Class II major histocompatibility complex genes of the sheep

A chromosome-scale reference genome and genome-wide genetic variations elucidate adaptation in yak

Yak is an important livestock animal for the people indigenous to the harsh, oxygen‐limited Qinghai‐Tibetan Plateau and Hindu Kush ranges of the Himalayas. The yak genome was sequenced in 2012, but its assembly was fragmented because of the inherent limitations of the Illumina sequencing technology used to analyse it. An accurate and complete reference genome is essential for the study of genetic variations in this species. Long‐read sequences are more complete than their short‐read counterparts and have been successfully applied towards high‐quality genome assembly for various species. In this study, we present a high‐quality chromosome‐scale yak genome assembly (BosGru_PB_v1.0) constructed with long‐read sequencing and chromatin interaction technologies. Compared to an existing yak genome assembly (BosGru_v2.0), BosGru_PB_v1.0 shows substantially improved chromosome sequence continuity, reduced repetitive structure ambiguity, and gene model completeness. To characterize genetic variation in yak, we generated de novo genome assemblies based on Illumina short reads for seven recognized domestic yak breeds in Tibet and Sichuan and one wild yak from Hoh Xil. We compared these eight assemblies to the BosGru_PB_v1.0 genome, obtained a comprehensive map of yak genetic diversity at the whole‐genome level, and identified several protein‐coding genes absent from the BosGru_PB_v1.0 assembly. Despite the genetic bottleneck experienced by wild yak, their diversity was nonetheless higher than that of domestic yak. Here, we identified breed‐specific sequences and genes by whole‐genome alignment, which may facilitate yak breed identification.

The diversity of major histocompatibility complex class II DRB1 gene in sheep breeds from Xinjiang, China

Exon 2 of the ovine leukocyte antigen OLA-DRB1 locus was examined in sheep from the Xinjiang Karakul Ram and Bashibai populations, and three generations of hybrids were derived from a cross between Bashibai and Altai Argali wild sheep. This identified 12 novel alleles and 30 previously reported alleles. A neighbor-joining tree of the amino acid sequences of these 42 alleles revealed allelic clusters shared across the study populations. There were significant differences in allelic frequency between Karakul Ram and Bashibai sheep. DRB1*K18cC was the most frequent allele in Kararul Ram with a frequency of 21.2%, while DRB1*2F10c8 (13.2%) and DRB1*0803 (13.2%) were the most frequent alleles found in Bashibai sheep; the alleles DRB1*2F16c2, DRB1*1601, and DRB1*0803 occurred most frequently in F1, F2, and F3 populations, with frequencies of 17.6%, 14.3%, and 20%, respectively. Although many alleles were shared by Bashibai and hybrid sheep, some alleles differed between them, especially in the F1 generation of the Bashibai × Altai Argali cross. The hybrid-specific alleles indicated the introgression of Altai Argali alleles into hybrid flocks. A population tree based on the OLA-DRB1 allelic frequency in each population indicated that the Bashibai sheep and three hybrid populations were similar, with Karakul Ram being genetically distinct.

A physical map of a BAC clone contig covering the entire autosome insertion between ovine MHC Class IIa and IIb

Background

The ovine Major Histocompatibility Complex (MHC) harbors genes involved in overall resistance/susceptibility of the host to infectious diseases. Compared to human and mouse, the ovine MHC is interrupted by a large piece of autosome insertion via a hypothetical chromosome inversion that constitutes ~25% of ovine chromosome 20. The evolutionary consequence of such an inversion and an insertion (inversion/insertion) in relation to MHC function remains unknown. We previously constructed a BAC clone physical map for the ovine MHC exclusive of the insertion region. Here we report the construction of a high-density physical map covering the autosome insertion in order to address the question of what the inversion/insertion had to do with ruminants during the MHC evolution.

