Molecular characterization of swine leucocyte antigen class I genes in outbred pig populations

The highly polymorphic swine leucocyte antigen ( SLA ) genes are one of the most important determinants in swine immune responses to infectious diseases, vaccines, and in transplantation success. Study of SLA influence requires accurate and effective typing methods. We developed a simple and rapid method to type alleles at the three classical SLA class I loci ( SLA-1 , SLA-3 and SLA-2 ) using the PCR-sequence-specific primer (PCR-SSP) strategy. This typing system relies on 47 discriminatory PCR primer pairs designed to amplify the SLA class I alleles by groups that have similar sequence motifs. We applied this low-resolution group-specific typing method to characterize the SLA class I alleles present in three outbred pig populations ( n =  202). Alleles from 24 class I allele groups corresponding to 56 class I genotypes were detected. We also identified 23 low-resolution SLA class I haplotypes in these pigs and found haplotypes Lr-1.0 ( SLA-1 *01XX- SLA-3 *01XX- SLA-2 *01XX) and Lr-4.0 ( SLA-1 *04XX- SLA-3 *04XX- SLA-2 *04XX) in all three pig populations with a high prevalence. Over 80% of the pigs examined ( n  =   162) were found to bear at least one of these haplotypes, resulting in a combined haplotype frequency of nearly 50%. This PCR-SSP-based typing system demonstrates a reliable and unambiguous detection of SLA class I alleles, and can be used to effectively investigate the SLA diversity in outbred pig populations. It will help to identify the role of SLA antigens in disease-resistant pigs and may facilitate the development of effective vaccines.     

Establishment of a resource population of SLA haplotype-defined Korean native pigs

The highly polymorphic porcine major histocompatibility complex (MHC), or the swine leukocyte antigens (SLA), has been repeatedly associated with variations in swine immune response to pathogens and vaccines as well as with production traits. The SLA antigens are also important targets for immunological recognition of foreign tissue grafts. We recently established a resource population of Korean native pigs as models for human transplantation and xenotransplantation research. In this study, 115 animals derived from three generations of the Korean native pigs were genotyped for three SLA class I (SLA-2, SLA-3 and SLA-1) and three SLA class II loci (DRB1, DQB1, DQA) using PCR with sequence-specific primers (PCR-SSP) at the allele group resolution. A total of seven SLA haplotypes (Lr-5.34, Lr-7.23, Lr-31.13, Lr-56.23, Lr-56.30, Lr-59.1, Lr-65.34), comprising six unique class I and five unique class II haplotypes, were characterized in the founding animals. Class I haplotype Lr-65.0 and class II haplotype Lr-0.34 were novel; and together with Lr-56.0 these haplotypes appeared to be breed-specific. In the progeny population, Lr-7.23 and Lr-56.30 appeared to be the most prevalent haplotypes with frequencies of 34.7% and 31.6%, respectively; the overall homozygosity was 27.4%. This resource population of SLA-defined Korean native pigs will be useful as large animal models for various transplantation and xenotransplantation experiments, as well as for dissecting the roles of SLA proteins in swine disease resistance and production traits.     

Investigation of SLA class I and II haplotypes in the NIH miniature pigs

Xenotransplantation involves the transplantation of organs, tissues and cells from one species to another. A major barrier to successful xenotransplantation is the rejection of the donor tissue by the recipient immune system. Swine leukocyte antigens (SLA) are important molecules within the immune system and play an essential role in fighting infectious diseases and viruses. The present study investigated three SLA class I (SLA-1, SLA-3 and SLA-2) and three SLA class II (DRB1, DQB1 and DQA) alleles in 60 NIH miniature pigs using PCR with sequence-specific primers (PCR-SSP). As the results, nine combinations of SLA class I and II haplotypes, comprising of three homozygous and six heterozygous haplotypes, were examined. The SLA homozygous haplotype Lr-2.4/2.4 was the most prevalent, with an overall frequency of 28.3% (17/60) and heterozygous haplotype Lr-2.2/4.4 was the second most common (20.0%; 12/60), followed by haplotype Lr-4.2/4.2 (16.7%; 10/60), Lr-2.2/2.4 (15.0%; 9/60), Lr-2.2/2.2 (5.0%; 3/60), Lr-2.2/4.2 (5.0%; 3/60), Lr-2.4/4.4 (5.0%; 3/60) and Lr-2.2/3.3 (3.3%; 2/60), Lr-4.2/4.4 (1.7%; 1/60), respectively. These results provide useful information that can be used to establish highly inbred pig lines with fixed SLA homozygous alleles and haplotypes.     

