Abstract
Several macaques species are used for HIV pathogenesis and vaccine studies, and the characterization of their major histocompatibility complex (MHC) class I genes is required to rigorously evaluate the cellular immune responses induced after immunization and/or infection. In this study, we demonstrate that the gene expressing the Mane-A*06 allele of pig-tailed macaques is an orthologue of the locus encoding the Mamu-A*05 allele family in rhesus macaques. Analysis of the distribution of this locus in a cohort of 63 pig-tailed macaques revealed that it encodes an oligomorphic family of alleles, highly prevalent (90%) in the pig-tailed macaque population. Similarly, this locus was very frequently found (62%) in a cohort of 80 Indian rhesus macaques. An orthologous gene was also detected in cynomolgus monkeys originating from four different geographical locations, but was absent in two African monkey species. Expression analysis in pig-tailed macaques revealed that the Mane-A*06 alleles encoded by this locus are transcribed at 10- to 20-fold lower levels than other MHC-A alleles (Mane-A*03 or Mane-A*10). Despite their conservation and high prevalence among Asian macaque species, the alleles of the Mane-A*06 family and, by extension their orthologues in rhesus and cynomolgus monkeys, may only modestly contribute to cellular immune responses in macaques because of their low level of expression.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Macaques are Asian non-human primates frequently used in biomedical research to study human pathogens or organ transplantation because of their genetic and immunologic similarities to humans. In this regard, infections of macaques with simian immunodeficiency viruses (SIV) or chimeric simian human immunodeficiency viruses (SHIV) have been extensively used as animal models to study HIV pathogenesis and vaccine development. Three species are commonly used for these experiments: the rhesus macaque (Macaca mulatta), the pig-tailed macaque (M. nemestrina), and the cynomolgus or crab-eating macaque (M. fascicularis). Although rhesus monkeys are currently the principal non-human primate species used, the differential susceptibility of Indian and Chinese rhesus macaque sub-species to SIV-induced disease and the small number of animals having particular immunologic characteristics (e.g., the Mamu-A*01 allele) can profoundly influence the outcome and the interpretation of logistically demanding experiments. The two other macaque species therefore represent valid alternatives as animal models. Furthermore, the relative higher susceptibility of pig-tailed macaques to a variety of SIV strains (SIVmac, SIVagm, and SIVsun) compared to rhesus and cynomolgus macaques, offers an opportunity to evaluate host factors affecting primate lentivirus induced disease and to study the role of immune responses in controlling these infections (Beer et al. 2005; Hirsch et al. 1995; Reimann et al. 2005).
The identification and characterization of genes involved in cellular immune responses, particularly the major histocompatibility complex (MHC) class I genes, is currently a major goal for understanding how non-human primates control lentivirus replication. A better definition of macaque immunogenetics would allow the selection of more homogeneous groups of animals for pathogenesis and vaccine studies, and possibly reduce the variable clinical courses frequently observed in SIV- or SHIV-infected animals due to their non-inbred status. Improved characterization of macaque genetic make-up would also contribute to a deeper understanding of the kinetics of immune responses induced after immunization and/or infection. Current knowledge of MHC organization in macaques accrues primarily from studies conducted in rhesus macaques (Adams and Parham 2001; Bontrop 2006). Initial experiments identified MHC class I alleles expressed by individual animals and demonstrated that rhesus macaques possess MHC-A (Mamu-A) and MHC-B (Mamu-B) genes but no MHC-C locus (Boyson et al. 1996). Since that initial report, several rhesus MHC class I alleles have been shown to present SIV-derived peptides, and detailed peptide-binding properties have been described for several of them (Mamu-A*01, Mamu-A*02, Mamu-A*08, Mamu-A*11, Mamu-B*01, Mamu-B*03, Mamu-B*04, Mamu-B*12, Mamu-B*17; Allen et al. 2001; Dzuris et al. 2000; Hickman-Miller et al. 2005; Loffredo et al. 2004, 2005; Mothe et al. 2002; Sette et al. 2005; Sidney et al. 2000). Based on the number of MHC-A and MHC-B alleles detected per animal, initial studies also suggested that the loci encoding MHC-A and MHC-B alleles were duplicated at least once on the rhesus chromosome. This observation has been recently confirmed by sequencing the MHC region of two different haplotypes (Daza-Vamenta et al. 2004; Kulski et al. 2004). Two functional Mamu-A loci were detected for each sequenced haplotype, whereas up to 15 MHC-B loci were identified on the rhesus chromosome. Some of these Mamu-B loci appeared to be functional, whereas others were shown to contain incapacitating mutations. A recent study involving a large rhesus macaque cohort reported that several haplotypes could be identified based on the number of MHC-A loci carried per chromosome (Otting et al. 2005). The presence of specific haplotypes for rhesus macaque MHC-B genes has been difficult to demonstrate because of the large number of loci and their highly variable copy number in different animals.
All macaque species have evolved from a common African ancestor. It is therefore expected that their genomes exhibit some strong organization similarities in their MHC class I region. The 20 recognized macaque species (Brandon-Jones et al. 2004; Sinha et al. 2005) have been separated into several “species groups” based on morphologic (Fooden 1976) and, more recently, genetic differences (Morales and Melnick 1998; Tosi et al. 2000, 2003). Cynomolgus and rhesus macaques are included in the Fascicularis group, whereas pig-tailed macaques are members of the Silenus group. These two groups evolved from the common ancestor of all Asian macaques that colonized Asia about 5.5 million year ago. The Silenus group, including pig-tailed macaques, diverged from the ancestor of the Fascicularis group 4.9 million years ago, and the rhesus and cynomolgus macaques speciation occurred 2.4 million years later. Whereas a similar genetic organization is expected between rhesus and cynomolgus macaques, pig-tailed macaques could have accumulated significant differences compared to the two other taxons during their 2.4 million year of separate evolution.
In contrast to the knowledge accumulated about the organization of the rhesus macaque MHC, investigations of the MHC class I genes of other macaque species have only recently begun. MHC class I alleles have been described for pig-tailed macaques (Lafont et al. 2003; Smith et al. 2005) and cynomolgus monkeys (Krebs et al. 2005; Uda et al. 2004, 2005). By microsatellite analysis, the MHC region in Mauritian cynomolgus macaques appears to have a general organization similar to that of rhesus macaques (Daza-Vamenta et al. 2004; Wiseman et al. 2007), but the number of MHC class I loci per haplotype remains unknown. Nothing is currently known about the organization of the MHC class I region in pig-tailed macaques nor the similarities or orthology of their loci with the rhesus and cynomolgus macaque loci. It is therefore important to investigate the orthology and paralogy of MHC class I loci between these three macaque species. Orthologues are genes, present in different species, which have been inherited from their common ancestor, whereas paralogs are homologous genes that derived from one another by gene duplication. The presence of an orthologue between pig-tailed macaques and rhesus or cynomolgus monkeys would indicate that other macaque species likely possess this orthologue. As orthologous genes may frequently exhibit similar functions, their identification may prove useful in assessing their role in immune responses of macaques to infectious agents such as SIV.
