Detection of H-2K mRNA in mouse 8-cell embryo by cDNA cloning

Mouse MHC class I gene expression in 8-cell embryo was examined by cDNA cloning. We constructed a cDNA library from 8-cell embryos of ICR mice and isolated a class I cDNA from 3.0 x 10(5) phage clones of the library. Sequencing analysis of this clone revealed it to include the cDNA fragment extending from the exon 6 of the cytoplasmic portion to 3' untranslated region 1 of H-2K gene. Qa, Tla or other embryonic class I cDNA have not been isolated in the library.     

Comparative structure of two duplicated T1a class I genes (T10c and 37) of the murine H-2d MHC. Implications on the evolution of the T1a region

The class I Ag encoded in the Qa/T1a regions of the murine MHC are much less polymorphic, and usually have a more restricted tissue distribution than the classical histocompatibility class I Ag, encoded by genes located in the H-2K, D, and L loci. The isolation of a quasi-ubiquitously expressed, poorly polymorphic class I gene of the T1a region of the H-2d mouse MHC, namely gene 37 (or T18d), has been recently reported. We describe the nucleotide sequence of a closely related gene, T10c gene, the counterpart of the gene 37 in the large duplicated parts of T1a region of the BALB/c (H-2d) MHC. The T10c gene structure and sequence are very similar to those of gene 37, but T10c gene is most likely a pseudogene. In A/J mouse strain, there appears to be a single gene related to 37, which is also found expressed in a variety of tissues. We show that this gene is likely to be a chimeric one derived from T10c for its 3' part, and from a gene closely related to gene 37 for its 5' part, which potentially encodes for an unusual class I molecule composed of the first two domains. Finally, Southern blot analysis of a number of wild mice and related animals suggests that a gene closely related to the present T10c gene may be the ancestor of this subfamily of class I genes characterized by the presence of an unusual second domain.     

Evolution and expression of the transplantation antigen gene family

We have cloned 26 different class I genes that are located in the major histocompatibility complex of the C57BL/10 mouse. Two of the three class I genes found in the H-2 complex encode the H-2Kb and H-2Db antigens; the other 23 class I genes map to the adjacent Tla complex. We have grouped the cosmids containing these genes into three clusters: one cluster links the H-2K and I-A regions, one cluster links the H-2D and Qa-2 regions, and the final cluster maps to the TL region. The class I gene organizations in the Qa-2 and TL regions of the C57BL/10 and BALB/c mice are generally similar, but there are several polymorphic segments. The Qa-2 region of both mice seems to have evolved by the duplication of gene pairs; furthermore, the H-2K region may have been generated by the translocation of a gene pair from the Qa-2 region. We have evidence that several of the genes in the Qa-2 region are expressed.     

Microrecombinations generate sequence diversity in the murine major histocompatibility complex: analysis of the Kbm3, Kbm4, Kbm10, and Kbm11 mutants.

The mechanism that generates spontaneous mutants of the Kb histocompatibility gene was analyzed. Nucleotide sequence analysis of four mutant genes (Kbm3, Kbm4, Kbm10, and Kbm11) revealed that each mutant K gene contains clustered, multiple nucleotide substitutions. Hybridization analyses of parental B6 genomic DNA and cloned class I genes with mutant-specific oligonucleotide probes, followed by sequence analyses, have identified major histocompatibility complex class I genes in the K, D, and Tla regions (K1, Db, and T5, respectively) that contain the exact sequences as substituted into mutant Kb genes. These data provide evidence for the hypothesis that the mutant Kb genes are generated by a microrecombination (gene conversion) mechanism that results in the transfer of small DNA segments from class I genes of all four regions of the major histocompatibility complex (K, D, Qa, and Tla) to Kb. Many of the nucleotides substituted into the mutant Kb genes were identical to those found in other naturally occurring K alleles such as Kd. Thus, we propose that the accumulation of microrecombination products within the K genes of a mouse population is responsible for the high sequence diversity among H-2 alleles.     