Difference in number of loci of swine leukocyte antigen classical class I genes among haplotypes

The structure of the entire genomic region of swine leukocyte antigen (SLA)-the porcine major histocompatibility complex--was recently elucidated in a particular haplotype named Hp-1.0 (H01). However, it has been suggested that there are differences in the number of loci of SLA genes, particularly classical class I genes, among haplotypes. To clarify the between-haplotype copy number variance in genes of the SLA region, we sequenced the genomic region carrying SLA classical class I genes on two different haplotypes, revealing increments of up to six in the number of classical class I genes in a single haplotype. All of the SLA-1(-like) (SLA-1 and newly designated SLA-12) and SLA-3 genes detected in the haplotypes thus analyzed were transcribed in the individual. The process by which duplication of SLA classical class I genes was likely to have occurred was interpreted from an analysis of repetitive sequences adjacent to the duplicated class I genes.     

Microsatellite diversity and crossover regions within homozygous and heterozygous SLA haplotypes of different pig breeds

Our aim was to investigate microsatellite (MS) diversity and find crossover regions at 42 polymorphic MS loci in the swine leukocyte antigen (SLA) genomic region of 72 pigs with different well-defined homozygous and heterozygous SLA haplotypes. We analyzed the genetic polymorphisms of 42 MS markers in 23 SLA homozygous-heterozygous, common pig breeds with 12 SLA serological haplotypes and 49 National Institutes of Health (NIH) and Clawn homozygous-heterozygous miniature pigs with nine SLA serological or genotyped haplotypes including four recombinant haplotypes. In comparing the same and different haplotypes, both haplospecific patterns and allelic variations were observed at the MS loci. Some of the shared haplotype blocks extended over 2 Mb suggesting the existence of strong linkage disequilibrium (LD) in the entire SLA region. Crossover regions were easily defined by the MS markers within the class I and/or III region in the NIH and Clawn recombinant haplotypes. The present haplotype comparison shows that our set of MS markers provides a fast and cost-efficient alternative, or complementary, method to the serological or sequence-based determination of the SLA alleles for the characterization of SLA haplotypes and/or the crossover regions between different haplotypes.     

Characterization of swine leukocyte antigen alleles and haplotypes on a novel miniature pig line,Microminipig

Microminipigs are extremely small‐sized, novel miniature pigs that were recently developed for medical research. The inbred Microminipigs with defined swine leukocyte antigen (SLA) haplotypes are expected to be useful for allo‐ and xenotransplantation studies and also for association analyses between SLA haplotypes and immunological traits. To establish SLA‐defined Microminipig lines, we characterized the polymorphic SLA alleles for three class I (SLA‐1, SLA‐2 and SLA‐3) and two class II (SLA‐DRB1 and SLA‐DQB1) genes of 14 parental Microminipigs using a high‐resolution nucleotide sequence‐based typing method. Eleven class I and II haplotypes, including three recombinant haplotypes, were found in the offspring of the parental Microminipigs. Two class I and class II haplotypes, Hp‐31.0 (SLA‐1*1502–SLA‐3*070102–SLA‐2*1601) and Hp‐0.37 (SLA‐DRB1*0701–SLA‐DQB1*0502), are novel and have not so far been reported in other pig breeds. Crossover regions were defined by the analysis of 22 microsatellite markers within the SLA class III region of three recombinant haplotypes. The SLA allele and haplotype information of Microminipigs in this study will be useful to establish SLA homozygous lines including three recombinants for transplantation and immunological studies.     

