Mhc-E polymorphism in Pongidae primates: the same allele is found in two different species

Major Histocompatibility Complex Allele Persistence in Eurasia and America in the Genus Carduelis (Spinus) During Million Years

Introduction:

GenusCarduelis(Fringillidaefamily) includes goldfinches, siskins, redpolls, greenfinches and crossbills. Many of the species classified within this genus and other related genera have been grouped by using molecular systematics and the mitochondrial cytochrome b (mt cyt b) gene. According to this, the Eurasian siskin (C. spinus)is the only one extant direct ancestor of several North American finches; North American / South American radiations may have been originated by Eurasian siskin (or extinct relative). In the present work, we aim to perform a study of transpecies and transcontinental analyses of MHC (Major Histocompatibility Complex) Class I alleles in several genusCarduelis/Spinusspecies in order to draw evolutionary conclusions in several wild bird species belonging to the genusCarduelis / Spinus.

Materials and Methods:

Blood was taken from worldwide wild bird species. Passerine phylogeny was done after analysing mtDNA with Maximun Likelihood and Bayesian dendrograms. Major histocompatibility complex alleles were obtained by standard DNA cloning and sequencing.

Results:

We found two matches between MHC-I DNA alleles from different South American siskins at DNA level. Also, it was observed that the Eurasian siskin shares a protein with pine siskin and another with three South American siskins. Eight South American siskins species also share the same MHC protein. In addition, studied songbirds MHC class I intron 2 is longer than that ofGallus gallus.

Conclusion:

We have drawn the following conclusions: 1) We present the first direct evidence that “Minimal Essential MHC” does not exist for birds; one of its main definition characters,i.e.: small intron size does not hold for songbirds. 2) We also report that MHC genes transpecies evolution exist in birds by showing also for the first time that worldwide bird species keep the same MHC protein and DNA alleles. 3) New evidences on MHC alleles conservation from EurasianCarduelis spinus(most ancient) to South American siskins (most recent) during million years support that Eurasian siskin is the parental species for American GenusCarduelis (Spinus)species. It is uncertain whether Eurasian siskin (or extant relative) had initially an Holoartic distribution, including America.

MHC-F DNA sequences in bonobo, gorilla and orangutan

The major histocompatibility complex (MHC)-F class Ib locus shows a limited polymorphism, and the function of its mainly intracellular protein is not clear. We have identified human leucocyte antigen (HLA)-F orthologous DNA sequences in Pongidae in order to study the MHC-F gene evolution and its products' function. HLA-F orthologous cDNA transcripts are found in chimpanzee and in the new primate species studied (bonobo, gorilla and orangutan). Analyses of the predicted amino acid sequences and their comparison with other primate MHC-F proteins show that MHC-F may be a protein with a typical class I structure and that the key residues of the peptide-binding region (PBR) are highly conserved in MHC-F in all studied primates species. Thus, MHC-F conservation along the primate evolution suggests an important role in cellular physiology. It is possible that the MHC-F protein could be involved, together with MHC-G and MHC-E, in the natural killer (NK) cell activity regulation, although rhesus macaque does not express MHC-G and MHC-E orthologues. The evolutionary pathway of the six-base-pair deletion at exon 2 existing in some primates is put forward.

Pig-tailed macaques (Macaca nemestrina) possess six MHC-E families that are conserved among macaque species: implication for their binding to natural killer receptor variants

MHC loci encode highly polymorphic molecules involved in the presentation of self and non-self peptides to cells of the adaptive and innate immune systems. Although variable, MHC-E genes are well conserved among primates and provide signals to natural killer cells. In this study, we sequenced and analyzed MHC-E alleles of pig-tailed macaque (Macaca nemestrina), a nonhuman primate used for HIV pathogenesis and vaccine studies. Among a group of seven macaques, the characterization of eight Mane-E alleles revealed an increased number of polymorphic sites compared with human HLA-E alleles. Phylogenetic analyses of MHC-E alleles from pig-tailed macaque, rhesus monkey (Macaca mulatta) and cynomolgus macaque (Macaca fascicularis) demonstrated that the three macaque species shared six families of macaque MHC-E alleles and indicated that these families existed in the common ancestor 5.5 million years ago. Polymorphic Mane-E sites were not concentrated within the peptide-binding pockets, but were distributed throughout the entire ORF. The peptide-binding domain of Mane-E is similar to its human analogue, and peptide substrates theoretically capable of binding to Mane-E molecules were found in the leader sequence of classical Mane-A and -B molecules. Additionally, the polymorphic amino acids located in the alpha(1) and alpha(2) domains of Mane-E molecules have side chains expected to be oriented toward solvent and away from the peptide-binding groove, suggesting that some of them (positions 19, 73, 79 and 145) might be available for interaction with polymorphic receptors of natural killer cells.

