key: cord-322575-3goj00ej authors: Karl, Julie A.; Bohn, Patrick S.; Wiseman, Roger W.; Nimityongskul, Francesca A.; Lank, Simon M.; Starrett, Gabriel J.; O’Connor, David H. title: Major Histocompatibility Complex Class I Haplotype Diversity in Chinese Rhesus Macaques date: 2013-07-01 journal: G3 (Bethesda) DOI: 10.1534/g3.113.006254 sha: doc_id: 322575 cord_uid: 3goj00ej The use of Chinese-origin rhesus macaques (Macaca mulatta) for infectious disease immunity research is increasing despite the relative lack of major histocompatibility complex (MHC) class I immunogenetics information available for this population. We determined transcript-based MHC class I haplotypes for 385 Chinese rhesus macaques from five different experimental cohorts, providing a concise representation of the full complement of MHC class I major alleles expressed by each animal. In total, 123 Mamu-A and Mamu-B haplotypes were defined in the full Chinese rhesus macaque cohort. We then performed an analysis of haplotype frequencies across the experimental cohorts of Chinese rhesus macaques, as well as a comparison against a group of 96 Indian rhesus macaques. Notably, 35 of the 51 Mamu-A and Mamu-B haplotypes observed in Indian rhesus macaques were also detected in the Chinese population, with 85% of the 385 Chinese-origin rhesus macaques expressing at least one of these class I haplotypes. This unexpected conservation of Indian rhesus macaque MHC class I haplotypes in the Chinese rhesus macaque population suggests that immunologic insights originally gleaned from studies using Indian rhesus macaques may be more applicable to Chinese rhesus macaques than previously appreciated and may provide an opportunity for studies of CD8(+) T-cell responses between populations. It may also be possible to extend these studies across multiple species of macaques, as we found evidence of shared ancestral haplotypes between Chinese rhesus and Mauritian cynomolgus macaques. Macaque monkeys are used extensively to model and understand human diseases. Historically, rhesus macaques (Macaca mulatta; Mamu) of Indian origin have been preferred for such research. However, exportation of rhesus macaques from India was halted in 1978 (Southwick and Siddiqi 1994) . As it became more difficult to obtain Indian rhesus macaques, researchers turned to other sources, including Chineseorigin rhesus macaques. Chinese rhesus macaques have been used to study infectious diseases including simian immunodeficiency virus/ human immunodeficiency virus, avian influenza, malaria, plague, and severe acute respiratory syndrome, as well as studies of xenotransplantation, stem cell therapies, reproduction, and neurobiology (Shen et al. 2007; Chen et al. 2009 Chen et al. , 2011 Chen et al. , 2012 Choi et al. 2011; Liu et al. 2011; Tian et al. 2011; Wei et al. 2011; Hutnick et al. 2012; Li et al. 2012b; Ling et al. 2013; Mumbauer et al. 2013 ). Yet comparatively little is known about the immunogenetics of these animals. The genome of a single Chinese rhesus macaque was sequenced in 2011, but whole-genome sequencing technology struggles to accurately characterize highly polymorphic, duplicated regions such as the major histocompatibility complex (MHC) loci and killer immunoglobulin receptor loci (Fang et al. 2011) . The MHC is an exceptionally polymorphic region of the genome responsible for presentation of peptides to T cells (Bontrop 2006) . Because of its pivotal role in immune response, understanding MHC genetics is essential for infectious disease research. Our group and others have shown that the repertoire of MHC class I alleles expressed by Chinese rhesus macaques is largely distinct from that observed in Indian rhesus macaques (Otting et al. 2007 (Otting et al. , 2008 Karl et al. 2008; Copyright © 2013 Karl et al. doi: 10.1534 /g3.113.006254 Manuscript received March 28, 2013 accepted for publication May 14, 2013 This is an open-access article distributed under the terms of the Creative Commons Attribution Unported License (http://creativecommons.org/licenses/ by/3.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Supporting information is available online at http://www.g3journal.org/lookup/ suppl/doi:10.1534/g3.113.006254/-/DC1. Sequence data from this article have been deposited with the EMBL/GenBank Data Libraries under accession nos. KC205288-KC205396 for novel Mamu MHC alleles. 