Class I major histocompatibility complex genes of the red-necked Wallaby, Macropus rufogriseus

Marsupials are one of three main evolutionary lineages in mammals, the other two being the monotremes and the placental mammals. The marsupial and the placental lineages separated between 120 and 156 million years ago. In this communication, we provide the first molecular description of class I major histocompatibility complex (Mhc) genes in a representative of the marsupial lineage, the red-necked wallaby, Macropus rufogriseus. Three different, nearly full-length class I Mhc sequences were identified in the cDNA library prepared from spleen mRNA of a single wallaby. The three sequences identify at least two loci. Under the assumption that two of the identified sequences are alleles, we designate the three wallaby genes Maru-Mhc-UA*01, Maru-Mhc-UA*02, and Maru-Mhc-UB*01. The three Maru sequences share several codon deletions and insertions not found in the class I genes of placental mammals. Comparisons of genetic distances among the known class I genes suggest that the Maru genes arose from one ancestral element, whereas the class I genes of the placental mammals arose from another, different ancestral element. The absence of an identifiable defect in the three Maru sequences suggests that the genes from which they were derived are functional. Hence, as in placental mammals, there appear to be two functional class I Mhc loci in the marsupials as well.

Trans-specific Mhc polymorphism and the origin of species in primates

The major histocompatibility complex (Mhc) is a cluster of loci controlling the specific immune response in vertebrates. Mhc alleles often differ by a large number of nucleotide substitutions, some of which began to accumulate before the emergence of extant species. We have applied the theory of allelic genealogy to the primate Mhc genes with the aim of estimating the size of the founding populations. The calculations indicate that the long-term effective population size of the studied species was between 10(4) and 10(5) individuals and that it most likely never dropped below 10(3) individuals.

Multiplication of Mhc-DRB5 loci in the orangutan: implications for the evolution of DRB haplotypes

The beta chain-encoding (B) class II genes of the primate major histocompatibility complex belong to several families. The DRB family of class II genes is distinguished by the occurrence of haplotype polymorphism--the existence of multiple chromosomal forms differing in length, gene number, and gene combinations, each form occurring at an appreciable frequency in the population. Some of the haplotypes, or fragments thereof, are shared by humans, chimpanzees, and gorillas. In an effort to follow the DRB haplotype polymorphism further back in time, we constructed DRB contig maps of the two chromosomes present in the orangutan cell line CP81. Two types of genes were found in the two haplotypes, Popy-DRB5 and Popy-DRB1*03, the former occurring in two copies and one gene fragment in each haplotype, so that the CP81 cell line contains four complete DRB5 genes and two DRB5 fragments altogether. Since the four genes are more closely related to one another than they are to other DRB5 genes, they must have arisen from a single ancestral copy by multiple duplications. At the same time, however, the two CP81 haplotypes differ considerably in their restriction enzyme sites and in the presence of Alu elements at different positions, indicating that they have been separated for a length of time that exceeds the lifespan of a primate species. Moreover, a segment of about 100 kilobase pairs is shared between the orangutan CP81-1 and the human HLA-DR2 haplotype. These findings indicate that part of the haplotype polymorphism may have persisted for more than 13 million years, which is the estimated time of human-orangutan divergence.

Different modes of Mhc evolution in primates

The human major histocompatibility complex (Mhc) is a chromosomal segment approximately 4 million bp long that contains > or = 84 genes. Some of these genes code for the class I and class II molecules, while the remaining genes code for complement components, cytochrome P450, tumor necrosis factor, and many other, unrelated proteins. We demonstrate on three examples (DP, C4-CYP21, and DRB) that different regions of the Mhc have different evolutionary histories. The organization of the DP region, which in humans contains four genes, was established in the ancestral Anthropoidea or earlier and has not changed since. The duplication that generated the two C4-CYP21 modules occurred in the ancestral Catarrhini or earlier, but the region has been undergoing periodic homogenizations via unequal crossing-over, which make paralogous genes in the same species more similar to each other than to orthologous genes of different species. The eight or nine genes of the DRB region were also generated in the ancestral Catarrhini, but the region has since been subject to frequent rearrangements, which generated various DRB haplotypes. Not only the alleles but, in part, also the haplotype polymorphism is evolving transspecifically. The DRB region of the Platyrrhini has an origin different from that of the Catarrhini. The picture emerging from these studies is that of both stability in some regions of the Mhc and tremendous evolutionary instability in other regions.

