Patterns of variation of the major histocompatibility complex class IIB loci in Chinese goose (<Emphasis Type="Italic">Anser Cygnoides</Emphasis>)

In order to understand the variations of genomic organization of the major histocompatibility complex (MHC) and provide data for the studies on disease resistance of avian species, the MHC class II polymorphism in Chinese Z-goose was investigated for the first time in the present study. Eight alleles, which probably came from different loci, were found in six different geese with only one obvious band in the restriction fragment length polymorphism data. The numbers of nonsynonymous substitutions (dN) in peptide binding region of exon 2 were higher than that of synonymous substitutions (dS), and no stop codons or frameshift mutations were found in this region, indicating that balance selection was in operation, and the sequences are not likely to be pseudogenes. In addition, we successfully obtained five different long MHC class II fragments (about 1,162 bp) in six geese and found that the length of intron 1 was longer than that in chicken and some other birds, but intron 2 seemed to be intermediate in length. The phylogenetic tree appeared to branch in an order consistent with accepted evolutionary pathway. X. Zhou and C. Li contributed equally to this work and shared the co-first authorship.     

Support for the minimal essential MHC hypothesis: a parrot with a single,highly polymorphic MHC class II <Emphasis Type="Italic">B</Emphasis> gene

We characterized the MHC class II B gene in the green-rumped parrotlet, Forpus passerinus. Three approaches were used: polymerase chain reaction amplification using primers complementary to conserved regions of exon 2, sequencing clones from a genomic library, and amplification of exon 2 using species-specific primers. All three methods indicate that there is only a single class II B locus in this species and no pseudogenes. We suggest that this is the ancestral state for birds. The gene is highly polymorphic; 33 alleles were found in a sample of 25 individuals. Variation in exon 2 is concentrated in the peptide binding residues which show a significant excess of non-synonymous substitutions consistent with the operation of selection in maintaining this extraordinary polymorphism. Genomic clones show that major histocompatibility complex (MHC) gene organization is different from that of chickens; the class II A locus is close to II B. These data provide support for the hypothesis that the bird MHC constitutes a “minimal essential MHC” for responding to infectious disease.     

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     

Molecular characterization of major histocompatibility complex class 1 (MHC-I) from squirrel monkeys (<Emphasis Type="Italic">Saimiri sciureus</Emphasis>)

Little is known about the major histocompatibility complex (MHC) class 1 in squirrel monkeys (Saimiri sciureus). We cloned, sequenced and characterized two alleles and the cDNA of the coding region of MHC class 1 in these New World monkeys. Phylogenetic analyses showed that these sequences are related to HLA class 1 genes (HLA-A and HLA-G). The structure and organization of one of the two identified clones was similar to that of a class 1 MHC gene (HLA-A2). All the exon/intron splice acceptor/donor sites are conserved and their locations correspond to the HLA-A2 gene. The sequences of the newly described cDNAs reveal that they code for the characteristic class 1 MHC proteins, with all the features thought necessary for cell surface expression. Typical sequences for the leader peptide, ₁, ₂, ₃, transmembrane and cytoplasmic domains were found.The nucleotide sequence data reported in this paper have been submitted to the GenBank database and have been assigned the accession numbers AJ438576 (Sasc-G*31), AJ438577 (Sasc-G*25), AY282760 (Sasc-G*03), AY282761 (Sasc-G*04) and AY282762 (Sasc-G*05). Sequences were named as recommended by Klein and co-workers (1990)     

Characterization of major histocompatibility complex class I and class II genes from the Tasmanian devil (<Emphasis Type="Italic">Sarcophilus harrisii</Emphasis>)

The Tasmanian devil (Sarcophilus harrisii) is currently threatened by an emerging wildlife disease, devil facial tumour disease. The disease is decreasing devil numbers dramatically and may lead to the extinction of the species. At present, nothing is known about the immune genes or basic immunology of the devil. In this study, we report the construction of the first genetic library for the Tasmanian devil, a spleen cDNA library, and the isolation of full-length MHC Class I and Class II genes. We describe six unique Class II beta chain sequences from at least three loci, which belong to the marsupial Class II DA gene family. We have isolated 13 unique devil Class I sequences, representing at least seven Class I loci, two of which are most likely non-classical genes. The MHC Class I sequences from the devil have little heterogeneity, indicating recent divergence. The MHC genes described here are most likely involved in antigen presentation and are an important first step for studying MHC diversity and immune response in the devil.     