Molecular characterization of swine leukocyte antigen gene diversity in purebred Pietrain pigs

The porcine major histocompatibility complex (MHC) harbors the highly polymorphic swine leukocyte antigen (SLA) class I and II gene clusters encoding glycoproteins that present antigenic peptides to T cells in the adaptive immune response. In Austria, the majority of commercial pigs are F ₂ descendants of F ₁ Large White/Landrace hybrids paired with Pietrain boars. Therefore, the repertoire of SLA alleles and haplotypes present in Pietrain pigs has an important influence on that of their descendants. In this study, we characterized the SLA class I ( SLA‐1 , SLA‐2 , SLA‐3 ) and class II ( SLA‐DRB1 , SLA‐DQB1 , SLA‐DQA ) genes of 27 purebred Pietrain pigs using a combination of the high‐resolution sequence‐based typing (SBT) method and a low‐resolution (Lr) PCR‐based method using allele‐group, sequence‐specific primers (PCR‐SSP). A total of 15 class I and 13 class II haplotypes were identified in the studied cohort. The most common SLA class I haplotype Lr‐43.0 ( SLA‐1 *11XX– SLA‐3 *04XX– SLA‐2 *04XX) was identified in 11 animals with a frequency of 20%. For SLA class II, the most prevalent haplotype, Lr‐0.14 [ SLA‐DRB1 *0901– SLA‐DQB1 *0801– SLA‐DQA *03XX], was found in 14 animals with a frequency of 26%. Two class II haplotypes, tentatively designated as Lr‐Pie‐0.1 [ SLA‐DRB1 *01XX/be01/ha04– SLA‐DQB1 *05XX– SLA ‐ DQA*blank] and Lr‐Pie‐0.2 [ SLA‐DRB1 *06XX– SLA‐DQB1 *03XX– SLA‐DQA *03XX], appeared to be novel and have never been reported so far in other pig populations. We showed that SLA genotyping using PCR‐SSP‐based assays represents a rapid and cost‐effective way to study SLA diversity in outbred commercial pigs and may facilitate the development of more effective vaccines or identification of disease‐resistant pigs in the context of SLA antigens to improve overall swine health.     

Diversity and locus specificity of chicken MHC B class I sequences

The major histocompatibility complex B (MHC B) region in a standard haplotype of Leghorn chickens contains two closely linked class I loci, B-FI and B-FIV. Few sequences of B-FI alleles are available, and therefore alleles of the two loci have not been compared with regard to sequence diversity or locus specificity. Here, we report eight new B-F alpha 1/alpha 2-coding sequences from broiler chicken MHC B haplotypes, and a unique recombinant between the two B-F loci. The new sequences were combined with existing B-F sequences from Leghorn and broiler haplotypes for analysis. On the basis of phylogenetic analysis and conserved sequence motifs, B-F sequences separated into two groups (Groups A and B), corresponding to B-FIV and B-FI locus, respectively. Every broiler haplotype had one B-F sequence in Group A and the second B-F sequence, if it existed, clustered in Group B. Group B (presumptive B-FI locus) sequences identified in broiler haplotypes resembled the human MHC class I HLA-C locus in their distinctive pattern of allelic polymorphism. Compared with B-FIV, B-FI alleles were less polymorphic and possessed a conserved locus-specific motif in the alpha1 helix, but nevertheless demonstrated evidence of diversifying selection. One B-FI alpha 1/alpha 2-coding nucleotide sequence was completely conserved in four different broiler haplotypes, but each allele differed in the exon encoding the alpha 3 domain.     

Molecular characterization of swine leucocyte antigen class II genes in outbred pig populations

The highly polymorphic swine leucocyte antigen (SLA) genes are among the most important determinants of swine immune responses to disease and vaccines. Accurate and effective SLA genotyping methods are required to understand how SLA gene polymorphisms affect immunity, especially in outbred pigs with diverse genetic backgrounds. In this study, we present a simple and rapid molecular‐based typing system for characterizing SLA class II alleles of the DRB1, DQB1 and DQA loci. This system utilizes a set of 47 sequence‐specific PCR primers developed to differentiate alleles by groups that share similar sequence motifs. We applied this typing method to investigate the SLA class II diversity in four populations of outbred pigs (n = 206) and characterized a total of 19 SLA class II haplotypes, six of which were shared by at least three of the sampled pig populations. We found that Lr‐0.1 (DRB1*01XX–DQB1*01XX–DQA*01XX) was the most prevalent haplotype with a combined frequency of 16.0%, followed by Lr‐0.2 (DRB1*02XX–DQB1*02XX–DQA*02XX) with 14.6% and Lr‐0.15b (DRB1*04XX–DQB1*0202–DQA*02XX) with 14.1%. Over 70% of the pigs (n = 147) had at least one copy of one of these three haplotypes. The PCR‐based typing system described in this study demonstrates a reliable and unambiguous detection method for SLA class II alleles. It will be a valuable tool for studying the influence of SLA diversity on various immunological, pathological and physiological traits in outbred pigs.     

