Serologically defined specificities of the pig main histocompatibility complex (SL-A)

Six antigens detectable by the complement-dependent lymphocytotoxic technique were determined in pigs by six groups of alloimmune sera. It was confirmed that these specificities are controlled by the main histocompatibility region (SL-A). Serological and genetic studies showed that the given specificities (provisionally designated LI to L6) form at least 6 haplotypes. In addition, family studies confirmed the linkage between SL-A region and C blood group locus. Maximum lod score values are in recombination fraction v = 0.2.     

Serologically defined subpopulations of human T lymphocytes.

Several rabbit antisera to T cells obtained from various sources (thymus, peripheral blood, brain, T-derived leukemias) were studied with the aim to obtain reagents specific for a subset of T cells. Sera were first absorbed on human tissues and B cells; thereafter these T cell-specific sera were additionally absorbed with T cells of different origin and especially with leukemic T cells, which are likely to represent a clonal expnasion of a subset of T cells with potentially unique antigenic markers. Three antigenically distinct subpopulations of T cells were delineated. The relationship of these subsets with previously defined human T cell subpopulations (T subsets with a receptor for the Fc or IgG or IgM or with a receptor for a lectin from wheat germ agglutinin) was investigated.     

Porcine major histocompatibility complex (MHC) class I molecules and analysis of their peptide-binding specificities

In all vertebrate animals, CD8⁺ cytotoxic T lymphocytes (CTLs) are controlled by major histocompatibility complex class I (MHC-I) molecules. These are highly polymorphic peptide receptors selecting and presenting endogenously derived epitopes to circulating CTLs. The polymorphism of the MHC effectively individualizes the immune response of each member of the species. We have recently developed efficient methods to generate recombinant human MHC-I (also known as human leukocyte antigen class I, HLA-I) molecules, accompanying peptide-binding assays and predictors, and HLA tetramers for specific CTL staining and manipulation. This has enabled a complete mapping of all HLA-I specificities (“the Human MHC Project”). Here, we demonstrate that these approaches can be applied to other species. We systematically transferred domains of the frequently expressed swine MHC-I molecule, SLA-1*0401, onto a HLA-I molecule (HLA-A*11:01), thereby generating recombinant human/swine chimeric MHC-I molecules as well as the intact SLA-1*0401 molecule. Biochemical peptide-binding assays and positional scanning combinatorial peptide libraries were used to analyze the peptide-binding motifs of these molecules. A pan-specific predictor of peptide–MHC-I binding, NetMHCpan, which was originally developed to cover the binding specificities of all known HLA-I molecules, was successfully used to predict the specificities of the SLA-1*0401 molecule as well as the porcine/human chimeric MHC-I molecules. These data indicate that it is possible to extend the biochemical and bioinformatics tools of the Human MHC Project to other vertebrate species.     

The pig histocompatibility system SLA: serological study on a group of antigenic specificities

The report presents an analysis of a group of class I SLA reagents which were highly correlated within one cluster in a previous analysis. Further population and family studies, and selected purification of several of these reagents led to the identification of 4 distinct specificities, namely SLA A 15, B 18, C 1 and A 16. Three of them, SLA A 15, B 18 and C 1, are actually in strong linkage disequilibrium and represent the main SLA haplotype in the Large White breed. SLA A 16 is present essentially in the Landrace breeds. SLA A 16 displays a strong cross-reaction with SLA A 15 and there is another specificity in linkage disequilibrium with SLA A 16 which cross-reacts with SLA B 18. Altogether, the strong linkage disequilibrium and the high degree of cross-reactivity among the allelic products of the SLA complex explain the failure to detect the diversity of our reagents in previous studies.     

The pig histocompatibility system SLA: Serological study on a group of antigenic specificities

The report presents an analysis of a group of class I SLA reagents which were highly correlated within one cluster in a previous analysis. Further population and family studies, and selected purification of several of these reagents led to the identification of 4 distinct specificities, namely SLA A 15, B 18, C 1 and A 16. Three of them, SLA A 15, B 18 and C 1, are actually in strong linkage disequilibrium and represent the main SLA haplotype in the Large White breed. SLA A 16 is present essentially in the Landrace breeds. SLA A 16 displays a strong cross-reaction with SLA A 15 and there is another specificity in linkage disequilibrium with SLA A 16 which cross-reacts with SLA B 18. Altogether, the strong linkage disequilibrium and the high degree of cross-reactivity among the allelic products of the SLA complex explain the failure to detect the diversity of our reagents in previous studies.     

