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.Experiments carried out in this work complied with current Colombian Ministry of Health law and regulations governing animal care and handling.An erratum to this article can be found at     

Comparative molecular and three-dimensional analysis of the peptide–MHC II binding region in both human and Aotus MHC-DRB molecules confirms their usefulness in antimalarial vaccine development

A vaccine against malaria is desperately needed, and Aotus monkeys are highly susceptible to experimental infection with malarial parasites. A thorough analysis of this monkey’s immune system molecules was thus undertaken in our institute. Cloning and sequencing, followed by three-dimensional analysis, has revealed high homology with some HLA-DRB1 molecules in terms of their peptide binding region pockets. Molecules such as HLA-DRB1*03, 11, 08, and HLA-DRB1*04 are so similar to Aotus MHC-DRB molecules that peptides identified as binding to these molecules and inducing protective immunity in these monkeys could be used in humans without further refinement, while small modifications seem to be needed for those binding to HLA-DRB1*07, HLA-DRB1*15, 16, and HLA-DRB1*10-like molecules, making this New World monkey an excellent model for tailor-made vaccine development, especially against malaria.     

Sequence and diversity of DRB genes of Aotus nancymaae, a primate model for human malaria parasites

 The New World primate Aotus nancymaae is susceptible to infection with the human malaria parasite Plasmodium falciparum and Plasmodium vivax and has therefore been recommended by the World Health Organization as a model for evaluation of malaria vaccine candidates. We present here a first step in the molecular characterization of the major histocompatibility complex (MHC) class II DRB genes of Aotus nancymaae (owl monkey or night monkey) by nucleotide sequence analysis of the polymorphic exon 2 segments. In a group of 15 nonrelated animals captivated in the wild, 34 MHC DRB alleles could be identified. Six allelic lineages were detected, two of them having human counterparts, while two other lineages have not been described in any other New World monkey species studied. As in the common marmoset, the diversity of DRB alleles appears to have arisen largely by point mutations in the β-pleated sheets and by frequent exchange of fixed sequence motifs in the α-helical portion. Pairs of alleles differing only at amino acid position b86 by an exchange of valine to glycine are present in Aotus, as in humans. Essential amino acid residues contributing to MHC DR peptide binding pockets number 1 and 4 are conserved or semiconserved between HLA-DR and Aona-DRB molecules, indicating a capacity to bind similar peptide repertoires. These results support fully our using Aotus monkeys as an animal model for evaluation of future subunit vaccine candidates. Received: 10 August 1999 / Revised: 11 October 1999     

MHC class I genes in the owl monkey: mosaic organisation, convergence and loci diversity

The MHC class I molecule plays an important role in immune response, pathogen recognition and response against vaccines and self- versus non-self-recognition. Studying MHC class I characteristics thus became a priority when dealing with Aotus to ensure its use as an animal model for biomedical research. Isolation, cloning and sequencing of exons 1–8 from 27 MHC class I alleles obtained from 13 individuals classified as belonging to three owl monkey species (A. nancymaae, A. nigriceps and A. vociferans) were carried out to establish similarities between Aotus MHC class I genes and those expressed by other New and Old World primates. Six Aotus MHC class I sequence groups (Ao-g1, Ao-g2, Ao-g3, Ao-g4, Ao-g5 and Ao-g6) weakly related to non-classical Catarrhini MHC were identified. An allelic lineage was also identified in one A. nancymaae and two A. vociferans monkeys, exhibiting a high degree of conservation, negative selection along the molecule and premature termination of the open reading frame at exon 5 (Ao-g5). These sequences high conservation suggests that they more likely correspond to a soluble form of Aotus MHC class I molecules than to a new group of processed pseudogenes. Another group, named Ao-g6, exhibited a strong relationship with Catarrhinis classical MHC-B-C loci. Sequence evolution and variability analysis indicated that Aotus MHC class I molecules experience inter-locus gene conversion phenomena, contributing towards their high variability.     

The T-cell receptor in primates: identifying and sequencing new owl monkey TRBV gene sub-groups

The New World primate Aotus nancymaae (owl monkey) has been shown to be an excellent experimental model when studying malarial parasites. Characterising the T-cell receptor (TR) repertoire by means of the different variable beta (TRBV) genes displayed contributes to a better understanding of these lymphocytes role in the response against several malarial antigens. This study describes identifying and characterising eleven new TRBV gene sub-groups in cDNA from Aotus nancymaaes peripheral blood lymphocytes; these 11 gene sequences displayed homology to the previously reported human TRBV3, TRBV10, TRBV11, TRBV14, TRBV18, TRBV19, TRBV20, TRBV25, TRBV27, TRBV29 and TRBV30 sub-groups, resulting in 83% overall homology at the amino acid level. An additional Aotus sequence was found having similarity with the human TRBJ-2–7*01 gene. Evolutionary relationships amongst these sequences and the homologous genes from both New and Old World primates have shown that the TRBV repertoire has been maintained in the species being studied, displaying varying association patterns and substitution rates, depending on the sub-group being studied. The degree of identity observed when comparing human and Aotus genes suggests that these species might have a similar TRBV repertoire.     