Analysis of MHC class I genes across horse MHC haplotypes

The genomic sequences of 15 horse major histocompatibility complex (MHC) class I genes and a collection of MHC class I homozygous horses of five different haplotypes were used to investigate the genomic structure and polymorphism of the equine MHC. A combination of conserved and locus-specific primers was used to amplify horse MHC class I genes with classical and nonclassical characteristics. Multiple clones from each haplotype identified three to five classical sequences per homozygous animal and two to three nonclassical sequences. Phylogenetic analysis was applied to these sequences, and groups were identified which appear to be allelic series, but some sequences were left ungrouped. Sequences determined from MHC class I heterozygous horses and previously described MHC class I sequences were then added, representing a total of ten horse MHC haplotypes. These results were consistent with those obtained from the MHC homozygous horses alone, and 30 classical sequences were assigned to four previously confirmed loci and three new provisional loci. The nonclassical genes had few alleles and the classical genes had higher levels of allelic polymorphism. Alleles for two classical loci with the expected pattern of polymorphism were found in the majority of haplotypes tested, but alleles at two other commonly detected loci had more variation outside of the hypervariable region than within. Our data indicate that the equine major histocompatibility complex is characterized by variation in the complement of class I genes expressed in different haplotypes in addition to the expected allelic polymorphism within loci.     

Sequence of the pig major histocompatibility region containing the classical class I genes

A segment comprising 307,078 nucleotides of the pig major histocompatibility complex (SLA) was completely sequenced. The segment corresponded to the entire SLA classical class I-containing region of the serologically defined SLA H01 haplotype. In all, 11 genes were characterized, comprising 7 class I genes located on the centromeric part of the sequence (SLA-1, 2, 3, 4, 5, 9, and 11) and 4 ring finger-related family genes located on its telomeric part. No member of one family was intermingled with a member of the other or with any third-party gene. All class I genes except SLA-11 were similarly orientated. The SLA-1, 2, and 3 genes displayed both promoter and overall coding regions compatible with normal functions. The SLA-4, 11, and 9 genes were considered pseudogenes because they exhibited marked anomalies. Although the SLA-5 gene had a complete coding region, it displayed mutations in promoter elements which could modify its expression. The great molecular similarity observed among the class I genes extended far outside them, and resulted from segmental duplications. The ring finger genes exhibited great homology with their human counterparts. In pig, one of these genes appeared to correspond to a complete gene which in humans is probably a pseudogene. In all, the 11 genes characterized span about 20% of the total sequence. The remaining 80% consists of interspersed repeat elements. The present results, together with the sequence previously reported involving the SLA class I-related genes, open the way for a better understanding of pig MHC organization.     

Evidence for Directional Selection at a Novel Major Histocompatibility Class I Marker in Wild Common Frogs (Rana temporaria) Exposed to a Viral Pathogen (Ranavirus)