Lack of MHC-G4 and soluble (G5, G6) isoforms in the higher primates, Pongidae

HLA-G is a class Ib (nonclassical) major histocompatibility complex (MHC) protein expressed at the materno-fetal interface that may inhibit natural killer (NK) cell-mediated lysis in an allotype-independent manner. The human MHC-G transcript is differentially spliced, giving rise to at least six different forms. In order to study the evolutionary importance of this phenomenon, the presence of alternative splicing in MHC-G mRNA molecules from Pongidae (Chimpanzee, Gorilla, and Orangutan) has been investigated in the present work, and three alternative spliced isoforms (i.e.: G1, G2, and G3) have been found, but not the G4 and the soluble G5 and G6 ones. In addition, a novel MHC-G isoform is described in Gorilla, "G2 short." This molecule is similar to the G2 isoform, but it lacks 29 amino acids normally encoded by exon 4. Our findings suggest that soluble isoforms are not necessary for MHC-G function(s) in Pongidae or that MHC-G is not a functional protein, because G1 is not necessary for survival in humans and Cercopithecinae bear stop codons in MHC-G exon 3.

Diversity is demonstrated in class I HLA-A and HLA-B alleles in Cameroon, Africa: description of HLA-A*03012, *2612, *3006 and HLA-B*1403, *4016, *4703

To examine the genetic diversity in west Africa, class I HLA-A and HLA-B alleles of 92 unrelated individuals from two areas in the Cameroon, the capital Yaoundé and the village of Etoa, were identified by direct automated DNA sequencing of exons 2 and 3 of the HLA-B locus alleles and sequence-specific oligonucleotide probe (SSOP) and/or sequencing of the HLA-A locus alleles. HLA-A*2301 (18.7%), A*2902 (10.4%), B*5301 (10.9%), and B*5802 (10.9%) were the most frequently detected alleles, present in at least 10% of the population. A total of 30 HLA-A locus and 33 HLA-B locus alleles, including six novel alleles, were detected. The novel alleles were HLA-A*03012, A*2612, A*3006 and HLA-B*1403, B*4016, and B*4703. HLA-B*4703 contains a novel amino acid sequence that is a combination of the first 5 amino acids of the Bw6 epitope and the last 2 residues of the Bw4 epitope. The addition of 6 alleles to the ever-expanding number of known class I HLA alleles supports our hypothesis that extensive genetic diversity, including previously undescribed alleles, would be observed in this African population. In the Yaoundé population, the allele frequency distribution at the HLA-A locus is consistent with distributions indicative of balancing selection. Extensive HLA-A-B haplotypes were observed in this population suggesting that only a fraction of the Cameroon HLA-A-B haplotype diversity has been observed.

Evolutionary lineages of RT1.Ba in the Australian Rattus

In this study, the evolutionary history of the variable second exon of RT1.Ba and its adjoining intron b are compared across a number of species and subspecies of the Australian RATTUS: Three lineages are identified in the second intron across a range of Rattus species. Two of these lineages, separated by the insertion of a probable rodent short interspersed nucleotide element and by point mutations outside the indel region, are both found in each of the major clades of the endemic Australian RATTUS: This pattern of ancestral polymorphism is reflected in the adjoining exon 2 sequences, although phylogenetic constraints confirm that the clustering is not identical to that of the associated intron sequences. In addition, the coding sequences show evidence of the retention of ancestral polymorphism, with identical exon sequences found in two divergent species, and some indication of gene conversion detected for the exon sequences.