Owl monkeys (Aotus) are highly divergent in mitochondrial Cytochromec Oxidase (COII) sequences

The evolutionary history and differentiation of the owl or night monkeys (Aotus),remain poorly resolved. Variation in pelage and skeletal morphology is relatively minor across their broad range, but cytogenetic studies have revealed that at least 12 karyotypically distinct forms exist, with 2Nchromosome numbers ranging from 46 to 58. We obtained DNA samples from three putative species- A. lemurinus, A. nancymae,and A. azarae-and five karyotypes (I, II, III, IV and VI), amplified the mitochondrial cytochrome coxidase subunit II gene (COII) via PCR and sequenced it. Comparisons of the sequences indicate relatively high levels of sequence divergence among the putative species (4.3 to 6.3%), and suggest that the taxa are genetically quite distinct and have likely experienced extended periods of isolated evolution. The levels of COII divergence represent approximately one- third of the levels found between divergent platyrrhine genera, such as Aotus, Saimiriand Callimico.Using estimates of substitution rates of COII evolution in hominoid primates,the estimated date of divergence for the AotusCOII sequences is 3.6 million years. The AotusCOII data support the existence of multiple species of Aotus,with origins predating late Pleistocene climatic events. Although A. nancymaeand A. azaraeboth live south of the Amazon River and have been considered members of the same species group, phylogenetic analysis of the COII sequences does not support a close relationship between them.     

Sequence and diversity of T-cell receptor alpha V, J, and C genes of the owl monkey Aotus nancymaae

 We cloned and sequenced TcR alpha chain cDNA of three healthy Aotus nancymaae monkeys. Fifteen different TRAJ segments and 9 different TRAV genes were identified in the 29 rearrangements analyzed. As expected from the greater phylogenetic distance, A. nancymaae TRA gene sequences diverged more from the human sequences than those of the chimpanzee or the rhesus macaque. However, no Aotus TRAJ segment or TRAV gene was found which lacked a human counterpart. These counterparts were AJ02, AJ05, AJ09, AJ15, AJ22, AJ23, AJ28, AJ30, AJ32, AJ34, AJ37, AJ40, AJ42, AJ45, AJ52 and AV2S1, AV2S3, AV3S1, AV8S1, AV12S1, AV15S1, ADV21S1/DV5, AV22S1S and AV23S1, respectively. In most cases the identity of amino acid sequences between corresponding Aotus and human genes was greater than 80%. This marked conservation of TRA gene sequences indicates a close structural relationship of Aotus and human TcR and demonstrates that the TcR repertoire in primates is remarkably stable. The results support the concept of using Aotus monkeys, which are susceptible to infection with the human malaria parasite Plasmodium falciparum, as an animal model for the evaluation of molecularly defined malaria vaccine candidates. Received: 15 January 1998 / Revised: 23 March 1998     

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.     

Molecular Phylogenetics of <Emphasis Type="Italic">Aotus</Emphasis> (Platyrrhini,Cebidae)

The accurate identification of taxa of Aotus is essential for 1) the development of precise biomedical assays, 2) the determination of potential illegal traffic of this genus, and 3) conservation. Although many studies have contributed to what we know about the phylogenetics of Aotus, none used a sufficiently large number of samples to clarify its complexity. To address this need, we sequenced 696 base pairs of the mitochondrial cytochrome-oxidase II gene (mtCOII) in 69 specimens of 7 taxa of Aotus. We also analyzed 8 microsatellite loci in 136 individuals of 6 taxa. In contrast to previous studies, we sampled only wild individuals and have a precise geographical origin for each one. The mtDNA results showed that: 1) the northern gray-necked group of Aotus is genetically more homogeneous than the polyphyletic red-necked group of Aotus; 2) the ancestors of Aotus vociferans seem to be the original species candidate for the current Aotus; 3) Aotus azarae azarae and A. a. boliviensis are the most differentiated taxa, likely a result of extreme genetic drift during stasipatric speciation; 4) the first genetic splits found among taxa of Aotus occurred during the Pliocene (or even Miocene) while the most recent ones happened during the Pleistocene, when forest refugia may have played an important role in speciation. The mean number of microsatellite alleles was 3–5.33 alleles per locus. We found some private alleles that could be useful in helping to identify illegal trade, although a larger sample size is needed to ensure that these alleles are really private to the relevant taxa. These new findings increase our understanding of the phylogeny of Aotus and the level of genetic diversity within different taxa of Aotus.     