Results

A total of 119 pairs of comparative bovine oligo primers were utilized to screen an ovine BAC library for positive clones and the orders and overlapping relationships of the identified clones were determined by DNA fingerprinting, BAC-end sequencing, and sequence-specific PCR. A total of 368 positive BAC clones were identified and 108 of the effective clones were ordered into an overlapping BAC contig to cover the consensus region between ovine MHC class IIa and IIb. Therefore, a continuous physical map covering the entire ovine autosome inversion/insertion region was successfully constructed. The map confirmed the bovine sequence assembly for the same homologous region. The DNA sequences of 185 BAC-ends have been deposited into NCBI database with the access numbers HR309252 through HR309068, corresponding to dbGSS ID 30164010 through 30163826.

Conclusions

We have constructed a high-density BAC clone physical map for the ovine autosome inversion/insertion between the MHC class IIa and IIb. The entire ovine MHC region is now fully covered by a continuous BAC clone contig. The physical map we generated will facilitate MHC functional studies in the ovine, as well as the comparative MHC evolution in ruminants.

MHC class II DR allelic diversity in bighorn sheep

We hypothesized that decreased diversity and/or unique polymorphisms in MHC class II alleles of bighorn sheep (BHS, Ovis canadensis) are responsible for lower titer of antibodies against Mannheimia haemolytica leukotoxin, in comparison to domestic sheep (DS, Ovis aries). To test this hypothesis, DRA and DRB transcripts from 24 captive BHS (Ovca-DRA and Ovca-DRB) were sequenced. Based on exon 2 (β1 domain) sequences, eight different Ovca-DRB cDNA sequences were identified in BHS. Six of them were 100% identical to previously reported Ovca-DRB genomic DNA sequences. The new alleles DRB*23 and DRB*24, were closely related to two other Ovca-DRB exon 2 genomic DNA sequences. Nineteen out of 24 BHS (79%) Ovca-DRB exon 3 (β2 domain) sequences were 100% identical to exon 3 sequence of DRB1 of DS (Ovar-DRB1). Ovca-DRA full length cDNA sequences exhibited >99% identity. Based upon exon 2 sequences, this BHS herd yielded higher Ovca-DRB allelic diversity than that reported in the previous study. Positively selected amino acid positions were identified in the peptide-binding groove of BHS and DS, but BHS showed more such sites. This highlights differing population histories, and may suggest differing needs for DR peptide-binding specificities. Presence of glutamine at position 52 (52Q) in some of the desert and captive BHS is predicted to alter the efficiency of DR dimerization, which may influence antigen presentation and T(h) cell activation. Functional assays with unique alleles should reveal whether the presentation of M. haemolytica leukotoxin peptides to T(h) cells by Ovca-DRB alleles is equivalent to that of Ovar-DRB1 alleles.

A single nomenclature and associated database for alleles at the major histocompatibility complex class II DRB1 locus of sheep

The development of standardised nomenclatures with associated databases containing reference sequences for alleles at polymorphic loci within the major histocompatibility complex (MHC) has been facilitated by the development of the immuno polymorphism database (IPD). Recently, included within IPD-MHC is information on allelic diversity within sheep species (IPD-MHC-OLA). Here, we present the first report of progress in populating the sheep IPD-MHC database with alleles at the class II MHC DRB1 locus. The sequence of 63 Ovar-DRB1 alleles within 24 allelic families is now held within the database, each meeting the minimum requirement of a complete second exon. These sequences are derived from a combination of genomic and cDNA-based approaches and represent the most extensive collection of validated alleles at the sheep DRB1 locus yet described. Although these 63 alleles probably represent only a fraction of the DRB1 allelic diversity in sheep species worldwide, we encourage the research community to use the official allelic nomenclature and to contribute allelic sequences to the database via its web-based submission tool. In time, the IPD-MHC-OLA resource will underpin population-based MHC genotyping studies and help to simplify meta-analyses of multi-source data from wild and domestic sheep populations.

