Evolution of introns and exons of class II major histocompatibility complex genes of vertebrates

 The phylogenetic relationships and patterns of nucleotide substitution were compared for introns and exons of class II major histocompatibility complex (MHC) genes in three datasets: human DRB1, human DQA1, and cyprinid fish DAB1. In both human DRB1 and cyprinid DAB1, there was strong evidence that recombination events between alleles have occurred in such a way that intron and exon sequences of a given allele do not necessarily share the same evolutionary history. In the case of human DRB1, recombination was found to have homogenized intron 1 and intron 2 sequences relative to exon 2 sequences within lineages of alleles but not between lineages. As a result, mean divergence times of intron sequences are much more recent than those of exonic sequences. Thus, the divergence time of DRB1 introns cannot be used to date that of exons in the same alleles, and the hypothesis that most human DRB1 polymorphism is of very recent origin is not supported. Received: 5 September 1999 / Revised: 30 December 1999     

Nonlinkage of major histocompatibility complex class I and class II loci in bony fishes

 In tetrapods, the functional (classical) class I and class II B loci of the major histocompatibility complex (Mhc) are tightly linked in a single chromosomal region. In an earlier study, we demonstrated that in the zebrafish, Danio rerio, order Cypriniformes, the two classes are present on different chromosomes. Here, we show that the situation is similar in the stickleback, Gasterosteus aculeatus, order Gasterosteiformes, the common guppy, Poecilia reticulata, order Cyprinodontiformes, and the cichlid fish Oreochromis niloticus, order Perciformes. These data, together with unpublished results from other laboratories suggest that in all Euteleostei, the classical class I and class II B loci are in separate linkage groups, and that in at least some of these taxa, the class II loci are in two different groups. Since Euteleostei are at least as numerous as tetrapods, in approximately one-half of jawed vertebrates, the class I and class II regions are not linked. Received: 30 August 1999 / Revised: 20 October 1999     

The helper T-cell repertoire of mice expressing class II major histocompatibility complex β chains in the absence of α chains

 Mutant mice generated by disrupting the H2-Aa ^b major histocompatibility complex (Mhc) gene are demonstrated here to express Aβ^b chains in the absence of α chains. These mice possess a CD4⁺ helper T cell (Th) repertoire that uses predominantly the Vβ7 T-cell antigen receptor (Tcr) segment for recognition of any protein antigen presented by the α-free Aβ molecule. As an alloantigen, the Aα-free Aβ molecule is recognized very poorly by T cells from a series of class II disparate mouse strains, indicating that it is grossly different from normal α/β heterodimers. Indeed, molecular modeling suggests a β/β homodimer arrangement with an altered geometry of the Tcr contact area. Interestingly, the mutant mice exhibit normal alloreactivity, without a restricted Vβ usage, toward a series of foreign α/β class II heterodimers, although their T cells developed in the absence of such heterodimers. Thus, the complementarity of Tcr to normal α/β heterodimers, and thereby also alloreactivity, appears to be an ontogeny independent (i. e., germline-encoded) feature. Received: 30 September 1996 / Revised: 18 October 1996     

Genomic analysis of common chimpanzee major histocompatibility complex class I genes

To investigate how MHC class I genes have changed in the approximately 5 million years since chimpanzees and humans diverged, we characterized six genomic fragments ranging in size from 5.1 to 6.1 kb, each containing the complete coding region, introns, and flanking regions of one of the following chimpanzee class I genes: Patr-A, Patr-E, Patr-F, Patr-G, Patr-H, and Patr-J. In humans, these genes are closely linked within the class I region and are representatives of three distinct functional categories of class I genes: the highly polymorphic Ia genes (HLA-A), the conserved Ib genes (HLA-E, HLA-F, and HLA-G), and the class I pseudogenes (HLA-H and HLA-J). Southern blot analysis of chimpanzee and human class I genes produced nearly identical patterns, suggesting that the organization and linkage of these genes differs little in the two species. Comparison of the chimpanzee fragment sequences with their human orthologues revealed structural conservation of these genes yet differences in their degree of functional constraint. This is apparent in the location and nature of the amino acid changes between species and the substantial differences in levels of divergence at functional and nonfunctional sites. Additionally, there is no correlation between patterns of divergence at these sites and intraspecific variation, an observation explained by either appreciable gene conversion or high levels of recombination, the latter unlikely given the observed strong linkage disequilibrium of these loci.     