Mamu-I: a novel primate MHC class I B-related locus with unusually low variability

The rhesus macaque is an important animal model for several human diseases and organ transplantation. Therefore, definition of the MHC of this species is crucial to the development of these models. Unfortunately, unlike humans, lymphocytes from a single rhesus macaque express up to 12 different MHC class I cDNAs. From which locus these various alleles are derived is unclear. In our attempts to define the MHC class I loci of the rhesus macaque, we have identified an unusual MHC class I locus, Mamu-I. We isolated 26 I locus alleles from three different macaque species but not from three other Cercopithecine genera, suggesting that the I locus is the result of a recent duplication of the B locus occurring after the divergence of macaques from the ancestor of the other extant Cercopithecine genera. Mamu-I mRNA transcripts were detected in all tissues examined and Mamu-I protein was produced in rhesus B lymphoblastoid cell lines. Furthermore, Mamu-I protein was detected by flow cytometry on the surface of human 721.221 cells transfected with Mamu-I. In contrast to the polymorphism present at this locus, there is unusually low sequence variability, with the mean number of nucleotide differences between alleles being only 3.6 nt. Therefore, Mamu-I is less variable than any other polymorphic MHC class I locus described to date. Additionally, no evidence for positive selection on the peptide binding region was observed. Together, these results suggest that Mamu-I is an MHC class I locus in primates that has features of both classical and nonclassical loci.

Polymorphism of Mhc-DRB alleles in Cercopithecus aethiops (green monkey): generation and functionality

DRB genes have been studied for the first time in green monkeys (Cercopithecus aethiops). Eleven new DRB alleles (exon 2, exon 3) have been obtained and sequenced from cDNA. A limited number of lineages have been identified: DRB1*03 (4 alleles), DRB1*07 (3 alleles), DRB5 (1 allele), DRB*w6 (1 allele), and DRB*w7 (2 alleles). The existence of Ceae-DRB1 duplications is supported by the finding of 3 DRB1 alleles in 3 different individuals. Ceae-DRB1*0701 may be non-functional because it bears serine at position 82, which hinders molecule surface expression in mice; the allele is only found in Ceae-DRB duplicated haplotypes. Base changes in cDNA Ceae-DRB alleles are consistent with the generation of polymorphism by point mutations or short segment exchanges between alleles. The eleven green monkey DRB alleles meet the requirements for functionality as antigen-presenting molecules (perhaps, excluding DRB1*0701), since: 1) they have been isolated from cDNA and do not present deletions, insertions or stop codons: 2) structural motifs necessary for a correct folding of the molecule, for the formation of DR/DR dimers and for CD4 interactions are conserved, and 3) the number of non-synonymous substitutions is higher than the number of synonymous substitutions in the peptide binding region (PBR), while the contrary holds true for the non-PBR region.

Allelic diversity at the primate MHC-DMB locus: presence of a conserved tyrosine inhibitory motif in the cytoplasmic tail

Ten new primate Mhc-DMB complete cDNA sequences have been obtained in chimpanzee (n=four), gorilla (n=three) and orangutan (n=three); this gene has not been previously studied in these species. Exonic allelism has been recorded all along the molecule domains and also in the leader peptide, but not in the transmembrane segment. An analysis of the residues critical in the conformation of the Mhc-DR peptide-binding site was done in order to look for a Mhc-DR homologue site; synonymous substitutions are favoured in this homologous HLA-DM region. This is another finding that supports the possibility that DM could not be typically presenting molecules. The immunoreceptor inhibition motif Tyr 230-Thr/Ser 231-Pro 232-Leu 233 (ITIM) is invariantly present in apes for at least 15 million years, and may have a double function: 1) To direct DMB-DMA molecules from the endoplasmic reticulum or cell surface towards the endosomal/lysosomal class II compartment and 2) to send an inhibitory signal to the cell in order to stop synthesis of unnecessary HLA-DR molecules, once all available antigenic peptides are loaded. Other molecules, like NK-cell receptors and Fc receptors, bear this type of tyrosine-based inhibitory motifs in order to switch off specific cell functions. DMB molecules (as previously shown in C4d molecules) do not present species-specific motifs in common chimpanzee, suggesting that this species is very close to gorilla or man; also, DMB, like C4d molecules, do not show a trans-species evolution pattern, suggesting the existence of extensive homogenization of DMB genes within each species or a recent generation of alleles. Finally, a clade grouping human and gorilla DMB cDNA sequences is obtained using a dendrogram (as for C4d trees); this is in contrast to others' results that obtain a human/chimpanzee clade using different DNA sequences.