A complete DNA sequence map of the ovine major histocompatibility complex

Background

The ovine Major Histocompatibility Complex (MHC) harbors clusters of genes involved in overall resistance/susceptibility of an animal to infectious pathogens. However, only a limited number of ovine MHC genes have been identified and no adequate sequence information is available, as compared to those of swine and bovine. We previously constructed a BAC clone-based physical map that covers entire class I, class II and class III region of ovine MHC. Here we describe the assembling of a complete DNA sequence map for the ovine MHC by shotgun sequencing of 26 overlapping BAC clones.

Results

DNA shotgun sequencing generated approximately 8-fold genome equivalent data that were successfully assembled into a finished sequence map of the ovine MHC. The sequence map spans approximately 2,434,000 nucleotides in length, covering almost all of the MHC loci currently known in the sheep and cattle. Gene annotation resulted in the identification of 177 protein-coding genes/ORFs, among which 145 were not previously reported in the sheep, and 10 were ovine species specific, absent in cattle or other mammals. A comparative sequence analyses among human, sheep and cattle revealed a high conservation in the MHC structure and loci order except for the class II, which were divided into IIa and IIb subregions in the sheep and cattle, separated by a large piece of non-MHC autosome of approximately 18.5 Mb. In addition, a total of 18 non-protein-coding microRNAs were predicted in the ovine MHC region for the first time.

Conclusion

An ovine MHC DNA sequence map was successfully assembled by shotgun sequencing of 26 overlapping BAC clone. This makes the sheep the second ruminant species for which the complete MHC sequence information is available for evolution and functional studies, following that of the bovine. The results of the comparative analysis support a hypothesis that an inversion of the ancestral chromosome containing the MHC has shaped the MHC structures of ruminants, as we currently observed in the sheep and cattle. Identification of relative large numbers of microRNAs in the ovine MHC region helps to provide evidence that microRNAs are actively involved in the regulation of MHC gene expression and function.

Trans-species polymorphism and selection in the MHC class II DRA genes of domestic sheep

Highly polymorphic genes with central roles in lymphocyte mediated immune surveillance are grouped together in the major histocompatibility complex (MHC) in higher vertebrates. Generally, across vertebrate species the class II MHC DRA gene is highly conserved with only limited allelic variation. Here however, we provide evidence of trans-species polymorphism at the DRA locus in domestic sheep (Ovis aries). We describe variation at the Ovar-DRA locus that is far in excess of anything described in other vertebrate species. The divergent DRA allele (Ovar-DRA*0201) differs from the sheep reference sequences by 20 nucleotides, 12 of which appear non-synonymous. Furthermore, DRA*0201 is paired with an equally divergent DRB1 allele (Ovar-DRB1*0901), which is consistent with an independent evolutionary history for the DR sub-region within this MHC haplotype. No recombination was observed between the divergent DRA and B genes in a range of breeds and typical levels of MHC class II DR protein expression were detected at the surface of leukocyte populations obtained from animals homozygous for the DRA*0201, DRB1*0901 haplotype. Bayesian phylogenetic analysis groups Ovar-DRA*0201 with DRA sequences derived from species within the Oryx and Alcelaphus genera rather than clustering with other ovine and caprine DRA alleles. Tests for Darwinian selection identified 10 positively selected sites on the branch leading to Ovar-DRA*0201, three of which are predicted to be associated with the binding of peptide antigen. As the Ovis, Oryx and Alcelaphus genera have not shared a common ancestor for over 30 million years, the DRA*0201 and DRB1*0901 allelic pair is likely to be of ancient origin and present in the founding population from which all contemporary domestic sheep breeds are derived. The conservation of the integrity of this unusual DR allelic pair suggests some selective advantage which is likely to be associated with the presentation of pathogen antigen to T-cells and the induction of protective immunity.