1 Otting et al. ; Wu et al. 2008; Ma et al. 2009; Wiseman et al. 2009; Naruse et al. 2010; Doxiadis et al. 2011) . Consequently, we inferred MHC class I2restricted CD8 + T-cell responses in these two populations would be unlikely to target many of the same epitopes. Here we reconsider the relationship between MHC class I genetics of Chinese-and Indian-origin rhesus macaques by focusing on MHC class I transcript2defined haplotypes inherited together, rather than simply analyzing individual allelic variants. Most studies that currently control for the complex rhesus macaque MHC class I region only account for the presence of one or a few widely studied alleles (Mamu-A1 Ã 001, etc.), with no regard for the majority of alleles expressed by the animal. Analysis on a haplotype level as presented here provides a more global view of the MHC class I alleles transcribed by each animal, creating the potential for a greater degree of allele matching between animals within a study. To define haplotypes with high resolution, we deep sequenced complementary DNA (cDNA) amplicons spanning most of exons 224 of Mamu-A and Mamu-B genes, the most polymorphic area of MHC class I corresponding to the peptide binding region. A total of 385 Chinese-origin rhesus macaques from five different experimental cohorts were examined, as well as 96 Indian-origin rhesus macaques from two distinct sources. Unexpectedly, we discovered that 35 of 51 of the Mamu-A and Mamu-B haplotypes observed in Indian rhesus macaques also were expressed by a significant majority of Chinese rhesus macaques. Conservation of these haplotypes suggests that functional CD8 + T-cell immunity to pathogens may be more similar between Chinese-and Indian-origin rhesus macaques than previously appreciated. Whole blood and peripheral blood mononuclear cell samples from 385 Chinese rhesus macaques were obtained over the span of 5 yr from five different sources, including Battelle Biomedical Research Center, Etubics Corporation, the National Institute of Allergy and Infectious Diseases/National Institutes of Health, and Harlan Laboratories, Inc. Cohorts are detailed in Table 1 . The core set of 51 Chinese rhesus macaque samples included 45 samples from cohort ChRh #1 and six samples from cohort ChRh #4. The expanded set of 334 Chinese rhesus macaque samples included an additional 142 animals from these two cohorts, as well as 192 animals from the three other sources. It is unknown from which provinces in China the animals or their ancestors were initially obtained, or any degree of relation between the animals sampled. Whole blood samples from 96 Indian rhesus macaques were obtained from the Wisconsin National Primate Research Center (WNPRC) and New England Primate Research Center (NEPRC) breeding colonies. The WNPRC cohort was selected to be unrelated based on pedigree records whereas the NEPRC cohort was taken from active adult breeding stock. Macaques at the WNPRC were cared for according to protocols approved by the University of Wisconsin-Madison Graduate School Animal Care and Use Committee, whereas macaques housed at the NEPRC were maintained in accordance with standards of the Association for Assessment and Accreditation of Laboratory Animal Care and the Harvard Medical School Animal Care and Use Committee. RNA isolation, cDNA synthesis, and polymerase chain reaction (PCR) amplification (normalization and pooling) RNA was isolated from whole blood or peripheral blood mononuclear cell samples using the Roche MagNA Pure instrument and RNA High Performance kit (Roche, Indianapolis, IN), following manufacturer's protocols (Supporting Information, File S1). Synthesis of cDNA and PCR amplification were performed as previously described, generating either a 248-bp or 638-bp genotyping amplicon (the shorter amplicon dates back to studies performed before Roche/454 sequencing technology advanced to~500-bp read lengths) (Wiseman et al. 2009; Fernandez et al. 2011 ). The amplicons for each sample were tagged during primary PCR with a multiplex identifier sequence, a unique 10-bp tag for each sample (File S1). Amplification was confirmed by running PCR products on a Flash Gel (Lonza Group Ltd, Basel, Switzerland), and bead-based purification was performed using AMPure XP SPRI beads (Agencourt Bioscience Corporation, Beverly, MA) to remove primer dimers. Quantification of purified products was performed using the Quant-iT dsDNA HS Assay kit and a Qubit fluorometer (Invitrogen, Carlsbad, CA). Products were then normalized to 0.3 ng/mL and pooled in equal volumes. Sequencing for all amplicons was performed using Roche/454 secondgeneration methods following manufacturer's protocols for emulsion PCR and pyrosequencing (Roche, Indianapolis, IN). The core set of 51 Chinese rhesus macaques and 96 Indian rhesus macaques were sequenced in a total of five runs on a GS Junior pyrosequencing instrument. The expanded set of 334 Chinese rhesus macaques were sequenced on a combination of GS Junior and GS FLX platforms; both platforms utilize the same basic chemistry, differing only in scale of the run (a single GS Junior run is~1/8 the scale of a full GS FLX run). For the core set of 51 Chinese-origin and 96 Indian-origin rhesus macaques, sequences were analyzed by trimming all sequences from the 39 end to fixed 430-bp lengths, binning sequences into separate animal groups by parsing for the unique multiplex identifier tags, then creating uni-directional contigs of sequence reads assembled at 100% n stringency using the program Geneious Pro (BioLegend, San Diego, CA). FASTA format