Three reciprocally monophyletic mtDNA lineages elucidate the taxonomic status of Grant’s gazelles

The intraspecific phylogeography of Grant’s gazelles Nanger granti was assessed with mitochondrial DNA control region sequences. Samples of 177 individuals from 17 Kenyan and Tanzanian populations were analysed. Three highly divergent, reciprocally monophyletic lineages were found, with among group net nucleotide distances of 8–12%. The three lineages—notata, granti and petersii—grouped populations according to their geographic origin, encompassing populations in the north, southwest, and east, respectively. The mtDNA lineages reflected distinct evolutionary trajectories, and the data are discussed in reference to the four currently recognised subspecies. We suggest Grant’s gazelles be raised to the superspecies Nanger (granti) comprising three taxonomic units corresponding to the three mtDNA lineages. There was no evidence of gene flow between the notata and granti lineages, despite their geographic proximity, suggesting reproductive isolation. These constitute evolutionary significant units within the adaptive evolutionary framework. Due to its restricted geographic distribution and genetic and morphological distinctiveness, we suggest the petersii lineage be raised to the species Nanger (granti) petersii within the Grant’s gazelles superspecies.     

Sharing of sleeping sites betweenAotus vociferans with other mammals in the Peruvian Amazon

In studies performed during 1986, 1987, 1990, and 1991, in the seasonally flooded forest of the Napo and Nanay river basin, we recorded seven instances of cohabitation in night monkeys,Aotus vociferans. Cohabitation refers to the sharing of a sleeping site of one species of animal with other different species of animals (Aquino & Encarnacion, 1986). We also recorded two instances of cooccupation of night monkeys with other species of nocturnal mammals. Cooccupation refers to the independent use of different sleeping sites within the same tree by two or more species of animals. This study is the first report of cooccupation within the generaAotus. Forty-five sleeping trees with entrance holes were used by the night monkeys. In addition, one sleeping site was observed in a small concavity of the foliar sheath on aMauritia flexuosa palm.     

Identification,classification and evolution of Owl Monkeys (<Emphasis Type="Italic">Aotus</Emphasis>, Illiger 1811)

Background  

Owl monkeys, belonging to the genus Aotus, have been extensively used as animal models in biomedical research but few reports have focused on the taxonomy and phylogeography of this genus. Moreover, the morphological similarity of several Aotus species has led to frequent misidentifications, mainly at the boundaries of their distribution. In this study, sequence data from five mitochondrial regions and the nuclear, Y-linked, SRY gene were used for species identification and phylogenetic reconstructions using well characterized specimens of Aotus nancymaae, A. vociferans, A. lemurinus, A. griseimembra, A. trivirgatus, A. nigriceps, A. azarae boliviensis and A. infulatus.     

Plasmodium vivax under the microscope: the Aotus model

The Aotus model for vivax malaria is extremely useful both as a source of living parasites in non-endemic areas, and as a model for vaccine and drug development research. Several species of New World primates can be infected with numerous different strains of Plasmodium vivax. This article reviews some aspects of the Aotus model, discusses the frequently observed hematological changes that can confound interpretation of hemogram data during the course of vivax infection, and provides a partial atlas of parasite forms and Aotus nancymai blood cells.     

A primate survey in northern Bolivia,with special reference to Goeldi’s monkey,Callimico goeldii

We conducted a 5-month survey on primates, with special attention to Goeldi’s monkey (Callimico goeldii),in the rainforest of northwestern Bolivia. Goeldi’s monkey is one of the least documented of all South American primates, and very little is known about its distribution. We report observations on distribution, abundance, and habitat of Callimico goeldiiand other primates, incidental sightings of other mammals, and preliminary behavioral observations on Callimicoand on two associated callitrichid monkey species: Saguinus fuscicollisand S. labiatus.We found a locality that appears to be particularly suitable for detailed field observations on Callimico on the north bank of the lower Río Tahuamanu. The fieldwork was carried out by A.C.; the analysis of the vocalizations, by T. G.     

Two new karyotypes in the Peruvian owl monkey (Aotus trivirgatus)

The observation of remarkable karyotypic variation in owl monkeys (Aotus trivirgatus) stimulated us to study the chromosomal evolution of this New World genus. As an extension of this project, we examined the chromosome complement of a “phenotype-B” Aotus population from Peru. In addition to karyotype V(2n = 46), two new karyotypes with diploid numbers of 47 and 48 were identified. A G-band comparison of these karyotypes indicated that the chromosome number polymorphism in these Peruvian owl monkeys resulted from a single fusion or fission event involving a single metacentric and two acrocentric chromosome pairs. This mechanism is also known to be responsible for the chromosome number polymorphism in at least two other populations of phenotype B Aotus, one from Colombia and the other from Panama.     

