Genetic definition of a further gene region and identification of at least three different histocompatibility genes in the rat major histocompatibility system

Two new recombinant haplotypes of the rat major histocompatibility system,RT1, have been detected in [LEW.1A (RT1 ^a ) ×LEW.1W (RT1 ^u )] × LEW 1N(RT1 ⁿ ) segregating hybrids. Recombinantr3 carries theRTL1. A region (determining classical transplantation antigens) and theRT1.B region (determining strong mixed lymphocyte reactivity and genetic control of antipolypeptide immune responsiveness) of the RT1^a parent, bur rejects RT1^a skin grafts. Recombinantr4 carries theA andB regions of the RT1^u parent, but rejects RT1^u skin grafts. The two histocompatibility genes detected are allelic to each other. The relevant locus, designated asH-C, maps to theB-region side of theRT1 system and appears to mark a thirdRT1 gene region,RT1.C. Availability of haplotypes r3 andr4 allowed the definition of a histocompatibility locus in theB region,H-B. The products ofH-C, H-B and of the previously describedH-A gene vary in antigenic strength.     

Gene order in the major histocompatibility complex of the rat

The loci in the major histocompatibility complex (MHC) of the rat which code for class I and class II antigens—RT1.A and RT1.B, respectively — have previously been separated by laboratory-derived recombinants and by observations in inbred and wild rats. Closely linked to the MHC is the growth and reproduction complex (Grc) which contains genes influencing body size (dw-3) and fertility (ft). These phenotypic markers were used in this study to orient the A and B loci of the MHC. Two recombinants were used for mapping. The BIL(R1) animal is a recombinant between the MHC and Grc, and it carries the haplotype RT1.A ^lB^lGrc⁺. The r10 animal is an intra-MHC recombinant, and it has the haplotype RT1.A ⁿB¹ Grc. These recombinants were characterized serologically, by mixed lymphocyte reactivity, by immune responsiveness to poly (Glu⁵²Lys³³Tyr¹⁵) and by the presence of the dw-3 gene. The data demonstrate that the gene order of the loci is: dw-3-RT1.B-RT1.A.     

Class I MHC allochimeric presentation of composite immunogenic and self epitopes induces tolerance to genetically diverse rat strains

Functional topography of rat class I major histocompatibility complex (MHC) molecule was studied. The α₁-helical sequences that are shared by class I RT1.A^l and RT1.A^u were substituted in the RT1.A^a molecule to produce the composite -RT1.A^a MHC class I allochimeric molecule. Dominant immunogenic epitopes that induce accelerated rejection were identified within the hypervariable regions of the α₁ domain of RT1.A^a, RT1.A^l, and RT1.A^u. Peri-transplant portal venous delivery of MHC class I allochimeric proteins, that included composite α₁ helical immunodominant epitopes of RT1.A^u and RT1.A^l, induced donor-specific tolerance to RT1^u (Wistar Furth, WF) and RT1^l Lewis, LEW) disparate cardiac allografts in ACI (RT1^a) hosts. Allochimeric generated tolerance was characterized by absence of T cell deletion or anergy. Donor specific IgM allo-Abs was not detected, while IgG alloresponse was markedly attenuated in sera of tolerant hosts. Further, long-term allografts in allochimeric-conditioned hosts exhibited moderate B cell infiltration when compared to rejecting controls. Analysis of intragraft cytokines revealed selective upregulation of IL-10 and marked inhibition of IL-2, IFN-γ, and IL-4. Our findings indicate the emergence of a peripherally induced tolerant state, afforded by the novel approach of soluble class I allochimeric conditioning that presents donor immunogenic epitopes in the context of recipient class I determinants.     

Linkage disequilibrium with the island model

Linkage disequilibrium between two linked loci was studied for a finite population with a subdivided population structure. Wright's island model was used; extinction and replacement of colonies were also incorporated. Two alleles (A₁ and A₂ at the first locus, and B₁ and B₂ at the second locus) with symmetric mutation rates were assumed, and equilibrium properties of linkage disequilibrium coefficients were analyzed. In terms of analogy with the subdivision of inbreeding coefficient, the variance of linkage disequilibrium is divided into several components: D²_IS (variance of within-colony disequilibrium), D²_ST (variance of correlation of A₁ and B₁ of different gametes of one colony relative to that of the total population), and D²_IT (total variance of disequilibrium). Other subdivisions are D'²_IS (variance of correlation of A₁ and B₁ of one gamete of a colony relative to that of the average gamete of the population) and D'²_ST (variance of the ordinary disequilibrium of the whole population). When migration is limited, the variance becomes large if the correlation of A₁ and B₁ of one colony is taken relative to that of the whole population (D²_ST and D'²_IS). Also, when the rate of extinction-replacement of colonies is high, the whole-population disequilibrium coefficient (D'²_ST) can become fairly large. Observed linkage disequilibria, such as those among markers in the major histocompatibility complex of man and mouse, may well be explained by limited migration, without assuming epistatic natural selection.     

Cim: an MHC class II-linked allelism affecting the antigenicity of a classical class I molecule for T lymphocytes

Two alleles at the major histocompatibility complex (MHC)-linked locus cim determine gain and loss changes in the rat RT1.A^a class I molecule which affect its structure both as an alloantigen and as a restriction element. Alleles at the cim locus also influence the post-translational modification of RT1.A^a. These effects may reflect the participation of the cim gene product in the processes of peptide loading or assembly of RT1.A^a. In this study we have used the discriminating RT1.A^a-specific monoclonal antibody JY3/84, as well as cytotoxic T cells raised in appropriate combinations, to determine the cim alleles of eight haplotypes in 15 independent inbred strains of rat. We have also employed the same techniques to analyse a panel of F1 hybrid animals derived from various MHC recombinant strains. These experiments map the cim locus to the class II region of RT1, probably between the DP-related genes (RT1.H) and the DQ-related RT1.B. Address correspondence and offprint requests to: G. W. Butcher.     

Water-soluble form of RT1.A class I MHC molecules in the kidney and liver of the rat

The RT1.A (H-2K,D type) class I major histocompatibility complex (MHC) antigens of the rat are well recognized as membrane-bound glycoproteins. In this report, we demonstrate that liver and kidney in the DA rat strain contain large amounts of a water-soluble RTl. A class I molecule with a discrete heavy chain approximately 5 kd smaller than the membrane-bound form. An identical molecule could be identified in DA rat serum. This small class I molecule carries all of the polymorphic antigenic determinants of the RT1.A^av1 class I molecule. The water-soluble molecule is readily denatured in its pure form when frozen and thawed, but this does not occur when it is mixed with serum, presumably because of a stabilizing interaction with one or more carrier proteins. The half-life of the class I molecule in serum was measured to be approximately 1.5 h. The LEW rat strain produced detectable but substantially smaller amounts of water-soluble RT1.A molecules. Our studies indicate that RT1.A^av1 class I MHC antigens are synthesized and presumably secreted in a smaller water-soluble form by liver, kidney, and possibly other tissues under physiological conditions, a point of con-siderable interest in view of the immunoregulatory functions of the membrane-bound forms of these molecules.     

RT1-Linked Ir and Is genes control the immune response to bovine insulin in the rat

The immune response to bovine or pork insulin (BI or PI, respectively) was studied in the rat using the in vitro insulin-induced lymphocyte-proliferation assay. Results indicated that 11 inbred rat strains were divided into categories of high and low responders. Two high responders, SDJ (RT1 ^u) and BN(RT1 ⁿ) inbred rat strains, appeared to recognize different antigenic determinant(s) on the insulin molecule. The results of linkage and segregation analyses in F₁, F₂, backcross, and partially congenic rats showed that the Ir gene (Ir-BI), which encodes the high responsiveness in the SDJ rats, is inherited associated with RT1 ^u, whereas the immune suppression gene (Is-BI), which encodes the low responsiveness in the WKA(_RT1 ^k) rats, is inherited together with RT1 ^k. The Is-BI is the first major histocompatibility complex (MHC)-linked Is gene reported in the rat. The LEJ(RTI-A ^u B ^b) inbred rat strain showed a low response to BI, indicating that Ir-BI is closer to RTI-B/RTI-D region than to RTI-A.Abbreviations used in this paper BI bovine insulin - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - It immune response - Is immune suppression - MHC major histocompatibility complex - mol. wt. molecular weight - PI pork insulin - sc subcutaneously - SD standard deviation - SI stimulation index     

Development of MHC Class I and II B Primers in Common Carp and its Molecular Characterization

The major histocompatibility complex (MHC) has an important role in immune response and is known as the most polymorphic locus in vertebrates. We developed three pairs of polymerase chain reaction primers of the alpha-2 domain (exon 3) of MHC class I and the beta-2 (exon 3) and beta-3 domains (exon 4) of MHC class II B gene in the German mirror common carp (Cyprinus carpio L.). We analyzed the three loci in a population of 65 individuals that had suffered the serious disease of gill rot. Five to six variable nucleotide sites and two to six variable amino acid sites (71.43%) were detected in the exon sequence of the sampled populations, indicating that many of them corresponded to amino acids involved in antigen recognition. Deviation from Hardy–Weinberg equilibrium and linkage disequilibrium were differentially found in some loci, which will be important for further study of disease resistance/susceptibility and population evolution.     