Sequence-based genotyping of the sheep MHC class II DRB1 locus

The immunopolymorphism database (IPD) provides a single nomenclature for alleles at the major histocompatibility complex (MHC) loci for a range of different species. The minimum requirements for inclusion of a sheep class II DRB1 sequence is a submission that includes all polymorphic sites within the second exon from at least two independent polymerase chain reactions (PCR). In order to meet these requirements, we have developed a DNA-based genotyping method for the rapid analysis of allelic diversity at the DRB1 locus in domestic sheep, Ovis aries. Using a series of primers located within introns flanking exon 2 and genomic DNA from a cohort of 214 sheep representing 15 different breeds and crossbreeds, the complete exon 2 sequences of 38 Ovar-DRB1 alleles were obtained. This sequence resource allowed the development of a generic set of locus-specific primers which amplify a fragment that includes all polymorphic sites within the second exon. Bidirectional sequence analysis of the PCR product provides a composite sequence where each polymorphic site is represented by the corresponding International Union of Biochemistry nucleotide code. A Basic Local Alignment Search Tool search of alleles held within the IPD or National Center for Biotechnology Information databases allows individual allele sequences to be identified. Low levels of homozygosity (7.48%) within the cohort and verification of previously genotyped samples confirmed the broad allelic specificity of this method. It improves on currently available methods and is broadly applicable to the analysis of MHC diversity in studies investigating linkages with resistance or susceptibility to disease.

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.

Genomic organisation and allelic diversity within coding and non-coding regions of the Ovar-DRB1 locus

In all but the most primitive vertebrates, multiple polymorphic genes associated with lymphocyte-mediated immunological surveillance are linked together within genomic regions termed the major histocompatibility complex (MHC). The extensive diversity at many MHC loci provides a valuable source of genetic markers for examining the complex relationships between host genotype and disease resistance or susceptibility. Such studies in domestic sheep (Ovis aries) have generally focused on exon 2 of the polymorphic class II MHC DRB1 gene and its adjacent sequences. We have determined the complete genomic sequences of two Ovar-DRB1 alleles, which has allowed an analysis of diversity at coding, non-coding and promoter regions of this gene. On the basis of these sequences, oligonucleotide primers were designed for amplification of full-length Ovar-DRB1 transcripts and used to evaluate diversity within an MHC-defined resource flock maintained at the Moredun Institute. We describe nine novel full-length Ovar-DRB1 sequences along with an improved direct-sequencing method for analysis of the entire exon 2 region of the Ovar-DRB1 gene based on previously unknown intronic sequences. We discuss how these data provide evidence on the evolution of MHC DRB diversity in domestic sheep.

A BAC clone-based physical map of ovine major histocompatibility complex

An ovine bacterial artificial chromosome (BAC) library containing 190,000 BAC clones was constructed and subsequently screened to construct a BAC-based physical map for the ovine major histocompatibility complex (MHC). Two hundred thirty-three BAC clones were selected by 84 overgo probes designed on human, mouse, and swine MHC sequence homologies. Ninety-four clones were ordered by DNA fingerprinting to form contigs I, II, and III that correspond to ovine MHC class I-class III, class IIa, and class IIb. The minimum tiling paths of contigs I, II, and III are 15, 4, and 4 BAC clones, spanning approximately 1900, 400, and 300 kb, respectively. The order and orientation of most BAC clones in each contig were confirmed by BAC-end sequencing. An open gap exists between class IIa and class III. This work helps to provide a foundation for detailed study of ovine MHC genes and of evolution of MHCs in mammals.

Identification and phylogenetic analysis of 15 MHC class II DRB1 β1 expressed alleles in a ewe–lamb flock