Polymorphism and selection in the major histocompatibility complex <Emphasis Type="Italic">DRA</Emphasis> and <Emphasis Type="Italic">DQA</Emphasis> genes in the family Equidae

The major histocompatibility complex genes coding for antigen binding and presenting molecules are the most polymorphic genes in the vertebrate genome. We studied the DRA and DQA gene polymorphism of the family Equidae. In addition to 11 previously reported DRA and 24 DQA alleles, six new DRA sequences and 13 new DQA alleles were identified in the genus Equus. Phylogenetic analysis of both DRA and DQA sequences provided evidence for trans-species polymorphism in the family Equidae. The phylogenetic trees differed from species relationships defined by standard taxonomy of Equidae and from trees based on mitochondrial or neutral gene sequence data. Analysis of selection showed differences between the less variable DRA and more variable DQA genes. DRA alleles were more often shared by more species. The DQA sequences analysed showed strong amongst-species positive selection; the selected amino acid positions mostly corresponded to selected positions in rodent and human DQA genes.     

Identification of peptides associated with chicken major histocompatibility complex class II molecules of <Emphasis Type="Italic">B21</Emphasis> and <Emphasis Type="Italic">B19</Emphasis> haplotypes

Chicken major histocompatibility complex (MHC) molecules present peptides to T cells to initiate immune response. Some variants of the chicken MHC, such as B19 and B21 haplotypes, are strongly associated with susceptibility and resistance to Mareks disease, respectively. The objective of the present study was to characterize the repertoire and origin of self-peptides presented by chicken MHC class II (B-L) molecules of B19 and B21 haplotypes. Following immunoaffinity purification of B21 and B19 B-L molecules from transformed B cell lines, their associated peptides were eluted, high performance liquid chromatography-fractionated, and sequenced by tandem mass spectrometry. Four peptides were identified associated with B21 B-L molecules. These ranged from 16 to 21 residues in length and had originated from membrane-bound, cytosolic, and mitochondrial proteins. Two of these peptides were present in form of an overlapping set, which is a common characteristic of MHC II-associated peptides. The single B19-associated peptide was 17 residues long and had originated from a cytosolic source. Presentation of endogenous peptides, such as those derived from cytosolic and mitochondrial proteins, by B-L molecules is indicative of cross-sampling between MHC class I and II antigen presentation pathways. These findings facilitate future studies aimed at elucidating mechanisms of chicken MHC association with disease resistance.     

Functional conservation of the human <Emphasis Type="Italic">EXT1</Emphasis> tumor suppressor gene and its <Emphasis Type="Italic">Drosophila</Emphasis> homolog <Emphasis Type="Italic">tout</Emphasis><Emphasis Type="Italic">velu</Emphasis>

Heparan sulfate proteoglycans play a vital role in signaling of various growth factors in both Drosophila and vertebrates. In Drosophila, mutations in the tout velu (ttv) gene, a homolog of the mammalian EXT1 tumor suppressor gene, leads to abrogation of glycosaminoglycan (GAG) biosynthesis. This impairs distribution and signaling activities of various morphogens such as Hedgehog (Hh), Wingless (Wg), and Decapentaplegic (Dpp). Mutations in members of the exostosin (EXT) gene family lead to hereditary multiple exostosis in humans leading to bone outgrowths and tumors. In this study, we provide genetic and biochemical evidence that the human EXT1 (hEXT1) gene is conserved through species and can functionally complement the ttv mutation in Drosophila. The hEXT1 gene was able to rescue a ttv null mutant to adulthood and restore GAG biosynthesis.     

