Genomic sequence analysis of the 238-kb swine segment with a cluster of TRIM and olfactory receptor genes located, but with no class I genes, at the distal end of the SLA class I region

Continuous genomic sequence has been previously determined for the swine leukocyte antigen (SLA) class I region from the TNF gene cluster at the border between the major histocompatibility complex (MHC) class III and class I regions to the UBD gene at the telomeric end of the classical class I gene cluster (SLA-1 to SLA-5, SLA-9, SLA-11). To complete the genomic sequence of the entire SLA class I genomic region, we have analyzed the genomic sequences of two BAC clones carrying a continuous 237,633-bp-long segment spanning from the TRIM15 gene to the UBD gene located on the telomeric side of the classical SLA class I gene cluster. Fifteen non-class I genes, including the zinc finger and the tripartite motif (TRIM) ring-finger-related family genes and olfactory receptor genes, were identified in the 238-kilobase (kb) segment, and their location in the segment was similar to their apparent human homologs. In contrast, a human segment (alpha block) spanning about 375 kb from the gene ETF1P1 and from the HLA-J to HLA-F genes was absent from the 238-kb swine segment. We conclude that the gene organization of the MHC non-class I genes located in the telomeric side of the classical SLA class I gene cluster is remarkably similar between the swine and the human segments, although the swine lacks a 375-kb segment corresponding to the human alpha block. The nucleotide sequence data reported in this paper have been submitted to DDBJ, EMBL, and GenBank databases under accession numbers AB158486 and AB158487     

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.     

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.     

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.     

The Phylogenetic History of the MHC Class I Gene Families in Pig,Including a Fossil Gene Predating Mammalian Radiation

More than 990 kb of the 1200 kb in the SLA class I region of the pig major histocompatibility complex (MHC) have been sequenced. The present study was designed to establish the evolution of this region which was best understood by distinguishing three periods. The most recent period, which extended from 40 to 15 mya, probably corresponded to five rounds of duplication of a basic unit. This unit consisted of a single class I gene linked to widely dispersed repeats, and one SLA-specific repeat motif. The duplications gave rise to six SLA classical class I genes. The second evolutionary period corresponded to the emergence of the SLA nonclassical class I genes, i.e. after the suidae separated from the other artiodactyl species about 65 mya. The third period appeared to correspond to a much more remote age when the ancestor of the gene SLA-11 existed. Comparative studies of the human and pig sequences of the class I-containing segments indeed revealed the presence within the human HSR1-ZNF segment of relics of a human class I fossil gene which appeared to be orthologous to the 5 moiety of the SLA-11 pseudogene. This was the first evidence that a class I gene existed in this location at least 110-120 mya in the MHC class I region of the precursor of the mammalian species. Human/pig sequence comparison also revealed that the presumably functional pig MIC2 gene was probably orthologous to the human functional MICA or MICB genes.     

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.     

Molecular characteristics of the SLA-2 gene from Chinese Hebao pigs

To study the molecular characteristics of swine leukocyte antigen (SLA) class I from the Hebao pig, a rare inbreed in China, a pair of primers was designed to amplify the SLA-2 gene (SLA-2-HB) and then the molecular characteristics of the gene were analyzed by computer. After cloning, sequencing and computer analysis, four SLA-2-HB alleles were found, all of 1119 bp. Sites 3-1097 were an open reading frame encoding 364 amino acids with two sets of intra-chain disulfide bonds comprising four cysteines situated in sites 125, 188, 227 and 283. By alignment of SLA-2-HB sequences with other SLA-2 alleles in the DNA Data Bank of Japan/European Molecular Biology Laboratory/GenBank database, nine key variable amino acid sites were found in the extracellular domain of the SLA-2-HB alleles at sites 23(F), 24(I), 43(A), 44(K), 50(Q), 73(N), 95(I), 114(R) and 216(S), which could be used to differentiate other SLA-2 alleles. The amino acid identities between SLA-2-HB and other SLA-2, SLA-3 and SLA-1 alleles were 87.1-97.0%, 85.0-93.9% and 83.3- 88.6%, respectively. The phylogenetic tree of SLA-2-HB showed that it was relatively independent of the other SLA-2 genes. Furthermore, the SLA-2-HB alleles were similar to HLA-B15 and HLA-A2 functional do- mains and preserved some functional sites of HLA-A2. It was concluded that SLA-2-HB is an allele of SLA-2 and that the Hebao pig might have evolved independently in China.     