Ovar-DRB1 is part of the major histocompatibility complex (MHC) class II of sheep and functions by presenting extracellular-derived peptides to the immune system. Although there are over 100 different Ovar-DRB1 DNA sequences reported in GenBank, only two Ovar-DRB1 mRNA sequences have been reported. As a first step in understanding MHC Class II function as it relates to disease progression in sheep, Ovar-DRB1 transcripts encoding the peptide-binding site or the first domain (beta1) of Ovar-DRB1 in a 32-ewe-lamb flock were identified and characterized by using reverse transcriptase-polymerase chain reaction, cloning, sequencing, and phylogenetic analysis. Fourteen new Ovar-DRB1 beta1 cDNA sequences out of a total of 15 Ovar-DRB1 beta1 cDNA sequences in a ewe-lamb flock of 32 sheep were identified. One Ovar-DRB1 beta1 cDNA sequence was 100% identical to M93432, one of the two Ovar-DRB1 mRNA sequences reported in GenBank. Twelve out of 15 Ovar-DRB1 beta1 cDNA sequences were 100% identical to the corresponding previously reported Ovar-DRB1 genomic DNA sequences, indicating that these Ovar-DRB1 genomic DNA sequences are also transcribed. One of three of the remaining Ovar-DRB1 beta1 cDNA sequences, DRB1*07012, had a synonymous substitution resulting in an identical deduced amino acid sequence to DRB1*0701. Two of the remaining three Ovar-DRB1 beta1 cDNA sequences had nucleotide differences and subsequent deduced amino acid sequence differences when compared to known Ovar-DRB1 beta1 genomic DNA sequences, and therefore, DRB1*0206 and DRB1*0353 represent new Ovar-DRB1 beta1 expressed alleles. Phylogenetic analysis of the 15 Ovar-DRB1 beta1 cDNA sequences revealed that DRB1*0206 had a strong phylogenetic relationship to DRB1*0203, and DRB1*0353 had a strong phylogenetic relationship to DRB1*0303.

Diversity of the ovine DQA2 gene1

Variation in the ovine DQA2 gene was investigated in approximately 2,000 sheep from six breeds. Fragments of DNA containing the ovine DQA2 exon 2 were amplified using PCR. Single-strand conformational polymorphism analysis and DNA sequence analysis were employed to detect genetic variation. Twenty-three nucleic acid sequences, encoding 22 DQA2 amino acid sequences, were identified. This increases the number of alleles identified from 10 to 23. In some cases, three or four unique sequences were isolated from individual sheep, suggesting that these DQA2 sequences may represent two loci. Phylogenetic tree analysis revealed that 5 of these 23 sequences were more closely related to cattle DQA3 or DQA4 sequences than to other sheep DQA2 sequences. These sequences clustered together and were called DQA2-like to differentiate them from other DQA2 sequences. There was no evidence of DQA5-like sequences in sheep. Information theory-based analysis indicated that some of the DQA2-like sequences had low information content at splice sites, suggesting that these alleles may have low functional activity. Allelic lineages were observed not only at the DQA2 locus, but also at the DQA2-like locus, supporting the trans-species mode of evolution of MHC genes. Comparison of the allelic sequences suggests that polymorphism seems to have arisen largely by point mutation and gene conversion, and a recent gene conversion event seems to have occurred between the DQA2 and DQA2-like loci. The high level of sequence polymorphism detected and varied number of loci demonstrate the extensive diversity of the ovine DQA2 gene.

Sequences and diversity of 17 new Ovar-DRB1 alleles from three breeds of sheep

To investigate the genetic diversity of the sheep MHC (Ovar) class II DRB1 locus, we amplified exon 2 of Ovar-DRB1 alleles by polymerase chain reaction (PCR) and determined the nucleotide sequences of both resultant strands after cloning. In our study of a total of 97 sheep of three breeds, namely, Suffolk, Cheviot and Corriedale, we identified 18 previously published alleles and 17 new alleles. These alleles were 83.4 to 94.1% identical at the nucleotide level and 71.4 to 90.9% identical at the amino acid level to Ovar-DRB1*0101. We identified six new alleles in Cheviot sheep and 11 new alleles in Suffolk sheep. Furthermore, we identified 15, 6 and 1 allele in Suffolk, Cheviot and Corriedale sheep, respectively, that have only been found in these breeds to date. Analysis of the frequencies of the various Ovar-DRB1 alleles in each breed indicated that Ovar-DRB1*0702 was the most frequent allele in Suffolk sheep (23.9%), Ovar-DRB1*0203 was the most frequent allele in Cheviot sheep (27.5%) and Ovar-DRB1*0201 was the most frequent allele in Corriedale sheep (25.0%). A comparative analysis of the positions of polymorphic residues in the first extracellular domain of the DRB genes of sheep, humans and mice revealed an extraordinary similarity amongst the positions of polymorphic residues that are associated with the antigen recognition site (ARS). Moreover, the extent of polymorphism seems to be similar in sheep, humans and mice.