sequences of all contigs for each sample were then exported, and bidirectional reads were assembled at 100% stringency using CodonCode Aligner (CodonCode, Dedham, MA). Bidirectional contigs were interrogated against a curated database of known rhesus macaque MHC class I alleles using the Basic Local Alignment Search Tool (i.e., BLAST), and novel alleles were submitted to GenBank (KC205288-KC205396). Putative haplotypes were inferred by looking for combinations of shared alleles between animals (File S1). Analyses of the Mamu-A and Mamu-B regions were performed independently, since these gene clusters are separated by~1.2 million base pairs and recombination is relatively common at the population level (Daza-Vamenta et al. 2004) . Once putative haplotypes were defined, a simpler workflow was used to assign haplotype designations to the additional 334 Chinese rhesus macaque samples from the expanded set. All individual sequence reads obtained for each sample were directly compared against our rhesus macaque MHC class I allele database using BLAST-like analysis tool (i.e., BLAT) in a local instance of Galaxy (Penn State, State College, PA; Emory, Atlanta, GA), following the data analysis workflow detailed in Figure S1 . Haplotypes were assigned by identifying groups of shared major alleles from the previously defined putative haplotypes. The unparalleled complexity of the nonhuman primate MHC class I region makes it difficult to describe simply the full diversity of class I alleles expressed by an animal. Macaques may encode as many as 30 distinct MHC class I transcripts expressed at widely differing steady state levels in peripheral blood. However, combinations of distinct alleles are inherited together on a chromosome as haplotypes, making it possible to assign a simplified name (i.e., haplotype A007) to each specific combination of alleles. Here, unique haplotypes were defined on the basis of transcriptionally abundant "major" Mamu-A and Mamu-B alleles; an example of this simplification for the A007 haplotype is illustrated in Figure 1 . Our operational criterion for defining a "major" allele is that it must exceed a 4% transcript abundance relative to all class I transcripts identified per animal. We previously showed that CD8 + T-cell responses are principally restricted by highly transcribed major MHC class I alleles expressed in macaques, so we believe functionally defining haplotypes based on configurations of major alleles is appropriate for assessing conservation of MHC alleles involved in antigen presentation to CD8 + T cells (Budde et al. 2011) . To further streamline haplotype definitions, only lineage level allele names were considered (commonly referred to as two-digit resolution in human HLA genotyping, e.g., all Mamu-A1 Ã 007 allelic variants were grouped with the designation Mamu-A1 Ã 007; Figure 1 ). Alleles are named by the nonhuman primate Immuno Polymorphism Database-MHC group based on similarity to other known macaque MHC class I alleles, such that alleles sharing a common lineage level designation are identical or nearly so within the peptide binding regions. A total of 123 unique haplotypic configurations were defined in the full cohort of 385 Chinese rhesus macaques, consisting of 53 distinct Mamu-A haplotypes and 70 Mamu-B haplotypes (Table S1 ). Names were assigned to each haplotype based on the presence of what we call a "diagnostic major" allele. Mamu-A region haplotypes typically contained a single major allele, usually from the Mamu-A1 locus, so that allele was considered the "diagnostic major." A few of the Mamu-A haplotypes and most of the Mamu-B haplotypes expressed two or more major alleles; for these haplotypes, the most transcriptionally abundant allele expressed on the haplotype was typically considered the "diagnostic major" allele. Occasionally the "diagnostic major" allele was selected based on known biological significance. For instance, even though the Mamu-B Ã 017 allele was not typically the most abundant transcript, it was considered the "diagnostic major" due to its known association with spontaneous control of SIV (Yant et al. 2006) . Different versions of a base haplotype, denoted with a lowercase letter following the haplotype name (for instance, B001a and B001b), were designated to indicate differences in the complement of major transcripts accompanying a shared diagnostic allele. By this method of haplotype definition, four simple haplotype names represent the full complement of MHC class I major alleles expressed by each macaque (Table S2 ). Because the geographical source of macaques within China has been indicated as a factor in frequency of specific MHC class I alleles, we wanted to explore the differences in chromosomal haplotype frequencies between our five experimental cohorts (Li et al. 2012a; Liu et al. 2013) . After identifying the 20 most common Chinese rhesus macaque Mamu-A and Mamu-B haplotypes across the data set as a whole, we examined the