Whilst the Major Histocompatibility Complex (MHC) is well characterized in the anuran Xenopus, this region has not previously been studied in another popular model species, the common frog (Rana temporaria). Nor, to date, have there been any studies of MHC in wild amphibian host-pathogen systems. We characterise an MHC class I locus in the common frog, and present primers to amplify both the whole region, and specifically the antigen binding region. As no more than two expressed haplotypes were found in over 400 clones from 66 individuals, it is likely that there is a single class I locus in this species. This finding is consistent with the single class I locus in Xenopus, but contrasts with the multiple loci identified in axolotls, providing evidence that the diversification of MHC class I into multiple loci likely occurred after the Caudata/Anura divergence (approximately 350 million years ago) but before the Ranidae/Pipidae divergence (approximately 230 mya). We use this locus to compare wild populations of common frogs that have been infected with a viral pathogen (Ranavirus) with those that have no history of infection. We demonstrate that certain MHC supertypes are associated with infection status (even after accounting for shared ancestry), and that the diseased populations have more similar supertype frequencies (lower F_ST) than the uninfected. These patterns were not seen in a suite of putatively neutral microsatellite loci. We interpret this pattern at the MHC locus to indicate that the disease has imposed selection for particular haplotypes, and hence that common frogs may be adapting to the presence of Ranavirus, which currently kills tens of thousands of amphibians in the UK each year.     

A locus-wide approach to assessing variation in the avian MHC: the B-locus of the wild turkey

Studies of major histocompatibility complex (MHC) diversity in non-model vertebrates typically focus on structure and sequence variation in the antigen-presenting loci: the highly variable and polymorphic class I and class IIB genes. Although these studies provide estimates of the number of genes and alleles/locus, they often overlook variation in functionally related and co-inherited genes important in the immune response. This study utilizes the sequence of the MHC B-locus derived from a commercial turkey to investigate MHC variation in wild birds. Sequences were obtained for nine interspersed MHC amplicons (non-class I/II) from each of 40 birds representing 3 subspecies of wild turkey (Meleagris gallopavo). Analysis of aligned sequences identified 238 single-nucleotide variants approximately one-third of which had minor allele frequencies >0.2 in the sampled birds. PHASE analysis identified 70 prospective MHC haplotypes in the wild turkeys, whereas a combined analysis with commercial birds identified almost 100 haplotypes in the species. Denaturing gradient gel electrophoresis (DGGE) of the class IIB loci was used to test the efficacy of single-nucleotide polymorphism (SNP) haplotyping to capture locus-wide variation. Diversity in SNP haplotypes and haplotype sharing among individuals was directly reflected in the DGGE patterns. Utilization of a reference haplotype to sequence interspersed regions of the MHC has significant advantages over other methods of surveying diversity while identifying high-frequency SNPs for genotyping. SNP haplotyping provides a means to identify both divergent haplotypes and homozygous individuals for assessment of immunological variation in wild and domestic populations.     

Uterine MHC class I molecules and beta 2-microglobulin are regulated by progesterone and conceptus interferons during pig pregnancy

MHC class I molecules and beta(2)-microglobulin (beta(2)m) are membrane glycoproteins that present peptide Ags to TCRs, and bind to inhibitory and activating receptors on NK cells and other leukocytes. They are involved in the discrimination of self from non-self. Modification of these molecules in the placenta benefits pregnancy, but little is known about their genes in the uterus. We examined the classical class I swine leukocyte Ags (SLA) genes SLA-1, SLA-2, and SLA-3, the nonclassical SLA-6, SLA-7, and SLA-8 genes, and the beta(2)m gene in pig uterus during pregnancy. Uterine SLA and beta(2)m increased in luminal epithelium between days 5 and 9, then decreased between days 15 and 20. By day 15 of pregnancy, SLA and beta(2)m increased in stroma and remained detectable through day 40. To determine effects of estrogens, which are secreted by conceptuses to prevent corpus luteum regression, nonpregnant pigs were treated with estradiol benzoate, which did not affect the SLA or beta(2)m genes. In contrast, progesterone, which is secreted by corpora lutea, increased SLA and beta(2)m in luminal epithelium, whereas a progesterone receptor antagonist (ZK137,316) ablated this up-regulation. To determine effects of conceptus secretory proteins (CSP) containing IFN-delta and IFN-gamma, nonpregnant pigs were implanted with mini-osmotic pumps that delivered CSP to uterine horns. CSP increased SLA and beta(2)m in stroma. Cell-type specific regulation of SLA and beta(2)m genes by progesterone and IFNs suggests that placental secretions control expression of immune regulatory molecules on uterine cells to provide an immunologically favorable environment for survival of the fetal-placental semiallograft.     

