The Biochemical characterization of syrian hamster cell-surface alloantigen : I. Analysis of allogeneic differences between recently wild and highly inbred hamsters

Limited MHC polymorphism in whales

Little is known about disease and genetic variation in aquatic mammalian species such as whales. In this paper human HLA class I and class II probes were used to study major histocompatibility complex (MHC) genes from two species of whale: Fin (Balaenoptera physalus) and Sei (B. borealis). Stronger signals were obtained on whale than on equivalent concentrations of mouse DNA. Evidence was obtained for several DRB-related genes, a DNA genes, one DQA gene, and multiple class I genes in whales. Interestingly, the whale genes, from the small panel studied, were less polymorphic than those of humans or mice. The aquatic environment of this mammalian species may be a unique factor in shaping its immune response through the MHC.

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.

Limited polymorphism of both classes of MHC genes in four different species of the Balkan mole rat

We analyzed the restriction fragment length polymorphism of class I and class II MHC genes in DNA from 20 individuals belonging to the four different species of the complex of species of Balkan mole rats Spalax leucodon captured at four different localities in Yugoslavia. All populations were tested with four restriction enzymes and one conserved mouse probe for each of the two classes of MHC genes. The probes employed detect either limited polymorphism of class I genes or lack of polymorphic bands containing class II genes. Of the two other subterranean rodents that have been studied, four karyotype forms of the Israeli mole rat show polymorphism in both classes of MHC genes similar to the one found in all other mammals (Nizetić et al. 1985), and the Syrian hamster shows limited polymorphism of class I genes and high polymorphism of class II genes (McGuire et al. 1985). Balkan mole rats belong to a new group in this respect, different from all mammals studied so far, since they apparently show limited polymorphism of both classes of MHC genes.

Syrian hamster DNA shows limited polymorphism at class I-like loci

The class I gene products of the Syrian hamster major histocompatibility complex are unique in that they lack functionally detectable polymorphism. Mouse cDNA and hamster genomic probes were used to analyze the hamster class I gene family using genomic Southern hybridization. These studies revealed that the hamster possesses a complex class I multigene family and that it shares extensive sequence homology with the corresponding mouse sequences. Unlike the mouse, however, the Syrian hamster demonstrates only limited restriction endonuclease polymorphism in these genes. These results suggest that the lack of detectable polymorphism in this species is directly related to limited DNA polymorphism. The data presented here support the hypothesis that this species has undergone an evolutionary bottleneck, i.e., that all surviving members of the species arose from a limited number of progenitors.

Syrian hamsters express two monomorphic class I major histocompatibility complex molecules

The description of the Syrian hamster major histocompatibility complex (MHC), Hm-1, has progressed to the point that multiple class II alloantigens have been defined using structural and functional studies. However, no comparable success has been achieved using allotypic differences to detect class I molecules. We now report that xenoantisera raised in other species against hamster tissues have made it possible to describe class I MHC homologues in the hamster. Evidence which confirms that these molecules exist includes (1) on immunoprecipitation of radiolabeled lymphoid cell lysates, heterodimers of approximate molecular weight 47 000 and 12 000 are identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), the latter representing hamster beta 2-microglobulin; (2) by direct immunoprecipitation these molecules are ubiquitously expressed on hamster tissues; (3) partial N-terminal amino acid sequence analysis reveals striking homology with class I molecules described in other species. In addition, the amino acid sequence data reveal that two class I molecules are expressed on the surfaces of hamster cells. On two-dimensional PAGE analysis, these molecules are invariant among the several strains of genetically disparate hamsters available for study. We conclude that (1) hamsters have the capacity to make class I MHC molecules, (2) at least two genetic loci are dedicated to this purpose, and (3) no allelic forms can be detected, suggesting that there is no class I polymorphism.

Detection of two distinct class II alpha:beta:Ii complexes in the Syrian hamster

Hamsters alloantisera and a monoclonal antibody originally generated against antigens controlled by the murine I-Ek subregion, which cross-reacts with hamster cell surface antigens, have been used to define two distinct Ia-like complexes in the Syrian hamster. These complexes have been named alpha 1:beta 1 and alpha 2:beta 2 and are detected by hamster alloantisera or monoclonal antibody 14-4-4, respectively. For the three strains studied, alpha 1:beta 1 appears to be polymorphic in both alpha and beta chains, while the alpha 2:beta 2 complex is nonpolymorphic, as revealed by 2-D PAGE analyses. A third nonpolymorphic glycoprotein that appears to be the hamster's equivalent of the murine invariant chain (Ii) is associated with both the alpha 1:beta 1 and alpha 2:beta 2 complexes. In addition, we report the first biochemical detection of polymorphism between the closely related CB and MHA Syrian hamster strains.

