Quantifying the degree of convergence in primate Mhc-DRB genes

Molecular mechanisms of self-incompatibility in Brassicaceae and Solanaceae

Self-incompatibility (SI) is a mechanism for preventing self-fertilization in flowering plants. SI is controlled by a single S-locus with multiple haplotypes (S-haplotypes). When the pistil and pollen share the same S-haplotype, the pollen is recognized as self and rejected by the pistil. This review introduces our research on Brassicaceae and Solanaceae SI systems to identify the S-determinants encoded at the S-locus and uncover the mechanisms of self/nonself-discrimination and pollen rejection. The recognition mechanisms of SI systems differ between these families. A self-recognition system is adopted by Brassicaceae, whereas a collaborative nonself-recognition system is used by Solanaceae. Work by our group and subsequent studies indicate that plants have evolved diverse SI systems.

Characterising a microsatellite for DRB typing in Aotus vociferans and Aotus nancymaae (Platyrrhini)

Non-human primates belonging to the Aotus genus have been shown to be excellent experimental models for evaluating drugs and vaccine candidates against malaria and other human diseases. The immune system of this animal model must be characterised to assess whether the results obtained here can be extrapolated to humans. Class I and II major histocompatibility complex (MHC) proteins are amongst the most important molecules involved in response to pathogens; in spite of this, the techniques available for genotyping these molecules are usually expensive and/or time-consuming. Previous studies have reported MHC-DRB class II gene typing by microsatellite in Old World primates and humans, showing that such technique provides a fast, reliable and effective alternative to the commonly used ones. Based on this information, a microsatellite present in MHC-DRB intron 2 and its evolutionary patterns were identified in two Aotus species (A. vociferans and A. nancymaae), as well as its potential for genotyping class II MHC-DRB in these primates.

Trans-species polymorphism and allele-specific expression in the CBF gene family of wild tomatoes

Abiotic stresses such as drought, extreme temperatures, and salinity have a strong impact on plant adaptation. They act as selective forces on plant physiology and morphology. These selective pressures leave characteristic footprints that can be detected at the DNA sequence level using population genetic tools. On the basis of a candidate gene approach, we investigated signatures of adaptation in two wild tomato species, Solanum peruvianum and S. chilense. These species are native to western South America and constitute a model system for studying adaptation, due to their ability to colonize diverse habitats and the available genetic resources. We have determined the selective forces acting on the C-repeat binding factor (CBF) gene family, which consists of three genes, and is known to be involved in tolerance to abiotic stresses, in particular in cold tolerance. We also analyzed the expression pattern of these genes after drought and cold stresses. We found that CBF3 evolves under very strong purifying selection, CBF2 is under balancing selection in some populations of both species (S. peruvianum/Quicacha and S. chilense/Nazca) maintaining a trans-species polymorphism, and CBF1 is a pseudogene. In contrast to previous studies of cultivated tomatoes showing that only CBF1 was cold induced, we found that all three CBF genes are cold induced in wild tomatoes. All three genes are also drought induced. CBF2 exhibits an allele-specific expression pattern associated with the trans-species polymorphism.

Independent evolution of functional MHC class II DRB genes in New World bat species

Genes of the major histocompatibility complex (MHC) play a pivotal role in the vertebrate immune system and are attractive markers for functional, fitness-related, genetic variation. Although bats (Chiroptera) represent the second largest mammalian order and are prone to various emerging infectious diseases, little is known about MHC evolution in bats. In the present study, we examined expressed MHC class II DRB sequences (exons 1 to 4) of New World bat species, Saccopteryx bilineata, Carollia perspicillata, Noctilio albiventris and Noctilio leporinus (only exon 2). We found a wide range of copy number variation of DRB loci with one locus detected in the genus Noctilio and up to ten functional loci observed in S. bilineata. Sequence variation between alleles of the same taxa was high with evidence for positive selection. We found statistical support for recombination or gene conversion events among sequences within the same but not between bat species. Phylogenetic relationships among DRB alleles provided strong evidence for independent evolution of the functional MHC class II DRB genes in the three investigated species, either by recent gene duplication, or homogenization of duplicated loci by frequent gene conversion events. Phylogenetic analysis of all available chiropteran DRB exon 2 sequences confirmed their monophyletic origin within families, but revealed a possible trans-species mode of evolution pattern in congeneric bat species, e.g. within the genera Noctilio and Myotis. This is the first study investigating phylogenetic relationships of MHC genes within bats and therefore contributes to a better understanding of MHC evolution in one of the most dominant mammalian order.