In this study, we have focused on MHC-A alleles of pig-tailed macaques and show that the gene expressing the Mane-A*06 allele (Lafont et al. 2003) is in fact an orthologue of the locus encoding the Mamu-A*05 allele family in rhesus macaques. An analysis of the distribution of this locus in a cohort of pig-tailed macaques demonstrated that it encodes an oligomorphic family of alleles, highly prevalent within the pig-tailed macaque population. An orthologous gene was also detected in cynomolgus monkeys but not in two African monkey species. Despite their conservation and high prevalence among Asian macaque species, the MHC-A alleles present at this locus appear to be expressed at very low levels, suggesting that MHC-A alleles of the Mane-A*06 family and, by extension, their orthologues in rhesus and cynomolgus monkeys, are very likely minor MHC class I alleles.
Materials and methods
Animals
Pig-tailed macaques (M. nemestrina; n = 63) were obtained from New Iberia and Osage Research Centers. Most of the animals were born in the US from parents having Indonesian ancestors. A minority were feral animals imported directly from Indonesia. Rhesus macaques (M. mulatta; n = 80) were all of Indian origin, whereas cynomolgus macaques (M. fascicularis) were imported from the Philippines (n = 5), Mauritius (n = 2), Vietnam (n = 1), China (n = 3) or were of unknown origin (n = 2). The vervet African green monkeys (Chlorocebus pygerythrus; n = 2) were imported from Tanzania and the Patas monkeys (Erythrocebus patas; n = 4) were born in the US from Nigerian ancestors. All animals were maintained in accordance with the Guide for the Care and Use of Laboratory Animals (Committee on Care and Use of Laboratory Animals 1985). The animals were housed in a biosafety level 2 facility; biosafety level 3 practices were followed. Animals were anesthetized with intramuscular injections of ketamine hydrochloride (Ketaject; Phoenix Pharmaceutical, St Joseph, MO, USA) and acepromazine acetate (Fermenta Animal Health, Kansas City, MO, USA) during phlebotomies.
Cell lines
Pig-tailed macaque B lymphocyte cell lines (B-LCL) were established by infecting peripheral blood mononuclear cells, isolated from whole blood using Percoll (Amersham Pharmacia Biotech AB, Uppsala, Sweden) gradient centrifugation, with Herpesvirus papio, present in the supernatant of the 594S cell line (Rabin et al. 1977), kindly provided by Dr. Jeffrey I. Cohen (Laboratory of Clinical Infectious Diseases, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, MD, USA). The stable B cell lines were maintained in RPMI 1640 medium (Cambrex Bio Science Walkersville, Walkersville, MD, USA) supplemented with 20% heat-inactivated fetal bovine serum (Hyclone, Logan, UT, USA), 2 mM l-glutamine, 100 U/ml penicillin-G, and 100 U/ml streptomycin (R20 medium).
Genomic DNA preparation
Genomic DNA from pig-tailed macaques, rhesus macaques, cynomolgus macaques, African Green monkeys, and Patas monkeys was extracted from peripheral blood leukocytes using the Wizard Genomic DNA purification kit (Promega, Madison, WI, USA) according to the manufacturer’s protocol. Briefly, 5 ml of ethylenediamine tetraacetic acid (EDTA)-treated whole blood were centrifuged 10 min at 2,500 rpm. After removing the plasma, red blood cells were lysed and the leukocytes were recovered after centrifugation at 2,500 rpm for 10 min, lysed with nuclei lysis solution, and incubated with RNase A (20 μg/ml) for 1 h at 37°C degrees. Cellular proteins were precipitated with protein precipitation solution and the genomic DNA was precipitated in 5 ml isopropanol. After a wash in 70% ethanol, the genomic DNA pellet was air dried and solubilized in 300–400 μl of water by incubating for 1 h at 65°C.
Mane-A*06/Mamu-A*05 genotyping by SSP-PCR
Genotyping for the presence of Mane-A*06/Mamu-A*05 alleles was performed on genomic DNA. Briefly, a sequence specific amplification, site specific primer-PCR (SSP-PCR), was performed using Mane-A6S sense (CAAGGCCGACACACAGACTCT) and Mane-A6R reverse (CTCTCCACTGCTCCGCCA) primers. An internal control of amplification was obtained using Mane-DRB S4 sense (TAAGTCTGAGTGTCATTTCTTCAATGGGA) and Mane-DRB R2 reverse (CCTCGCCGCTGCACTGT) primers. The PCR mixture contained 50 mM KCl, 1.5 mM MgCl2, 10 mM Tris-HCl, pH 8.3, 0.2 mM each dATP, dTTP, dCTP, and dGTP, 20 pmol of each Mane-A*06 specific primers, 25 pmol of each Mane-DRB specific primers, and 5 U of Ampli Taq DNA polymerase (Perkin Elmer, Wellesley, MA, USA) in a final volume of 50 μl. The reactions were heated at 94°C for 5 min, and amplification was conducted for 25 cycles as follows: denatured for 30 s at 94°C, annealed for 30 s at 65.5°C, and extended for 30 s at 72°C. A final extension was then conducted for 7 min at 72°C. Fifteen microliters of PCR reactions were loaded onto a 1.5% agarose Tris-acetate-EDTA gel and separated by electrophoresis. A 246 bp Mane DRB specific product was amplified in all animals, whereas an additional 679 bp product was generated with Mane-A*06 positive animals. For sequence analysis, PCR was performed without the Mane DRB primers and using the SuperTaq plus DNA polymerase (Ambion, Austin, TX, USA). PCR amplicons were gel-purified using Qiaquick gel extraction kit (Qiagen, Valencia, CA, USA) and were directly sequenced using an Applied Biosystems 3130XL genetic analyzer.