Family relationships of murine major histocompatibility complex class I genes. Sequence of the T2Aa pseudogene, a member of gene family 3

The major histocompatibility complex of the mouse contains numerous class I genes, most of which are encoded in the Qa and Tla regions. By hybridizations, the murine class I genes have been classified into three major families (Rogers, J. H. (1985a) Immunogenetics 21, 343-353). As yet, complete sequences are available only for members of family 1 (several H-2 and Qa genes) or family 2 (the pseudoallelic Tla genes T3b and T13c). We here present the complete nucleotide sequence of a gene from the Tla region that belongs to family 3. This gene, T2Aa, is a pseudogene by several criteria. The general structure of the gene is nonetheless well preserved. A comparison of the T2Aa sequence to those of other murine class I genes confirms the classification into three gene families. Members of gene families 2 and 3, located in the Tla region, are no more similar to each other than to family 1 (the H-2 and Qa2,3 genes). This suggests that families 2 and 3 were both created by ancient duplications of the functionally important family 1 genes. The fact that families 2 and 3 have diverged extensively both from family 1 and from each other may suggest that they are devoid of function.     

Tracing the evolution of H-2 D region genes using sequences associated with a repetitive element

The class I genes in the murine MHC are genetically divided into the K, D, Qa, and T1a region subfamilies. These genes presumably arose by duplication from a common class I ancestor. Oligonucleotide probes specific for sequences associated with a moderately repetitive B2 SINE element, which is inserted into the 3' untranslated region of the H-2D and H-2L genes, were used to examine the evolutionary relationship between these classically defined D region genes (H-2D and H-2L) and the other members of the class I gene family. Hybridization analyses of recombinant cosmid and genomic DNA indicated that the D region genes separated genetically from the other members of the class I gene family 12 to 14 million years ago. The evidence suggests that during this time frame the chromosomal segment harboring the characteristic insertion became fixed in the ancestral population which gave rise to Mus domesticus. Previous studies have shown that the number of genes present in the Qa and T1a regions varies among inbred strains and among laboratory stocks of wild mice derived from more distant species on the genus Mus. No evidence was found in this study to support the hypothesis that variation in class I gene number is the result of recent duplications of the functionally defined class I genes of the D region, H-2D and H-2L.     

Locus specificity of polymorphic alleles and evolution by a birth-and-death process in mammalian MHC genes

We have conducted an extensive phylogenetic analysis of polymorphic alleles from human and mouse major histocompatibility complex (MHC) class I and class II genes. The phylogenetic tree obtained for 212 complete human class I allele sequences (HLA-A, -B, and -C) has shown that all alleles from the same locus form a single cluster, which is highly supported by bootstrap values, except for one HLA-B allele (HLA-B*7301). Mouse MHC class I loci did not show locus-specific clusters of polymorphic alleles. This was considered to be because of either interlocus genetic exchange or the confusing designation of loci in different haplotypes at the present time. The locus specificity of polymorphic alleles was also observed in human and mouse MHC class II loci. It was therefore concluded that interlocus recombination or gene conversion is not very important for generating MHC diversity, with a possible exception of mouse class I loci. According to the phylogenetic trees of complete coding sequences, we classified human MHC class I (HLA-A, -B, and -C) and class II (DRB1) alleles into three to five major allelic lineages (groups), which were monophyletic with high bootstrap values. Most of these allelic groups remained unchanged even in phylogenetic trees based on individual exons, though this does not exclude the possibility of intralocus recombination involving short DNA segments. These results, together with the previous observation that MHC loci are subject to frequent duplication and deletion, as well as to balancing selection, indicate that MHC evolution in mammals is in agreement with the birth-and-death model of evolution, rather than with the model of concerted evolution.     

Organization and structure of the Qa genes of the major histocompatibility complex of the C3H mouse: implications for Qa function and class I evolution.

