Songbird genomics: analysis of 45 kb upstream of a polymorphic Mhc class II gene in red-winged blackbirds (Agelaius phoeniceus)

Here we present the sequence of a 45 kb cosmid containing a previously characterized poly-morphic Mhc class II B gene (Agph-DAB1) from the red-winged blackbird (Agelaius phoeniceus). We compared it with a previously sequenced cosmid from this species, revealing two regions of 7.5 kb and 13.0 kb that averaged greater than 97% similarity to each another, indicating a very recent shared duplication. We found 12 retroelements, including two chicken repeat 1 (CR1) elements, constituting 6.4% of the sequence and indicating a lower frequency of retroelements than that found in mammalian genomic DNA. Agph-DAB3, a new class II B gene discovered in the cosmid, showed a low rate of polymorphism and may be functional. In addition, we found a Mhc class II B gene fragment and three genes likely to be functional (encoding activin receptor type II, a zinc finger, and a putative gamma-filamin). Phylogenetic analysis of exon 2 alleles of all three known blackbird Mhc genes indicated strong clustering of alleles by locus, implying that large amounts of interlocus gene conversion have not occurred since these genes have been diverging. Despite this, interspecific comparisons indicate that all three blackbird Mhc genes diverged from one another less than 35 million years ago and are subject to concerted evolution in the long term. Comparison of blackbird and chicken Mhc promoter regions revealed songbird promoter elements for the first time. The high gene density of this cosmid confirms similar findings for the chicken Mhc, but the segment duplications and diversity of retroelements resembles mammalian sequences.     

A 39-kb sequence around a blackbird Mhc class II gene: ghost of selection past and songbird genome architecture

To gain an understanding of the evolution and genomic context of avian major histocompatibility complex (Mhc) genes, we sequenced a 38.8-kb Mhc-bearing cosmid insert from a red-winged blackbird (Agelaius phoeniceus). The DNA sequence, the longest yet retrieved from a bird other than a chicken, provides a detailed view of the process of gene duplication, divergence, and degeneration ("birth and death") in the avian Mhc, as well as a glimpse into major noncoding features of a songbird genome. The peptide-binding region (PBR) of the single Mhc class II B gene in this region, Agph-DAB2, is almost devoid of polymorphism, and a still-segregating single-base-pair deletion and other features suggest that it is nonfunctional. Agph-DAB2 is estimated to have diverged about 40 MYA from a previously characterized and highly polymorphic blackbird Mhc gene, Aph-DAB1, and is therefore younger than most mammalian Mhc paralogs and arose relatively late in avian evolution. Despite its nonfunctionality, Agph-DAB2 shows very high levels of nonsynonymous divergence from Agph-DAB1 and from reconstructed ancestral sequences in antigen-binding PBR codons-a strong indication of a period of adaptive divergence preceding loss of function. We also found that the region sequenced contains very few other unambiguous genes, a partial Mhc- class II gene fragment, and a paucity of simple-sequence and other repeats. Thus, this sequence exhibits some of the genomic streamlining expected for avian as compared with mammalian genomes, but is not as densely packed with functional genes as is the chicken Mhc.     

Songbird Genomics: Analysis of 45 kb Upstream of a Polymorphic Mhc Class II Gene in Red-Winged Blackbirds (Agelaius phoeniceus)