Serologically defined V region subgroups of human lambda light chains

The availability of numerous antisera prepared against lambda-type Bence Jones proteins and lambda chains of known amino acid sequence has led to the differentiation and classification of human lambda light chains into one of five V lambda subgroups. The five serologically defined subgroups, V lambda I, V lambda II, V lambda III, V lambda IV, and V lambda VI, correspond to the chemical classification that is based on sequence homologies in the first framework region (FR1). Proteins designated by sequence as lambda V react with specific anti-lambda II antisera and are thus included in the V lambda II subgroup classification. The isotypic nature of the five V lambda subgroups was evidenced through analyses of lambda-type light chains that were isolated from the IgG of normal individuals. Based on analyses of 116 Bence Jones proteins, the frequency of distribution of the lambda I, lambda II/V, lambda III, lambda IV, and lambda VI proteins in the normal lambda chain population is estimated to be 27%, 37%, 23%, 3%, and 10%, respectively. This distribution of V lambda subgroups was comparable to that found among 82 monoclonal Ig lambda proteins. Considerable V lambda intragroup antigenic heterogeneity was also apparent. At least two sub-subgroups were identified among each of the five major V lambda subgroups, implying the existence of multiple genes in the human V lambda genome. The V lambda classification of 54 Ig lambda proteins obtained from patients with primary or multiple myeloma-associated amyloidosis substantiated the preferential association of lambda VI light chains with amyloidosis AL and the predominance of the normally rare V lambda VI subgroup in this disease.     

Analysis of the fine specificities of sheep major histocompatibility complex class II-specific monoclonal antibodies using mouse L-cell transfectants

The fine specificities of two panels of monoclonal antibodies (mAbs) for sheep major histocompatibility complex (MHC) class II molecules were determined using five mouse L-cell transfectaents, each expressing a defined sheep DQ or DR MHC class II A/B gene pair. Using the transfectants in an indirect fluorescence antibody assay, previous immunochemical characterization of the mAbs was confirmed for 16 of 23 mAbs tested. The MHC class II subtype specificity ( DQ or DR ) of each mAb was assigned without interference from the products of other expressed class II loci. This allowed the identification of both cross-locus specificities as well as defining fine specificities of mAbs previously only partially characterized by immunochemical techniques.     

Close association between DNA polymorphism of bovine major histocompatibility complex class I genes and serological BoLA-A specificities

Class I genes of the bovine major histocompatibility complex (MHC) were investigated by Southern blot hybridization and by serological analysis. A large number of class I restriction fragments and an extensive polymorphism were revealed when genomic DNA samples, digested with the restriction enzyme PvuII, were hybridized with a human cDNA probe. The result indicated the presence of multiple class I genes in cattle. The extensive restriction fragment length polymorphism (RFLP) was interpreted genetically by analysing five paternal half-sib families comprising, besides the bulls, 50 offspring and their dams. No less than 21 RFLP types were distinguished in this limited sample. The class I polymorphism was also analysed using a serological test with sera corresponding to four workshop specificities (w2, w6, w10 and w16) and three locally defined specificities (SRB1, SRB2 and SRB3). There was an excellent agreement between the two typing methods since no RFLP type was associated with more than one specificity and five of the seven specificities were associated with a single RFLP type. Evidence for close genetic linkage between class I and DQ class II genes was obtained since no recombinant was found among 45 informative offspring. Linkage disequilibrium among class I, DQ class II and C4 genes was also observed. The blood group specificity M' was completely associated with the w16 class I specificity and with the haplotype I1DQ1BC4(2) in this material.     