We have determined the structure and organization of the entire Qa family of class I genes from the major histocompatibility complex of the C3H mouse. Restriction maps of overlapping lambda and cosmid clones reveal that there are only five Qak genes: Q1k, Q2k, Q4k, Q10k and a Q5/9 hybrid, presumably generated by unequal homologous recombination. The resulting deletion of Q6-Q9 is consistent with the Qa-2null phenotype of this mouse strain. We have sequenced the Qak genes, and predict that each may encode a class I molecule with a structure comparable with that proposed for the transplantation antigens. Furthermore, these Qa products should be able to bind peptides and interact with appropriate T-cell receptors. Interestingly, in comparing Qak and H-2k sequences, we find limited evidence of interlocus gene conversion between Qa and H-2 loci, suggesting that the Qa genes are not likely to serve as a reservoir of genetic information for the generation of H-2 diversity within this haplotype.     

H-2M3 encodes the MHC class I molecule presenting the maternally transmitted antigen of the mouse

Mta, the maternally transmitted antigen of mice, is a hydrophobic, N-formylated mitochondrial peptide, MTF, presented on the cell surface to cytotoxic T lymphocytes by a novel major histocompatibility complex class I molecule, encoded by H-2M3. We have cloned and sequenced two alleles of M3, which differ in their ability to present MTF despite greater than 99% identity in the coding regions. M3 is as divergent from classical, antigen-presenting H-2 molecules as from other class I genes of the Hmt and the Qa/Tla regions. Amino acids critical for folding of class I molecules are conserved in M3. Noncharged amino acids lining the peptide-binding groove and phenylalanine 171 may explain the unique interaction with MTF, and leucine 95 appears critical for immunological activity.     

Identification and expression of the Tla region gene T11b and its Qa-like product

In spite of the large number of class I genes in the Qa-Tla region of the H-2 complex, only few membrane-bound Qa and TL Ag have been identified. We show that one of the Qa-Tla region genes, the T11b gene, is transcribed in lymphoid cells, lymphoma cell lines, teratocarcinoma cell lines, and L cells transfected with the cloned T11b gene. The T11b gene potentially encodes a polypeptide with normal class I characteristics. The product as present at the cell surface of L cells transfected with the cloned T11b gene, is a sialylated protein of m.w. 41,000, associated with beta 2-microglobulin. This T11b Ag shares epitopes with H-2K and H-2D molecules of various haplotypes and with Qa-2 molecules, but has distinct biochemical properties. RFLP analysis revealed that the T11b gene is found in mice of the Tlab and Tlaf haplotype. Genes homologous to, but distinct from, T11b (allelic or duplicated) are present in all Tla haplotypes tested.     

Contrasting patterns of selection acting on MHC class I and class II DRB genes in the Alpine marmot (Marmota marmota)

The major histocompatibility complex (MHC) genes code for proteins that play a critical role in the immune system response. The MHC genes are among the most polymorphic genes in vertebrates, presumably due to balancing selection. The two MHC classes appear to differ in the rate of evolution, but the reasons for this variation are not well understood. Here, we investigate the level of polymorphism and the evolution of sequences that code for the peptide-binding regions of MHC class I and class II DRB genes in the Alpine marmot (Marmota marmota). We found evidence for four expressed MHC class I loci and two expressed MHC class II loci. MHC genes in marmots were characterized by low polymorphism, as one to eight alleles per putative locus were detected in 38 individuals from three French Alps populations. The generally limited degree of polymorphism, which was more pronounced in class I genes, is likely due to bottleneck the populations undergone. Additionally, gene duplication within each class might have compensated for the loss of polymorphism at particular loci. The two gene classes showed different patterns of evolution. The most polymorphic of the putative loci, Mama-DRB1, showed clear evidence of historical positive selection for amino acid replacements. However, no signal of positive selection was evident in the MHC class I genes. These contrasting patterns of sequence evolution may reflect differences in selection pressures acting on class I and class II genes.     