Diversity and evolutionary patterns of immune genes in free-ranging Namibian leopards (Panthera pardus pardus)

The genes of the major histocompatibility complex (MHC) are a key component of the mammalian immune system and have become important molecular markers for fitness-related genetic variation in wildlife populations. Currently, no information about the MHC sequence variation and constitution in African leopards exists. In this study, we isolated and characterized genetic variation at the adaptively most important region of MHC class I and MHC class II-DRB genes in 25 free-ranging African leopards from Namibia and investigated the mechanisms that generate and maintain MHC polymorphism in the species. Using single-stranded conformation polymorphism analysis and direct sequencing, we detected 6 MHC class I and 6 MHC class II-DRB sequences, which likely correspond to at least 3 MHC class I and 3 MHC class II-DRB loci. Amino acid sequence variation in both MHC classes was higher or similar in comparison to other reported felids. We found signatures of positive selection shaping the diversity of MHC class I and MHC class II-DRB loci during the evolutionary history of the species. A comparison of MHC class I and MHC class II-DRB sequences of the leopard to those of other felids revealed a trans-species mode of evolution. In addition, the evolutionary relationships of MHC class II-DRB sequences between African and Asian leopard subspecies are discussed.

Characterisation and comparative analysis of MHC-DPA1 exon 2 in the owl monkey (Aotus nancymaae)

The Aotus nancymaae (owl monkey) is an important animal model in biomedical research, particularly for the preclinical evaluation of vaccine candidates against Plasmodium falciparum and Plasmodium vivax, which require a precisely typed major histocompatibility complex. The exon 2 from A. nancymaae MHC-DPA1 gene was characterised in order to infer its allelic diversity and evolutionary history. Aona-DPA1 shows no polymorphism and is related to other primate DPA alleles (including Catarrhini and Platyrrhini), constituting an ancient trans-specific and strongly supported lineage with different variability and selective patterns when compared to other primate-MHC-DPA1 lineages. A. nancymaae monkeys have thus a smaller MHC-DP polymorphism than MHC-DQ or MHC-DR.

Sequence polymorphism and geographical variation at a positively selected MHC-DRB gene in the finless porpoise (Neophocaena phocaenoides): implication for recent differentiation of the Yangtze finless porpoise?

Sequence polymorphism at the MHC class II DRB locus was investigated in three finless porpoise (Neophocaena phocaenoides) populations in Chinese waters. Intragenic recombination and strong positive selection were the main forces in generating sequence diversity in the DRB gene. MHC sequence diversity changed significantly along the study period. Significant decrease in heterozygosity and lost alleles have been detected in the Yangtze River population and South China Sea population since 1990. Furthermore, there is a trend of increasing population differentiation over time. Especially, the genetic differentiation between the Yangtze River population and the Yellow Sea population was very low prior to 1990 (F (ST) = 0.036, P = 0.009), but became very significant after 1990 (F (ST) = 0.134, P < 0.001), suggesting a recent augmentation of genetic differentiation between both populations probably in a relatively short-term period. Porpoises from the Yangtze River displayed divergent frequencies of shared and private alleles from those displayed by two marine populations, which suggest that the former riverine population has been under a different selection regime (characteristic of a fresh water environment) than that of its marine counterparts.