The biochemical characterization of Syrian hamster cell-surface alloantigens. II. Immunochemical relationships between cell-surface alloantigens and class II MHC homologues

Immunochemical comparisons between hamster cell-surface p39/p29 alloantigens and putative MHC class I and II products indicate that p39/p29 alloantigens are probable class II products. Both p39/p29 alloantigens and class II homologues have varying expression in hamster lymphoid tissues and are absent from fibroblasts. In addition, analysis by nonequilibrium pH gradient electrophoresis demonstrates similar, although nonidentical, alloantigen and class II homologous charge profiles. This observation could reflect multiple class II subregions within the hamster MHC. These data therefore suggest an immunochemical description of the hamster MHC which is compatible with MHC models proposed for other mammalian species.

Immunochemical characterization of Syrian hamster major histocompatibility complex homologues

Based primarily on studies in mice and man, the organization and gene-product structures of the mammalian major histocompatibility complex (MHC) are thought to be extensively conserved. However, attempts to generalize from the specific observations of other species to Syrian hamsters have not been completely successful. Previous studies in hamsters have suggested abnormal structure, expression, and/or function of the putative hamster MHC and its products. Characterization of hamster MHC gene-products is therefore of interest. This study concerns the identification and characterization of hamster cell-surface glycoproteins homologous to MHC products of man and mouse. Utilizing radioimmunoprecipitation and serologic techniques, these molecules have been characterized with regard to molecular weight, tissue distribution and immunochemical homology to human and murine class I and II MHC products. In addition, alloantisera raised between histoincompatible hamster strains have been similarly used to identify cell-surface alloantigens of this species. The alloantisera detect cell-surface hamster molecules with immunochemical properties and tissue distribution resembling MHC class II rather than class I products. Thus, in contrast to other species, hamsters appear not to express extensively polymorphic major transplantation antigens of the class I type. Some hamster alloantigens are apparently homologous of Ia determinants since their genes are linked to Hm-1. However, other alloantigens with similar molecular weights are seemingly encoded by genes unlinked to the hamster MHC. These data support the hypothesis that the hamster MHC contains genes which encode for molecular products similar to those described in man and mouse, but that the organization and/or expression of these genes may be atypical.

Genetic analyses of alloreactions between recently wild and classical inbred strains of Syrian hamsters: evidence in favor of a major histocompatibility complex

Cytotoxic alloantisera were raised between recently wild and classical inbred strains of Syrian hamsters. Antisera produced by immunizing the classical inbred strains with tissue from the partially inbred, recently wild hamsters detect several specificities shared between the classical and recently wild strains. Reciprocal mixed lymphocyte reactions between the two different groups of hamsters suggest that the new source of hamsters possesses several unique MLR phenotypes which may represent new Hm-1 haplotypes. Moreover, several recently wild strains express MLR phenotypes quite similar if not identical to the Hm-1a haplotype of the inbred strain, MHA. Genetic analyses of alloreactions between domestic inbred and recently wild strains suggest that a single locus or chromosomal region encodes the allodeterminants that induce strong MLR reactivity. Six unique MLR phenotypes have been defined which most likely represent haplotypes of the hamster MHC equivalent, Hm-1. Genetic linkage studies indicate that some alloantisera detect determinants encoded by loci closely linked to the MLR locus, and therefore define Hm-1 determinants. Moreover, other alloantisera recognize determinants encoded by a locus that is unlinked to Hm-1. These studies suggest that Syrian hamsters express a polymorphic MHC equivalent, Hm-1, which encodes determinants that induce both cell-mediated and humoral alloreactivity.

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 (G alpha HT) serum. Hamster lymphoid cell suspensions treated with G alpha HT lose much of their capacity to induce local graft-versus-host 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.

Immune response to acute virus infection in the Syrian hamster. I. Studies on genetic restriction of cell-mediated cytotoxicity

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 polymorphism is unusual among mammals examined to date, and of unknown biologic significance.