Selection, trans-species polymorphism, and locus identification of major histocompatibility complex class IIβ alleles of New World ranid frogs

Genes encoded by the major histocompatibility complex (MHC) play key roles in the vertebrate immune system. However, our understanding of the evolutionary processes and underlying genetic mechanisms shaping these genes is limited in many taxa, including amphibians, a group currently impacted by emerging infectious diseases. To further elucidate the evolution of the MHC in frogs (anurans) and develop tools for population genetics, we surveyed allelic diversity of the MHC class II β1 domain in both genomic and complementary DNA of seven New World species in the genus Rana (Lithobates). To assign locus affiliation to our alleles, we used a “gene walking” technique to obtain intron 2 sequences that flanked MHC class IIβ exon 2. Two distinct intron sequences were recovered, suggesting the presence of at least two class IIβ loci in Rana. We designed a primer pair that successfully amplified an orthologous locus from all seven Rana species. In total, we recovered 13 alleles and documented trans-species polymorphism for four of the alleles. We also found quantitative evidence of selection acting on amino acid residues that are putatively involved in peptide binding and structural stability of the β1 domain of anurans. Our results indicated that primer mismatch can result in polymerase chain reaction (PCR) bias, which influences the number of alleles that are recovered. Using a single locus may minimize PCR bias caused by primer mismatch, and the gene walking technique was an effective approach for generating single-copy orthologous markers necessary for future studies of MHC allelic variation in natural amphibian populations.     

Genetic polymorphism of the swine major histocompatibility complex (SLA) class I genes, SLA-1, -2 and -3

In order to identify and characterize genetic polymorphism of the swine major histocompatibility complex (Mhc: SLA) class I genes, RT-PCR products of the second and third exons of the three SLA classical class I genes, SLA-1, SLA-2 and SLA-3 were subjected to nucleotide determination. These analyses allowed the identification of four, eight and seven alleles at the SLA-1, SLA-2 and SLA-3 loci, respectively, from three different breeds of miniature swine and one mixed breed. Among them, 12 alleles were novel. Construction of a phylogenetic tree using the nucleotide sequences of those 19 alleles indicated that the SLA-1 and -2 genes are more closely related to each other than to SLA-3. Selective forces operating at single amino acid sites of the SLA class I molecules were analyzed by the Adaptsite Package program. Ten positive selection sites were found at the putative antigen recognition sites (ARSs). Among the 14 positively selected sites observed in the human MHC (HLA) classical class I molecules, eight corresponding positions in the SLA class I molecules were inferred as positively selected. On the other hand, four amino acids at the putative ARSs were identified as negatively selected in the SLA class I molecules. These results suggest that selective forces operating in the SLA class I molecules are almost similar to those of the HLA class I molecules, although several functional sites for antigen and cytotoxic T-lymphocyte recognition by the SLA class I molecules may be different from those of the HLA class I molecules.The DNA sequence data reported in this paper have been submitted to the DDBJ, EMBL and GenBank nucleotide databases and have been assigned the accession numbers, AB105379, AB105380, AB105381, AB105382, AB105383, AB105384, AB105385, AB105386, AB105388, AB105389, AB105390 and AB105391     

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.     

BTL-II : a polymorphic locus with homology to the butyrophilin gene family, located at the border of the major histocompatibility complex class II and class III regions in human and mouse

 Comparison of human and mouse genomic sequence at the border of the major histocompatibility complex (MHC) class II and class III regions revealed a locus encoding six exons with homology to the butyrophilin gene family and the location of a previously decribed gene, testis-specific basic protein (TSBP). We named the new locus BTL-II, for butyrophilin-like MHC class II associated. The six discernable exons of the BTL-II locus encode a small hydrophobic amino acid sequence (which may be a signal peptide), two immunoglobulin domains, a small 7-amino acid, heptad repeat-like exon, and a further two immunoglobulin domains. In mouse, an additional butyrophilin-like gene (NG10) is situated adjacent to BTL-II. Expression studies of the BTL-II locus in mouse showed that it is expressed in a range of gut tissues. We demonstrate that like many other genes from the MHC, BTL-II is polymorphic in a selection of diverse HLA haplotypes. In the light of the newly discovered locus, we revisit and discuss the possible origin of the butyrophilin gene family Received: 20 September 1999 / Revised: 28 December 1999     