Heterochromatic and genetic features are consistent with recombination suppression of the self-incompatibility locus in Antirrhinum

Self-incompatibility (SI) is a genetic mechanism to prevent self-fertilization that is found in many species of flowering plants. Molecular studies have demonstrated that the S-RNase and SLF/SFB genes encoded by the single polymorphic S locus, which control the pollen and pistil functions of SI in three distantly related families, the Solanaceae, Scrophulariaceae and Rosaceae, are organized in a haplotype-specific manner. Previous work suggested that the haplotype structure of the two genes is probably maintained by recombination suppression at the S locus. To examine features associated with this suppression, we first mapped the S locus of Antirrhinum hispanicum, a member of the Scrophulariaceae, to a highly heterochromatic region close to the distal end of the short arm of chromosome 8. Both leptotene chromosome and DNA fiber fluorescence in situ hybridization analyses showed an obvious haplotype specificity of the Antirrhinum S locus that is consistent with its haplotype structure. A chromosome inversion was also detected around this region between A. majus and A. hispanicum. These results revealed that DNA sequence polymorphism and a heterochromatic location are associated with the S locus. Possible roles of these features in maintenance of the haplotype specificity involved in both self and non-self recognition are discussed.

High levels of diversity characterize mandrill (Mandrillus sphinx) Mhc-DRB sequences

The major histocompatibility complex (MHC) is highly polymorphic in most primate species studied thus far. The rhesus macaque (Macaca mulatta) has been studied extensively and the Mhc-DRB region demonstrates variability similar to humans. The extent of MHC diversity is relatively unknown for other Old World monkeys (OWM), especially among genera other than Macaca. A molecular survey of the Mhc-DRB region in mandrills (Mandrillus sphinx) revealed extensive variability, suggesting that other OWMs may also possess high levels of Mhc-DRB polymorphism. In the present study, 33 Mhc-DRB loci were identified from only 13 animals. Eleven were wild-born and presumed to be unrelated and two were captive-born twins. Two to seven different sequences were identified for each individual, suggesting that some mandrills may have as many as four Mhc-DRB loci on a single haplotype. From these sequences, representatives of at least six Mhc-DRB loci or lineages were identified. As observed in other primates, some new lineages may have arisen through the process of gene conversion. These findings indicate that mandrills have Mhc-DRB diversity not unlike rhesus macaques and humans.

Owl monkey MHC-DRB exon 2 reveals high similarity with several HLA-DRB lineages

One hundred and ten novel MHC-DRB gene exon 2 nucleotide sequences were sequenced in 96 monkeys from three owl monkey species (67 from Aotus nancymaae, 30 from Aotus nigriceps and 13 from Aotus vociferans). Owl monkeys, like humans, have high MHC-DRB allele polymorphism, revealing a striking similarity with several human allele lineages in the peptide binding region and presenting major convergence with DRB lineages from several Catarrhini (humans, apes and Old World monkeys) rather than with others New World monkeys (Platyrrhini). The parallelism between human and Aotus MHC-DRB reveals additional similarities regarding variability pattern, selection pressure and physicochemical constraints in amino acid replacements. These observations concerning previous findings of similarity between the Aotus immune system molecules and their human counterparts affirm this specie's usefulness as an excellent animal model in biomedical research.

Recombination and the origin of sequence diversity in the DRB MHC class II locus in chamois (Rupicapra spp.)

We examined the evolutionary processes contributing to genetic diversity at the major histocompatibility complex (MHC) class II DRB locus in chamois (Rupicapra spp., subfamily Caprinae). We characterised the pattern of intragenic recombination (or homologous gene conversion) and quantified the amount of recombination in the genealogical history of the two chamois species, Pyrenean chamois (Rupicapra pyrenaica) and Alpine chamois (Rupicapra rupicapra). We found evidence for intragenic recombination, and the estimated amount of population recombination suggests that recombination has been a significant process in generating DRB allelic diversity in the genealogical history of the genus Rupicapra. Moreover, positive selection appears to act on the same peptide-binding residues in both analysed chamois species, but not in identical intensity. Recombination coupled with positive selection drives the rapid evolution at the peptide-binding sites in the MHC class II DRB gene. Many chamois MHC class II DRB alleles are thus much younger than previously assumed.

