Evolution of major histocompatibility complex class I genes in Cetartiodactyls

Previous studies of cattle MHC have suggested the presence of at least four classical class I loci. Analysis of haplotypes showed that any combination of one, two or three genes may be expressed, although no gene is expressed consistently. The aim of this study was to examine the evolutionary relationships among these genes and to study their phylogenetic history in Cetartiodactyl species, including cattle and their close relatives. A secondary aim was to determine whether recombination had occurred between any of the genes. MHC class I data sets were generated from published sequences or by polymerase chain reaction from cDNA. Phylogenetic analysis revealed that MHC class I sequences from Cetartiodactyl species closely related to cattle were distributed among the main cattle gene "groups", while those from more distantly related species were either scattered (sheep, deer) or clustered in a species-specific manner (sitatunga, giraffe). A comparison between gene and species trees showed a poor match, indicating that divergence of the MHC sequences had occurred independently from that of the hosts from which they were obtained. We also found two clear instances of interlocus recombination among the cattle MHC sequences. Finally, positive natural selection was documented at positions throughout the alpha 1 and 2 domains, primarily on those amino acids directly involved in peptide binding, although two positions in the alpha 3 domain, a region generally conserved in other species, were also shown to be undergoing adaptive evolution.     

Evolution of MHC class I in the Order Crocodylia

The major histocompatibility complex (MHC) is a dynamic genomic region with an essential role in the adaptive immunity of jawed vertebrates. The evolution of the MHC has been dominated by gene duplication and gene loss, commonly known as the birth-and-death process. Evolutionary studies of the MHC have mostly focused on model species. However, the investigation of this region in non-avian reptiles is still in its infancy. To provide insights into the evolutionary mechanisms that have shaped the diversity of this region in the Order Crocodylia, we investigated MHC class I exon 3, intron 3, and exon 4 across 20 species of the families Alligatoridae and Crocodilidae. We generated 124 DNA sequences and identified 31 putative functional variants as well as 14 null variants. Phylogenetic analyses revealed three gene groups, all of which were present in Crocodilidae but only one in Alligatoridae. Within these groups, variants generally appear to cluster at the genus or family level rather than in species-specific groups. In addition, we found variation in gene copy number and some indication of interlocus recombination. These results suggest that MHC class I in Crocodylia underwent independent events of gene duplication, particularly in Crocodilidae. These findings enhance our understanding of MHC class I evolution and provide a preliminary framework for comparative studies of other non-avian reptiles as well as diversity assessment within Crocodylia.     

Serological and molecular diversity in the cattle MHC class I region

Information on major histocompatibility complex (MHC) diversity in cattle is important to aid our understanding of immune responses and may contribute to maintenance of healthy cattle populations. Equally, understanding the mechanisms involved in generating this diversity may shed light on the complex nature of mammalian MHC evolution. The aim of this study was to assess molecular and serological variation within cattle MHC class I molecules and to study the mechanisms generating diversity. To address this aim, sequence variation was examined in 12 serologically assigned alleles from three putative loci and correlated with monoclonal antibody (mAb) binding data. The results demonstrate that both alloantisera and mAbs often fail to distinguish gene products that differ by a significant number of amino acids. Conversely, some mAbs could distinguish alleles differing by only one or two amino acids. Examination of the sequences demonstrates sharing of motifs between alleles, some encoded at distinct loci, supporting the occurrence of interlocus recombination within the cattle MHC class I region. The implications of this for MHC sequence diversity, and functional capability, are discussed.     

Comparative genomic analysis of the major histocompatibility complex class I region in the teleost genus <Emphasis Type="Italic">Oryzias</Emphasis>