MHC cDNA cloning and sequencing
Cloning of Mane-A*06 allele cDNA was performed by reverse transcription (RT)-PCR amplification in two steps. Briefly, total cellular RNA was extracted from 5 × 106 cells from individual pig-tailed macaque B cell lines using Tri reagent (Molecular Research Center, Cincinnati, OH, USA). To generate the complete 5′ extremity of Mane-A*06 allele cDNA, a RNA ligase mediated rapid amplification of cDNA extremities (RLM-RACE) was performed using the First Choice RLM RACE kit (Ambion, Austin, TX, USA) according to the manufacturer’s instructions. The first PCR amplification was performed using the 5′ RACE outer primer from the kit and ManeA7ex (GCACTGTCACTGCTTGCAG), an MHC-A specific primer annealing to the junction between exons 6 and 7. The PCR reactions contained 50 mM KAc, 1.5 mM MgSO4, 10 mM Tris-HCl, pH 9.0, 0.2 mM each dATP, dTTP, dCTP, and dGTP, 20 pmol of each primer, and 5 U of SuperTaq Plus DNA polymerase (Ambion). The reactions were heated at 94°C for 5 min, and amplification was conducted for 30 cycles as follows: denatured for 30 s at 94°C, annealed for 30 s at 63.5°C, and extended for 90 s at 72°C. A nested PCR was then performed using the 5′ RACE inner primer provided in the kit and the ManeA6R reverse primer. Almost full-length Mane-A*06 allele cDNAs were generated using the 3′ RACE adapter from the First Choice RLM RACE kit (Ambion) as primer in a reverse transcription reaction following the manufacturer’s instructions. PCR amplification was performed using Mane-A6S and the 3′ RACE outer primer from the kit. The PCR reactions contained 50 mM KAc, 1.5 mM MgSO4, 10 mM Tris-HCl, pH 9.0, 0.2 mM each dATP, dTTP, dCTP, and dGTP, 20 pmol of each primer and 5 U of SuperTaq Plus DNA polymerase (Ambion). Each reaction contained 2 μl of cDNA in a final volume of 50 μl. A single PCR was sufficient to amplify enough products in 3′ RACE reactions. The reactions were heated at 94°C for 5 min, and amplification was conducted for 25 cycles as follows: denatured for 30 s at 94°C, annealed for 30 s at 63.5°C, and extended for 1 min and 30 s at 72°C. A final extension was conducted for 7 min at 72°C. PCR products were gel-purified using a Qiaquick gel extraction kit and then cloned into the pCR2.1 TOPO cloning vector (Invitrogen, Carlsbad, CA, USA). Individual clones were sequenced using an Applied Biosystems 3130XL genetic analyzer. Following recommendations to avoid PCR-generated mutations for HLA alleles (Ennis et al. 1990; Marsh et al. 2002), individual alleles were defined by the presence of an identical sequence in a minimum of three independent clones.
Mane-A*06 expression analysis
RT-PCR amplifications were performed on total RNA extracted from pig-tailed macaque B-LCL to analyze Mane-A allele expression. Complete Mane-A cDNAs were generated using the 3′ RACE adapter from the First Choice RLM RACE kit (Ambion) as primer in a reverse transcription reaction. The PCR amplification was performed using Mane5UA sense primer (GATTCTCCGCAGACGCCCA), an oligonucleotide annealing in the 5′UTR of Mane-A cDNA, and the 3′ RACE outer reverse primer. The PCR reactions contained 50 mM KAc, 1.5 mM MgSO4, 10 mM Tris-HCl, pH 9.0, 0.2 mM each dATP, dTTP, dCTP, and dGTP, 20 pmol of each primer and 5 U of SuperTaq Plus DNA polymerase (Ambion). Each reaction contained 2 μl of cDNA in a final volume of 50 μl. The reactions were heated at 94°C for 5 min, and then amplification was conducted for 25 cycles as follows: denatured for 30 s at 94°C, annealed for 30 s at 63.5°C, and extended for 90 s at 72°C. A final extension was conducted for 7 min at 72°C. PCR products were gel-purified using Qiaquick gel extraction kit and then cloned into the pCR2.1 TOPO cloning vector (Invitrogen). Thirty clones were randomly chosen for miniprep, and clones containing an insert were identified by restriction analysis using EcoRI. Mane-A alleles of each clone were identified by sequencing and/or allele specific SSP-PCR.
Sequence analysis and phylogeny
Sequences were aligned using the Clustal W program of MacVector 8.1.2 software (Accelrys, San Diego, CA, USA) with minor manual adjustments. Phylogenetic trees were constructed based on the alignment using the neighbor-joining method of the same software (Saitou and Nei 1987). Genetic distances were estimated using Kimura’s two-parameter method (Kimura 1980). Bootstrap analysis was performed (1,000 replicates) to assign confidence to tree nodes (Felsenstein 1985). Values higher than 70% are shown on the tree.
GenBank accession numbers of MHC sequences
The GenBank accession numbers of sequences used in Fig. 1 are the following: Mane-E*0101 (AY204714), Mane-A*01 (AY204715), Mane-A*02 (AY204723), Mane-A*03 (AY204724), Mane-A*0302 (DQ097863), Mane-A*04 (AY204725), Mane-A*05 (AY204726), Mane-A*06 (AY204727), Mane-A*07 (AY204728), Mane-A*08 (AY204729), Mane-A*09 (AY204730), Mane-A*10 (AY557348), Mane-A*11 (AY557349), Mane-A*12 (AY557350), Mane-A*13 (AY557351), Mane-A*14 (AY557352), Mane-A*15 (AY557353), Mane-A*16 (AY557354), Mamu-E*05 (U41837), Mamu-AG*01 (U84783), Mamu-AG*02011 (U84784), Mamu-AG*03011 (U84787), Mamu-A*01 (U50836), Mamu-A*02 (U50837), Mamu-A*03 (U41379), Mamu-A*04 (U41380), Mamu-A*05 (U41831), Mamu-A*0502 (AF157394), Mamu-A*0504 (AF157396), Mamu-A*0505 (AJ551315), Mamu-A*0506 (AJ551316), Mamu-A*0507 (AJ551317), Mamu-A*0508 (AJ551318), Mamu-A*0509 (AJ551318), Mamu-A*0510 (AJ551319), Mamu-A*0511 (AJ551320), Mamu-A*06 (U41834), Mamu-A*0602 (AJ542567), Mamu-A*07 (U41832), Mamu-A*0702 (AF157397), Mamu-A*08 (AF243179), Mamu-A*11 (AF199357), Mamu-A*12 (AF157398), Mamu-A*1301 (AF157399), Mamu-A*1302 (AJ542569), Mamu-A*1303 (AF157401), Mamu-A*1304 (AY707076), Mamu-A*1305 (AJ551321), Mamu-A*1403 (AY707077), Mamu-A*1602 (AJ542572), Mamu-A*19 (AJ542573), Mamu-A*23 (AJ542575), and Mamu-A*24 (AJ542576).