Here we present the sequence of a 45 kb cosmid containing a previously characterized poly-morphic Mhc class II B gene (Agph-DAB1) from the red-winged blackbird (Agelaius phoeniceus). We compared it with a previously sequenced cosmid from this species, revealing two regions of 7.5 kb and 13.0 kb that averaged greater than 97% similarity to each another, indicating a very recent shared duplication. We found 12 retroelements, including two chicken repeat 1 (CR1) elements, constituting 6.4% of the sequence and indicating a lower frequency of retroelements than that found in mammalian genomic DNA. Agph-DAB3, a new class II B gene discovered in the cosmid, showed a low rate of polymorphism and may be functional. In addition, we found a Mhc class II B gene fragment and three genes likely to be functional (encoding activin receptor type II, a zinc finger, and a putative γ-filamin). Phylogenetic analysis of exon 2 alleles of all three known blackbird Mhc genes indicated strong clustering of alleles by locus, implying that large amounts of interlocus gene conversion have not occurred since these genes have been diverging. Despite this, interspecific comparisons indicate that all three blackbird Mhc genes diverged from one another less than 35 million years ago and are subject to concerted evolution in the long term. Comparison of blackbird and chicken Mhc promoter regions revealed songbird promoter elements for the first time. The high gene density of this cosmid confirms similar findings for the chicken Mhc, but the segment duplications and diversity of retroelements resembles mammalian sequences.     

Expansion and contraction of major histocompatibility complex genes: a teleostean example

The MHC is a multigene family that has arisen through recurrent expansion and contraction of genes, and a continuum of the evolutionary process is observed in the teleost fishes. The number of duplicated genes observed in different phylogenetic groups of teleost fish varies from one to 42, with only a few genes observed in the primitive euteleost species, and greater numbers of genes observed in the more advanced neoteleost species. In this study, an attempt is made to isolate all of the Mhc class I genes of an early neoteleost species, Atlantic cod (Gadus morhua L.), in the superorder Paracanthopterygii. Eighty-three sequences were isolated from the cDNA of an individual G. morhua. The level of gene duplication observed within each of the lineages and sublineages was similar, and most contained an estimated two to four duplicated genes. Mhc class I gene duplication in G. morhua was independent of, and possibly more recent than, extensive duplication in the Acanthopterygian superorder. Only limited contraction of Mhc genes is observed in G. morhua. A low level of haplotype diversity is observed, with most individuals containing at least one copy of each of the lineages tested. Divergence of the conserved N- and C-terminal residues of the antigen recognition site is observed, indicative of the initial stage of degeneration from classical to non-classical genes. However, most or all of the lineages are still polymorphic, and degeneration is present both within and among lineages. Thus, the outcome (i.e., which genes will remain classical) is as yet undetermined.     

Mhc diversity in two passerine birds: no evidence for a minimal essential Mhc

Humans express an array of Mhc genes, while the chicken has an Mhc that is relatively small and compact with fewer expressed genes. Here we ask whether the "minimal essential Mhc" of the chicken is representative for birds. We investigated the RFLP genotypes in 55 great reed warblers Acrocephalus arundinaceus and 10 willow warblers Phylloscopus trochilus to obtain an overview of the number of class II B genes. There were 13-17 bands per individual in the great reed warblers and 25-30 in the willow warblers, and every individual had a unique RFLP genotype. The high number of RFLP bands indicates that both species have a large number of class II B genes although some may be pseudogenes. Seven different class II B sequences were detected in a great reed warbler cDNA library. There was considerable sequence divergence between the cDNA sequences in exon 2 (peptide-binding region, PBR), whereas they were very similar in exon 3. The cDNA sequences were easily alignable to a classical chicken class II B sequence, and balancing selection was acting in the PBR. One of the cDNA sequences had two deletions and is likely nonfunctional. Finally, the polymorphic class I and class II B RFLP fragments seemed to be linked in the five studied great reed warbler families. These and previous results suggest that birds of the order Passeriformes in general have more Mhc class I and II B genes than birds of the order Galliformes. This difference could be caused by their phylogenetic past, and/or by variance in the selection pressure for maintaining a high number of Mhc genes.     

Good copy, bad copy: choosing animal models for HLA-linked diseases

Recent large-scale sequencing and comparative analyses of the major histocompatibility complex (Mhc) provide a novel view of this long-studied region. The main insight is that even though Mhcs are defined by the presence of the Mhc class I and II genes, the regions encoding class I/II histocompatibility antigens are the least conserved among the species; hence the difficulty of modeling the human class I/II-linked diseases. Fortunately, the majority of the genes in the Mhc, the non-class I/II genes, are conserved among the investigated mammals. The full set of Mhc genes in their evolutionary context presents new possibilities to study Mhc-linked diseases by allowing systematic evaluation of the various experimental animals and approaches.     

