon MHC class I molecules. Finally, these findings suggest that the recombination event between the HLA-A and -E loci occurred over 38 million years ago. These data indicate that the HLA-A and -B loci are extremely stable and that recombination between them is rare. Furthermore, the data presented here argue against the role of concerted evolution in the evolution of primate MHC class I molecules.     

Specific molecular interaction between the insulin receptor and a D product of MHC class I

The density of MHC class I was determined on a murine thymoma cell line (R1), an H-2 negative variant (R1E), and R1E-derived cell lines in which H-2 expression was restored by transfection of various MHC class I genes (Db, Kb, and truncated Db) and/or a beta-2-microglobulin gene (beta 2-m; B2). Appreciable MHC class I expression was found on R1 cells and on the variants in which MHC class I expression was restored by transfection of Db/beta 2-m or Kb/beta 2-m genes. Only approximately 20% difference was observed between the number of Db molecules and Kb molecules on the R1E/B2/Db and on R1E/B2/Kb, respectively. However, specific insulin binding was significantly different between these lines. By using a computer assisted curve fitting program, the insulin binding data for R1 and R1E/B2/Db cell lines best fitted a two-site model (K approximately 6 x 10(-9) M for high-affinity sites and a 2 to 3 x 10(-7) M for low-affinity sites), whereas all other lines only expressed one type of insulin binding site. These sites were unrelated to IGF-I and IGF-II receptors. Cross-linking of 125I-labeled insulin demonstrated specific binding of the ligand to a Mr approximately 130,000 dalton band in all lines. In the R1E/B2/Db cells, insulin also cross-linked to cell membrane molecules with Mr approximately 48,000 and approximately 60,000 Da, which were identified by immunoprecipitation to be the H chain of MHC class I and the heavy chain of MHC class I plus beta 2-m, respectively. It is concluded that the insulin receptors in the cell membrane interact specifically with D-products of MHC class I and that class I molecules of MHC may have a crucial role in insulin receptor expression. This may reflect a more general nonimmunologic role of MHC class I.     

Peptide-bound major histocompatibility complex class I molecules associate with tapasin before dissociation from transporter associated with antigen processing

Major histocompatibility complex (MHC) class I molecules present antigenic peptides to CD8 T cells. The peptides are generated in the cytosol, then translocated across the membrane of the endoplasmic reticulum by the transporter associated with antigen processing (TAP). TAP is a trimeric complex consisting of TAP1, TAP2, and tapasin (TAP-A) as indicated for human cells by reciprocal coprecipitation with anti-TAP1/2 and anti-tapasin antibodies, respectively. TAP1 and TAP2 are required for the peptide transport. Tapasin is involved in the association of class I with TAP and in the assembly of class I with peptide. The mechanisms of tapasin function are still unknown. Moreover, there has been no evidence for a murine tapasin analogue, which has led to the suggestion that murine MHC class I binds directly to TAP1/2. In this study, we have cloned the mouse analogue of tapasin. The predicted amino acid sequence showed 78% identity to human tapasin with identical consensus sequences of signal peptide, N-linked glycosylation site, transmembrane domain and double lysine motif. However, there was less homology (47%) found at the predicted cytosolic domain, and in addition, mouse tapasin is 14 amino acids longer than the human analogue at the C terminus. This part of the molecule may determine the species specificity for interaction with MHC class I or TAP1/2. Like human tapasin, mouse tapasin binds both to TAP1/2 and MHC class I. In TAP2-mutated RMA-S cells, both TAP1 and MHC class I were coprecipitated by anti-tapasin antiserum indicative of association of tapasin with TAP1 but not TAP2. With crosslinker-modified peptides and purified microsomes, anti-tapasin coprecipitated both peptide-bound MHC class I and TAP1/2. In contrast, anti-calreticulin only coprecipitated peptide-free MHC class I molecules. This difference in association with peptide-loaded class I suggests that tapasin functions later than calreticulin during MHC class I assembly, and controls peptide loading onto MHC class I molecules in the endoplasmic reticulum.     

Characterization of a divergent non-classical MHC class I gene in sharks

Sharks are the most ancient group of vertebrates known to possess members of the major histocompatibility complex (MHC) gene family. For this reason, sharks provide a unique opportunity to gain insight into the evolution of the vertebrate immune system through comparative analysis. Two genes encoding proteins related to the MHC class I gene family were isolated from splenic cDNA derived from spiny dogfish shark ( Squalus acanthias). The genes have been designated MhcSqac-UAA*01 and MhcSqac-UAA*NC1. Comparative analysis demonstrates that the Sqac-UAA*01 protein sequence clusters with classical MHC class I of several shark species and has structural elements common to most classical MHC class I molecules. In contrast, Sqac-UAA*NC1 is highly divergent from all vertebrate classical MHC class I proteins, including the Sqac-UAA *01 sequence and those of other shark species. Although Sqac-UAA*NC1 is clearly related to the MHC class I gene family, no orthologous genes from other species were identified due to the high degree of sequence divergence. In fact, the Sqac NC1 protein sequence is the most divergent MHC class-I-like protein identified thus far in any shark species. This high degree of divergence is similar in magnitude to some of the MHC class-I-related genes found in mammals, such as MICA or CD1. These data support the existence of a class of highly divergent non-classical MHC class I genes in the most primitive vertebrates known to possess homologues of the MHC and other components of the adaptive immune system.     