The intron 2 sequences of Mane-A alleles described in Fig. 3 have been deposited in GenBank under accession numbers DQ916060–DQ916065. GenBank accession numbers for intron 2 sequence of Mamu-A*01 and Mamu-A*05 are AF161322 and AF161323, respectively. The sequence of the new Mane-A alleles described in Figs. 5 and 6 were deposited to GenBank under accession numbers EF010510–EF010521.
Results
Mane-A*06 is phylogenetically related to Mamu-A*05 alleles from rhesus macaques
To compare the MHC-A alleles of pig-tailed macaque (Mane-A) with those expressed by rhesus macaques (Mamu-A), phylogenetic analyses were performed using the sequences of 38 Mamu-A alleles and 16 Mane-A described previously (Boyson et al. 1996, 1997; Evans et al. 2000; Lafont et al. 2003, 2004; Miller et al. 1991; Smith et al. 2005; Urvater et al. 2000a; Voss and Letvin 1996; Watanabe et al. 1994). Three Mamu-AG alleles were also included because of their relationship with Mamu-A alleles (Boyson et al. 1997, 1999). One MHC-E sequence from each macaque species was used as a phylogenetic root. As shown in Fig. 1, MHC-A alleles did not segregate based on their species of origin but were distributed into two major clusters of alleles, designated A1 and A2. We have previously reported that this separation results from the presence of multiple polymorphic sites in exon 2 (Lafont et al. 2003). Each cluster contained MHC-A alleles from both species; additional sub-clusters were observed for alleles closely related to one another, in particular for alleles of the Mamu-A*05 (A5) and Mamu-A*13 (A13) families (Fig. 1). Among the 16 Mane-A alleles, two were closely related to particular Mamu-A alleles: Mane-A*04 was associated with Mamu-A*04, differing from one another by a single T to C transition at position 527 of the ORF; Mane-A*06 was found in association with the group of Mamu-A*05 alleles. This family of rhesus MHC-A alleles currently comprises 11 different members, and their sequence identity to Mane-A*06 is very high, ranging from 98.5% (Mamu-A*05 for 1,076 bp) to 100% (Mamu-A*0504 for 423 bp). By comparison, the sequence identity between Mane-A*06 and the 15 other Mane-A alleles is more limited, varying from 91.7% (Mane-A*09) to 96.3% (Mane-A*08) over a common 943 bp fragment. Interestingly, among the five nucleotide positions found to differ between Mane-A*06 and one or several Mamu-A*05 alleles, four (80%) were also polymorphic within the Mamu-A*05 family. This close identity of Mane-A*06 with Mamu-A*05 alleles suggested that the MHC-A locus expressing Mane-A*06 in pig-tailed macaques might be orthologous to the locus expressing Mamu-A*05 in rhesus macaques.
Mane-A*06 possesses an insertion in intron 2 similar to Mamu-A*05 alleles
The MHC-A locus encoding the Mamu-A*05 allele family has been reported to possess an unusual 162 bp insertion at the 3′ extremity of intron 2 (Otting et al. 2005; Urvater et al. 2000b). To analyze the potential relationship between the loci encoding Mane-A*06 in pig-tailed macaques and the Mamu-A*05 allele family in rhesus macaques, the length of intron 2 was examined for several Mane-A alleles. Allele specific primers were designed within the polymorphic regions of exons 2 and 3 of Mane-A*01, Mane-A*03, Mane-A*06, Mane-A*07, Mane-A*08 and Mane-A*10 (Fig. 2a). Site-specific PCR amplifications were carried out for each allele on genomic DNA extracted from leukocytes of pig-tailed macaques, previously identified as carriers of these alleles (Lafont et al. 2003). Whereas the PCR for Mane-A*01, Mane-A*03, Mane-A*07, Mane-A*08, and Mane-A*10 samples resulted in the amplification of a fragment ranging between 492 bp for Mane-A*10 and 549 bp for Mane-A*01, the Mane-A*06 amplification generated a significantly larger 679 bp fragment (Fig. 2b). Sequence analysis was performed on each PCR product to verify the identity of the allele and to assess the length of intron 2 (Fig. 3). Intron 2 sequences of Mane-A*01, Mane-A*03, Mane-A*08 and Mane-A*10 alleles were all 243 bp long as previously described for Mamu-A*01 and for MHC-A of human and several non-human primate species (Urvater et al. 2000b). The intron 2 of Mane-A*07 contained a 5 bp deletion resulting in a length of only 238 bp. In contrast, intron 2 of Mane-A*06 was 405 bp in length, possessing an additional 162 bp at its 3′ extremity, compared to all of the other intron 2 sequences of Mane-A alleles. The size of Mane-A*06 intron 2 was, in fact, identical to the size of intron 2 present in Mamu-A*05 and differed from that of Mamu-A*05 at only 3 nucleotide positions. Taken together, these results indicate that the locus expressing Mane-A*06 is an orthologue of the locus expressing Mamu-A*05 alleles in rhesus macaques.
The locus encoding Mane-A*06 is highly prevalent in pig-tailed macaques and is oligomorphic
We next assessed the prevalence of Mane-A*06 in a cohort of pig-tailed macaques. Site specific PCR amplifications for Mane-A*06 were performed on pig-tailed macaque genomic DNA using the primers designed from sequences present in exons 2 and 3 for this allele. Co-amplification of a constant Mane-DRB sequence was used as an internal control of amplification as shown in Fig. 4. Genomic DNA samples from 63 pig-tailed macaques were tested for the presence of Mane-A*06 (Table 1). Most of the animals (90%) were found to be positive. Sequence analysis performed on 28 (50%) of these positive samples revealed that the products were Mane-A*06 related, but sequence variations were detected in both intron and exon sequences (Table 2 and data not shown). This result firmly establishes that this pig-tailed macaque locus encodes a family of MHC-A alleles related to Mane-A*06. In a majority (69%) of the cases, the amplified product contained mixed base pairs at a few positions indicating that individual animals were carrying two different alleles (Table 1). Taken together, these results indicate that a majority of pig-tailed macaques possess a MHC-A locus encoding an oligomorphic family of alleles related to the Mamu-A*05 allele family from rhesus macaques. The failure to detect a Mane-A*06 specific product in 10% of our cohort indicates that this MHC-A locus is not always present on the pig-tailed macaque chromosome. Therefore, several different haplotypes are present within the pig-tailed macaque population, some containing this MHC-A locus and others lacking it. This suggests that, similar to rhesus monkeys (Otting et al. 2005), pig-tailed macaques possess several MHC-A haplotypes, differing from one another by the number of MHC-A loci they carry.