Contribution of homoplasy and of ancestral polymorphism to the evolution of genes in anthropoid primates

Molecular phylogenies of lineages that split from one another in short succession are often difficult to resolve because different loci and different sites within the same locus yield incongruent relationships. The incongruity is commonly attributed to two causes: differential assortment of ancestral polymorphisms and homoplasy. To assess the relative contribution of these two causes, sequences of 57 segments from 51 loci in six primate lineages (human, chimpanzee, gorilla, orangutan, macaque, and tamarin, abbreviated as H, C, G, O, M, and T, respectively) were subjected to "partitioning" analysis, in which phylogenetically informative sites were identified in all 15 pairwise comparisons of each of the 57 segments and tallied for their support or lack thereof for each of the theoretically possible phylogenies. The six lineages include one of the best known cases of a difficult-to-resolve phylogeny: the trichotomy (H, C, G), in which the three lineages may have diverged from each other within a short period of time. In this period many of the ancestral polymorphisms apparently persisted and yielded phylogenetically incongruent signals. By contrast, no ancestral polymorphism is expected to have survived during the interval separating the divergences of the O, M, and T lineages from the ancestor of the (H, C, G) group. Any phylogenetic incompatibilities at sites in the O, M, and T lineages relative to the (H, C, G) group are therefore presumably the result of homoplasy. The frequency of homoplasy estimated in this manner is unexpectedly high: 12% for the (H, C, G) clade and 19% for the (H, C, G, O) clade. At least three-quarters of the 48% incompatibility observed in the (H, C) clade is attributable to the sorting out of ancestral polymorphisms coupled with intragenic recombination. Possible reasons for this high level of homoplasy in the O, M, and T lineages are discussed, and a computer simulation has been carried out to produce a model explaining the observed data.

The implications of intergenic polymorphism for major histocompatibility complex evolution

A systematic survey of six intergenic regions flanking the human HLA-B locus in eight haplotypes reveals the regions to be up to 20 times more polymorphic than the reported average degree of human neutral polymorphism. Furthermore, the extent of polymorphism is directly related to the proximity to the HLA-B locus. Apparently linkage to HLA-B locus alleles, which are under balancing selection, maintains the neutral polymorphism of adjacent regions. For these linked polymorphisms to persist, recombination in the 200-kb interval from HLA-B to TNF must occur at a low frequency. The high degree of polymorphism found distal to HLA-B suggests that recombination is uncommon on both sides of the HLA-B locus. The least-squares estimate is 0.15% per megabase with an estimated range from 0.02 to 0.54%. These findings place strong restrictions on possible recombinational mechanisms for the generation of diversity at the HLA-B.

Alu elements support independent origin of prosimian, platyrrhine, and catarrhine Mhc-DRB genes

The primate major histocompatibility complex (Mhc) genes fall into two classes and each of the classes into several families. Of the class II families, the DRB family has a long and complex evolutionary history marked by gene turnover, rearrangement, and molecular convergence. Because the history is not easily decipherable from sequences alone, Alu element insertions were used as cladistic markers to support the surmised phylogenetic relationships among the DRB genes. Intron 1 segments of 24 DRB genes from five platyrrhine species and five DRB genes from three prosimian species were amplified by PCR and cloned, and the amplification products were sequenced or PCR-typed for Alu repeats. Three Alu elements were identified in the platyrrhine and four in the prosimian DRB genes. One of the platyrrhine elements (Alu50J) is also found in the Catarrhini, whereas the other two (Alu62Sc, Alu63Sc) are restricted to the New World monkeys. Similarly, the four prosimian elements are found only in this taxon. This distribution of Alu elements is consistent with the phylogeny of the DRB genes as determined from their intron 1 sequences in an earlier and the present study. It contradicts the exon 2-based phylogeny and thus corroborates the conclusion that the evolution of DRB exon 2 sequences is, to some extent, shaped by molecular convergence. Taken together, the data indicate that each of the assemblages of DRB genes in prosimians, platyrrhines, and catarrhines is derived from a separate ancestral gene.