Major histocompatibility complex class II genes of zebrafish

Twenty cDNA clones derived from beta-chain-encoding class II genes of the zebrafish (Brachydanio rerio) major histocompatibility complex (MHC) have been sequenced. They fall into three groups identifying three loci of expressed genes. The length and organization of these genes are similar to those of their mammalian homologs. Amplification by polymerase chain reaction and sequencing of genomic DNA from zebrafish collected at different locations in India indicate the existence of a fourth group of sequences (fourth locus). A high degree of polymorphism at the B. rerio MHC loci and concentration of variability to the putative peptide-binding region of the beta 1-domain-encoding part of the gene are also indicated. Large genetic distances between alleles suggest trans-specific evolution of fish MHC polymorphism. Zebrafish genes appear to be derived from a different ancestor than the various class II gene families of other vertebrates. In spite of great sequence divergence between fish and mammalian MHC genes, there seems to be a striking conservation in their overall organization.

The molecular clock ticks regularly in muroid rodents and hamsters

Extensive DNA sequence data are used to compare the rates of nucleotide substitution in the mouse, rat, and hamster lineages. A relative rate test using hamster sequences as references shows that the rates of synonymous and nonsynonymous substitution in the mouse and rat lineages are nearly equal and a test using human sequences as references shows that the rates in the mouse, rat, and hamster lineages are also nearly equal. Under the assumptions that the guinea pig lineage and the myomorph (mouse, rat, and hamster) lineage diverged 70-100 million years (Myr) ago and that the rate of nucleotide substitution has been constant in all these lineages since their divergence, the date of the mouse-rat split is estimated to be between 20 and 29 Myr ago, which is considerably older than the date (approximately 12 Myr) suggested by available rodent fossils and considerably younger than the date (approximately 35 Myr) suggested by Wilson and colleagues. The murid-hamster split is estimated to be 1.6 times older than the mouse-rat split.

Trans-species origin of Mhc-DRB polymorphism in the chimpanzee

Trans-specific evolution of allelic polymorphism at the major histocompatibility complex loci has been demonstrated in a number of species. Estimating the substitution rates and the age of trans-specifically evolving alleles requires detailed information about the alleles in related species. We provide such information for the chimpanzee DRB genes. DNA fragments encompassing exon 2 were amplified in vitro from genomic DNA of ten chimpanzees. The nucleotide sequences were determined and their relationship to the human DRB alleles was evaluated. The alleles were classified according to their position in dendrograms and the presence of lineage-specific motifs. Twenty alleles were found at the expressed loci Patr-DRB1, -DRB3, -DRB4, -DRB5, and at the pseudogenes Patr-DRB6, -DRB7; of these, 13 are new alleles. Two other chimpanzee sequences were classified as members of a new lineage tentatively designated DRBX. Chimpanzee counterparts of HLA-DRB1*01 and *04 were not detected. The number of alleles found at individual loci indicates asymmetrical distribution of polymorphism between humans and chimpanzees. Estimations of intra-lineage divergence times suggest that the lineages are more than 30 million years old. Predictions of major chimpanzee DRB haplotypes are made.

Shared polymorphism between gorilla and human major histocompatibility complex DRB loci