The locus encoding an oligomorphic family of <Emphasis Type="Italic">MHC-A</Emphasis> alleles (<Emphasis Type="Italic">Mane-A</Emphasis>*06/<Emphasis Type="Italic">Mamu-A</Emphasis>*05) is present at high frequency in several macaque species

Several macaques species are used for HIV pathogenesis and vaccine studies, and the characterization of their major histocompatibility complex (MHC) class I genes is required to rigorously evaluate the cellular immune responses induced after immunization and/or infection. In this study, we demonstrate that the gene expressing the Mane-A*06 allele of pig-tailed macaques is an orthologue of the locus encoding the Mamu-A*05 allele family in rhesus macaques. Analysis of the distribution of this locus in a cohort of 63 pig-tailed macaques revealed that it encodes an oligomorphic family of alleles, highly prevalent (90%) in the pig-tailed macaque population. Similarly, this locus was very frequently found (62%) in a cohort of 80 Indian rhesus macaques. An orthologous gene was also detected in cynomolgus monkeys originating from four different geographical locations, but was absent in two African monkey species. Expression analysis in pig-tailed macaques revealed that the Mane-A*06 alleles encoded by this locus are transcribed at 10- to 20-fold lower levels than other MHC-A alleles (Mane-A*03 or Mane-A*10). Despite their conservation and high prevalence among Asian macaque species, the alleles of the Mane-A*06 family and, by extension their orthologues in rhesus and cynomolgus monkeys, may only modestly contribute to cellular immune responses in macaques because of their low level of expression.     

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.     

Linkage of <Emphasis Type="Italic">Patr-AL</Emphasis> to <Emphasis Type="Italic">Patr-A</Emphasis> and-<Emphasis Type="Italic">B</Emphasis> in the major histocompatibility complex of the common chimpanzee (<Emphasis Type="Italic">Pan troglodytes</Emphasis>)

Patr-AL is a recently described gene found only in the common chimpanzee, but closely related in structure to the highly polymorphic Patr-A and HLA-A genes of the chimpanzee and human MHCs, respectively. Unlike Patr-A and HLA-A, the Patr-AL gene has little polymorphism and is not fixed in the chimpanzee genome. To determine whether Patr-AL is located in the MHC or elsewhere, we compared segregation of the Patr-AL gene with segregation of Patr-A and - B alleles in chimpanzee families. The results demonstrate that Patr-AL is an MHC class I gene present on different MHC haplotypes as defined by their combination of Patr-A and B alleles.     

Unique haplotypes of co-segregating major histocompatibility class II <Emphasis Type="Italic">A</Emphasis> and class II <Emphasis Type="Italic">B</Emphasis> alleles in Atlantic salmon (<Emphasis Type="Italic">Salmo salar</Emphasis>) give rise to diverse class II genotypes

Sequence-based typing of a breeding population (G1) consisting of 84 Atlantic salmon individuals revealed the presence of 7 Sasa-DAA and 7 Sasa-DAB expressed alleles. Subsequent typing of 1,182 individuals belonging to 33 families showed that Sasa-DAA and Sasa-DAB segregate as haplotypes. In total seven unique haplotypes were established, with frequencies in the population studied ranging from 0.01 to 0.49. Each haplotype is characterized by a unique minisatellite marker size embedded in the 3' untranslated region of the Sasa-DAA gene. These data corroborate the fact that Atlantic salmon express a single class II locus, consisting of tightly linked class II A and class B genes. The seven haplotypes give rise to 15 genotypes with frequencies varying between 0.01 and 0.23; 21 class II homozygous individuals were present in the G1 population. We also studied the frequency distribution in another breeding population (G4, n=374) using the minisatellite marker. Only one new marker size was present, suggesting the presence of one new class II haplotype. The marker frequency distribution in the G4 population differed markedly from the G1 population. The genomic organizations of two Sasa-DAA and Sasa-DAB alleles were determined, and supported the notion that these alleles belong to the same locus. In contrast to other studies of salmonid class II sequences, phylogenetic analyses of brown trout and Atlantic class II A and class II B sequences provided support for trans-species polymorphism.     