Exchanges of short polymorphic DNA segments predating speciation in feline major histocompatibility complex class I genes

Sequence comparisons of 14 distinct MHC class I cDNA clones isolated from species representing the three major taxonomic lineages of Felidae (domestic cat lineage, ocelot lineage, and pantherine lineage) revealed that feline MHC class I alleles have highly mosaic structures with short polymorphic sequence motifs that are rearranged between alleles of individual MHC loci, between MHC class I genes within cat species, and between homologous MHC loci in different species. The pattern of sequence variation in felids supports the role of the following factors in production and maintenance of MHC variation: (1) gradual spontaneous mutation; (2) selective pressure to conserve certain residues but also to vary in hypervariable regions, notably residues that functionally participate in antigen recognition and presentation; and (3) recombination-mediated gene exchange between alleles and between related genes. The overall amount of genetic variation observed among MHC class I genes in the Felidae family is no greater than the amount of variation within any outbred cat species (i.e., domestic cat, ocelot). The occurrence of equivalent levels of polymorphism plus the simultaneous persistence of the same sequence motifs in divergent feline species suggest that most MHC class I nucleotide site polymorphism predated species divergences. Ancient polymorphisms have been transmitted through the speciation events and modern feline MHC class I alleles were derived by recombinational exchange of polymorphic sequence motifs. Moreover, some of these sequence motifs were found in other mammalian MHC class I genes, such as classical human HLA-B5, nonclassical human HLA-E class I genes, and bovine class I genes. These results raise the prospect of an ancient origin for some motifs, although the possibility of convergence in parallel mammalian radiations cannot be excluded. Correspondence to: N. Yuhki     

A single gene encodes soluble and membrane-bound forms of the major histocompatibility Qa-2 antigen: anchoring of the product by a phospholipid tail

The H-2, Qa, and Tla genes of the murine major histocompatibility complex are related to each other by DNA sequence homology. The H-2 genes encode ubiquitously expressed transplantation antigens that serve as recognition structures for cytotoxic T cells. The identities of the Qa and Tla products, their sites of expression, and their functions are largely unknown. We report here that the Qa region gene Q7 encodes a membrane-bound as well as a secreted form of the serologically defined antigen Qa-2. The Q7 gene introduced into liver-derived cells is expressed as a membrane-bound and as a secreted molecule. In transfected L cells it is expressed only as a soluble protein. Biochemical analysis suggests that the Q7 product is anchored to the liver cell membranes by a phospholipid tail. This feature may be responsible for cell type-specific expression of the two forms of the Qa-2 molecules.     

HLA class I homologous transcripts in the human embryonal carcinoma cell line Tera-2

We have used the human teratocarcinoma-derived embryonal carcinoma cell line Tera-2 cl. 13 to explore the putative expression of novel HLA class I(-like) genes. Serological analyses revealed that Tera-2 cells do not express polymorphic HLA class I (-A, -B, -C) specificities, but do express HLA class I-like antigens. These phenotypic properties parallel those of certain mouse embryonal carcinoma cells. To study the expression of HLA class I(-like) genes in the Tera-2 cells two different approaches were used. Screening of a Tera-2 cDNA library with a full-length HLA class I cDNA probe under conditions that would allow for the identification of relatively distinct HLA class I-like sequences yielded 27 positive clones, all of which were of the regular HLA-A, -B, -C type. Reverse northern hybridizations of the restriction enzyme-digested Tlab region comprising cosmids with Tera-2 cDNA as the probe resulted in the identification of several putative human genes whose equivalents map within the mouse Tla region. However, none of these genes appeared to be structurally related to HLA class I. A putative H3.3 histone gene was identified in the proximal Tla region of the C57BL/10 mouse. It is concluded that no structural homologues of mouse Qa/Tla genes are expressed in the human developmental cell line Tera-2.     

