Genetics of Ia-like alloantigens in chickens and linkage with B major histocompatibility complex

Two sets of backcross matings were performed to test for linkage between genes coding for the Ia-like antigens ("Ia") and the B erythrocyte antigens (Ea-B) of the chicken. Evidence is presented which indicates that the "Ia" antigens are determined by a single codominant locus and that the Ea-B and "Ia" loci are on the same chromosome. Failure to detect a single recombinant between the Ea-B and "Ia" loci out of 208 progeny suggests close linkage of the two genes with a map distance of up to about 2 centimorgans. The "Ia" genes are thus included in the B major histocompatibility complex of the chicken.     

Kidney alloantigens determined by two regions of the rat major histocompatibility complex

Recombination inH-1, the major histocompatibility complex (MHC) of the rat, has defined two regions,H-1A andH-1B, which determine antigens apparently homologous to the KJD and Ia antigens of the mouse, respectively. Alloantisera directed at these antigens have been absorbed with kidney homogenates. The results showed that cells in the kidney express serologically detectable MHC antigens determined by both theH-1A andH-1B region. Control absorptions indicated that to account for these results in terms of recirculating lymphocytes, two perfused kidneys would need to contain more than 60 percent of the recirculating lymphocyte pool. It appears likely, therefore, that H-1B antigens are expressed by cells resident in the kidney.     

B lymphocyte alloantigens controlled by theI region of the major histocompatibility complex in mice

An antiserum was produced by reciprocal immunization of congenic resistent inbred strains of mice which differed only with respect to theI andS regions of theH- 2 complex. This antiserum permitted the serological detection of lymphocyte alloantigens, designated Ia (=I region associated antigens). Ia determinants are only present on mature B lymphocytes. They could not be found on thymocytes, splenic or lymph node T cells, or on the majority of bone marrow cells. Absorption studies demonstrated existence of several Ia specificities which are associated with differentI region types. Thus, theI region of theH- 2 complex appears to control not only T-cellexpressed antigen specific immune response genes, but also B-cell-expressed Ia determinants. The relevance of the Ia alloantigen system for cellular interaction in immune reactions is discussed.     

Differential expression of alloantigens of the major histocompatibility complex on unfertilized and fertilized mouse eggs

Mouse oocytes at the dictyate and metaphase II stages as well as fertilized eggs have been studied by indirect immunofluorescence for the expression of H-2 histocompatibility antigens on surface membranes. Serologically specific reactivity to H-2 antibody was observed as patchy fluorescence distributed over the surface of the oocyte membrane. In contrast, one-cell zygotes exhibited variable reactivity, and early two-cell stages were negative. Absorption studies confirmed the serologic specificity of the reactivity on oocytes, which could be shown to be due to H-2 antibody. The results suggest that fertilization results in altered expression of major histocompatibility complex surface antigens, and confirms earlier studies that cleavage stage mouse embryos are not reactive with H-2 antibody.     

Molecular characterization of major histocompatibility complex (B) haplotypes in broiler chickens

In Leghorn (laying) chickens, susceptibility to a number of infectious diseases is strongly associated with the major histocompatibility ( B ) complex. Nucleotide sequence data have been published for six class I ( B-F ) alleles and for class II ( B-Lβ ) alleles or isotypes from 17 Leghorn haplotypes. It is not known if classical B-L or B-F alleles in broilers are identical, at the sequence level, to any Leghorn alleles. This report describes molecular and immunogenetic characterization of two haplotypes from commercial broiler breeder chickens that were originally identified by serology as a single haplotype, but were differentiated serologically in the present work. The two haplotypes, designated B ^A4 and B ^A4variant, shared identical B-G restriction fragment length polymorphism patterns, but differed in one B-Lβ fragment that cosegregated with the serological B haplotype. Furthermore, the nucleotide sequences of the highly variable exons of an expressed B-LβII family gene and B-F gene from the two haplotypes were markedly different from each other. Both the B-LβII family and B-F gene sequences from the B ^A4 haplotype were identical to the sequences obtained from the reference B ²¹ haplotype in Leghorns; however, in the B ^A4 haplotype the B-Lβ ²¹ and B-F ²¹ alleles were in linkage with B-G alleles that were not G ²¹. The nucleotide sequences from B ^A4variant were unique among the reported chicken B-LβII family and B-F alleles.     

Genetic control of Rous sarcoma regression in chickens: Linkage with the major histocompatibility complex

Studies with two closely related inbred chicken strains show that regression of Rous sarcoma virus-induced tumors is a dominantly inherited trait, controlled by a gene within, or closely linked to, the major histocompatibility complex (B region). Strain G-B2 birds are capable of regressing Rous tumors, while strain G-B1 birds are uniformly susceptible to progressive Rous tumor development. Evidence for crossing over between the genes controlling serologically determined MHC antigens on erythrocytes and genes controlling Rous sarcoma growth was obtained. The MHC-linked gene which confers the ability to regress Rous sarcomas is designatedR-Rs-1. The allelic gene which allows for progressive tumor growth in homozygous birds is designatedr-Rs-1.     