The locus encoding Mane-A*06/Mamu-A*05 is highly prevalent in macaques but is absent from two African primate species
A similar analysis was performed on a cohort of 80 Indian rhesus macaques to assess the frequency of the Mamu-A*05 family (Table 1). A majority (62%) of these animals tested positive using the Mane-A*06 specific SSP-PCR assay. Sequence analysis performed on 13% of the positive samples confirmed that they were Mamu-A*05 related and that a minority (23%) were derived from animals carrying two different Mamu-A*05 alleles. To investigate further the presence of this particular MHC-A locus among non-human primate monkeys, we performed Mane-A*06 SSP-PCR on genomic DNAs from cynomolgus macaques, African green monkeys (vervet), and Patas monkeys (Fig. 4). Thirteen cynomolgus macaques originating from Vietnam, China, the Philippines, Mauritius, or from unknown geographical regions were tested. A majority of these monkeys (85%) were positive, and only two animals, both of Chinese origin, tested negative by our Mane-A*06 SSP-PCR. Sequence analysis performed on all positive samples confirmed that all were closely related to the Mane-A*06 and Mamu-A*05 orthologues (Table 1). Three cynomolgus macaques (27%) appeared to possess two different alleles at this locus. In two additional animals, one cynomolgus macaque originating from the Philippines and the other obtained from Mauritius, an identical 8 bp deletion was detected in exon 3 suggesting that the cynomolgus orthologue of the Mane-A*06/Mamu-A*05 locus might be non-functional in some animals. In contrast to these results, none of the two vervet African green monkeys or four Patas monkeys were positive by our Mane-A*06 SSP-PCR. Based on this limited number of animals, the MHC-A locus encoding the Mamu-A*05 and Mane-A*06 family of alleles appears to be absent in two African non-human primate species and might only be specific to macaques. Another possibility is that an orthologue of this locus is present in these African non-human primates on some but not all haplotypes and that the animals we tested were carrying haplotypes lacking this locus. Nonetheless, our results suggest that the MHC-A locus encoding the Mamu-A*05 and Mane-A*06 family of alleles was present in the common ancestor of the pig-tailed macaques, rhesus macaques, and cynomolgus monkeys at least 5.5 million year ago.
Mane-A*06 alleles are oligomorphic in pig-tailed macaques
Sequence analysis revealed the presence of mixed base pairs in the Mane-A*06 SSP-PCR products (Table 2). This observation suggested the presence of different Mane-A*06 alleles in the pig-tailed macaque population. Mane-A*06-related alleles were cloned from several individual pig-tailed macaques. Over the complete open reading frame (ORF), only 21 positions were found to be polymorphic, 9 (43%) of which were also polymorphic among Mamu-A*05 alleles. The predicted protein sequence from Mane-A*06 alleles identified four polymorphic sites in the leader peptide, two in the alpha 1 domain, four in the alpha 2 domain, two in the alpha 3 domain, two in the trans-membrane domain, and two in the cytoplasmic tail (Fig. 5 and data not shown). One polymorphic site results in a leucine to isoleucine change at position 95, an amino acid known to be part of the F pocket of the peptide-binding site. This conservative mutation very likely has little effect on the peptide-binding characteristics of the Mane-A*06 allele family. Three additional polymorphic residues at positions 63, 167, and 171 of the mature MHC class I molecule affect amino acids that constitute the A pocket. This pocket interacts with the amino terminal residue of the peptide and could function as an anchor of the peptide as observed in the human HLA-A*26 or HLA-B*27 alleles (Griffin et al. 1997; Yamada et al. 1999). These polymorphisms could affect the peptide-binding properties and modulate the pool of peptides selected by the different Mane-A*06 alleles. However, the overall data suggest that Mane-A*06 and Mamu-A*05 alleles present overlapping peptide pools.
The Mane-A*06 alleles are expressed at low level
Finally, the expression level of Mane-A*06 alleles was analyzed by cloning full-length Mane-A transcripts from seven Mane-A*06 positive pig-tailed macaques having different MHC genotypes. For each animal, 22 to 29 cDNA clones were isolated and the alleles they carried were identified (Fig. 6). One to four different Mane-A alleles were detected in each monkey. Mane-A*01, Mane-A*03, Mane-A*10, or Mane-A*18 transcripts were readily amplified from this panel of animals and comprised 48 to 100% of the transcripts detected per animal. RNA from other alleles, such as Mane-A*0802 or Mane-A*19, represented only 14 to 24% of the transcripts, a three- to fourfold lower level of transcription compared to the first group of Mane-A alleles. By comparison, Mane-A*06 RNA transcripts were found at 10- or 20-fold lower frequency than the most abundant MHC-A allele transcripts. Mane-A*06 transcripts represented a minor fraction (4 to 9%, 6 clones among 101 clones analyzed) of Mane-A transcripts in four of the cell lines. In the three additional B-LCL, Mane-A*06 full-length transcripts were not detected among 71 clones, although Mane-A*06 transcript could be readily amplified by RT-PCR from the same B-LCL using Mane-A*06 specific primers. Taken together, these results indicate that pig-tailed macaques differentially express their Mane-A alleles and that Mane-A*06 alleles are among the least frequently transcribed.
Discussion
In this study, we have analyzed the presence of Mane-A*06 in a cohort of 63 pig-tailed macaques. We found that Mane-A*06 is a representative of a highly prevalent, oligomorphic MHC-A allele family in pig-tailed macaques that is orthologous to the Mamu-A*05 allele family present in rhesus macaques. Cynomolgus macaques from four different geographical locations also possessed an orthologue of this gene. These observations suggest that the locus encoding these oligomorphic MHC-A alleles in pig-tailed, rhesus, and cynomolgus macaques was present in their common ancestor at least 5.5 million year ago (Morales and Melnick 1998; Tosi et al. 2000, 2003). Therefore, an orthologue of this locus is likely to be found in other Asian macaque species such as the Japanese macaque (Macaca fuscata) or the lion tailed macaque (M. silenus). We failed to detect a Mane-A*06 orthologue in two African non-human primate species, namely, Patas monkeys and vervet African green monkeys. Furthermore, all MHC-A alleles described to date from two species of baboons (yellow and olive baboons) are phylogenetically related to the A1 group of MHC-A alleles, whereas the Mane-A*06 and Mamu-A*05 alleles cluster with the A2 group (Fig. 1; Lafont et al. 2003; Prilliman et al. 1996; Sidebottom et al. 2001). This suggests that baboons may also lack this specific locus. It is also possible that this locus is present on some MHC haplotype of African non-human primates but was not detected because our group of African monkeys was too small to reveal it. Further analyses on larger cohort of African non-human primates will be required to clarify this issue.