Identification of DRB alleles in rhesus monkeys using polymerase chain reaction-sequence-specific primers (PCR-SSP) amplification

Major histocompatibility complex (MHC) class In molecules play a vital role in the regulation of T-cell functions in the mammalian immune system. Two key features characterize the polymorphism of MHC haplotypes in humans and non-human primates: the existence of a large number of alleles, and the high degree of genetic diversity between those alleles. Rhesus monkeys and Chimpanzees have been extensively used as relevant models for human diseases and transplantation We have investigated DRB genes in 19 macaques, members of 3 families, using polymerase chain reaction with sequence-specific primers (PCR-SSP) and denaturing gradient gel electrophoresis (DGGE). After amplification PCR products were purified and subjected direct sequencing. Seven animals (Madison #1) were typed by DDGE also. We report that the DRB haplotypes defined by PCR-SSP exhibit a high degree of concordance with the data obtained by DGGE and direct sequening. Our data show prominent variability in the number of DRB1 alleles ranging from 1-4 per genotype within these families. This analysis demonstrated that most of the amplicons were identical to Mamu-DRB alleles that our PCR primers were to amplify. However, 98-99% similarity was noticed in the case of Mamu-DRB1*0303, Mamu-DRB6*0103 and Mamu-DRB*W201 alleles. The observed mismatches were located in non-polymorphic regions. Thus, family studies in rhesus macaques performed by molecular methods confirmed the multiplicity of Mamu-DRB1 alleles per haplotype and the existence of allelic associations published earlier. In addition, we propose 3 more DRB allele associations (haplotypes): Mamu-DRB1*04-DRB5*03; Mamu-DRB1*04-*DRB*W5; Mamu-DRB1*04*W2. The proposed medium-resolution PCR-SSP technique appears to be a highly reproducible and discriminatory typing method for detecting polymorphisms of DRB genes in rhesus monkeys.

Intronic sequence motifs of HLA-DQB1 are shared between humans, apes and Old World monkeys, but a retroviral LTR element (DQLTR3) is human specific

Long terminal repeats (LTRs) of the human endogenous retrovirus K (HERV-K) family have been found at several sites within the human genome, of which one is located in the vicinity of HLA-DQB1. Since this DQLTR3 is only present on some haplotypes, we performed a linkage analysis in 130 Caucasian families. In order to date the integration event we also investigated the presence of this DQLTR3 in apes and Old World monkeys. Additionally, we sequenced the adjacent region of DQLTR3-positive and -negative haplotypes in humans, apes and old world monkeys to elucidate their evolution. Linkage analysis revealed a differential integration of DQLTR3 on specific HLA-DQ haploypes: there was a high frequency of this LTR on haplotypes containing HLA-DQB1*0302 (0.96) and a moderate frequency on HLA-DQB1*0402 (0.78), HLA-DQB1*0303 (0.44), HLA-DQB1*0502 (0.38) and HLA-DQB1*0301 (0.35). HLA-DQB1*0201 (0.18), HLA-DQB1*0503 (0.15), HLA-DQB1*0603 (0.15), HLA-DQB1*0602 (0.04), HLA-DQB1*0501 (0.03) and HLA-DQB1*0604 were rarely positive or devoid of DQLTR3. In apes and Old World primates there was no DQLTR3 rendering it a human specific insertion. Sequence analysis of the adjacent region showed two different motifs in humans corresponding to either presence or absence of DQLTR3. Two different motifs were observed within three sequences of Macaca mulatta: One motif is closely related to the sequence from Macaca nemestrina and Macaca fascicularis whereas the other sequence is more closely related with that of Papio papio and Cercopithecus aethiops. Therefore the analysis of retroviral elements as well as intronic sequences of MHC-DQB1 could help to clarify the evolution of this gene region as well the phylogenic relationship between humans, apes and Old World monkeys.

