Identification of an Mhc-DPB1 allele involved in susceptibility to experimental autoimmune encephalomyelitis in rhesus macaques.

Experimental autoimmune encephalomyelitis (EAE) is an inducible autoimmune disorder that in rodents is known to be influenced by genetic background, specifically the Mhc class II region. Immunization of a group of outbred rhesus macaques with bovine high homogenate results in induction of the disease in approximately 65% of the animals. No clear association between the Mamu-DR or -DQ subregion of the rhesus macaque MHC (MhcMamu) and susceptibility or resistance to the disease has been documented. In this communication we describe a CD4+ Th cell line, isolated from an animal diagnosed with EAE, which proliferated in response to purified bovine myelin basic protein (MBP), a major constituent of the myelin sheath surrounding nerve cells. More specifically it only recognized a peptide including residues 61-82 of the molecule. Analysis of the T cell receptor (Tcr) usage of this MBP reactive T cell line showed functional transcripts for only two members of the V alpha 1 and one of each of the V beta 3 and V beta 6 families. The antigen-specific proliferative response was inhibited by a mAb reactive with MHC-DP molecules. Molecular analysis of the Mamu-DP region, in concert with allogeneic antigen presentation studies, demonstrated that the Mamu-DPB1*01 gene product functions as the restriction element for MBP peptide presentation. Retrospective analyses showed that this particular allele is frequently found in the group of EAE susceptible animals but is absent in the resistant animals (P < 0.01). As a consequence, the Mamu-DPB1*01 allele may represent one of the risk factors involved in determining susceptibility to EAE in an outbred population of rhesus macaques.

Allelic diversity at the Mhc-DP locus in rhesus macaques (Macaca mulatta).

Allelic diversity at the major histocompatibility complex class II DP locus of rhesus macaques was studied by sequencing exon 2 of Mamu-DPA1 and -DPB1 genes. The Mamu-DPA1 gene is apparently invariant, whereas the Mamu-DPB1 locus displays polymorphism. Here we report the characterization of 1 Mamu-DPA1 and 13 Mamu-DPB1 alleles which were compared with other available primate Mhc-DPA1 and -DPB1 sequences. As compared with Mhc-DRB and -DQB1, most codons for the contact residues in the antigen binding site of the primate Mhc-DPB1 gene have a relatively low degree of variation in encoding various types of amino acids. In contrast to Mhc-DRB and -DQB, the HLA- and Mamu-DPB1 sequences cluster in a species-specific manner in phylogenetic trees. Mhc-DPB1 polymorphisms, however, are inherited in a transspecies mode of evolution, as is demonstrated by the sharing of lineage members between closely related macaque species. The data demonstrate that the transspecies character of Mhc-DPB1 polymorphism was retained over much shorter periods of time as compared with its sister class II loci, Mhc-DQ and -DR.

Gel electrophoretic analysis of rhesus macaque major histocompatibility complex class II DR molecules.

Rhesus macaque MHC class II DR molecules were isolated from radiolabeled B-cell line extracts by immunoprecipitation with the mAbs 7.3.19.1 and B8.11.2 and subsequently analyzed by 2D-gel electrophoresis. The B-cell lines used for this study were obtained from monkeys that are homozygous for the Mamu-DR region as defined by serologic techniques. Some of these animals have been selectively bred and originate from consanguineous matings. These analyses show that monkeys with the same allotyping may express different types of DR molecules. As in humans, the number of DR molecules expressed per haplotype is not constant and varies from 1 to 3, depending on the serologically defined Mamu-DR specificity, whereas it has been shown that the number of Mamu-DRB genes present per haplotype varies from 2 to 6. Therefore the present study also demonstrates that some of the rhesus macaque DR regions contain one or more pseudogenes.

Expansion and contraction of rhesus macaque DRB regions by duplication and deletion.

Previous sequence analysis of the rhesus macaque MHC (MhcMamu) class II DRB region has allowed the detection of at least 34 alleles belonging to different lineages. In this communication, 36 new Mamu-DRB alleles are reported. The gene content of the DRB region has been determined for several homozygous animals of consanguineous origin. As in other primates, the number of DRB genes present per haplotype is not constant, varying from two to six genes in rhesus macaques. Six major groups of DRB haplotypes have been defined in our rhesus macaque colony. Two haplotype groups were found to carry, as well as other Mamu-DRB genes, two genes that cluster into distinct HLA-DRB1 lineages. In one of these two groups, a haplotype harbors another two sets of DRB alleles that belong to the Mhc-DRB6 and -DRB*W6 lineages, respectively. Such a haplotype was probably generated by duplication, and our data suggest that after this particular expansion of the DR region, one of the duplicated Mamu-DRB6 alleles was the target of an Alu insertion. Although certain transspecies allelic lineages are evolutionarily stable, and have been conserved for at least 36 million years, the rhesus macaque class II haplotypes differ significantly from those found in humans, chimpanzees, and gorillas. Mhc-DRB regions are therefore comparatively unstable over longer evolutionary time spans, with regard to both the number of genes and the gene content, and must have been subjected to expansion and contraction.

The biologic importance of conserved major histocompatibility complex class II motifs in primates.

Phylogenetic comparisons of polymorphic second-exon sequences of MHC class II DRB genes showed that equivalents of the HLA-DRB1*03 alleles are present in various nonhuman primate species such as chimpanzees, gorillas, and rhesus macaques. These alleles must root from ancestral structure(s) that were once present in a progenitor species that lived about 35 million years ago. Due to accumulation of genetic variation, however, sequences that cluster into a lineage are generally unique to a species. To investigate the biologic importance of such conservation and variation, the peptide-binding capacity of various Mhc-DRB1*03 lineage members was studied. Primate Mhc-DRB1*03 lineage members successfully binding the p3-13 peptide of the 65-kD heat-shock protein of Mycobacterium tuberculosis/leprae share a motif that maps to the floor of the peptide-binding site. Apart from that, some rhesus macaque MHC class-II-positive cells were able to present the p3-13 peptide to HLA-DR17-restricted T cells whereas cells obtained from great ape species failed to do so. Therefore, these studies open ways to understand which MHC polymorphisms have been maintained in evolution and which MHC residues are essential for peptide binding and T-cell recognition.

Evolutionary conservation of major histocompatibility complex-DR/peptide/T cell interactions in primates.

Many major histocompatibility complex (MHC) polymorphisms originate from ancient structures that predate speciation. As a consequence, members of the Mhc-DRB1*03 allelic lineage are not only present in humans but in chimpanzees and rhesus macaques as well. This emphasizes that Mhc-DRB1*03 members must have been present in a common ancestor of these primate species that lived about 30 million years ago. Due to the accumulation of genetic variation, however, alleles of the Mhc-DRB1*03 lineage exhibit species-unique sequences. To investigate the biological importance of such conservation and variation, we have studied both the binding and antigen presentation capacity of various trans-species Mhc-DRB1*03 lineage members. