Discrimination between major histocompatibility complex class II DQ and DR locus products in cattle

We have used a panel of anti-major histocompatibility complex (MHC) class II monoclonal antibodies (mAbs) and have assessed their specificity for the products of the individual bovine MHC (BoLA) class II subregions. The mAbs identified two distinct class II molecules by affinity purification and ELISA. Two-dimensional immunoblotting confirmed these data and NH₂-terminal sequencing of the purified class II α chains of one member of each group identified the subregion specificity of the mAbs. The mAbs VPM36, TH22A and TH81A are specific for BoLA DQ, whereas VPM54, TH14B and J11 are specific for BoLA DR. SW73.2 reacts with both MHC subgroups of all cattle tested.     

Restriction fragment length polymorphism of DQ and DR class II genes of the bovine major histocompatibility complex

DQ alpha, DQ beta, DR alpha and DR beta class II genes of the bovine major histocompatibility complex (MHC) were investigated by Southern blot hybridizations using human probes. Hybridizations of these probes to genomic DNA, digested with PvuII or TaqI, revealed extensive restriction fragment length polymorphisms (RFLPs). The polymorphisms were interpreted genetically by analysing a family material, comprising five sires, 48 dams and 50 offspring, and a population sample comprising 197 breeding bulls. The analysis resolved 20 DQ alpha, 17 DQ beta, 5 DR alpha and 25 DR beta RFLP types. The segregation data were consistent with simple Mendelian inheritance of the RFLPs. The analysis of the bull sample showed that it is possible to apply the RFLP method for routine typing of class II polymorphism in population samples. The linkage disequilibrium in the DQ-DR region was found to be extremely strong as only about 20 DQ and about 30 DQ-DR haplotypes were observed despite the large number of possible haplotypes. Close linkage to the blood group locus M was also found; the M' allele occurred in strong linkage disequilibrium with the class II haplotype DQ1BDR alpha 4DR beta 1B. A population genetic analysis of the DQ data in the sample of breeding bulls revealed that the frequency of homozygotes was significantly lower than Hardy-Weinberg expectation and that the allele frequency distribution deviated significantly from the one expected for selectively neutral alleles.     

Molecular mapping class II polymorphisms in the human major histocompatibility complex. II. DQ beta

The restriction fragment length polymorphisms have been determined for six restriction enzymes (Bam HI, Bg1 II, Eco RI, Hinc II, Hind III, and Pvu II) and a DQ beta probe on 25 cell lines that are homozygous by consanguinuity at the MHC. These patterns reflect both DR haplotypes and DQ types of the cells tested. At least one non-polymorphic band is present in all the cell lines with every restriction enzyme except Hinc II. This band most probably represents DX beta hybridization. The polymorphic bands indicate that more polymorphism exists in the DQ subregion than is predicted serologically. Each DR haplotype is associated with a unique set of restriction fragments except for DR2 and DR6. The patterns are largely consistent within each DR haplotype. In addition, some bands reflect the established DQ specificities DQw1 and DQw2. Individual bands can be identified that are unique to the haplotypes DR1, DR4, DR5, and DR6 and the DQw1- and DQw2-associated haplotypes. Subdivisions of haplotypes can be identified with this probe. In particular, MVL (DR1), Akiba (DR2), QBL (DR3), FPF (DR5), and APD (DR6) have polymorphisms that distinguish them from other members of their DR haplotype.     

The major histocompatibility complex of the rat,RT 1

Recombinational analysis has shown that the rat MHC,RT1 is divided into two regions:RT1.A, which codes for class I (transplantation) antigens, andRT1.B, which controls the humoral immune response and proliferative response to allogeneic cells as well as the expression of class II (Ia) antigens. Serological and sequence studies suggest that there might be more than one antigen-coding locus within theRT1.A region. Results obtained by sequential immunoprecipitation reveal that both regions code for at least two gene products. By implication, theRT1 complex must therefore harbor at least four loci;RT1.A andD coding for class I glycoproteins (45,000 daltons); andRT1.B andE coding for class II (Ia) glycoproteins (35,000 and 28,000 daltons).     

The major histocompatibility complex of the rat,RT1

The antigenic determinants expressed on RBC and lymphocytes and coded for by the MHC, RT1,of the MNR (RT1 ( m )) rat strain were compared to those of the BN.DA(RT1 ( a )), ALB (RT1 ( b )), and AUG (RT1 ( c )) strains by direct cytotoxicity and absorption analysis with RT1 typing sera, sera produced against MNR cells, and sera produced in MNR responders against cells carrying thea, b, andc haplotype determinants. The results indicate that MNR shares major class I (A) antigens with DA, and major class II (B) determinants with AUG, but that MNR differs from DA and AUG with respect to both classes of determinant. It appears, therefore, that the MNR haplotype does not represent a simple composite of the two other haplotypes,RT1 ( a ) andRT1 ( c ), as reported earlier.     

Genomic organization and sequence of the rat major histocompatibility complex class Ia gene RT1.A u

The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the accession number X82669     

Molecular mapping of class II polymorphisms in the human major histocompatibility complex. I. DR beta

We have studied 27 cell lines homozygous by consanguinity for the major histocompatibility complex to establish the restriction fragment length polymorphism (RFLP) patterns seen with six different restriction enzymes (Bam HI, Bg1 II, Eco RI, Hinc II, Hind III, Pvu II) and DR beta chain probes. The probes used were a full-length cDNA DR beta probe and a probe specific for the 3' untranslated region. The RFLP obtained represent the first standard patterns for the individual haplotypes DR1 through 7 and DR9 as defined by genetically homozygous lines. The patterns obtained reflect the DR specificities closely, as well as the DRw52 and DRw53 specificities. These latter specificities are associated with the most prominent patterns of RFLP. Bands are present which are unique for the haplotypes DR1, DR2, DR4, DR7, DRw52, and DRw53, and could be used for typing these haplotypes in heterozygotes. Subtypes can be identified for all of the haplotypes except DR1. These subtypes indicate that there is an extensive amount of polymorphism in the DR subregion that has not been identified serologically.     

Considerable haplotypic diversity in the RT1-CE class I gene region of the rat major histocompatibility complex

The major histocompatibility complex (MHC) class I region extending between the Bat1 and Pou5f1 genes shows considerable genomic plasticity in mouse and rhesus macaque but not in human haplotypes. In the rat, this region is known as the RT1-CE region. The recently published rat MHC sequence gave rise to a complete set of class I gene sequences in a single MHC haplotype, namely the RT1ⁿ haplotype of the widely used BN inbred strain. To study the degree of genetic diversity, we compared the RT1-CE region-derived class I genes of the RT1ⁿ haplotype with class I sequences of other rat haplotypes. By using phylogenetic tree analyses, we obtained evidence for extensive presence and absence polymorphisms of single loci and even small subfamilies of class I genes in the rat. Alleles of RT1-CE region class I genes could also be identified, but the rate of allelic nucleotide substitutions appeared rather low, indicating that the diversity in the RT1-CE region is mainly based on genomic plasticity.     

Mapping of class I DNA sequences within the human major histocompatibility complex

Mutants that had lost expression of alleles of one or more HLA loci were isolated with immunoselection after gamma-irradiation of a human lymphoblastoid cell line LCL 721. DNAs from the mutants were digested with restriction endonucleases and analyzed by Southern blotting using probes for class I HLA genes. Eight polymorphic cut sites for HindIII and PvuII were discovered in class I-associated sequences of LCL 721. Losses of specific fragments generated by restriction enzymes could be associated with losses of specific antigenic expressions and it was possible in this way to assign HLA-A1, HLA-A2, and HLA-B8 to specific DNA fragments. Patterns of gamma-ray-induced segregations of DNA fragments permitted rough linkage alignment of about 30% of the fragments generated by PvuII. The resultant map showed that there are class I HLA genes on the telomeric side of the HLA-A locus. Restriction enzyme site polymorphisms were also examined in a panel of DNAs isolated from peripheral blood lymphocytes (PBLs) of HLA-typed individuals. This panel of PBL DNA complemented the analysis using the HLA deletion mutants.     

Characterization of naturally processed and presented peptides associated with bovine major histocompatibility complex (BoLA) class II DR molecules

Differential regulation of genetic resistance to infectious disease may partially be explained by variation in the binding affinity and the repertoire of pathogen-derived antigenic peptides associated with major histocompatibility complex (MHC) molecules. In this study, we investigated characteristics of peptides that bind to the bovine MHC allele BoLA-DRB3*2703, which is associated with occurrence of clinical mastitis in Holstein dairy cattle, and assigned a putative peptide-binding motif to this allele. This was achieved by in vitro expression of allele *2703 as well as a control allele, BoLA-DRB3*1201 which is present at high frequency in Holsteins. Transfected cell lines alone (for allele *1201) or in combination with blood mononuclear cells from an animal homozygous for allele *2703 were used as the source of naturally processed and presented peptides. Subsequent to elution of peptides from BoLA-DR+ cells, their sequences were determined by electrospray ionization mass spectrometry. Eluted peptides were between 13 and 20 amino acids long and the majority were in sets of overlapping sequences. These peptides were derived from intra- and extracellular proteins, as well as foreign proteins present in the culture medium. Some peptides had originated from molecular chaperones present in the endoplasmic reticulum, such as ER-60 and GRP78, pointing to some degree of overlap and cross-sampling between MHC class I and class II antigen presentation pathways. Consistent with reports of human and mouse MHC class II-associated peptides, putative peptide-binding motifs could be assigned to alleles *2703 and *1201, comprising a hydrophobic or an aromatic residue at relative position 1, a hydrophobic residue at position 4 and a small residue at position 6 of the eluted peptides. These findings provide the foundation for future studies of molecular mechanisms of MHC-disease associations of cattle.     

Peptide specificity of RT1-A1(c), an inhibitory rat major histocompatibility complex class I natural killer cell ligand

The rat major histocompatibility complex class Ia allelomorph RT1-A1(c) is a potent ligand for the recently identified inhibitory rLy-49 receptor, STOK-2. With the ultimate objective of studying the interactions of these molecules using structural and functional methods, we undertook a detailed study of its peptide specificity. The study revealed that designing an "ideal peptide" by choosing the most abundant residues in the "binding motif" obtained by pool sequencing does not necessarily yield an optimal binding peptide. For RT1-A1(c), as many as four positions, P2, P4, P5, and P9, were detected as putative anchors. Since this molecule displays a preference for highly hydrophobic peptides, we tested binding of peptides derived from the known leader peptide sequences of other rat histocompatibility complex class I molecules. One such peptide, found to bind well, requiring 1.6 microm peptide to achieve 50% stabilization, was searched for in vivo. Natural RT1-A1(c) binding peptides were purified from rat splenocytes and characterized by mass spectrometry using a combined matrix-assisted laser desorption ionization/time-of-flight and quadrupole time-of-flight approach. Results showed that the signal sequence-derived peptide was not detectable in the purified peptide pool, which was composed of a complex spectrum of peptides. Seven of these self-peptides were successfully sequenced.     

Physical mapping of the major histocompatibility complex class II and class III regions of the rat

A contig of overlapping bacterial and P1-derived artificial chromosome (BAC, PAC) clones derived from the inbred rat strain BN was constructed that encompasses the class II and the class III regions of the rat MHC (RT1 complex). The genomic structure of the rat, human, and mouse class II and class III regions is highly similar. However, different from human and mouse, a copy of the C4, Cyp21, and Stk19 genes is found that maps to the class II region in the rat. Gene trees constructed from human, rat, and mouse C4, Cyp21, and Stk19 sequences show species-specific clustering of the duplicated genes. The class II/III contig reported here links two previously published PAC contigs of the BN rat that contain the centromeric and the telomeric class I regions, RT1-A and RT1-C/E/M, respectively. Thus, the MHC of the rat is now completely mapped in a single contig of BAC/PAC clones derived from a single RT1 haplotype and encompasses about 3.7 Mb.     

New genes in the class II region of the human major histocompatibility complex

A detailed map of the class II region of the human major histocompatibility complex has been constructed by pulsed-field gel electrophoresis. This map revealed clusters of sites for enzymes that cut preferentially in unmethylated CpG-rich DNA often found at the 5' ends of genes. Three of these clusters have been cloned by cosmid walking and chromosome jumping. Analysis of the clones encompassing these regions through the use of zoo blots, Northern blots, and cDNA libraries resulted in the discovery of four novel genes. The D6S111E and D6S112E genes are centromeric to the HLA-DPB2 gene, while D6S113E and D6S114E are between HLA-DNA and HLA-DOB. Preliminary characterization of the new genes indicates that they are unrelated to the class II genes themselves, although D6S114E expression, like class II expression, is inducible with interferon. In addition, the HLA-DNA gene has been accurately positioned and oriented for the first time.     

Expression and characterization of ovine major histocompatibility complex class II (OLA-DR) genes

Previous work made use of nucleic acid probes corresponding to different subtypes of the class II regions of the human and murine major histocompatibility complex (MHC) to isolate seven different alpha and 24 different beta genes of the ovine MHC from two cosmid libraries. In an attempt to identify pairs of alpha and beta genes capable of cell surface expression, all permutations of alpha and beta genes were in turn transfected into mouse L-cells. Two pairs of alpha and beta genes co-expressed and stable ovine MHC class II L-cell lines were developed. The expressed alpha genes had previously been defined as DR-alpha homologues (DRA) by differential Southern hybridization to human subtype specific class II probes. The expressed ovine beta genes were also assigned as ovine DR-beta homologues (DRB) on the basis of their sequence having a higher degree of similarity with human DRB than any other subtype. A total of eight out of 23 anti-sheep class II specific monoclonal antibodies were typed OLA-DR specific by FACScan analysis using the L-cell lines.