Haplotype analysis of rhesus macaques has previously shown that the MHC-A loci number can vary with two, three, or four MHC-A loci per haplotype (Otting et al. 2005). The locus encoding the oligomorphic Mamu-A*05 allele family (locus 2) was described as not always being present on the rhesus chromosome (Otting et al. 2005). In this regard, the sequencing of the rhesus MHC region of two different haplotypes has revealed that one carries a Mamu-A*05 allele (Mamu-A*0504 in association with Mamu-A*01; Kulski et al. 2004), whereas the other does not (Mamu-A*04 and Mamu-A*1403; Daza-Vamenta et al. 2004). We have found that a minority of animals in the three macaques species did not carry Mane-A*06/Mamu-A*05 alleles. It is therefore very likely that, similar to rhesus macaques, pig-tailed and cynomolgus macaques also possess different MHC haplotypes, with or without this specific MHC-A locus.
Our experiments have shown that an orthologue of this MHC-A locus was present in the genome of cynomolgus macaques. This result contrasts with three reports that used RT-PCR and reference strand conformational analysis (RSCA) to analyze the MHC class I alleles expressed by cynomolgus macaques originating from Vietnam, China, and Mauritius (Krebs et al. 2005; Wiseman et al. 2007) or on animals of unknown origin (Uda et al. 2004). Surprisingly, none of the 51 currently identified Mafa-A alleles in these studies are phylogenetically related to either Mane-A*06 or Mamu-A*05 allele families (data not shown). It is always possible that both studies were performed on animals lacking the locus encoding these allele families. However, this seems unlikely because we detected an orthologue of Mane-A*06/Mamu-A*05 in cynomolgus macaques originating from four different geographical locations including the three that were previously analyzed (Krebs et al. 2005; Wiseman et al. 2007). In particular, the locus was detected in Mauritian cynomolgus macaques, which exhibit limited genetic diversity of their mitochondrial DNA and MHC class I genes compared to cynomolgus macaques from other locations (Krebs et al. 2005; Lawler et al. 1995). A more likely explanation is that Mane-A*06 related alleles were not previously detected in cynomolgus macaques because their expression levels are quite low. In pig-tailed macaques, alleles of the Mane-A*06 family are expressed at 10- to 20-fold lower levels than other MHC-A alleles. Sequence analysis of Mane-A*06 SSP-PCR amplicons from 2 of 11 positive cynomolgus macaques also identified an 8 bp deletion within the coding sequence (exon 3), suggesting that this locus may have become a pseudogene, due to incapacitating mutations, in some cynomolgus monkeys. In rhesus macaques, the transcription levels of Mamu-A*05 alleles are currently unknown. It should be stressed, however, that since their initial identification in 1995, Mamu-A*05 alleles have not been associated with any particular epitopes, although these MHC-A alleles have been frequently detected (Boyson et al. 1996; Otting et al. 2005; Urvater et al. 2000a). For example in a study investigating Shigella-induced arthritis, 18 of 24 rhesus macaques (75%) infected with Shigella flexneri were positive for Mamu-A*05 alleles (Urvater et al. 2000a).
Our observations may also be relevant in understanding the evolution of the MHC region in macaques. On the one hand, this locus is highly prevalent in the macaque population. Its high prevalence suggests that at some point in macaque evolution, this locus was under strong selective pressure to be retained in the monkey genome. On the other hand, our results show that either the current transcription level is low (in pig-tailed macaques and perhaps also in cynomolgus monkeys) or that the gene may be not functional (in cynomolgus macaques). These data suggest that the selective pressure to maintain this locus has diminished, or even disappeared, more recently, possibly reflecting its functional substitution by other MHC loci for presenting antigens or protection against contemporary pathogens. In this regard, it should be recalled that rhesus macaques possess up to 17 functional classical MHC class I genes on a single MHC haplotype (Daza-Vamenta et al. 2004; Kulski et al. 2004). This is a much higher number than that observed in most mammalian species. Humans, for instance, possess only three classical MHC class I genes per haplotype for protection against pathogens. The advantages and disadvantages of having a large numbers of MHC class I genes per individual has been discussed previously by others (Daza-Vamenta et al. 2004). Every additional MHC class I molecule possessing a different antigen presentation capability would result in a concomitant increase in the number of epitopes presented in an individual. As a consequence, additional T cell clones would be stimulated, giving the host the capacity to respond to a larger selection of antigens and pathogens. However, this increased capacity to present antigen would also apply to self-derived antigens and would result in the elimination, by negative selection, of a larger faction of the T cell repertoire due to its autoreactive properties. These opposing effects have probably contributed to the selection of a limited number of active MHC class I loci per individual, while conserving a large MHC diversity at the population level. In this respect, the large number of functional MHC class I loci present in rhesus macaques seems particularly surprising.
It seems quite possible that the regulation of MHC class I genes at the transcription level plays a significant role in countering the potential deleterious effect of having excessive numbers of functional MHC class I alleles. In this regard, our study shows that the transcription level of different Mane-A alleles is not identical in pig-tailed macaques. Some alleles appear to dominate the pool of MHC class I transcripts (Mane-A*10 or Mane-A*03), whereas others are less represented (Mane-A*0802 or Mane-A*19) or are even marginally expressed (alleles of the Mane-A*06 family). Similar observations were previously reported for the MHC-B alleles of rhesus macaques (Daza-Vamenta et al. 2004; Otting et al. 2005). Studies in chickens have also shown that the two B loci present per haplotype are not equally expressed. One locus, B major, is transcribed at tenfold higher levels than the other, designated B minor, resulting in dominant protein production and peptide presentation by the former (Wallny et al. 2006). We currently have no information whether the differential pattern of transcription observed in our in vitro analysis occurs also in vivo in macaques and if MHC class I transcription is upregulated in a locus specific manner after immune stimulation. This could explain why the Mane-A*06 allele family has been retained in the macaque genome, even though it appears to be marginally expressed in the in vitro assays described. Further analyses will be required to elucidate the role of Mamu-A*05/Mane-A*06 alleles in the adaptive immune responses to microbial infections.