A high degree of polymorphism and high nucleotide diversity mark the functional genes of the major histocompatibility complex (Mbc). Alleles at the different Mbc loci can be classified into distinct lineages that are shared between species and, therefore, are presumed to have been founded before speciation. We have sequenced the most polymorphic part of 25 gorilla Mbc-DRB genes from six individuals. (The DRB genes code for the beta-polypeptide chain of the alpha beta heterodimer that constitutes one family of the class II MHC molecules.) Fifteen of the sequences identify new alleles at four DRB loci; each of the six gorillas was heterozygous at one of the loci at least. Thirteen of the alleles could be assigned to lineages identified previously; the remaining two alleles represent new lineages. All the major human DRB allelic lineages are now known to be shared with apes, and all must have originated before the human-gorilla-chimpanzee divergence more than six million years (my) ago. The presence of some of the gorilla and human lineages in Old World monkeys suggests that these lineages emerged before the divergence of apes and cercopithecids. We argue that the major allelic lineages at the DRB1 locus began to diverge shortly after the rounds of duplication that generated the different DRB loci now found in the hominoids and that this event occurred more than 30 my ago. Comparison of closely related gorilla DRB sequences indicates that polymorphism may be generated by several mechanisms: point mutations, slippage during DNA replication, and recombination. Deduced gene linkages provide evidence for transspecies evolution of haplotype polymorphism.

Major-histocompatibility-complex DRB genes of a New-World monkey, the cottontop tamarin (Saguinus oedipus)

The DRB region of the human and great-ape major histocompatibility complex displays not only gene but also haplotype polymorphism. The number of genes in the human DRB region can vary from one to four, and even greater variability exists among the DRB haplotypes of chimpanzees, gorillas, and orangutans. Accumulating evidence indicates that, like gene polymorphism, part of the haplotype polymorphism predates speciation. In an effort to determine when the gene haplotype polymorphisms emerged in the primate lineage, we sequenced three cDNA clones of the New-World monkey, the cottontop tamarin (Saguinus oedipus). We could identify two DRB loci in this species, one (Saoe-DRB1) occupied by apparently functional alleles (*0101 and *0102) which differ by only two nucleotide substitutions and the other (Saoe-DRB2) occupied by an apparent pseudogene. The Saoe-DRB2 gene contains an extra sequence derived from the 3' portion of exon 2 and placed 5' to this exon. This sequence contains a stop codon which makes the translation of the bulk of the Saoe-DRB2 gene unlikely. Preliminary Southern blot hybridization analysis with probes derived from these two genes suggests that both the DRB gene polymorphism and the haplotype polymorphism in the cottontop tamarin may be low. In most individuals the DRB region of this species probably consists of three genes. Comparisons of the Saoe-DRB sequences with those of other primates suggest that probably all of the DRB genes found until now in the Catarrhini were derived from a common ancestor after the separation of the Catarrhini and Platyrrhini lineages. The extant DRB gene and haplotype polymorphism may therefore have been founded in the mid-Oligocene some 33 Mya.

Evolutionary origin of mutations in the primate cytochrome P450c21 gene

The CYP21 gene codes for the enzyme cytochrome P450c21 (21-hydroxylase), which is critically involved in the synthesis of glucocorticoids and mineralocorticoids. Standard human haplotypes contain two copies of CYP21--a functional gene and a pseudogene. Inactivation of the functional gene leads to congenital adrenal hyperplasia (CAH). The pseudogene has three main defects: an 8-bp deletion in exon 3, a T insertion in exon 7, and a stop codon in exon 8. To determine the origin of these defects and to shed light on the evolution of the CYP21 gene, we sequenced relevant segments of 10 primate CYP21 genes--three from a chimpanzee, another three from a gorilla, and four from an orangutan. We could show that the 8-bp deletion is present in the chimpanzee and humans, while the other two defects are restricted to humans only. In the gorilla and the orangutan, however, extra CYP21 copies are inactivated by other defects so that the number of functional copies is reduced in each species. Comparison of the sequences has revealed evidence for intraspecific homogenization (concerted evolution) of the CYP21 genes, presumably through an expansion-contraction process effected by relatively frequent unequal but homologous crossing-over.