Alloreactive T-cell recognition of bovine major histocompatibility complex class II products defined by one-dimensional isoelectric focusing

T-cell recognition of bovine MHC (BoLA) class II antigens was investigated in relation to BoLA class II polymorphisms defined by one-dimensional isoelectric focusing (1D-IEF). One-way mixed lymphocyte reactions (MLRs), and allospecific cell lines and clones were used. In general, T-cell responses correlated with the 1D-IEF defined haplotypes (EDF types). However, with MLRs some responses appeared to be associated with BoLA class I differences. All combinations of responder-stimulator pairs produced alloreactive T-cell responses both in MLR and in generation of allolines/clones. Thus allospecific lines and clones were generated to all EDF types tested. Splits in the IEF typing were observed with EDF6 and EDF3, indicating that distinct BoLA class II haplotypes are not necessarily distinguished by 1D-IEF alone. Furthermore, the patterns of reactivity with EDF3 expressing cells were complex with the T-cell specificities splitting EDF3 into several distinct types. Also, in some cases it was clear that more than one T-cell specificity per EDF type was detectable. Thus, allospecific lines and clones provide complementary and additional information to the 1D-IEF typing for polymorphism of the BoLA class II complex. This extra information is particularly important in terms of the functional significance of the BoLA complex for antigen presentation and immune response gene effects.     

The bovine major histocompatibility complex (BoLA): Close linkage of the genes controlling serologically defined antigens and mixed lymphocyte reactivity

Detection of linkage between genetic loci in cattle has been hampered by the lack of large full-sib families. A unique source of full-sib families is now available from embryo transplantation. Lymphocytes from six full-sib families, ranging in size from three to seven siblings, were tested for serologically defined BoLA antigens (BoLA-A). In addition, mixed lymphocyte reactivity (MLR) was tested between all paired combinations of cells within each family to distinguish BoLA-D specificities. Serologically identical siblings within each family were reciprocally nonreactive in MLR, and vice versa; thus, no recombinants were detected between the BoLA-A and the BoLA-D loci. Classical genetic linkage analysis revealed that these loci are significantly closer than 11.9 centimorgans.     

The major histocompatibility complex of the guinea pig. I. Serologic and genetic studies.

Serologic and genetic studies of the antigens which comprise the guinea pig MHC have demonstrated three distinct but linked genetic regions. Antisera to the B region were raised by cross-immunization of random-bred animals; this region controls antigens B.1, B.2, B.3, and B.4 which behave as alleles at a single locus and which resemble the products of the murine D or K region genes in their tissue distribution and molecular characteristics. Cross-immunization of inbred strain 2 and strain 13 animals, both of which bear the B.1 antigen, leads to sera which identify antigens which resemble the products of the I region of the murine MHC. Specific absorption experiments have demonstrated four distinct I region antigens. In addition to the B and I regions, inbred strain 2, strain 13, and some outbred animals bear an antigen (S.1) which is the product of a third genetic region and which also resembles the murine D or K region gene products in molecular size. The results of these studies should facilitate the use of the guinea pig as an experimental model for studies of genetic control of the immune response and the function of the histocompatibility-linked Ir genes.     

'Good genes as heterozygosity': the major histocompatibility complex and mate choice in Atlantic salmon (Salmo salar).

According to the theory of mate choice based on heterozygosity, mates should choose each other in order to increase the heterozygosity of their offspring. In this study, we tested the 'good genes as heterozygosity' hypothesis of mate choice by documenting the mating patterns of wild Atlantic salmon (Salmo salar) using both major histocompatibility complex (MHC) and microsatellite loci. Specifically, we tested the null hypotheses that mate choice in Atlantic salmon is not dependent on the relatedness between potential partners or on the MHC similarity between mates. Three parameters were assessed: (i) the number of shared alleles between partners (x and y) at the MHC (M(xy)), (ii) the MHC amino-acid genotypic distance between mates' genotypes (AA(xy)), and (iii) genetic relatedness between mates (r(xy)). We found that Atlantic salmon choose their mates in order to increase the heterozygosity of their offspring at the MHC and, more specifically, at the peptide-binding region, presumably in order to provide them with better defence against parasites and pathogens. This was supported by a significant difference between the observed and expected AA(xy) (p = 0.0486). Furthermore, mate choice was not a mechanism of overall inbreeding avoidance as genetic relatedness supported a random mating scheme (p = 0.445). This study provides the first evidence that MHC genes influence mate choice in fish.