Variation at the major histocompatibility complex in Savannah sparrows

The class I and class II genes of the major histocompatibility complex (Mhc) encode dimeric glycoproteins responsible for eliciting the adaptive immune response of vertebrates. Recent work with birds suggests that the number, size, and arrangement of these genes can differ markedly across species, although the extent of this variation, and its causes and consequences, are poorly understood. We have used a 157-base-pair (bp) portion of the second exon of a class II B gene to probe the Mhc in a free-living population of Savannah sparrows (Passerculus sandwichensis). Segregation analysis of Mhc bands suggests that class II B genes can be found in two independently assorting clusters, as previously described for domestic chickens (Gallus gallus) and ring-necked pheasants (Phasianus colchicus) but unlike gene organization in mammals. The Mhc in Savannah sparrows appears large (with many class II B genes) and variable; we found 42 unique genotypes among 48 adults breeding on Kent Island, New Brunswick, Canada in 1995. Savannah sparrows are long-distance migrants, and these results support recent predictions that migratory birds should show higher levels of Mhc polymorphism and/or a greater number of genes than sedentary species. Savannah sparrows are also socially polygynous with high levels of extra-pair paternity, suggesting that a history of sexual selection might also influence the size and/or structure of the avian Mhc.     

家禽MHC结构研究进展

禽主要组织相容性复合体(Major histocompatibility complex,MHC)的结构与禽病防控、禽免疫学、禽类遗传学研究密切相关。文章对鸡、火鸡、鹌鹑、鸭和鹅的MHC结构方面的研究进展进行了综述,表明其有以下共同特点:都有保守的MHC区域,包括MHC I基因和MHC II基因及一些功能未知基因;基因排列简单而紧凑;MHC I基因内含子的长度都比哺乳动物小;鸡、火鸡、鸭和鹅的MHC I基因组序列都有8个外显子和7个内含子,MHC IIβ基因组序列都有6个外显子和5个内含子;鸡、火鸡和鹌鹑的BG基因结构模式相同;都存在微卫星重复单元。但也存在种属差异:鸡的MHC I基因和MHC II基因是双拷贝,而鸭、鹅和鹌鹑有若干个拷贝;BG基因的拷贝数及其外显子数目不同。对主要家禽MHC结构进行分析比较,将有利于对禽病学及禽免疫遗传学的进究。     

Isolation and characterization of three class II MHC genomic clones from the chicken

A genomic library was constructed from sperm DNA from an individual of the inbred chicken line G-B2, MHC haplotype B6. The library was screened with a chicken class II probe (beta 2 exon specific) and three MHC class II beta chain genomic clones were isolated. The restriction maps of the three clones showed that each of the three clones was unique. The position of the beta chain sequence was located in each of the three genomic clones by Southern blot hybridization. Subclones containing the beta chain gene were produced from each of the genomic clones and the orientation of the leader peptide, beta 1, beta 2, transmembrane, and cytoplasmic exons was determined by Southern blot hybridization and nucleotide sequencing. The complete nucleotide sequence of two of the three subclones was determined. Comparison of the nucleotide and predicted amino acid sequences of the two subclones with other class II beta chain sequences showed that the B6 chicken beta chain genes are evolutionarily related to the class II beta chain genes from chickens of other MHC haplotypes, and to class II beta chain genes from other species. Analysis of Southern blots of B6 chicken DNA, as well as the isolation of the three beta chain genes, suggests that chickens of the B6 haplotype possess at least three MHC class II beta chain genes.     