References
Adams EJ, Parham P (2001) Species-specific evolution of MHC class I genes in the higher primates. Immunol Rev 183:41–64
Allen TM, Mothe BR, Sidney J, Jing P, Dzuris JL, Liebl ME, Vogel TU, O’Connor DH, Wang X, Wussow MC, Thomson JA, Altman JD, Watkins DI, Sette A (2001) CD8(+) lymphocytes from simian immunodeficiency virus-infected rhesus macaques recognize 14 different epitopes bound by the major histocompatibility complex class I molecule mamu-A*01: implications for vaccine design and testing. J Virol 75:738–749
Beer BE, Brown CR, Whitted S, Goldstein S, Goeken R, Plishka R, Buckler-White A, Hirsch VM (2005) Immunodeficiency in the absence of high viral load in pig-tailed macaques infected with Simian immunodeficiency virus SIVsun or SIVlhoest. J Virol 79:14044–14056
Bontrop RE (2006) Comparative genetics of MHC polymorphisms in different primate species: duplications and deletions. Hum Immunol 67:388–397
Boyson JE, Shufflebotham C, Cadavid LF, Urvater JA, Knapp LA, Hughes AL, Watkins DI (1996) The MHC class I genes of the rhesus monkey. Different evolutionary histories of MHC class I and II genes in primates. J Immunol 156:4656–4665
Boyson JE, Iwanaga KK, Golos TG, Watkins DI (1997) Identification of a novel MHC class I gene, Mamu-AG, expressed in the placenta of a primate with an inactivated G locus. J Immunol 159:3311–3321
Boyson JE, Iwanaga KK, Urvater JA, Hughes AL, Golos TG, Watkins DI (1999) Evolution of a new nonclassical MHC class I locus in two Old World primate species. Immunogenetics 49:86–98
Brandon-Jones D, Eudey AA, Geissmann T, Groves CP, Melnick DJ, Morales JC, Shekelle M, Stewart C-B (2004) Asian primate classification. Int J Primatol 25:97–164
Committee on Care and Use of Laboratory Animals (1985) Guide for the care and use of laboratory animals. National Institutes of Health, Department of Health and Human Services publication no. (NIH) 85–23, Washington, DC
Daza-Vamenta R, Glusman G, Rowen L, Guthrie B, Geraghty DE (2004) Genetic divergence of the rhesus macaque major histocompatibility complex. Genome Res 14:1501–1515
Dzuris JL, Sidney J, Appella E, Chesnut RW, Watkins DI, Sette A (2000) Conserved MHC class I peptide binding motif between humans and rhesus macaques. J Immunol 164:283–291
Ennis PD, Zemmour J, Salter RD, Parham P (1990) Rapid cloning of HLA-A, B cDNA by using the polymerase chain reaction: frequency and nature of errors produced in amplification. Proc Natl Acad Sci U S A 87:2833–2837
Evans DT, Jing P, Allen TM, O’Connor DH, Horton H, Venham JE, Piekarczyk M, Dzuris J, Dykhuzen M, Mitchen J, Rudersdorf RA, Pauza CD, Sette A, Bontrop RE, DeMars R, Watkins DI (2000) Definition of five new simian immunodeficiency virus cytotoxic T-lymphocyte epitopes and their restricting major histocompatibility complex class I molecules: evidence for an influence on disease progression. J Virol 74:7400–7410
Felsenstein J (1985) Confidence limits on phylogenies: an approach using the bootstrap. Evolution 39:783–791
Fooden J (1976) Provisional classifications and key to living species of macaques (primates: Macaca). Folia Primatol (Basel) 25:225–236
Griffin TA, Yuan J, Friede T, Stevanovic S, Ariyoshi K, Rowland-Jones SL, Rammensee HG, Colbert RA (1997) Naturally occurring A pocket polymorphism in HLA-B*2703 increases the dependence on an accessory anchor residue at P1 for optimal binding of nonamer peptides. J Immunol 159:4887–4897
Hickman-Miller HD, Bardet W, Gilb A, Luis AD, Jackson KW, Watkins DI, Hildebrand WH (2005) Rhesus macaque MHC class I molecules present HLA-B-like peptides. J Immunol 175:367–375
Hirsch VM, Dapolito G, Johnson PR, Elkins WR, London WT, Montali RJ, Goldstein S, Brown C (1995) Induction of AIDS by simian immunodeficiency virus from an African green monkey: species-specific variation in pathogenicity correlates with the extent of in vivo replication. J Virol 69:955–967
Kimura M (1980) A simple method for estimating evolutionary rates of base substitutions through comparative studies of nucleotide sequences. J Mol Evol 16:111–120
Krebs KC, Jin Z, Rudersdorf R, Hughes AL, O’Connor DH (2005) Unusually high frequency MHC class I alleles in Mauritian origin cynomolgus macaques. J Immunol 175:5230–5239
Kulski JK, Anzai T, Shiina T, Inoko H (2004) Rhesus macaque class I duplicon structures, organization, and evolution within the alpha block of the major histocompatibility complex. Mol Biol Evol 21:2079–2091
Lafont BA, Buckler-White A, Plishka R, Buckler C, Martin MA (2003) Characterization of pig-tailed macaque classical MHC class I genes: implications for MHC evolution and antigen presentation in macaques. J Immunol 171:875–885
Lafont BA, Buckler-White A, Plishka R, Buckler C, Martin MA (2004) 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. Immunogenetics 56:142–154
Lawler SH, Sussman RW, Taylor LL (1995) Mitochondrial DNA of the Mauritian macaques (Macaca fascicularis): an example of the founder effect. Am J Phys Anthropol 96:133–141
Loffredo JT, Sidney J, Wojewoda C, Dodds E, Reynolds MR, Napoe G, Mothe BR, O’Connor DH, Wilson NA, Watkins DI, Sette A (2004) Identification of seventeen new simian immunodeficiency virus-derived CD8+ T cell epitopes restricted by the high frequency molecule, Mamu-A*02, and potential escape from CTL recognition. J Immunol 173:5064–5076
Loffredo JT, Sidney J, Piaskowski S, Szymanski A, Furlott J, Rudersdorf R, Reed J, Peters B, Hickman-Miller HD, Bardet W, Rehrauer WM, O’Connor DH, Wilson NA, Hildebrand WH, Sette A, Watkins DI (2005) The high frequency Indian rhesus macaque MHC class I molecule, Mamu-B*01, does not appear to be involved in CD8+ T lymphocyte responses to SIVmac239. J Immunol 175:5986–5997
Marsh SG, Albert ED, Bodmer WF, Bontrop RE, Dupont B, Erlich HA, Geraghty DE, Hansen JA, Mach B, Mayr WR, Parham P, Petersdorf EW, Sasazuki T, Schreuder GM, Strominger JL, Svejgaard A, Terasaki PI (2002) Nomenclature for factors of the HLA system. Eur J Immunogenet 29:463–515