Recombination and selection at Brassica self-incompatibility loci

In Brassica species, self-incompatibility is controlled genetically by haplotypes involving two known genes, SLG and SRK, and possibly an as yet unknown gene controlling pollen incompatibility types. Alleles at the incompatibility loci are maintained by frequency-dependent selection, and diversity at SLG and SRK appears to be very ancient, with high diversity at silent and replacement sites, particularly in certain "hypervariable" portions of the genes. It is important to test whether recombination occurs in these genes before inferences about function of different parts of the genes can be made from patterns of diversity within their sequences. In addition, it has been suggested that, to maintain the relationship between alleles within a given S-haplotype, recombination is suppressed in the S-locus region. The high diversity makes many population genetic measures of recombination inapplicable. We have analyzed linkage disequilibrium within the SLG gene of two Brassica species, using published coding sequences. The results suggest that intragenic recombination has occurred in the evolutionary history of these alleles. This is supported by patterns of synonymous nucleotide diversity within both the SLG and SRK genes, and between domains of the SRK gene. Finally, clusters of linkage disequilibrium within the SLG gene suggest that hypervariable regions are under balancing selection, and are not merely regions of relaxed selective constraint.

Flowering plant self-incompatibility: the molecular population genetics of Brassica S-loci

Self-incompatibility systems in different angiosperm families are reviewed, and the evidence that incompatibility has arisen several times is outlined. New data on the sequence polymorphism of self-incompatibility loci from two different angiosperm families are compared with results from other highly polymorphic loci, particularly MHC loci. We discuss what molecular genetic analyses of these sequences can tell us about the nature and maintenance of the polymorphism at self-incompatibility loci. We suggest that there is evidence for recombination at the Brassica self-incompatibility loci, so that it may be possible to discern regions that are particularly functionally important in the recognition reaction, even though the long-term maintenance of polymorphisms in these amino acid residues has caused the evolution of many other sequence differences between alleles.

Effects of intra-locus recombination of HLA polymorphism

The observed number of alleles (n(a)) at some human major histocompatibility complex (HLA) loci is more than twice as large as the pairwise mean number (KB) of nonsynonymous nucleotide substitutions in the peptide-binding region (PBR), although the KB is about the same as that predicted by a model of balancing selection. In order to assess the joint effect of intra-locus recombination and balancing selection on the HLA polymorphism, large scale computer simulation is conducted. It reveals that (1) both rate and location of break points of recombination are crucial factors to determine n(a), (2) intra-locus recombination tends to decrease KB, and (3) the rate of PBR nonsynonymous substitutions is insensitive to the recombination rate. Although a large number of alleles can be generated by intra-locus recombination, this fact alone is insufficient to account for the HLA polymorphism. It is argued that even patchwork patterns of PBR motifs, presumably owing to intra-locus recombination, must be maintained primarily by balancing selection.

Evolutionary relationship of HLA-DRB genes inferred from intron sequences

The major histocompatibility complex (Mhc) consists of class I and class II genes. In the human Mhc (HLA) class II genes, nine DRB loci have been identified. To elucidate the origin of these duplicated loci and allelic divergences at the most polymorphic DRB1 locus, introns 4 and 5 as well as the 3' untranslated region (altogether approximately 1,000 base pairs) of seven HLA-DRB loci, three HLA-DRB1 alleles, and nine nonhuman primate DRB genes were examined. It is shown that there were two major diversification events in HLA-DRB genes, each involving gene duplications and allelic divergences. Approximately 50 million years (my) ago, DRB1*04 and an ancestor of the DRB1*03 cluster (DRB1*03, DRB1*15, and DRB3) diverged from each other and DRB5, DRB7, DRB8, and an ancestor of the DRB2 cluster (DRB2, DRB4, and DRB6) arose by gene duplication. Later, about 25 my ago, DRB1*15 diverged from DRB1*03, and DRB3 was duplicated from DRB1*03. Then, some 20 my ago, the lineage leading to the DRB2 cluster produced two new loci, DRB4 and DRB6. The DRB1*03 and DRB1*04 allelic lineages are extraordinarily old and have persisted longer than some duplicated genes. The orthologous relationships of DRB genes between human and Old World monkeys are apparent, but those between Catarrhini and New World monkeys are equivocal because of a rather rapid expansion and contraction of primate DRB genes by duplication and deletion.