A comparative map of macrochromosomes between chicken and Japanese quail based on orthologous genes

In order to develop a comparative map between chicken and quail, we identified orthologous gene markers based on chicken genomic sequences and localized them on the Japanese quail Kobe-NIBS linkage map, which had previously been constructed with amplified fragment length polymorphisms. After sequencing the intronic regions of 168 genes located on chicken chromosomes 1-8, polymorphisms among Kobe-NIBS quail family parents were detected in 51 genes. These orthologous markers were mapped on eight Japanese quail linkage groups (JQG), and they allowed the comparison of JQG to chicken macrochromosomes. The locations of the genes and their orders were quite similar between the two species except within a previously reported inversion on quail chromosome 2. Therefore, we propose that the respective quail linkage groups are macrochromosomes and designated as quail chromosomes CJA 1-8.     

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.     

Comparative genomics of natural killer cell receptor gene clusters

Many receptors on natural killer (NK) cells recognize major histocompatibility complex class I molecules in order to monitor unhealthy tissues, such as cells infected with viruses, and some tumors. Genes encoding families of NK receptors and related sequences are organized into two main clusters in humans: the natural killer complex on Chromosome 12p13.1, which encodes C-type lectin molecules, and the leukocyte receptor complex on Chromosome 19q13.4, which encodes immunoglobulin superfamily molecules. The composition of these gene clusters differs markedly between closely related species, providing evidence for rapid, lineage-specific expansions or contractions of sets of loci. The choice of NK receptor genes is polarized in the two species most studied, mouse and human. In mouse, the C-type lectin-related Ly49 gene family predominates. Conversely, the single Ly49 sequence is a pseudogene in humans, and the immunoglobulin superfamily KIR gene family is extensive. These different gene sets encode proteins that are comparable in function and genetic diversity, even though they have undergone species-specific expansions. Understanding the biological significance of this curious situation may be aided by studying which NK receptor genes are used in other vertebrates, especially in relation to species-specific differences in genes for major histocompatibility complex class I molecules.     

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.     

Analysis of a 26-kb region linked to the Mhc in zebrafish: genomic organization of the proteasome component beta/transporter associated with antigen processing-2 gene cluster and identification of five new proteasome beta subunit genes.

Sequencing of zebrafish (Danio rerio) bacterial artificial chromosome and P1 artificial chromosome genomic clone fragments and of cDNA clones has led to the identification of five new loci coding for beta subunits of proteasomes (PSMB). Together with the four genes identified previously, nine PSMB genes have now been defined in the zebrafish. Six of the nine genes reside in the zebrafish MHC (Mhc) class I region, four of them reside in a single cluster closely associated with TAP2 on a 26-kb long genomic fragment, and two reside at some distance from the fragment. In addition to homologues of the human genes PSMB5 through PSMB9, two new genes, PSMB11 and PSMB12, have been found for which there are no known corresponding genes in humans. The new genes reside in the PSMB cluster in the Mhc. Homology and promoter region analysis suggest that the Mhc-associated genes might be inducible by IFN-gamma. The zebrafish class I region contains representatives of three phylogenetically distinguishable groups of PSMB genes, X, Y, and Z. It is proposed that these genes were present in the ancestral PSMB region before Mhc class I genes became associated with it.     

A contig map of the Mhc class I genomic region in the zebrafish reveals ancient synteny

In contrast to the human and mouse Mhc, in which the clusters of class I and class II loci reside in close vicinity to one another, in the zebrafish, Danio rerio, they are found in different linkage groups. Chromosome walking using BAC (bacterial artificial chromosome) and PAC (P1 artificial chromosome) clones reveals the zebrafish class I region to occupy a segment of approximately 450 kb and to encompass at least 19 loci. These include three class I (Dare-UDA, -UEA, -UFA), five proteasome subunit beta (PSMB8, -9A, -9C, -11, -12), two TAPs (TAP2A, TAP2B), and one TAP binding protein (TAPBP). This arrangement contrasts with the arrangements found in human and mouse Mhc, in which the orthologues of the PSMB, TAP, and TAPBP loci reside within the class II region. In addition to this main zebrafish class I contig, a shorter contig of about 150 kb contains two additional class I (UBA, UCA) and at least five other loci. It probably represents a different haplotype of part of the class I region. The previously identified UAA gene shares an identical 5' part with UEA, but the two genes differ in their 3' parts. One of them is probably the result of an unequal crossing over. The described organization has implications for the persistence of syntenic relationships, coevolution of loci, and interpretation of the origin of the human/mouse Mhc organization.     