Characterization of expressed class II MHC sequences in the banner-tailed kangaroo rat (<Emphasis Type="Italic">Dipodomys spectabilis</Emphasis>) reveals multiple <Emphasis Type="Italic">DRB</Emphasis> loci

Genes of the major histocompatibility complex (MHC) are exceptionally polymorphic due to the combined effects of natural and sexual selection. Most research in wild populations has focused on the second exon of a single class II locus (DRB), but complete gene sequences can provide an illuminating backdrop for studies of intragenic selection, recombination, and organization. To this end, we characterized class II loci in the banner-tailed kangaroo rat (Dipodomys spectabilis). Seven DRB-like sequences (provisionally named MhcDisp-DRB*01 through *07) were isolated from spleen cDNA and most likely comprise ≥5 loci; this multiformity is quite unlike the situation in muroid rodents such as Mus, Rattus, and Peromyscus. In silico translation revealed the presence of important structural residues for glycosylation sites, salt bonds, and CD4+ T-cell recognition. Amino-acid distances varied widely among the seven sequences (2–34%). Nuclear DNA sequences from the Disp-DRB*07 locus (∼10 kb) revealed a conventional exon/intron structure as well as a number of microsatellites and short interspersed nuclear elements (B4, Alu, and IDL-Geo subfamilies). Rates of nucleotide substitution at Disp-DRB*07 are similar in both exons and introns (π = 0.015 and 0.012, respectively), which suggests relaxed selection and may indicate that this locus is an expressed pseudogene. Finally, we performed BLASTn searches against Dipodomys ordii genomic sequences (unassembled reads) and find 90–97% nucleotide similarity between the two kangaroo rat species. Collectively, these data suggest that class II diversity in heteromyid rodents is based on polylocism and departs from the muroid architecture. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Nucleotide sequence data reported are available in the DDBJ/EMBL/GenBank databases under the accession numbers EU817477–EU817485.     

2004 Nomenclature for the chicken major histocompatibility (<Emphasis Type="Italic">B</Emphasis> and <Emphasis Type="Italic">Y</Emphasis> ) complex

The first standard nomenclature for the chicken (Gallus gallus) major histocompatibility (B) complex published in 1982 describing chicken major histocompatibility complex (MHC) variability is being revised to include subsequent findings. Considerable progress has been made in identifying the genes that define this polymorphic region. Allelic sequences for MHC genes are accumulating at an increasing rate without a standard system of nomenclature in place. The recommendations presented here were derived in workshops held during International Society of Animal Genetics and Avian Immunology Research Group meetings. A nomenclature for B and Y (Rfp-Y) loci and alleles has been developed that can be applied to existing and newly defined haplotypes including recombinants. A list of the current standard B haplotypes is provided with reference stock, allele designations, and GenBank numbers for corresponding MHC class I and class II sequences. An updated list of proposed names for B recombinant haplotypes is included, as well as a list of over 17 Y haplotypes designated to date.     

Polymorphism of canonical and noncanonical <Emphasis Type="Italic">gypsy</Emphasis> sequences in different species of <Emphasis Type="Italic">Drosophila </Emphasis><Emphasis Type="Italic">melanogaster</Emphasis> subgroup: possible evolutionary relations

Mobile genetic elements constitute a substantial part of eukaryotic genome and play an important role in its organization and functioning. Co-evolution of retrotransposons and their hosts resulted in the establishment of control systems employing mechanisms of RNA interference that seem to be impossible to evade. However, “active” copies of endogenous retrovirus gypsy escape cellular control in some cases, while its evolutionary elder “inactive” variants do not. To clarify the evolutionary relationship between “active” and “inactive” gypsy we combined two approaches: the analysis of gypsy sequences, isolated from G32 Drosophila melanogaster strain and from different Drosophila species of the melanogaster subgroup, as well as the study of databases, available on the Internet. No signs of “intermediate” (between “active” and “inactive”) gypsy form were found in GenBank, and four full-size G32 gypsy copies demonstrated a convergence that presumably involves gene conversion. No “active” gypsy were revealed among PCR generated gypsy ORF3 sequences from the various Drosophila species indicating that “active” gypsy appeared in some population of D. melanogaster and then started to spread out. Analysis of sequences flanking gypsy variants in G32 revealed their predominantly heterochromatic location. Discrepancy between the structure of actual gypsy sites in G32 and corresponding sequences in database might indicate significant inter-strain heterochromatin diversity. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.