Analysis of the major histocompatibility complex in Syrian hamsters. III. Cellular and humoral immunity to alloantigens.

Among the genetic loci incorporated into the major histocompatibility complex in every species studied to date have been prominent genes encoding for strong histocompatibility determinants that elicit detectable alloantibody responses and which are the chief antigenic targets of cell-mediated cytotoxicity reactions. The K and D regions of the H-2 complex in the mouse and the A, B, and C regions of the HLA complex in man are representative examples. Syrian hamsters, as described in this report, do not make alloantibodies to antigens of this type and only very poorly do they carry out in vitro cell-mediated cytotoxicity to target cells putatively bearing these antigens. Since hamsters are quite capable of discriminating analogous antigenic differences in xenogeneic species, and xenogeneic sources cannot distinguish immunologically between the antigens encoded by the two hamster major histocompatibility alleles. Hm-1a and Hm-1b, we conclude that the hamster strains we work with are serologically indistinguishable by the methods used here. However, they obviously differ for determinants which elicit T cell-mediated responses, as evidenced by their ability to express acute skin graft rejection, mixed lymphocyte reactivity, graft-vs-host reactions, and cell-mediated cytotoxicity reactions. Such alloreactivity may reflect a mutation at an SD locus, affecting antigenic sites recognized only by T cells, or that the available hamster strains are SD identical, but differ at loci similar to the I region loci in mice. Alternatively, we cannot exclude the possibility that Syrian hamsters somehow fail to express properly the genes coding for SD determinants.     

Marek's disease and major histocompatibility complex haplotypes in chickens selected for high or low antibody response

Sublines of chickens differing in genotypes at the major histocompatibility complex (MHC) were developed from lines selected for high (HA) and low (LA) antibody response to sheep erythrocytes. To evaluate the influence of MHC genotypes in diverse background genomes on resistance to Marek's disease, chicks with MHC genotypes B13B13, B13B21 and B21B21 from both background genomes were exposed naturally commencing at 1 day of age. Individuals which died up to 120 days of age were autopsied to determine cause of death. Mortality due to Marek's disease was greater for HA than LA chickens and greater for males than females. Interactions of MHC genotypes with background genome and with sex suggest a complex picture of the influence of MHC genotypes. A heterozygous advantage for resistance to Marek's disease was noted, as would be predicted by genetic theory concerning maintenance of polymorphism at the MHC.     

Genotypic variability at the major histocompatibility complex (B and Rfp-Y) in Camperos broiler chickens

Evidence for the importance of major histocompatibility complex (MHC) genotype in immunological fitness of chickens continues to accumulate. The MHC B haplotypes contribute resistance to Marek's and other diseases of economic importance. The Rfp-Y, a second cluster of MHC genes in the chicken, may also contribute to disease resistance. Nevertheless, the MHC B and Rfp-Y haplotypes segregating in broiler chickens are poorly documented. The Camperos, free-range broiler chickens developed in Argentina, provide an opportunity to evaluate MHC diversity in a genetically diverse broiler stock. Camperos are derived by cross-breeding parental stocks maintained essentially without selection since their founding. We analysed 51 DNA samples from the Camperos and their parental lines for MHC B and Rfp-Y variability by restriction fragment pattern (rfp) and SSCP typing methods for B-G, B-F (class Ia), B-Lbeta (class II) and Y-F (class Ib) diversity. We found evidence for 38 B-G genotypes. The Camperos B-G patterns were not shared with White Leghorn controls, nor were any of a limited number of Camperos B-G gene sequences identical to published B-G sequences. The SSCP assays provided evidence for the presence of at least 28 B-F and 29 B-Lbeta genotypes. When considered together B-F, B-L, and B-G patterns provide evidence for 40 Camperos B genotypes. We found even greater Rfp-Y diversity. The Rfp-Y class I-specific probe, 163/164f, revealed 44 different rfps among the 51 samples. We conclude that substantial MHC B and Rfp-Y diversity exists within broiler chickens that might be drawn upon in selecting for desirable immunological traits.     

Designation by restriction fragment length polymorphism of major histocompatibility complex class IV haplotypes in meat-type chickens

Major histocompatiblity complex (MHC) class IV haplotypes were identified in a population of meat-type chickens by restriction fragment length polymorphism (RFLP) analysis. Fourteen different haplotypes were designated on the basis of restriction patterns obtained from Southern blots of PvuII- or BglII-digested DNA, hybridized with the MHC class IV cDNA probe bg32.1. Digestion with each restriction enzyme yielded the same level of polymorphism among individuals. For each haplotype, 4–10 restriction fragments ranging from 0–8 to 8 kb were observed. Such a designation of meat-type chicken MHC class IV haplotypes enables a rapid recognition of previously defined haplotypes, is readily adjustable to additional, newly found restriction patterns and could prove useful in practical breeding programmes.     