Miller MD, Yamamoto H, Hughes AL, Watkins DI, Letvin NL (1991) Definition of an epitope and MHC class I molecule recognized by gag-specific cytotoxic T lymphocytes in SIVmac-infected rhesus monkeys. J Immunol 147:320–329
Morales JC, Melnick DJ (1998) Phylogenetic relationships of the macaques (Cercopithecidae: Macaca), as revealed by high resolution restriction site mapping of mitochondrial ribosomal genes. J Hum Evol 34:1–23
Mothe BR, Sidney J, Dzuris JL, Liebl ME, Fuenger S, Watkins DI, Sette A (2002) Characterization of the peptide-binding specificity of Mamu-B*17 and identification of Mamu-B*17-restricted epitopes derived from simian immunodeficiency virus proteins. J Immunol 169:210–219
Otting N, Heijmans CM, Noort RC, de Groot NG, Doxiadis GG, van Rood JJ, Watkins DI, Bontrop RE (2005) Unparalleled complexity of the MHC class I region in rhesus macaques. Proc Natl Acad Sci USA 102:1626–1631
Prilliman K, Lawlor D, Ellexson M, McElwee N, Confer D, Cooper DK, Kennedy RC, Hildebrand W (1996) Characterization of baboon class I major histocompatibility molecules. Implications for baboon-to-human xenotransplantation. Transplantation 61:989–996
Rabin H, Neubauer RH, Hopkins RF 3rd, Dzhikidze EK, Shevtsova ZV, Lapin BA (1977) Transforming activity and antigenicity of an Epstein-Barr-like virus from lymphoblastoid cell lines of baboons with lymphoid disease. Intervirology 8:240–249
Reimann KA, Parker RA, Seaman MS, Beaudry K, Beddall M, Peterson L, Williams KC, Veazey RS, Montefiori DC, Mascola JR, Nabel GJ, Letvin NL (2005) Pathogenicity of simian-human immunodeficiency virus SHIV-89.6P and SIVmac is attenuated in cynomolgus macaques and associated with early T-lymphocyte responses. J Virol 79:8878–8885
Saitou N, Nei M (1987) The neighbor-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol 4:406–425
Sette A, Sidney J, Bui HH, Del Guercio MF, Alexander J, Loffredo J, Watkins DI, Mothe BR (2005) Characterization of the peptide-binding specificity of Mamu-A*11 results in the identification of SIV-derived epitopes and interspecies cross-reactivity. Immunogenetics 57:53–68
Sidebottom DA, Kennedy R, Hildebrand WH (2001) Class I MHC expression in the yellow baboon. J Immunol 166:3983–3993
Sidney J, Dzuris JL, Newman MJ, Johnson RP, Kaur A, Amitinder K, Walker CM, Appella E, Mothe B, Watkins DI, Sette A (2000) Definition of the Mamu A*01 peptide binding specificity: application to the identification of wild-type and optimized ligands from simian immunodeficiency virus regulatory proteins. J Immunol 165:6387–6399
Sinha A, Datta A, Madhusudan MD, Mishra C (2005) Macaca munzala: a new species from western Arunachal Pradesh, Northeastern India. Int J Primatol 26:977–989
Smith MZ, Dale CJ, De Rose R, Stratov I, Fernandez CS, Brooks AG, Weinfurter J, Krebs K, Riek C, Watkins DI, O’Connor DH, Kent SJ (2005) Analysis of pigtail macaque major histocompatibility complex class I molecules presenting immunodominant simian immunodeficiency virus epitopes. J Virol 79:684–695
Tosi AJ, Morales JC, Melnick DJ (2000) Comparison of Y chromosome and mtDNA phylogenies leads to unique inferences of macaque evolutionary history. Mol Phylogenet Evol 17:133–144
Tosi AJ, Morales JC, Melnick DJ (2003) Paternal, maternal, and biparental molecular markers provide unique windows onto the evolutionary history of macaque monkeys. Evolution Int J Org Evolution 57:1419–1435
Uda A, Tanabayashi K, Yamada YK, Akari H, Lee YJ, Mukai R, Terao K, Yamada A (2004) Detection of 14 alleles derived from the MHC class I A locus in cynomolgus monkeys. Immunogenetics 56:155–163
Uda A, Tanabayashi K, Fujita O, Hotta A, Terao K, Yamada A (2005) Identification of the MHC class I B locus in cynomolgus monkeys. Immunogenetics 57:189–197
Urvater JA, McAdam SN, Loehrke JH, Allen TM, Moran JL, Rowell TJ, Rojo S, Lopez de Castro JA, Taurog JD, Watkins DI (2000a) A high incidence of Shigella-induced arthritis in a primate species: major histocompatibility complex class I molecules associated with resistance and susceptibility, and their relationship to HLA-B27. Immunogenetics 51:314–325
Urvater JA, Steffen SR, Rehrauer W, Watkins DI (2000b) An unusual insertion in intron 2 of apparently functional MHC class I alleles in rhesus macaques. Tissue Antigens 55:153–156
Voss G, Letvin NL (1996) Definition of human immunodeficiency virus type 1 gp120 and gp41 cytotoxic T-lymphocyte epitopes and their restricting major histocompatibility complex class I alleles in simian-human immunodeficiency virus-infected rhesus monkeys. J Virol 70:7335–7340
Wallny HJ, Avila D, Hunt LG, Powell TJ, Riegert P, Salomonsen J, Skjodt K, Vainio O, Vilbois F, Wiles MV, Kaufman J (2006) Peptide motifs of the single dominantly expressed class I molecule explain the striking MHC-determined response to Rous sarcoma virus in chickens. Proc Natl Acad Sci USA 103:1434–1439
Watanabe N, McAdam SN, Boyson JE, Piekarczyk MS, Yasutomi Y, Watkins DI, Letvin NL (1994) A simian immunodeficiency virus envelope V3 cytotoxic T-lymphocyte epitope in rhesus monkeys and its restricting major histocompatibility complex class I molecule Mamu-A*02. J Virol 68:6690–6696
Wiseman RW, Wojcechowskyj JA, Greene JM, Blasky AJ, Gopon T, Soma T, Friedrich TC, O’Connor SL, O’Connor DH (2007) Simian immunodeficiency virus SIVmac239 infection of major histocompatibility complex-identical cynomolgus macaques from Mauritius. J Virol 81:349–361
Yamada N, Ishikawa Y, Dumrese T, Tokunaga K, Juji T, Nagatani T, Miwa K, Rammensee HG, Takiguchi M (1999) Role of anchor residues in peptide binding to three HLA-A26 molecules. Tissue Antigens 54:325–332
Acknowledgements
This work was supported by the Intramural Research Program of the National Institute of Allergy and Infectious Diseases, National Institutes of Health.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Lafont, B.A.P., McGraw, C.M., Stukes, S.A. et al. The locus encoding an oligomorphic family of MHC-A alleles (Mane-A*06/Mamu-A*05) is present at high frequency in several macaque species. Immunogenetics 59, 211–223 (2007). https://doi.org/10.1007/s00251-007-0190-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00251-007-0190-1