The major histocompatibility complex (MHC) class I region of teleosts harbors a tight cluster of the class IA genes and several other genes directly involved in class I antigen presentation. Moreover, the dichotomous haplotypic lineages (termed d- and N- lineages) of the proteasome subunit beta genes, PSMB8 and PSMB10, are present in this region of the medaka, Oryzias latipes. To understand the evolution of the Oryzias MHC class I region at the nucleotide sequence level, we analyzed bacterial artificial chromosome clones covering the MHC class I region containing the d- lineage of Oryzias luzonensis and the d- and N- lineages of Oryzias dancena. Comparison among these three elucidated sequences and the published sequences of the d- and N- lineages of O. latipes indicated that the order and orientation of the encoded genes were completely conserved among these five genomic regions, except for the class IA genes, which showed species-specific variation in copy number. The PSMB8 and PSMB10 genes showed trans-species dimorphism. The remaining regions flanking the PSMB10, PSMB8, and class IA genes showed high degrees of sequence conservation at interspecies as well as intraspecies levels. Thus, the three independent evolutionary patterns under apparently distinctive selective pressures are recognized in the Oryzias MHC class I region. Electronic Supplementary Material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The dominant MHC class I gene is adjacent to the polymorphic<Emphasis Type="Italic"> TAP2</Emphasis> gene in the duck,<Emphasis Type="Italic"> Anas platyrhynchos</Emphasis>

We are investigating the expression and linkage of major histocompatibility complex (MHC) class I genes in the duck (Anas platyrhynchos) with a view toward understanding the susceptibility of ducks to two medically important viruses: influenza A and hepatitis B. In mammals, there are multiple MHC class I loci, and alleles at a locus are polymorphic and co-dominantly expressed. In contrast, in lower vertebrates the expression of one locus predominates. Southern-blot analysis and amplification of genomic sequences suggested that ducks have at least four loci encoding MHC class I. To identify expressed MHC genes, we constructed an unamplified cDNA library from the spleen of a single duck and screened for MHC class I. We sequenced 44 positive clones and identified four MHC class I sequences, each sharing approximately 85% nucleotide identity. Allele-specific oligonucleotide hybridization to a Northern blot indicated that only two of these sequences were abundantly expressed. In chickens, the dominantly expressed MHC class I gene lies adjacent to the transporter of antigen processing (TAP2) gene. To investigate whether this organization is also found in ducks, we cloned the gene encoding TAP2 from the cDNA library. PCR amplification from genomic DNA allowed us to determine that the dominantly expressed MHC class I gene was adjacent to TAP2. Furthermore, we amplified two alleles of the TAP2 gene from this duck that have significant and clustered amino acid differences that may influence the peptides transported. This organization has implications for the ability of ducks to eliminate viral pathogens.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers AY294416–22     

Pinpointing a selective sweep to the chimpanzee MHC class I region by comparative genomics

Chimpanzees experienced a reduction of the allelic repertoire at the major histocompatibility complex (MHC) class I A and B loci, which may have been caused by a retrovirus belonging to the simian immunodeficiency virus (SIV) family. Extended MHC haplotypes were defined in a pedigreed chimpanzee colony. Comparison of genetic variation at microsatellite markers mapping inside and outside the Mhc region was carried out in humans and chimpanzees to investigate the genomic extent of the repertoire reduction. Multilocus demographic analyses underscored that chimpanzees indeed experienced a selective sweep that mainly targeted the chromosomal segment carrying the Mhc class I region. Probably due to genetic linkage, the sweep also affected other polymorphic loci, mapping in the close vicinity of the Mhc class I region genes. Nevertheless, although the allelic repertoire at particular Mhc class I and II loci appears to be limited, naturally occurring recombination events allowed the establishment of haplotype diversity after the sweep. However, recombination did not have sufficient time to erase the signal of the selective sweep.     

Ancient Interlocus Exon Exchange in the History of the Hla-a Locus

The major histocompatibility complex (MHC) in humans and chimpanzees includes three classical class I loci, A, B and C, which encode glycoproteins expressed on the surface of all nucleated cells. There are also several nonclassical class I loci including E, which have more limited expression. By analyzing published sequences, we have shown that in exons 4 and 5, A locus alleles from both humans and chimpanzees are much more similar to E than to B or C alleles, whereas in exons 2 and 3 alleles from all three classical class I loci are much more similar to each other than any one is to E. We propose that some 20 million years ago, interlocus recombination led to the formation of a hybrid gene in which exons 2 and 3 were derived from the original A locus and exons 4 and 5 were derived from the E locus. The fact that such an ancient event can still be detected suggests that interlocus recombination is rare in the MHC and does not significantly contribute to MHC polymorphism, which is known to be extremely high. The present finding, however, supports Gilbert's idea that exons in a gene may occasionally be replaced by those from another gene in the evolutionary process.     