Polymorphism at the ovine major histocompatibility complex class II loci

Southern hybridization analysis of the ovine major histocompatibility complex (MHC) (MhcOvar) class II region, using sheep-specific probes for the DQA1, DQA2, DQB and DRA loci, has revealed extensive polymorphism. DQA1 and DQA2 had eight and 16 alleles respectively, DQB had six and DRA had three alleles. Little information was derived from the DRB locus owing to extensive cross-hybridization between the DRB probe and the DQB locus. Differences in allele frequency between breeds were revealed. At the DQA1 locus a null allele (DQA1-N) was observed with a frequency of between 27% and 45%, making this the most common DQA1 allele in all breeds examined. The frequency of DQA1-N homozygotes was between 11% and 18%, raising questions as to the functional significance of the DQA1 gene. Linkage analysis between the DQA1, DQA2, DQB and DRA loci did not reveal any recombination.

The use of embryo genotyping in the propagation of genes involved in the immune response

Multiple ovulation and embryo transfer (MOET) now enables researchers to produce identical twin animals, to obtain progeny from pre-pubertal females and to obtain more offspring from valuable animals. MOET and sexed semen have produced genetic progress of up to 60% of milk production. The oestrous cycles of animals are synchronized with progestagens before superovulation with gonadal hormones, pregnant mare serum gonadotrophin and follicle stimulating hormone. Surgical, non-surgical and laparoscopic methods are applied to recover and transfer embryos. Sexing and genotyping of the pre-implantation embryos is a key step in improving the management and breeding programmes for livestock, as well as in the human for the prenatal diagnosis of genetic disorders. Several serological and physiological methods have been used to determine the sex of the pre-implantation embryos; none has had satisfactory results in terms of time and accuracy. Sexing by polymerase chain reaction (PCR) using male-specific chromosome sequences alone or with female-specific chromosomal DNA probes simultaneously has been sufficient to identify the sex of the embryos with 100% accuracy. However, caution should be taken against sources of the contamination. The MHC class I, class II and background genes have been implicated in resistance to internal parasites in animals. Biotechnological methods such as screening of embryos prior to transfer using PCR and primer extension pre-amplification have already made it possible to detect transgenic or genetically disordered embryos and could be applied to select those embryos bearing immunological genotypes of interest, such as resistance to internal parasites. Ultimately, cloning and nuclear transplantation would provide the possibility of isolating these resistance genes and to transfer them to livestock pre-implantation embryos to propagate these desirable traits.

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 transfectants, 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.

Evidence for the expression of two distinct MHC class II DR beta like molecules in the sheep

This study used monoclonal antibodies to sheep MHC class II molecules as well as an L cell transfectant (T8.1) which expresses DRA and DRB genes to show that two distinct DR beta chains are expressed in the sheep. Two anti-beta chain specific monoclonal antibodies VPM37 and VPM43 react with DR antigen but not DQ antigen by ELISA. These two antibodies do not react with the DR beta chain expressed in the T8.1 cell line. Two-dimensional immunoblotting shows that these antibodies recognize a subgroup of the spots recognized by the DR-specific monoclonal antibody VPM57 which does react with the T8.1 beta chain. Amino-terminal sequence analysis of the alpha chain associated with VPM37 beta chain shows that this alpha chain is homologous to the human DR alpha chain strongly indicating that the beta chain is DR-like. VPM37 and VPM43 are shown to be directed against different epitopes on sheep MHC class II molecules so it is highly unlikely that the data can be explained by the presence of post-translational modifications or the existence of a very common allele. These data provide clear evidence for the expression of two distinct DR beta chains in the sheep.