Gene organization of the quail major histocompatibility complex (MhcCoja) class I gene region

 Class I genomic clones of the quail (Coturnix japonica) major histocompatibility complex (MhcCoja) were isolated and characterized. Two clusters spanning the 90.8 kilobase (kb) and 78.2 kb class I gene regions were defined by overlapping cosmid clones and found to contain at least twelve class I loci. However, unlike in the chicken Mhc, no evidence for the existence of any Coja class II gene was obtained in these two clusters. Based on comparative analysis of the genomic sequences with those of the cDNA clones, Coja-A, Coja-B, Coja-C, and Coja-D (Shiina et al. 1999), these twelve loci were assigned to represent one Coja-A gene, two Coja-B genes (Coja-B1 and -B2), four Coja-C genes (Coja-C1-C4), four Coja-D genes (Coja-D1-D4), and one new Coja-E gene. A class I gene-rich segment of 24.6 kb in which five of these genes (Coja-B1, -B2, -D1, -D2 and -E) are densely packed were sequenced by the shotgun strategy. All of these five class I genes are very compact in size [2089 base pairs (bp)–2732 bp] and contain no apparent genetic defect for functional expression. A transporter associated with the antigen processing (TAP) gene was identified in this class I gene-rich segment. These results suggest that the quail class I region is physically separated from the class II region and characterized by a large number of the expressible class I loci (at least seven) in contrast to the chicken Mhc, where the class I and class II regions are not clearly differentiated and only at most three expressed class I loci so far have been recognized. Received: 9 March 1998 / Revised: 12 October 1998     

QUOD ERAT FACIENDUM: sequence analysis of the H2-D and H2-Q regions of 129/SvJ mice

The H2-D and -Q regions of the mouse major histocompatibility complex ( Mhc or H2) have been sequenced from strain 129/SvJ (haplotype bc), revealing a D/Q region different from all other investigated haplotypes, including the closely related b haplotype. The 300-kb class I-rich region consists of the classical class I, H2-D, and 11 non-classical class I genes. The Q region was formed by two series of tandem duplications. Comparison of the segment between the D and Q1 genes with the H2-K region provides evidence that class I genes were translocated from the K region to the D region, and gives a new explanation for the weak locus specificity of the H-Kand H2-Dalleles.     

Molecular and functional characterization of genes encoding horse MHC class I antigens

Sequence and functional analyses were undertaken on two cDNAs and a genomic clone encoding horse major histocompatibility complex (MHC) class I molecules. All of the clones were isolated from a single horse that is homozygous for all known horse MHC class I and class II antigens. The two cDNAs (clones 8-9 and 1-29) were isolated from a lymphocyte library and encode polymorphic MHC antigens from two loci. The genomic cosmid clone, isolated from a sperm library, contains the 8-9 gene. All three genes were expressed in mouse L-cells and were recognized by alloantisera and, for the cDNAs, by alloreactive cytotoxic T lymphocytes. A total of 3815 bp of the genomic clone were sequenced, extending from 429 bp upstream (5') of the leader peptide through the 3' untranslated region. Promoter region motifs and an intron-exon structure characteristic of MHC class I genes of other species were found. A subclone containing 407 bp of the promoter region was inserted into a chloramphenicol acetyl transferase reporter plasmid, tested in transient transfection assays, and found to have promoter activity in heterologous cells. This genomic clone will enable detailed studies of MHC class I gene regulation in horse trophoblasts, and in horse retroviral infections.