The evolutionary origin of the HLA-DR3 haplotype

The human HLA-DR3 haplotype consists of two functional genes (DRB1*03 and DRB3*01) and one pseudogene (DRB2), arranged in the order DRB1...DRB2...DRB3 on the chromosome. To shed light on the origin of the haplotype, we sequenced 1480 nucleotides of the HLA-DRB2 gene and long stretches of two other genes, Gogo-DRB2 from a gorilla, "Sylvia" and Patr-DRB2 from a chimpanzee, "Hugo". All three sequences (HLA-DRB2, Gogo-DRB2, Patr-DRB2) are pseudogenes. The HLA-DRB2 and Gogo-DRB2 pseudogenes lack exon 2 and contain a twenty-nucleotide deletion in exon 3, which destroys the correct translational reading frame and obliterates the highly conserved cysteine residue at position 173. The Patr-DRB2 pseudogene lacks exons 1 and 2; it does not contain the twenty-nucleotide deletion, but does contain a characteristic duplication of that part of exon 6 which codes for the last four amino acid residues of the cytoplasmic region. When the nucleotide sequences of these three genes are compared to those of all other known DRB genes, the HLA-DRB2 is seen as most closely related to Gogo-DRB2, indicating orthologous relationship between the two sequences. The Patr-DRB2 gene is more distantly related to these two DRB2 genes and whether it is orthologous to them is uncertain. The three genes are in turn most closely related to HLA-DRBVI (the pseudogene of the DR2 haplotype) and Patr-DRB6 (another pseudogene of the Hugo haplotype), followed by HLA-DRB4 (the functional but nonpolymorphic gene of the DR4 haplotype). These relationships suggest that these six genes evolved from a common ancestor which existed before the separation of the human, gorilla, and chimpanzee lineages. The DRB2 and DRB6 have apparently been pseudogenes for at least six million years (myr). In the human and the gorilla haplotype, the DRB2 pseudogene is flanked on each side by what appear to be related genes. Apparently, the DR3 haplotype has existed in its present form for more than six myr.

C4 genes of the chimpanzee, gorilla, and orang-utan: evidence for extensive homogenization

The human complement component 4 is encoded in two genes, C4A and C4B, residing between the class I and class II genes of the major histocompatibility complex. The C4A and C4B molecules differ in their biological activity, the former binding more efficiently to proteins than to carbohydrates while for the latter, the opposite holds true. To shed light on the origin of the C4 genes we isolated cosmid clones bearing the C4 genes of a chimpanzee, a gorilla, and an orang-utan. From the clones, we isolated the fragments coding for the C4d part of the gene (exons and introns) and sequenced them. Altogether we sequenced eight gene fragments: three chimpanzee (Patr-C4-1*01, Patr-C4-1*02, Patr-C4-2*01), two gorilla (Gogo-C4-1*01, Gogo-C4-2*01), and three orang-utan (Popy-C4-1*01, Popy-C4-2*01, Popy-C4-3*01). Comparison of the sequences with each other and with human C4 sequences revealed that in the region believed to be responsible for the functional difference between the C4A and C4B proteins the C4A genes of the different species fell into one group and the C4B genes fell into another. In the rest of the sequence, however, the C4A and C4B genes of each species resembled each other more than they did C4 genes of other species. These results are interpreted as suggesting extensive homogenization (concerted evolution) of the C4 genes in each species, most likely by repeated unequal, homologous, intragenic crossing-over.

Gorilla major histocompatibility complex-DRB pseudogene orthologous to HLA-DRBVIII

The HLA-DR4 haplotype consists of four DRB genes: DRB1*04, DRBVII, DRBVIII, and DRB4*01, arranged in this order on the chromosome. The DRB1 and DRB4 genes code for beta chains of the alpha beta heterodimers expressed on the cell surface and bearing the HLA-DR4 and HLA-DRw53 determinants, respectively; the DRBVII and DRBVIII are pseudogenes. We found and sequenced a gene closely related to HLA-DRBVIII in the genome of the lowland gorilla "Sylvia." We designate this gene Gogo-DRB8. The close relationship between the two genes is indicated by the overall sequence similarity, the absence of recognizable exons 1 and 2 in both genes, the presence of two Alu repeats at corresponding positions, and high sequence similarity between corresponding repeats. The comparison with an outgroup (tamarin) gene and the functional counterparts of the DRB8 gene indicate that DRB8 emerged between 18 and 26 million years ago and became inactivated at the same time as or shortly after its creation. Hence DRB8 has probably existed as a pseudogene since the divergence of apes from Old World monkeys more than 20 million years ago.