TheRT1.G locus in the rat encodes a Qa/TL-like antigen

A new antigenic system in the rat homologous to theQa/TL antigen system in the mouse has been characterized. It was detected by antibodies raised in donor-recipient combinations that were matched for theRT1. A, B, D, E loci in the major histocompatibility complex (MHC): (R11×BN)F₁ anti-BN.1L(LEW), (R18×BN)F₁ anti-BN.1L, and BN.1LV1(F344) anti-BN.1L. Absorption analyses using these antisera and a variety of inbred, congenic and recombinant strains identified three alleles,RT1.G ^a ,G ^b ,G ^c , of whichG ^c is a null allele. The strain distribution of these alleles was determined, using 37 strains of rats representative of all of the prototypic haplotypes and a number of congenic and recombinant strains. The use of the congenic and recombinant strains showed that theRT1.G locus was linked to the MHC and that the most probable gene order wasA-E-G. Testcross analysis showed that the map distance betweenA andG was 1.4 cM(4/285 recombinants). The RT1.G antigen has a heavy chain ofM _r 46 000 and is present on both T and B cells.     

Demonstration of a new genetic locus in the major histocompatibility system of the rat

A new recombination within the major histocompatibility complex (RT1) of the rat has been detected. The recombination occurred between a wild-derived haplotype, provisionally designated p1, and the RT1 haplotype of the BN strain. The recombinant haplotype, designated p3, carries the RT1.A locus (classical histocompatibility antigens) of the BN strain, a locus from the BN strain that codes for the expression of an Ia antigen and strong mixed lymphocyte response (MLR), and a second locus derived from the p1 haplotype that controls the expression of a second Ia antigen, the ability to elicit a strong MLR and the immune response to poly(G1u⁵²Lys³³Tyr¹⁵). This recombinant therefore demonstrates the division of the RT1.B region into two loci, tentatively designated RT1.B and RT1.D, and provides evidence for the existence of at least four loci in the MHC of the rat.     

Genetic polymorphism of complement C6 and haplotype analysis between C6 and C7 in a Japanese population

Summary Genetic polymorphism of C6 in the Japanese population has been described using polyacrylamide gel isoelectric focusing electrophoresis followed by the electrophoretic blotting technique, and haplotype analysis between C6 and C7 has also been investigated. In 565 plasma samples five different common patterns and three rare variant patterns were observed, and these were controlled by autosomal codominance at a single locus with three common and one rare alleles. These alleles were designated C6^*B, C6^*A, C6^*B2, and C6^*M, and gene frequencies were estimated to be 0.50265, 0.43186, 0.06018, and 0.00531 for C6^*B, C6^*A, C6^*B2, and C6^*M, respectively. It is noteworthy that C6^*B2 has a polymorphic frequency in the Japanese population. The distribution of phenotypes fitted the Hardy-Weinberg equilibrium. Two combinations between C6 and C7 alleles, namely C6B-C7B and C6M-C7B, were shown to be in significant positive linkage disequilibrium. The presence of allelic combinations showing linkage disequilibrium suggests the close proximity between the C6 and C7 loci.     

Peptide motif for the rat MHC class II molecule RT1.Da: similarities to the multiple sclerosis-associated HLA-DRB1*1501 molecule

Experimental autoimmune encephalomyelitis induced with myelin proteins in DA and LEW.1AV1 rats is a model of multiple sclerosis (MS). It reproduces major aspects of this detrimental disease of the central nervous system. MS is associated with the HLA-DRB1*1501, DRB5*0101, and DQB1*0602 haplotype. DA and LEW.1AV1 rats share the RT1^av1 haplotype. So far, no MHC class II peptide motif of RT1.D^a molecules has been described. Sequence alignment of the chain of the rat MHC class II molecule RT1.D^a with human HLA class II molecules revealed strong similarity in the peptide-binding groove of RT1.D^a and HLA-DRB1*1501. According to the putative peptide-binding pockets of RT1.D^a, after comparison with the pockets of HLA-DRB1*1501, we predicted the peptide motif of RT1.D^a. To verify the predicted motif, naturally processed peptides were eluted by acidic treatment from immunoaffinity-purified RT1.D^a molecules of lymphoid tissue of DA rats and subsequently analyzed by ESI tandem mass spectrometry. In addition, we performed binding studies with combinatorial nonapeptide libraries to purified RT1.D^a molecules. Based on these studies we could define a peptide-binding motif for RT1.D^a characterized by aliphatic amino acid residues (L, I, V, M) and of F for the peptide pocket P1, aromatic residues (F, Y, W) for P4, basic residues (K, R) for P6, aliphatic residues (I, L, V) for P7, and aromatic residues (F, Y, W) and L for P9. Both methods revealed similar binding characteristics for peptides to RT1.D^a. This data will allow epitope predictions for analysis of peptides, relevant for experimental autoimmune diseases.     