Patterns of variation in MHC class II beta loci of the little greenbul (Andropadus virens) with comments on MHC evolution in birds

We have isolated major histocompatibility complex (MHC) class II beta loci from the little greenbul (Andropadus virens), an African songbird. We utilized preexisting information about conserved regions of the avian MHC to design primers to amplify a pool of sequences representing multiple loci. From this pool, a unique locus spanning 1109 bp that we designate as Anvi-DAB1 was cloned and sequenced. We designed locus-specific primers based on this sequence information and amplified six alleles from seven individuals. Compared to other A. virens MHC sequences obtained from genomic DNA or cDNA, the variability of sequences from Anvi-DAB1 was low and the ratio of nonsynonymous to synonymous substitution was much less than one, suggesting that Anvi-DAB1 may either be a pseudogene or a nonclassical MHC locus. Phylogenetic analysis revealed that the Anvi-DAB1 locus was highly divergent when compared with other passerine or A. virens genomic or transcribed MHC sequences. The use of conserved MHC primers followed by analysis of cloned sequences allows rapid isolation of MHC loci from exotic species and avoids laborious large-scale cloning and sequencing.     

Restriction fragment length polymorphism of the major histocompatibility complex of the pig

Human HLA cDNA probes were used to analyze the restriction fragment length polymorphism (RFLP) of the SLA major histocompatibility complex in swine. Cellular genomic DNA from 19 SLA homozygous pigs representing 13 different haplotypes was digested with restriction endonucleases Eco RI, Hind III, or Bam H1, separated by electrophoresis, and transferred onto diazobenzyloxymethyl paper by the Southern blot technique. The blots were probed with ³²P-labeled class I or beta-DR class II cDNA. Depending on the haplotypes and the endonucleases used, seven to ten restriction fragments hybridized with the class I probe, and five to seven with the beta-DR probe. Their sizes ranged from 3.4 to 22 kilobase-pairs. Few bands were common to all 13 haplotypes. With all but one haplotype, identical autoradiogram patterns were obtained from unrelated, but phenotypically SLA-identical pigs, suggesting that most of the RFLP revealed were controlled by the SLA region. Further polymorphism was found in a group of seven unrelated pigs which typed serologically as SLA A15 CI B18 homozygotes but could be divided into two subgroups, with five animals in one subgroup and two in the other, when the genomic DNA was hybridized with the class I probe. When the class 11 beta-DR probe was tested on the same seven pigs, another subdivision was seen, and this correlated with MLR data. These results demonstrate that HLA class I and class II probes can be used to identify certain well-established SLA haplotypes and to identify subclasses within at least one SLA haplotype.Abbreviations MHC major histocompatibility complex - MLR mixed lymphocyte reaction - kbp kilobase pair(s) - RFLP restriction fragment length polymorphism     

Mapping of C2, Bf, and C4 genes to the swine major histocompatibility complex (swine leukocyte antigen)

Three miniature swine lines, inbred for swine leukocyte antigen (SLA) haplotypes, a, c, and d, and a recombinant line, haplotype g, were analyzed for possible restriction fragment length polymorphisms (RFLP) by Southern blot hybridization with human C2, factor B (Bf), and C4 specific probes. The search for RFLP by using a human C2 probe failed to reveal any variants. However, a Taq I polymorphism was identified with the human Bf probe and Bam HI and Pvu II polymorphisms were identified with the human C4 probe. Overlapping restriction fragments were found with the C2 and Bf probes, which strongly suggests close linkage of C2 and Bf genes in swine. Segregation analyses of the Bf and C4 polymorphisms indicated that the polymorphic fragments followed a Mendelian pattern of inheritance. The recombinant haplotype g, which expresses class I genes of haplotype c and class II genes of haplotype d, was shown to produce an identical RFLP pattern, by using the Bf and C4 probes, as haplotype d, but different from that of haplotype c. This indicates that there is a close association of [C4-Bf-C2] and class II genes in miniature swine. Although these data do not show conclusively the location of the [C4-Bf-C2] genes, it is hypothesized that swine [C4-Bf-C2] genes are located between the class II and class I genes, as has been demonstrated in mouse and man.