Polymorphism and signature of selection in the MHC class I genes of the three-spined stickleback Gasterosteus aculeatus

The role and intensity of positive selection maintaining the polymorphism of major histocompatibility complex (MHC) class I genes in the three-spined stickleback Gasterosteus aculeatus was investigated. The highly polymorphic set of MHC class I genes found was organized in a single linkage group. Between 5 and 14 sequence variants per individual were identified by single-stranded conformation polymorphism (SSCP) analysis. Segregation analysis studied in 10 three-spined stickleback families followed the expected pattern of Mendelian inheritance. The gamete fusion in three-spined stickleback thus seems to be random with respect to the MHC class I genes. The DNA sequence analyses showed that the expressed MHC class I loci are under strong selection pressure, possibly mediated by parasites. Codons that were revealed to be under positive selection are potentially important in antigen binding. MHC class I sequences did not form significant supported clusters within a phylogenetic tree. Analogous to MHC class II genes, it was not possible to assign the class I sequences to a specific locus, suggesting that the class I genes may have been generated by recent gene duplication.     

Two patterns of variation among MHC class I loci in Tuatara (Sphenodon punctatus)

The genes of the major histocompatibility complex (MHC) are a central component of the immune system in vertebrates and have become important markers of functional, fitness-related genetic variation. We have investigated the evolutionary processes that generate diversity at MHC class I genes in a large population of an archaic reptile species, the tuatara (Sphenodon punctatus), found on Stephens Island, Cook Strait, New Zealand. We identified at least 2 highly polymorphic (UA type) loci and one locus (UZ) exhibiting low polymorphism. The UZ locus is characterized by low nucleotide diversity and weak balancing selection and may be either a nonclassical class I gene or a pseudogene. In contrast, the UA-type alleles have high nucleotide diversity and show evidence of balancing selection at putative peptide-binding sites. Twenty-one different UA-type genotypes were identified among 26 individuals, suggesting that the Stephens Island population has high levels of MHC class I variation. UA-type allelic diversity is generated by a mixture of point mutation and gene conversion. As has been found in birds and fish, gene conversion obscures the genealogical relationships among alleles and prevents the assignment of alleles to loci. Our results suggest that the molecular mechanisms that underpin MHC evolution in nonmammals make locus-specific amplification impossible in some species.     

The nucleotide sequence and comparative analysis of the H-2Dp class I H-2 gene

We present the complete nucleotide sequence and the deduced amino acid sequence of the H-2Dp class I gene. This gene, which was cloned from a B10.P genomic DNA library, encodes and intact, functional H-2Dp molecule. Comparative analysis of the Dp sequence with other class I sequences reveals both similarities and differences. This analysis also shows that these genes exhibit D region-specific, locus-specific, as well as allele-specific sequences. The H-2Dp nucleotide sequence is greater than 90% homologous to the H-2Ld and H-2Db genes and only approximately 85% homologous to the H-2Dd gene. The K region and Qa region genes are less homologous. The 3' noncoding sequences appear to be region-specific. All of the previously described D region genes, Db, Ld, and Dd, possess the B2-SINE Alu-like repetitive sequence, as does Dp. Thus, this B2 repeat is a region-specific marker present in all D region genes studied so far. The additional polyadenylation site found in the H-2Dp gene starting at nucleotide 4671, which is homologous to non-D region sequences, as well as unique protein Dp coding sequences, make this gene an interesting model for studying the evolution of polymorphism and structure/function relationships in the class I gene family.     

MHC class I genes of birds of prey: isolation, polymorphism and diversifying selection

The threat of emerging infectious diseases encourages the investigation of functional loci related to host resilience, such as those belonging to the major histocompatibility complex (MHC). Through careful primer design targeting to conserved regions of MHC class I sequences in birds, we successfully amplified a genomic fragment spanning exons 2–4 in three birds of prey. The identification of a highly conserved region within intron 2 allowed cross-amplifying complete exon 3 sequences in diurnal raptors, owls and New World vultures. We found evidence through PCR and cloning for 1–2 polymorphic class I loci, although this is almost certainly an underestimate. Inferences of diversifying selection in the kestrel MHC revealed that the two major regions of exon 3 exhibiting positive selection mostly agree with those described for the human HLA-A2 molecule. In contrast to passerines, where a high incidence of gene duplications and pseudogenes has been commonly documented, birds of prey emerge as nice model species for the investigation of the evolutionary significance and conservation implications of MHC diversity in vertebrates.