Lifetime of major histocompatibility complex class-I membrane clusters is controlled by the actin cytoskeleton

Lateral heterogeneity of cell membranes has been demonstrated in numerous studies showing anomalous diffusion of membrane proteins; it has been explained by models and experiments suggesting dynamic barriers to free diffusion, that temporarily confine membrane proteins into microscopic patches. This picture, however, comes short of explaining a steady-state patchy distribution of proteins, in face of the transient opening of the barriers. In our previous work we directly imaged persistent clusters of MHC-I, a type I transmembrane protein, and proposed a model of a dynamic equilibrium between proteins newly delivered to the cell surface by vesicle traffic, temporary confinement by dynamic barriers to lateral diffusion, and dispersion of the clusters by diffusion over the dynamic barriers. Our model predicted that the clusters are dynamic, appearing when an exocytic vesicle fuses with the plasma membrane and dispersing with a typical lifetime that depends on lateral diffusion and the dynamics of barriers. In a subsequent work, we showed this to be the case. Here we test another prediction of the model, and show that changing the stability of actin barriers to lateral diffusion changes cluster lifetimes. We also develop a model for the distribution of cluster lifetimes, consistent with the function of barriers to lateral diffusion in maintaining MHC-I clusters.     

The major and a minor class II β-chain (B-LB ) gene flank the Tapasin gene in the B-F /B-L region of the chicken major histocompatibility complex

 We have identified the major histocompatibility complex class II β-chain (B-LB) genes present in the B-F/B-L region of the B complex of nine well-characterized lines of chickens and have cleared up much of the confusion concerning numbers and location of B-LB genes in this region. By amplifying DNA sequences between adjacent genes, we found two B-LB genes that lie on either side of Tapasin. The dominantly expressed 'major' B-LB gene in all haplotypes lies between Tapasin and RING-3, and belongs to the B-LBII family of class II β-chain genes. The poorly expressed 'minor' B-LB gene in all haplotypes lies between B-lec1 and Tapasin, and belongs either to the B-LBII family or to the previously unmapped B-LBVI family of class II β-chain genes. The data suggest that the B-LBII and B-LBVI genes are two lineages of B-LB genes and we propose that they all be termed B-LB genes. The location of a third B-LB gene in the B12 haplotype (and possibly other haplotypes as well) has yet to be determined. The structural organization and expression of the class II β-chain genes in the B-F/B-L region is similar to that of chicken class I (B-F) genes, one functional result of which is differential resistance to disease and response to vaccines. Received: 29 July 1999 / Revised: 27 September 1999     

Isolation and characterization of major histocompatibility class IIβ genes in an endangered North American cyprinid fish, the Rio Grande silvery minnow (Hybognathus amarus)

The major histocompatibility complex (MHC) is a critical component of the adaptive immune response in vertebrates. Due to the role that MHC plays in immunity, absence of variation within these genes may cause species to be vulnerable to emerging diseases. The freshwater fish family Cyprinidae comprises the most diverse and species-rich group of freshwater fish in the world, but some are imperiled. Despite considerable species richness and the long evolutionary history of the family, there are very few reports of MHC sequences (apart from a few model species), and no sequences are reported from endemic North American cyprinids (subfamily Leuciscinae). Here we isolate and characterize the MH Class II beta genes from complementary DNA and genomic DNA of the non-model, endangered Rio Grande silvery minnow (Hybognathus amarus), a North American cyprinid. Phylogenetic reconstruction revealed two groups of divergent MH alleles that are paralogous to previously described loci found in deeply divergent cyprinid taxa including common carp, zebrafish, African large barb and bream. Both groups of alleles were under the influence of diversifying selection yet not all individuals had alleles belonging to both allelic groups. We concluded that the general organization and pattern of variation of MH class II genes in Rio Grande silvery minnow is similar to that identified in other cyprinid fishes studied to date, despite distant evolutionary relationships and evidence of a severe genetic bottleneck.     