Analyzing the genetic characteristics and function of the swine leukocyte antigen 2 gene in a Chinese inbreed of pigs

To study the genetic characteristics and function of swine leukocyte antigen (SLA) class I from the Hebao pig, a rare inbreed in China, a pair of primers was designed to amplify the SLA-2 gene (SLA-2-HB) and then the genetic characteristics of the gene were analyzed. The 3D homology modeling was used to analyze the structure and function of SLA-2-HB proteins. After cloning, sequencing and computer analysis, four SLA-2-HB alleles were found, all of 1119 bp. Sites 3-1097 were an open reading frame encoding 364 amino acids with two sets of intra-chain disulfide bonds comprising four cysteines situated in sites 125, 188, 227 and 283. By alignment of SLA-2-HB sequences with other SLA-2 alleles in the IPD database, 11 key variable amino acid sites were found in the extracellular domain of the SLA-2-HB alleles at sites 23(F), 24(I), 43(A), 44(K), 50(Q), 73(N), 95(I), 114(R), 155(G), 156(E) and 216(S), which could be used to differentiate other SLA-2 alleles. The 3D homology modeling demonstrated that the eight of 11 key variable amino acid sites were all in antigenic binding groove of SLA-2-HB proteins. The amino acid identities between SLA-2-HB and other SLA-2, SLA-1 and SLA-3 alleles were 86.2-97.0%, 85.0-93.9% and 83.3-88.6%, respectively. The phylogenetic tree of SLA-2-HB showed that it was relatively independent of the other SLA-2 genes. Furthermore, the SLA-2-HB alleles were similar to HLA-B15 and HLA-A2 functional domains and preserved some functional sites of HLA-A2. It was concluded that SLA-2-HB are novel alleles of SLA-2 and that the Hebao pig might have evolved independently in China.     

An ordered BAC contig map of the equine major histocompatibility complex

A physical map of ordered bacterial artificial chromosome (BAC) clones was constructed to determine the genetic organization of the horse major histocompatibility complex. Human, cattle, pig, mouse, and rat MHC gene sequences were compared to identify highly conserved regions which served as source templates for the design of overgo primers. Thirty-five overgo probes were designed from 24 genes and used for hybridization screening of the equine USDA CHORI 241 BAC library. Two hundred thirty-eight BAC clones were assembled into two contigs spanning the horse MHC region. The first contig contains the MHC class II region and was reduced to a minimum tiling path of nine BAC clones that span approximately 800 kb and contain at least 20 genes. A minimum tiling path of a second contig containing the class III/I region is comprised of 14 BAC clones that span approximately 1.6 Mb and contain at least 34 genes. Fluorescence in situ hybridization (FISH) using representative clones from each of the three regions of the MHC localized the contigs onto ECA20q21 and oriented the regions relative to one another and the centromere. Dual-colored FISH revealed that the class I region is proximal to the centromere, the class II region is distal, and the class III region is located between class I and II. These data indicate that the equine MHC is a single gene-dense region similar in structure and organization to the human MHC and is not disrupted as in ruminants and pigs.     

Rapid assignment of swine leukocyte antigen haplotypes in pedigreed herds using a polymerase chain reaction-based assay