differences in the frequencies for those haplotypes between the five cohorts ( Figure 2 ). Frequencies were calculated based on the total number of chromosomes examined (770 Chinese rhesus macaque chromosomes), to account for each animal expressing pairs of Mamu-A and Mamu-B haplotypes. Some haplotype frequencies, such as A019, A018a, and B056a, were relatively consistent across the cohorts; however, some frequencies varied greatly from cohort to cohort. One example is the A004 haplotype, which was observed in~18% of the total chromosomes examined for cohort ChRh #5, but only~5% for cohort ChRh #2. Overall, frequency differences between cohorts were more pronounced for the Mamu-B haplotypes, and some cohorts did not contain one or more of the 20 most common Mamu-A and Mamu-B haplotypes. This finding is not unexpected for cohort ChRh #5, because it only contained 11 macaques. The remaining cohorts each contained at least 46 macaques, minimizing the effect of sample size on observed frequencies in these cohorts. These results emphasize the point that not all research Figure 1 Simplification of MHC class I allele calls from full allele down to haplotype designation. Schematic representation of reducing the A007 haplotype observed in Chinese-origin rhesus macaques, from full allele name to major alleles to lineage designation to final haplotype call. cohorts of Chinese rhesus macaques are equal from the standpoint of MHC class I diversity, as the complement of major MHC class I alleles expressed by Chinese rhesus macaques can vary greatly between different sample groups. However, despite frequency differences, common haplotypes can still be identified across all five cohorts. We next performed MHC class I haplotype analysis on a group of 96 Indian rhesus macaques, allowing for haplotype comparison between the two geographically isolated populations. In total, 51 haplotypes were identified in the Indian rhesus macaque cohort, including 21 Mamu-A haplotypes and 30 Mamu-B haplotypes. Interestingly, only 16 haplotypes (four Mamu-A and 12 Mamu-B haplotypes) were unique to Indian rhesus macaques in this comparison (Figure 3) . These findings indicate that although the allelic variation between Chinese-and Indian-origin rhesus macaques is largely distinct (Table S3) , the two populations frequently inherit shared combinations of closely related allelic variants. Overall, 35 of the 51 MHC class I haplotypes present within Indian rhesus macaques have closely related homologs in the Chinese population. The frequencies of these 35 shared haplotypes in each population are shown in Figure 4 ; frequencies were again based on total number of chromosomes examined. Although several of these shared haplotypes were not among the most abundant in this study, there were four haplotypes (A004, A019, B001a, and B015b) observed at a chromosomal frequency of at least 3% in each population. Remarkably, 85% of the Chinese rhesus macaques in this study express at least one of the 35 shared Mamu-A or Mamu-B haplotypes (64% carry at least one of the 17 shared Mamu-A haplotypes, and 62% carry one or more of the 18 shared Mamu-B haplotypes). Likewise, 99% of the Indian rhesus macaques in this cohort express at least one haplotype shared with Chinese-origin animals ( Figure 5 ). Therefore, there is a high likelihood that these shared haplotypes were present in prior studies using Indian-origin rhesus macaques that researchers might reproduce or expand upon today using Chinese-origin rhesus macaques. MHC class I genotyping would need to be performed to confirm presence of shared haplotypes between populations for any specific studies. We also compared our 139 Chinese-and Indian-origin rhesus macaque haplotypes against the well-characterized panel of Mauritian cynomolgus macaque (Macaca fascicularis; Mafa) haplotypes to explore possible ancestral haplotype sharing between the two species (Wiseman et al. 2007; Budde et al. 2010) . Mauritian cynomolgus macaques exhibit extremely limited MHC class I diversity, as the population arose from a small group of founder cynomolgus macaques deposited on the island in the 1500s (Lawler et al. 1995) . The MHC class I diversity of Mauritian cynomolgus macaques is effectively described by five Mafa-A and seven Mafa-B haplotypes (one Mafa-A haplotype is commonly associated with three distinct Mafa-B haplotypes) (Wiseman et al. 2007; Budde et al. 2010) . Three of our Mamu-A haplotypes (A033, A060, and A063) and two of our Mamu-B haplotypes (B045a and B150) were homologous to Mauritian cynomolgus macaque haplotypes (Table S1 ). Four of these haplotypes were observed exclusively in Chinese rhesus macaques; the fifth haplotype (B045a) was detected in both Chinese-origin and Indian-origin rhesus macaques. It has previously been shown that the specific MHC class I alleles expressed by Chinese-and Indian-origin rhesus macaques are largely distinct, and those distinctions were thought to equate to an unfathomable MHC class