Trans-species polymorphism of class II Mhc loci in danio fishes

A characteristic feature of the major histocompatibility complex (Mhc) polymorphism in mammals is the existence of allelic lineages shared by related species. This trans-species polymorphism has thus far been documented only in primates, rodents, and artiodactyls. In this communication we provide evidence that it also exists in cyprinid (bony) fishes at the class II A and B loci coding for the alpha and beta polypeptide chains of the class II alpha:beta heterodimers. The study has focused on three species of the family Cyprinidae, subfamily Rasborinae: the zebrafish (Danio rerio), the giant danio (D. malabaricus), and the pearl danio (D. albolineatus). The polymerase chain reaction was used to amplify and then sequence intron 1 and exon 2 of the class II B loci and exon 2 of the class II A loci in these species. Phylogenetic analysis of the sequences revealed the existence of allelic lineages whose divergence predates the divergence of the three species at both the A and B loci. The lineages at the B locus in particular are separated by large genetic distances. The polymorphism is concentrated in the peptide-binding region sites and is apparently maintained by balancing selection. Sharing of this unique Mhc feature by both bony fishes and mammals suggests that the main function of the Mhc (presentation of peptides to T lymphocytes) has not changed during the last 400 million years of its evolution.

Structure and organization of pig MHC class II DRB genes: evidence for genetic exchange between loci

The pig major histocompatibility complex DRB genes were studied by polymerase chain reaction (PCR) amplification of exon 2 from eight domestic pigs and two European wild boars. Sequence comparisons together with a phylogenetic analysis showed the existence of at least three DRB genes of which only one appears to be expressed. The two putative DRB pseudogenes contained deletions in exon 2, making it possible to confirm the presence of three non-allelic DRB genes by analyzing the length polymorphism of the amplified PCR products. The expressed gene shows allelic polymorphism at the same positions as in the human DRB1 gene. In addition, this pig gene shows extensive allelic polymorphism at positions 84-88, whereas, e.g., human DRB genes do not. Surprisingly, the two putative DRB pseudogenes also display a considerable amount of allelic polymorphism, albeit of a different character as compared with the expressed DRB gene. Short stretches of sequences are shared between individual alleles at different loci. These sequence similarities cannot be due to natural selection, since two of the three DRB genes involved are polymorphic pseudogenes constituting allelic series that have diverged after the inactivation event. Instead, the results indicate that the sequences have been exchanged between the DRB genes by intergenic recombination.

Contrasting histories of avian and mammalian Mhc genes revealed by class II B sequences from songbirds

To explore the evolutionary dynamics of genes in the major histocompatibility complex (Mhc) in nonmammalian vertebrates, we have amplified complete sequences of the polymorphic second (beta1) and third (beta2) exons of class II beta chain genes of songbirds. The pattern of nucleotide substitution in the antigen-binding site of sequences cloned from three behaviorally and phylogenetically divergent songbirds [scrub jays Aphelocoma coerulescens), red-winged blackbirds (Agelaius phoeniceus), and house finches (Carpodacus mexicanus) reveals that class II B genes of songbirds are subject to the same types of diversifying forces as those observed at mammalian class II loci. By contrast, the tree of avian class II B genes reveals that orthologous relationships have not been retained as in placental mammals and that, unlike class II genes in mammals, genes in songbirds and chickens have had very recent common ancestors within their respective groups. Thus, whereas the selective forces diversifying class II B genes of birds are likely similar to those in mammals, their long-term evolutionary dynamics appear to be characterized by much higher rates of concerted evolution.