Mapping and characterization of the DQ subregion of the ovine MHC

A map of the ovine MHC class II DQ subregion has been constructed from overlapping cosmid clones. This region consists of two loci linked on a linear tract of 130 kb DNA. Each locus consists of a DQA and a DQB gene in a tail-to-tail orientation. The genes in each locus are transcribed but only those designated DQ1 express class II molecules at the surface of mouse L cells following DNA-mediated gene transfection. The DQA1 and DQB1 genes are separated by 11 kb while the DQA2 and B2 genes are 25 kb apart. The loci are separated by 22 kb.

Restriction fragment length polymorphism of DQB and DRB class II genes of the ovine major histocompatibility complex

The ovine major histocompatibility complex (MhcOvar) class II region was investigated by Southern blot hybridizations using ovine probes specific for the second exons of Ovar-DRB and Ovar-DQB genes. Multiple bands were revealed when genomic DNA was digested with each of five restriction enzymes (BamHI, EcoRI, HindIII, PvuII and TaqI), and successively hybridized with the two radiolabelled ovine probes. Restriction fragment length polymorphisms (RFLPs) were analysed in 89 sheep originating from six inbred families and the inheritance of the fragment patterns was determined. Forty-one fragments were recorded with the DQB probe; 32 were detected with the DRB probe. They constituted 9 DQB and 10 DRB allelic patterns. Twelve DQB-DRB haplotypes were resolved in this study.

Isolation, characterization and evolution of ovine major histocompatibility complex class II DRA and DQA genes

Four full-length ovine major histocompatibility complex (MHC) class II A cDNA clones coding for new alleles of DRA, DQA1 and DQA2 genes were isolated from two ovine lambda gt10 cDNA libraries. The derived amino acid sequences of these clones resemble class II A molecules from other species in both size and structure. Restriction fragment length polymorphism analysis, using an Ovar-DRA probe on DNA from Merino and Romney sheep revealed only limited polymorphism in contrast to the high levels of polymorphism revealed by Ovar-DQA probes. Comparison of the predicted amino acid sequences for the three ovine A genes with class II A genes from five other species revealed that the most variable region of the molecule is the signal peptide. Although virtually every amino acid site shows variation, within or between species, there are some blocks of highly conserved residues. Within gene comparisons of nucleotide differences reveal that the greatest number of changes is found between the alleles of Ovar-DQA1 and -DQA2 genes and the least between Ovar-DRA1 alleles. Phylogenetic analysis of class II A sequences from several species place DRA and DQA genes on two distinct branches, with Ovar-DRA1 and BOLA-DRA, and Ovar-DQA1 and BOLA-DQA being most similar on their respective branches.

Towards covering immunological genes with highly informative markers: a trans-species approach

To establish a highly informative screening system for immunologically relevant genes ("immunoprinting") we co-amplified via polymerase chain reaction (PCR) polymorphic exons plus adjacent intronic simple repetitive dinucleotide stretches in the T-cell receptor (Tcr) Vb6 and Major Histocompatibility Complex (MHC)-DRB loci in man and several ungulate species. In both gene families the basic structure of the simple repeat was found to be preserved for more than 70 x 10(6) years in all investigated species. The simple repeats exhibit extensive length variability. Distinct exon sequences are correlated with a defined repeat length and substructure. In addition, PCR and the oligonucleotides for typing were applicable to a broad range of species from different mammalian orders. Multiplex PCR of different members of the Tcr Vb6 family and MHC-DRB resulted in a complex pattern similar to an oligolocus fingerprint. Hence immunoprinting can be employed for searching for associations of immunologically relevant genes with diseases even across species barriers.