We present a simple assay to determine the swine leukocyte antigen (SLA) haplotypes of animals within two experimental populations of MHC defined miniature pigs. The Yucatan miniature pigs have four founder haplotypes ( w, x, y, z) and one recombinant haplotype ( q). The NIH miniature pigs have three founder haplotypes ( a, c, d) and two recombinant haplotypes ( f, g). Because most crossovers occur between the class I and class II regions, haplotypes can be assigned by typing one class I locus and one class II locus for practical purposes. We have previously characterized these seven founder haplotypes by sequencing the cDNA of three SLA class I loci, designated as SLA-1, SLA-3 and SLA-2 and four SLA class II loci, SLA-DQA1, SLA-DQB1, SLA-DRA1 and SLA-DRB1. These sequences were used to design allele-specific primers to amplify one MHC class I and one MHC class II gene for each haplotype. Primers were tested for specificity in homozygous and heterozygous animals. Positive control primers were also designed to amplify a portion of the E-selectin or alpha-actin gene and multiplexed with the allele-specific primers to check for false negatives. This combination of allele-specific and positive control primers produced specific and robust PCR-site-specific primer assays for assigning SLA haplotypes in the two populations.     

Molecular organization of the canine major histocompatibility complex

The major histocompatibility complex (MHC) is composed of a tightly linked cluster of genes; in dogs, this is referred to as the dog leukocyte antigen (DLA) region. The canine MHC is located on chromosome 12, and several genes within the DLA region have been identified that have significant sequence similarity to their human counterparts. However, in order to characterize other loci in the DLA region, DNA sequencing has begun using a canine bacterial artificial chromosome (BAC) library. Initially 135 BAC clones were isolated from a BAC library using a mixture of human and canine probes. These BAC clones were screened with locus-specific primers in polymerase chain reactions (PCRs). Fifty-six BAC clones were subjected to FingerPrinted Contig (FPC) analysis and several overlapping clones were identified. One BAC clone RP81-231-G24 has been sequenced. Preliminary sequence analysis of this 150 kb clone indicates that it contains the region where the class I and class III regions are joined and encompasses DLA-12a, DLA-53, DLA-12, DLA-64, TNF-alpha, and a canine gene that appears to resemble the HLA class III gene HSPA1A (HSP70-1).     

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.     

Physical localization and order of genes in the class I region of the bovine MHC

Fluorescence in situ hybridization (FISH) analyses were used to order 16 bacterial artificial chromosomes (BAC) clones containing loci from the bovine lymphocyte antigen (BoLA) class I and III regions of bovine chromosome 23 (BTA23). Fourteen of these BACs were assigned to chromosomal band locations of mitotic and pachytene chromosomes by single- and dual-colour FISH. Dual-colour FISH confirmed that class II DYA is proximal to and separated from BoLA class I genes by approximately three chromosome bands. The FISH results showed that tumour necrosis factor alpha (TNFA), heat shock protein 70 (HSP70.1) and 21 steroid dehydrogenase (CYP21) are closely linked in the region of BTA23 band 22 along with BoLA class I genes, and that male enhanced antigen (MEA) mapped between DYA and the CYP21/TNFA/HSP70.1 gene region. All BAC clones containing BoLA class I genes mapped distal to CYP21/TNFA/HSP70.1 and centromeric to prolactin (PRL). Myelin oligodendrocyte glycoprotein (MOG) was shown to be imbedded within the BoLA class I gene cluster. The cytogenetic data confirmed that the disrupted distribution of BoLA genes is most likely the result of a single large chromosomal inversion. Similar FISH results were obtained when BoLA DYA and class I BAC clones were mapped to discrete chromosomal locations on the BTA homologue in white-tailed deer, suggesting that this chromosomal inversion predates divergence of the advanced ruminant families from a common ancestor.     

Characterization of microsatellite loci in the SLA class I region

Microsatellite (MS) markers in the SLA-1 region were characterized via sequencing analysis with BAC clones generated from the National Institute of Health miniature pigs (MIPs). A total of 16 BAC clones were sequenced producing 15,228 shotgun reads, corresponding to 11.2 X sequencing coverage, that were used to construct a contig of 12.18 Mb in length. MS markers were compared with previously deposited GenBank sequences to verify the existence of 423 potential MS candidate markers in the SLA-1 region. Evaluation of these polymorphisms confirmed 59 markers in MIPs, and the combined data including sequences from GenBank revealed 155 polymorphic MS markers. MS markers identified from this analysis can be used to provide an alternative method to direct typing for determining an individual's SLA-1 haplotype.     

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.