Primate numts and reticulate evolution of capped and golden leaf monkeys (Primates: Colobinae)

A recent phylogenetic study of langurs and leaf monkeys of South Asia suggested a reticulate evolution of capped and golden leaf monkeys through ancient hybridization between Semnopithecus and Trachypithecus. To test this hybridization scenario, I analysed nuclear copies of the mitochondrial cytochrome b gene (numts) from capped, golden and Phayre’s leaf monkeys. These numts were aligned with mitochondrial cytochrome b sequences of various species belonging to the genera Semnopithecus and Trachypithecus. In the phylogenetic tree derived from this alignment, the numts fell into three distinct clades (A, B and C) suggesting three independent integration events. Clade A was basal to Semnopithecus, and clades B and C were basal to Trachypithecus. Among the numts in clades A and C were sequences derived from species not represented in their respective sister mitochondrial groups. This unusual placement of certain numts is taken as additional support for the hybridization scenario. Based on the molecular dating of these integration events, hybridization is estimated to have occurred around 7.1 to 3.4 million years ago. Capped and golden leaf monkeys might have to be assigned to a new genus to reconcile their unique evolutionary history. Additionally, northeast India appears to be a ‘hot spot’ for lineages that might have evolved through reticulate evolution.     

Residue 3 of β2-microglobulin affects binding of class I MHC molecules by the W6/32 antibody

 Previous studies of class I MHC molecules have shown that the owl monkey (Aotus) possesses at least two variants of the β₂-microglobulin (β₂m) protein. These two variants have different isoelectric points, and exhibit differential reactivity with the monoclonal antibody W6/32. We report cDNA sequences of the B2m gene, from W6/32-positive and W6/32-negative Aotus cell lines. The two β₂m variants we identified exhibit a single amino acid difference at position three. An arginine residue at position 3 was correlated with W6/32 reactivity, whereas histidine was associated with non-reactivity. W6/32 reactivity was conferred to a W6/32-negative Aotus cell line when it was transfected with the B2m from the W6/32-positive cell line. Residue 3 of β₂m is located at the surface of the class I molecule. It is also close to position 121 of the MHC class I heavy chain, which has previously been shown to influence W6/32 antibody binding. We conclude that W6/32 binds a compact epitope on the class I molecule that includes both residue 3 of β₂m and residue 121 of the heavy chain. We examined the distribution of the two β₂m motifs in a sample Aotus population using an allele-specific polymerase chain reaction assay. The pattern of β₂m segregation we observed matches that which was defined previously by serology. Additionally, we identified laboratory-born hybrid animals who possess both variants of β₂m. Received: 1 April 1998 / Received: 3 July 1998     

Evolutionary relationships of membrers of the generaTaphrina, Protomyces, Schizosaccharomyces, and related taxa within the archiascomycetes: Integrated analysis of genotypic and phenotypic characters

To study the phylogeny and evolution of archiascomycetes, we determined the full sequence of the nuclear 18S rRNA gene from 14Taphrina species and 2Protomyces species, and the partial sequence ofSchizosaccharomyces japonicus var.japonicus. The sequences were phylogenetically analyzed by the neighbor-joining, maximum parsimony, and maximum-likelihood methods. We also looked at their principal phenotypic characters and genotypic character. Relationships within the Ascomycota are concordant with the previously published phylogenies inferred from 18S rDNA sequence divergence and divide the archi-, hemi-and euascomycetes into distinct major lineages. All the trees show that, within the archiascomycete lineage, 11 of the 14Taphrina species and the 2Protomyces species are monophyletic. A core groups ofTaphrina andProtomyces is always monophyletic. The evidence from molecular and phenotypic characters such as cell wall sugar composition, ubiquinone, cell wall ultrastructure, and mode of conidium ontogeny, strongly suggests that ‘T’. californica CBS 374.39, ‘T’. maculans CBS 427.69 and ‘T’. farlowii CBS 376.39 should be excluded from the archiascomycete lineage. ‘Taphrina’ farlowii CBS 376.39 groups withCandida albicans in the Saccharomycetales, whereas ‘T’. californica CBS 374.39 and ‘T’. maculans CBS 427.69 have a basidiomycete affinity and group with Tremellalean members in the hymenomycete lineage.Schizosaccharomyces is monophyletic. The strictly anamorphic yeastSaitoella complicata groups with the apothecial ascomyceteNeolecta vitellina rather than theTaphrina/Protomyces branch.