Polymorphic Alu insertions within the Major Histocompatibility Complex class I genomic region: a brief review

Most polymorphic Alu insertions (POALINs) belong to a subgroup of the Alu multicopy retrotransposon family of short interspersed nucleotide elements (SINEs) that are categorized as AluYb8 and AluYa5. The number of AluYb8/AluYa5 members (approximately 4,492 copies) is significantly less than the approximately one million fixed Alu copies per human genome. We have studied the presence of POALINs within the Major Histocompatibility Complex (MHC) class I region on the short arm of chromosome 6 (6p21.3) because this region has a high gene density, many genes with immune system functions, large sequence variations and diversity, duplications and redundancy, and a strong association with more than 100 different diseases. Since little is known about POALINs within the MHC genomic region, we undertook to identify some of the members of the AluYb8/AluYa5 subfamily and to study their frequency of distribution and genetic characteristics in different populations. As a result of our comparative genomic analyses, we identified the insertion sites for five POALINs distributed within the MHC class I region. This brief review outlines the locations of the insertions and sequence features of the five MHC POALINs, their single site and haplotype frequencies in different geographic populations, and their association with different HLA class I genes and disease. We show that the MHC POALINs have a potential value as lineage and linkage markers for the study of human population genetics, disease associations, genomic diversity and evolution.     

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     

Evolution of a new nonclassical MHC class I locus in two Old World primate species

 HLA-G is a nonclassical major histocompatibility complex (MHC) class I molecule that is expressed only in the human placenta, suggesting that it plays an important role at the fetal-maternal interface. In rhesus monkeys, which have similar placentation to humans, the HLA-G orthologue is a pseudogene. However, rhesus monkeys express a novel placental MHC class I molecule, Mamu-AG, which has HLA-G-like characteristics. Phylogenetic analysis of AG alleles in two Old World primate species, the baboon and the rhesus macaque, revealed limited diversity characteristic of a nonclassical MHC class I locus. Gene trees constructed using classical and nonclassical primate MHC class I alleles demonstrated that the AG locus was most closely related to the classical A locus. Interestingly, gene tree analyses suggested that the AG alleles were most closely related to a subset of A alleles which are the products of an ancestral interlocus recombination event between the A and B loci. Calculation of the rates of synonymous and nonsynonymous substitution at the AG locus revealed that positive selection was not acting on the codons encoding the peptide binding region. In exon 4, however, the rate of nonsynonymous substitution was significantly lower than the rate of synonymous substitution, suggesting that negative selection was acting on these codons. Received: 22 April 1998 / Revised: 15 July 1998     

Ancestral organization of the MHC revealed in the amphibian Xenopus

With the advent of the Xenopus tropicalis genome project, we analyzed scaffolds containing MHC genes. On eight scaffolds encompassing 3.65 Mbp, 122 MHC genes were found of which 110 genes were annotated. Expressed sequence tag database screening showed that most of these genes are expressed. In the extended class II and class III regions the genomic organization, excluding several block inversions, is remarkably similar to that of the human MHC. Genes in the human extended class I region are also well conserved in Xenopus, excluding the class I genes themselves. As expected from previous work on the Xenopus MHC, the single classical class I gene is tightly linked to immunoproteasome and transporter genes, defining the true class I region, present in all nonmammalian jawed vertebrates studied to date. Surprisingly, the immunoproteasome gene PSMB10 is found in the class III region rather than in the class I region, likely reflecting the ancestral condition. Xenopus DMalpha, DMbeta, and C2 genes were identified, which are not present or not clearly identifiable in the genomes of any teleosts. Of great interest are novel V-type Ig superfamily (Igsf) genes in the class III region, some of which have inhibitory motifs (ITIM) in their cytoplasmic domains. Our analysis indicates that the vertebrate MHC experienced a vigorous rearrangement in the bony fish and bird lineages, and a translocation and expansion of the class I genes in the mammalian lineage. Thus, the amphibian MHC is the most evolutionary conserved MHC so far analyzed.     

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.