Identification of two Ia-like alloantigens on rabbit B lymphocytes

Alloimmunizations with rabbit lymphoid cells have resulted in the identification of two cell-surface alloantigens, Ia1 and Ia2. These antigens reside on nearly all B cells; few, if any thymus cells or T cells of mesenteric lymph nodes bear these antigens. Genetic studies showed that Ia1 and Ia2 molecules appear to be controlled by allelic genes at a locus closely linked to the MHC. Immunochemical analyses revealed that Ia1 and Ia2 are glycoproteins and that each is composed of two polypeptide chains of molecular weights of 28 000 and 30 000–32 000. Thus, the alloantigens identified by these two antisera appear to be Ia-like molecules.     

The major histocompatibility complex of primates

The major histocompatibility complex (MHC) encodes cell surface glycoproteins that function in self-nonself recognition and in allograft rejection. Among primates, the MHC has been well defined only in the human; in the chimpanzee and in two species of macaque monkeys the MHC is less well characterized. Serologic, biochemical and genetic evidence indicates that the basic organization of the MHC linkage group has been phylogenetically conserved. However, the number of genes and their linear relationship on the chromosomes differ between species. Class I MHC loci encode molecules that are the most polymorphic genes known. These molecules are ubiquitous in their tissue distribution and typically are recognized together with nominal antigens by cytotoxic lymphocytes. Class II MHC loci constitute a smaller family of serotypes serving as restricting elements for regulatory T lymphocytes. The distribution of class II antigens is limited mainly to cell types serving immune functions, and their expression is subject to up and down modulation. Class III loci code for components C2, C4 and Factor B (Bf) of the complement system.Interspecies differences in the extent of polymorphism occur, but the significance of this finding in relation to fitness and natural selection is unclear. Detailed information on the structure and regulation of MHC gene expression will be required to understand fully the biologic role of the MHC and the evolutionary relationships between species. Meanwhile, MHC testing has numerous applications to biomedical research, especially in preclinical tissue and organ transplantation studies, the study of disease mechanisms, parentage determination and breeding colony management. In this review, the current status of MHC definition in nonhuman primates will be summarized. Special emphasis is placed on the CyLA system of M. fascicularis which is a major focus in our laboratory. A highly polymorphic cynomolgus MHC has been partially characterized and consists of at least 14 A locus, 11 B locus, 7 C locus class I allelic specificities, 9 Ia-like class II antigens and 6 Bf (class III) variants.     

猪主要组织相容性复合体研究进展

主要组织相容性复合体（major histocompatibility complex,MHC）分子首先作为主要组织相容性抗原被发现,进而以此命名。随着其抗原结合分子及T细胞信使生物学功能本质的揭示,关于MHC结构与功能的研究就进入了一个崭新时代,并在这一领域中取得了许多可喜的成果。论述了近年来猪MHC（SLA）结构与功能方面的研究进展,包括SLA的分类及多态性、SLA分子结构特点、SLA分子功能及SLA分子相关领域的最新研究进展。     

The major histocompatibility complex in the chicken

The chicken B complex is the first non-mammalian MHC characterized at the molecular level. It differs from the human HLA and murine H-2 complexes in the small size of the class I (B-F) and class II (B-L) genes and their close proximity. This proximity accounts for the absence of recombination between B-F and B-L genes and leaves no space for class III genes. Moreover the B-F and B-L genes are tightly linked to unrelated genes absent from mammalian MHCs, such as the polymorphic B-G genes and a member of the G protein beta subunit family. This linkage could form the basis for resistance to viral-induced tumors associated with some B complex haplotypes.     

The major histocompatibility complex and human evolution

Many alleles at the human major histocompatibility complex (HLA) loci diverged before the divergence of humans and great apes from a common ancestor. This fact puts a lower limit on the size of the bottleneck in human evolution: the genus Homo must have been founded by no less than ten and probably by more than 10,000 individuals.     

Parasite immunity and the major histocompatibility complex

Parasite infestations offer fertile ground for investigation of the relationship between immunity, disease and the major histocompatibility complex (MHC). However, due to the complexities of parasite life cycles and the success of parasites in evading the immune response, immune reactions against the parasite often do not parallel protective immunity, and immunity does not imply lack of disease. — An additional level of complexity is introduced in some forms of parasite immunity by accessory effector cells, e. g., macrophages and eosinophils, that need to be activated for maximal effectiveness, and the activated form of these cells may partly compensate for a deficiency in specific immune responses. — It is not surprising, therefore, that polygenic effects operate in parasite immunity and reports linking non-MHC genes with parasite immunity far out number those linking MHC genes with it. From the reports that do link MHC genes with parasite immunity, two areas emerge that are interesting. First, the increased incidence of certainHLA genes in people with schistosomiasis who develop hepatosplenic disease may pinpoint individuals at risk of morbidity and direct early treatment to them. Second, mechanisms that intimately involve MHC products but are not linked to a particular MHC haplotype, may indicate newer areas in the investigation of parasite immunity.