A new major histocompatibility complex class I b gene expressed in the mouse blastocyst and placenta

 Because of the role major histocompatibility complex (MHC) class I b molecules may play during mouse embryonic development, we thought it would be interesting to search for additional MHC class I b molecules that might be expressed in preimplantation embryos, and in particular in the trophoblastic lineage. We therefore screened a mouse preimplantation blastocyst cDNA library for MHC class I sequences. This search led to the identification and characterization of a new MHC class I b gene, blastocyst MHC. Sequences identical to the exons and 3′ untranslated region of this gene have been found in many laboratory mouse strains, as well as in the related mouse species Mus spreciligus. The presence of this gene in mouse strains of different MHC class I haplotypes argues that blastocyst MHC is a unique, newly-described gene rather than a new allele of a previously described mouse MHC class I gene. Blastocyst MHC has the structure of an MHC class I b gene, with the six exons characteristic of T-region genes. It is linked to H2-D. The amino acid sequence encoded by this gene maintains all the features of a functional antigen-presentation domain. The blastocyst MHC gene, like the human class I b gene HLA-G, is expressed at the blastocyst stage and in the placenta, and may be the mouse analog for HLA-G. Received: 31 May 1996 / Revised: 19 August 1996     

Evolution of Phosphagen Kinase VII. Isolation of Glycocyamine Kinase from the Polychaete Neanthes diversicolor and the cDNA-Derived Amino Acid Sequences of α and β Chains

Glycocyamine kinase (GK) was isolated from the marine polychaete Neanthes diversicolor by gel filtration, DEAE-cellulose chromatography, butyl-Toyopearl hydrophobic chromatography, and chromatofocusing. The GK was eluted as a single peak on the latter three chromatographies, and the molecular mass for the native GK was estimated to be about 80 kDa. The SDS–PAGE showed that the isolated GK consists of two distinct subunits in equal proportion, α and β chains, with molecular masses of 42.2 and 43.8 kDa, respectively. The present results suggest that the Neanthes GK has a heterodimeric structure. The cDNAs for α and β chains of Neanthes GK were amplified by PCR and their cDNA-derived amino acid sequences were determined. The α and β chains are composed of 374 and 390 amino acids, and the molecular masses were calculated to be 42,392 and 43,966 Da, respectively, in good agreement with the apparent masses on SDS–PAGE. The β chain has a characteristic N-terminal extension of 15 amino acids, and all of the sequence differences between α and β chains were restricted in the N-terminal region of 50 residues. The overall sequence identity was 92%. The occurrence of heterodimeric nature in Neanthes GK is of great interest from the evolutionary point of view, because the heterodimeric structure is only known for creatine kinase MB-isozyme specific for mammalian heart muscle among phosphagen kinases.     

Cloning and sequence analysis of cDNAs encoding the MHC class II β chain in Atlantic salmon (Salmo salar)

Atlantic salmon (Salmo salar) cDNAs encoding the major histocompatibility complex (Mhc-Sasa) class II chain were isolated from a leucocyte library by a polymerase chain reaction (PCR) approach. Three different cDNAs (c144, c22, and c157) encoding the entire mature chain have been analyzed. Clone c144 differs from clone c157 in 12.6% of the nucleotides in the 1-encoding region. The corresponding differences between clones c144 and c22, and clones c22 and c157, are 10.3% and 5.2%, respectively. This variation is, at least in part, most likely attributable to allelism. The similarity indices between the highly conserved 2 domains from Atlantic salmon and corresponding sequences from humans (DQ), chicken (BL), carp (TLAII-1), and rainbow trout (O. M. No. 55) are 45%, 40%, 66%, and 97%, respectively. Variable residues in the 1 domains from Atlantic salmon correspond with polymorphic sites of 1 domains from higher vertebrates. The frequency of substitutions in the 1-encoding region exceeds that in the 3-untranslated (UT) region with several folds, indicating extensive 1 polymorphism in Atlantic salmon.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers (C 144) X 70165, (C 157) X 70166, and (C 22) X 70167.This study was supported by grants from the Norwegian Fisheries Research Council (NFFR) and the Norwegian Agricultural Research Council (NLVF).