Cytotoxic T lymphocytes of the rat are predominantly restricted by RTL1.A and Not RT1.C-determined major histocompatibility class I antigens

Two types of biochemically defined class I major histocompatibility complex (MHC) antigens are found in the rat, RTLA antigens that are ubiquitously expressed and RTLC antigens which so far are detectable only on certain cell types, notably B and T lymphocytes. It is shown that the cytotoxic T lymphocyte response to minor H antigens of the LEW strain, including the H-Y antigen, and to TNP-modified syngeneic lymphoid cells is restricted by RTLA but not RTLC gene products. This conclusion is based on bulk culture assays including cold target inhibition tests and limiting dilution experiments using recombinants between the RT1 ^a and RT1 ^u haplotypes. The possibility that class I MHC antigens exist which have no major restriction function is discussed.     

Analysis of genetic structure in soil populations of Rhizobium leguminosarum recovered from the USA and the UK

Although many studies have shown that animal-associated bacterial species exhibit linkage disequilibrium at chromosomal loci, recent studies indicate that both animal-associated and soil-borne bacterial species can display a nonclonal genetic structure in which alleles at chromosomal loci are in linkage equilibrium. To examine the situation in soil-borne species further, we compared genetic structure in two soil populations of Rhizobium leguminosarum bv. trifolii and two populations of R. leguminosarum bv. viciae from two sites in Oregon, with genetic structure in R. leguminosarum bv. viciae populations recovered from peas grown at a site in Washington, USA, and at a site in Norfolk, UK. A total of 234 chromosomal types (ET) were identified among 682 strains analysed for allelic variation at 13 enzyme-encoding chromosomal loci by multilocus enzyme electrophoresis (MLEE). Chi-square tests for heterogeneity of allele frequencies showed that the populations were not genetically uniform. A comparison of the genetic diversity within combined and individual populations confirmed that the Washington population was the primary cause of genetic differentiation between the populations. Each individual population exhibited linkage disequilibrium, with the magnitude of the disequilibrium being greatest in the Washington population and least in the UK population of R. leguminosarum bv. viciae. Linkage disequilibrium in the UK population was created between two clusters of 9 and 23 ETs, which, individually, were in linkage equilibrium. Strong linkage disequilibrium between the two major clusters of 8 and 12 ETs in the Washington population was caused by the low genetic diversity of the ETs within each cluster relative to the inter-cluster genetic distance. Because neither the magnitude of genetic diversity nor of linkage disequilibrium increased as hierarchical combinations of the six local populations were analysed, we conclude that the populations have not been isolated from each other for sufficient time, nor have they been exposed to enough selective pressure to develop unique multilocus genetic structure.     

Intragraft Selection of the T Cell Receptor Repertoire by Class I MHC Sequences in Tolerant Recipients

Background

Allograft tolerance of ACI (RT1^a) recipients to WF (RT1^u) hearts can be induced by allochimeric class I MHC molecules containing donor-type (RT1A^u) immunogenic epitopes displayed on recipient-type (RT1A^a) sequences. Here, we sought the mechanisms by which allochimeric sequences may affect responding T cells through T cell receptor (TCA) repertoire restriction.

Methodology/Principal Findings

The soluble [α_1h ^u]-RT1.A^a allochimeric molecule was delivered into ACI recipients of WF hearts in the presence of sub-therapeutic dose of cyclosporine (CsA). The TCR Vβ spectrotyping of the splenocytes and cardiac allografts showed that the Vβ gene families were differentially expressed within the TCR repertoire in allochimeric- or high-dose CsA-treated tolerant recipients at day +5 and +7 of post-transplantation. However, at day 30 of post-transplantation the allochimeric molecule-treated rats showed the restriction of TCR repertoire with altered dominant size peaks representing preferential clonal expansion of Vβ7, Vβ11, Vβ13, Vβ 14, and Vβ15 genes. Moreover, we found a positive correlation between the alteration of Vβ profile, restriction of TCR repertoire, and the establishment of allograft tolerance.

Conclusions

Our findings indicate that presentation of allochimeric MHC class I sequences that partially mimic donor and recipient epitopes may induce unique tolerant state by selecting alloresponsive Vβ genes.     