Immune response to acute virus infection in the Syrian hamster

Syrian hamsters show evidence of classical T-cell-mediated immune reactivity to acute virus infection as judged by primary foot pad swelling, kinetics of in vitro cytotoxic activity, and virus specificity of cytotoxic effector cells. In spite of this, no evidence of genetic restriction is observed among the variety of allodisparate inbred strains tested. This virus-induced, cell-mediated killing extends across strain barriers despite strong cellular and serologic alloreactivity among some of the strains utilized. To account for the apparent lack of genetic restriction, we currently favor the hypothesis that all hamsters examined thus far share at least one class I MHC antigen. Since these animals differ at hamster loci which elicit MLR, GVHR, acute SGR, CML, and alloantibody, we presume class II MHC polymorphism exists in this species. The presence of putative class II MHC polymorphism without detectable class I MHC polymorphism is unusual among mammals examined to date, and of unknown biologic significance.     

Hamster T cells participate in MHC alloimmune reactions but do not effect virus-induced cytotoxic activity

The participation of hamster T cells in a variety of putative MHC-determined reactions was studied utilizing a well-characterized, highly selective goat anti-hamster thymocyte (GHT) serum. Hamster lymphoid cell suspensions treated with GHT lose much of their capacity to induce local graft-versushost reactions and to function as responder cells in mixed lymphocyte reactions. In contrast to the participation of hamster T cells in alloimmune reactions (MLR and GVHR), virus-induced, cytotoxic activity in hamsters undergoing acute virus infection is not T-cell-mediated. This latter finding was rather surprising in view of the major role played by cytotoxic T effector cells in comparably infected mice and rats. These results suggest that, although hamsters are able to respond to putative class II MHC disparities in allogeneic reactions, MHC-encoded molecules, presumably class I, are not utilized for induction of effective cytotoxic activity in response to acute virus infection in this species. The implications of these findings are discussed in relation to our present understanding of the hamster MHC.     

Amino acid substitutions in the putative MHC class II "dimer of dimers" interface inhibit CD4+ T cell activation

Activation of T lymphocytes is dependent on multiple ligand-receptor interactions. The possibility that TCR dimerization contributes to T cell triggering was raised by the crystallographic analysis of MHC class II molecules. The MHC class II molecules associated as double dimers, and in such a way that two TCR (and two CD4 molecules) could bind simultaneously. Several subsequent studies have lent support to this concept, although the role of TCR cross-linking in T cell activation remains unclear. Using DRA cDNAs modified to encode two different C-terminal tags, no evidence of constitutive double dimer formation was obtained following immunoprecipitation and Western blotting from cells transiently transfected with wild-type DRB and tagged DRA constructs, together with invariant chain and HLA-DM. To determine whether MHC class II molecules contribute actively to TCR-dependent dimerization and consequent T cell activation, panels of HLA-DR1beta and H2-E(k) cDNAs were generated with mutations in the sequences encoding the interface regions of the MHC class II double dimer. Stable DAP.3 transfectants expressing these cDNAs were generated and characterized biochemically and functionally. Substitutions in either interface region I or III did not affect T cell activation, whereas combinations of amino acid substitutions in both regions led to substantial inhibition of proliferation or IL-2 secretion by human and murine T cells. Because the amino acid-substituted molecules were serologically indistinguishable from wild type, bound antigenic peptide with equal efficiency, and induced Ag-dependent CD25 expression indicating TCR recognition, the reduced ability of the mutants to induce full T cell activation is most likely the result of impaired double dimer formation. These data suggest that MHC class II molecules, due to their structural properties, actively contribute to TCR cross-linking.     