I diversity between the two geographically divided populations (Otting et al. 2007 (Otting et al. , 2008 Karl et al. 2008; Wu et al. 2008; Ma et al. 2009; Wiseman et al. 2009; Naruse et al. 2010; Doxiadis et al. 2011) . However, our model of defining MHC class I haplotypes of coinherited highly expressed major alleles provides a novel approach for assessing putatively functional similarities between macaque populations. Most notably, more than two thirds of the haplotypes observed in Indian rhesus macaques were shared with Chinese rhesus macaques. This indicates that ancestral haplotypes were retained in both populations after the split from their most recent common ancestor~162,000 years ago, despite subsequent shrinking and expansion of the Indian and Chinese rhesus macaque populations, respectively (Hernandez et al. 2007) . Although Chinese rhesus macaques overall display a greater repertoire of MHC class I haplotypes private to the population than Indian rhesus macaques, 85% of the Chinese rhesus macaques in this study express at least one of the shared ancestral Mamu-A or Mamu-B haplotypes described here ( Figure 5 ). These homologous haplotypes may provide a valuable resource for cross-population studies of functional CD8 + T-cell immune response to pathogens. Does conservation of MHC class I haplotypes correspond to conservation of CD8 + T-cell immune responses? Though this remains to be tested at the haplotype level, a previous study demonstrated that it was possible to create Mamu-B Ã 017:03 (a Chinese rhesus macaquespecific allelic variant of the Mamu-B Ã 017 lineage) monomers and tetramers with the SIV Nef 165-173 peptide IW9 (Ouyang et al. 2009 ). This amino acid sequence was characterized as a CTL epitope restricted by Mamu-B Ã 017:01 in Indian rhesus macaques, an allele that has been associated with control of SIVmac239 viral replication (Mothe et al. 2002; Yant et al. 2006) . Mamu-B Ã 017:03 differs from Mamu-B Ã 017:01 by four amino acids, three of which occur in the peptide binding domain encoded by exons 2-3. These amino acid substitutions did not appear to alter the ability of Mamu-B Ã 017:03 to bind SIV Nef 165-173 peptide IW9 (Ouyang et al. 2009 ). If the highly similar allelic variants expressed on homologous haplotypes are also able to bind the same peptides, it is very likely those haplotypes would mount similar CD8 + T-cell responses in both Chinese-and Indianorigin rhesus macaques. To extend these observations, class I alleles of specific interest sharing a lineage designation would need to be analyzed for predicted binding preferences as well as the functional ability to present specific peptides. There is also early evidence that sharing of homologous haplotypes may be a pan-macaque phenomenon. Comparison of the rhesus macaque haplotypes identified in this study to an established panel of Mauritian cynomolgus macaque haplotypes revealed a total of five putative orthologous haplotypes, including three of the five Mafa-A haplotypes. Interestingly, the cynomolgus macaque haplotypes with putative rhesus macaque orthologs account for more than 62% and 20% of the Mafa-A and Mafa-B diversity, respectively, in Mauritian cynomolgus macaques (Budde et al. 2010) . It may therefore be possible to also explore whether rhesus and cynomolgus macaques with conserved ancestral MHC class I haplotypes mount similar CD8 + Tcell immune responses. Additional haplotype similarities are also likely to exist between rhesus macaques and cynomolgus macaques of other geographic populations, or between rhesus macaques and other macaque species, but a current lack of defined haplotypes for these other populations make comparisons difficult. Overall, this study provides the first large-scale description of MHC class I transcript-based haplotypes in rhesus macaques. It begins to explore some of the variability of haplotypes observed between independent experimental research cohorts of Chinese rhesus macaques, and provides a valuable chromosomal haplotype frequency survey for groups looking to study high-frequency Chinese rhesus macaque alleles. Importantly, it highlights the unexpected sharing of Indian rhesus macaque haplotypes with rhesus macaques from China, which may facilitate comparisons of MHC class I2mediated response to pathogens across populations. 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We also thank the staff of the W.M. Keck Center for Comparative and Functional Genomics at the University of Illinois at Urbana-Champaign for performing Roche/454 GS FLX sequencing. This work was supported by the National Institute of Allergy and Infectious Diseases (HHSN266200400088C, HHSN272201100013C), the National Center for Research Resources (P51 RR000167), and the Office of Research Infrastructure Programs (P51 OD011106) of the National Institutes of Health. This research was conducted at a facility constructed with support from the Research Facilities Improvement Program (RR15459-01, RR020141-01).