Genetic control of lymphocyte antigens in sheep: TheOLA complex and two minor loci

Lymphocytotoxic reagents allowed us to define 11 lymphocyte factors in sheep. After a genetic control of monospecificity had been made, a genetic study based on 400 crossings indicated that nine factors are transmitted in two haplotypes containing 0.1 or 2 factors. The linked factors of the bifactorial haplotypes are the products of two genes at two closely linked loci,OLA- A andOLA- B, having a recombination rate of about 0.6%. The nine factors are the products of fiveOLA- A and fourOLA- B alleles. Allelic frequencies at the two loci, ranging from 0.05 to 0.23 were obtained by two methods. A linkage disequilibrium between the loci is described. Among the possible causes of this, inbreeding is excluded, whereas selective pressure or more probably old fusions between sheep populations must be retained. A tenth factor (frequency 0.33 to 0.35) has a 26% recombination with OLA factors; its locus (OL-X) would be on the same chromosome but very far from theOLA complex. An 11th factor (frequency 0.30) is probably independent ofOLA; its locus (OL-Z) may be on another chromosome. The two linkedOLA loci give evidence of a major histocompatibility complex in sheep; the observed linkage disequilibrium allows one to foretell certain applications in phylogeny and perhaps in selection.     

Structure of tumor necrosis factor-alpha haploblocks in European populations

DNA variants in the tumor necrosis factor-α (TNF) and linked lymphotoxin-α genes, and specific alleles of the highly polymorphic human leukocyte antigen B (HLA-B) gene have been implicated in a plethora of immune and infectious diseases. However, the tight linkage disequilibrium characterizing the central region of the human major histocompatibility complex (MHC) containing these gene loci has made difficult the unequivocal interpretation of genetic association data. To alleviate these difficulties and facilitate the design of more focused follow-up studies, we investigated the structure and distribution of HLA-B-specific MHC haplotypes reconstructed in a European population from unphased genotypes at a set of 25 single nucleotide polymorphism sites spanning a 66-kilobase long region across TNF. Consistent with the published data, we found limited genetic diversity across the so-called TNF block, with the emergence of seven common MHC haplotypes, termed TNF block super-haplotypes. We also found that the ancestral haplotype 8.1 shares a TNF block haplotype with HLA-B*4402. HLA-B*5701, a known protective allele in HIV-1 pathogenesis, occurred in a unique TNF block haplotype.     

Polymorphism, natural selection, and structural modeling of class Ia MHC in the African clawed frog (Xenopus laevis)

In the African clawed frog (Xenopus laevis), two deeply divergent allelic lineages of multiple genes of the class I MHC region have been discovered. For the MHC class I UAA locus, functional differences and the molecular basis for lineages maintenance are unknown. Alleles of linked class I region genes also exhibit strong disequilibrium with specific MHC alleles, but the underlying cause is not clear. We use MHC class Ia sequence data to estimate substitution rates and investigate structural differences between allelic lineages from protein models. Results indicate the operation of natural selection, and differences in the steric properties in the F pocket of the peptide-binding region among lineages. Variability in this pocket likely enables allelic lineages to bind very different sets of peptides and to interact differently with MHC chaperones in the endoplasmic reticulum. These results constitute evidence of the molecular evolutionary basis for 1) the maintenance of allelic lineages, 2) functional differences among lineages, and 3) strong linkage disequilibrium of allelic variants of class I region genes in X. laevis.Electronic Supplementary Material Supplementary material is available for this article at     

Comparison of rat MHC class I antigens by peptide mapping

Monoclonal antibodies specific for the rat major histocompatibility complex (MHC) class I antigens RT1.Aⁿ, RT1.A^u, and RT1.E^u were used for immunoprecipitation of antigens biosynthetically radiolabeled with¹⁴C- or³H-labeled arginine, lysine, and tyrosine; with arginine or tyrosine alone; and with or without tunicamycin in the culture medium. Heavy chains of the glycosylated and unglycosylated antigens were purified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and their tryptic and chymotryptic peptides were compared by high performance liquid chromatography. The antigens coded by the same locus in two different haplotypes (Aⁿ and A^u) differed by 30%, whereas the products of two different loci in the same haplotype (A^u and E^u) differed only by 1–3%. Comparative analysis of the data for samples labeled with single amino acids indicated that two amino acids in A^u have been substituted by an arginine and probably by a tyrosine residue, respectively, in E^u. The high degree of homology between the products of theA andE loci in the same haplotype accounts for the difficulty in detecting recombinational events within the MHC of the rat by classical serological approaches.We dedicate this publication to Professor Paul Doty on the occasion of his sixty-fifth birthday