Primate DRB6 pseudogenes: clue to the evolutionary origin of the HLA-DR2 haplotype

The HLA-DR2 haplotype contains three beta-chain encoding DRB genes and one alpha-chain encoding DRA gene. Of the three DRB genes, two are presumably functional (HLA-DRB1 and HLA-DRB5), whereas the third (HLA-DRBVI) is a pseudogene. A pseudogene closely related to HLA-DRBVI is present in the chimpanzee (Patr-DRB6) and in the gorilla (Gogo-DRB6). We sequenced the HLA-DRBVI and Patr-DRB6 pseudogenes (all exons and most of the introns), and compared the sequence to that of the Gogo-DRB6 gene (of which only the exon sequence is available). All three pseudogenes seem to lack exon 1 and contain other deletions responsible for shifts in the translational reading frame. At least the HLA-DRBVI pseudogene, however, seems to be transcribed nevertheless. The chimpanzee pseudogene contains two inserts in intron 2, one of which is an Alu repeat belonging to the Sb subfamily, while the other remains unidentified. These inserts are lacking in the human gene. A comparison with sequences published by other investigators revealed the presence of the HLA-DRBVI pseudogene also in the DR1 and DRw10 haplotypes. Measurements of genetic distances indicate DRB6 to be closely related to the DRB2 pseudogene and to the HLA-DRB4 functional gene. In humans, gorillas, and chimpanzees, the DRB6 pseudogene is associated with the same functional gene (DRB5) indicating that this linkage disequilibrium is at least six million years old and that DR2 is one of the oldest DR haplotypes in higher primates.

Origins of H-2 polymorphism in the house mouse. II. Characterization of a model population and evidence for heterozygous advantage

Comparison of the rate of synonymous and nonsynonymous nucleotide substitutions suggests that certain regions of the functional H-2 genes, which are part of the mouse major histocompatibility complex (Mhc), are under strong positive selection pressure. Thus far, however, little evidence has been provided for the existence of such pressure in natural mouse populations. We have, therefore, initiated experiments designed to test the hypothesis of positive selection acting on H-2 loci. The experiments are being carried out on two natural mouse populations in Jerusalem, Israel. One population occupies a space of about 100 m2 in a chicken coop, the other lives in a nearby field in which "mouse stations" providing food and shelter have been set up. Extensive typing of these two populations revealed the presence of only four H-2 haplotypes. Mice in the two populations breed continually all year around, yet population size varies seasonally, with population maxima in winter and minima in summer. The population in the chicken coop contains a relatively stable nucleus which may be organized in demes with an excess of females over males and limited territorial mobility. The rest of the mice stay in the population for a short time only and then either die or emigrate. The field population is smaller and more loosely organized than the chicken-coop population, with demes probably forming only during population maxima. For the rest of the time breeding in this population is probably panmictic. At a population minimum in the summer of 1984, H-2 homozygotes happened to predominate over heterozygotes. This situation, however, lasted for a short time only and thereafter there was a continuous, statistically highly significant increase in the proportion of H-2 heterozygotes of one or two types. The increase occurred in both populations but was more apparent in the chicken-coop population. This observation provides the first experimental evidence that heterozygous advantage might be one of the mechanisms maintaining high H-2 polymorphism in natural populations of the house mouse.

Cloning and sequencing of bovine apolipoprotein A-I cDNA and molecular evolution of apolipoproteins A-I and B-100

We have cloned and sequenced bovine apoA-I cDNA. Comparison with the apoA-I sequences of six other vertebrates shows the bovine gene to be most similar to that of the dog. Estimates of substitution rates show that apoA-I evolves approximately 25% faster than an average gene in mammalian lineages. All portions of the coding region evolve at roughly similar rates, suggesting that global conformation is conserved. However, a region of the rat protein has evolved rapidly both relative to other portions of the rat sequence and relative to homologous regions in other mammals. To extend our analysis to other apolipoproteins, we compared four vertebrate apoB-100 sequences. Conserved regions were found to include two putative LDL receptor binding domains, in addition to several regions of unidentified function. Comparison of the apoA-I sequences and the apoB-100 sequences indicates that the latter evolve approximately 40% faster than the former and at twice the average rate for mammalian proteins.