Three different MHC class I molecules bind the same CTL epitope of the influenza virus in a primate species with limited MHC class I diversity

One of the most remarkable features of the MHC class I loci of most outbred mammalian populations is their exceptional diversity, yet the functional importance of this diversity remains to be fully understood. The cotton-top tamarin (Saguinus oedipus) is unusual in having MHC class I loci that exhibit both limited polymorphism and sequence variation. To investigate the functional implications of limited MHC class I diversity in this outbred primate species, we infected five tamarins with influenza virus and defined the CTL epitopes recognized by each individual. In addition to an immunodominant epitope of the viral nucleoprotein (NP) that was recognized by all individuals, two tamarins also made a response to the same epitope of the matrix (M1) protein. Surprisingly, these two tamarins used different MHC class I molecules, Saoe-G*02 and -G*04, to present the M1 epitope. In addition, CTLs from one of the tamarins recognized target cells that expressed neither Saoe-G*02 nor -G*04, but, rather, a third MHC class I molecule, Saoe-G*12. Sequence analysis revealed that Saoe-G*12 differs from both Saoe-G*02 and -G*04 by only two nucleotides and was probably generated by recombination between these two alleles. These results demonstrate that at least three of the tamarin's MHC class I molecules can present the same epitope to virus-specific CTLs. Thus, four of the tamarin's 12 MHC class I molecules bound only two influenza virus CTL epitopes. Therefore, the functional diversity of cotton-top tamarin's MHC class I loci may be even more limited than their genetic diversity suggests.     

Association of MR1 protein, an MHC class I-related molecule, with beta(2)-microglobulin.

MR1 is a major histocompatibility complex (MHC) class I-related gene conserved among mammals, and its predicted amino acid sequence is relatively closer to the classical MHC class I molecules among several divergent class I molecules. However, as its molecular nature and function have not yet been clarified, we set out in this study to establish transfected P388 murine cell lines that stably produce a large number of MR1 proteins and conducted analyses to investigate the molecular nature of MR1. Immunoprecipitation and Western blot analyses with specific antisera revealed that the MR1 protein can associate with beta(2)-microglobulin, suggesting its molecular form of a typical class I heterodimer composed of a heavy and a light chain (beta(2)-microglobulin), like the classical MHC class I molecules.     

Molecular characterization of MHC class I and beta-2 microglobulin in a clonal strain of ginbuna crucian carp, Carassius auratus langsdorfii

Clonal ginbuna crucian carp is, a naturally gynogenetic fish, and is a useful model animal for studying T-cell-mediated immunity. To gain molecular information on MHC class I molecules from this species, we have identified four types of MHC class I (caauUA-S3n, caauUF-S3n, caauZE-S3n, and caauZB-S3n) and five beta 2-microglobulin (β(2)m) (caauβ2m-1a, caauβ2m-1b, caauβ2m-2, caauβ2m-3a and caauβ2m-3b) by an expressed sequence tag (EST) analysis and using homology cloning with degenerated primers. Like UA class I genes in other cyprinid fish, the caauUA-S3n shows features of classical MHC class I, such as conservation of all key amino acids interacting with antigenic peptides, and ubiquitous tissue expression. A phylogenetic analysis shows that the β(2)m-1 and β(2)m-2 isoforms are clustered with those of other cyprinid fishes, while β(2)m-3 isoforms make a cluster that is separated from a common ancestor of salmonid and cyprinid fishes. This finding suggests that the β(2)m isoforms of ginbuna cruician carp comprise two lineages and may possess different functions. The MHC class I and β(2)m sequences from one clonal strain will facilitate our understanding of the interaction of MHC class I with β(2)m in teleosts.     

Exchanges of short polymorphic DNA segments predating speciation in feline major histocompatibility complex class I genes

Sequence comparisons of 14 distinct MHC class I cDNA clones isolated from species representing the three major taxonomic lineages of Felidae (domestic cat lineage, ocelot lineage, and pantherine lineage) revealed that feline MHC class I alleles have highly mosaic structures with short polymorphic sequence motifs that are rearranged between alleles of individual MHC loci, between MHC class I genes within cat species, and between homologous MHC loci in different species. The pattern of sequence variation in felids supports the role of the following factors in production and maintenance of MHC variation: (1) gradual spontaneous mutation; (2) selective pressure to conserve certain residues but also to vary in hypervariable regions, notably residues that functionally participate in antigen recognition and presentation; and (3) recombination-mediated gene exchange between alleles and between related genes. The overall amount of genetic variation observed among MHC class I genes in the Felidae family is no greater than the amount of variation within any outbred cat species (i.e., domestic cat, ocelot). The occurrence of equivalent levels of polymorphism plus the simultaneous persistence of the same sequence motifs in divergent feline species suggest that most MHC class I nucleotide site polymorphism predated species divergences. Ancient polymorphisms have been transmitted through the speciation events and modern feline MHC class I alleles were derived by recombinational exchange of polymorphic sequence motifs. Moreover, some of these sequence motifs were found in other mammalian MHC class I genes, such as classical human HLA-B5, nonclassical human HLA-E class I genes, and bovine class I genes. These results raise the prospect of an ancient origin for some motifs, although the possibility of convergence in parallel mammalian radiations cannot be excluded. Correspondence to: N. Yuhki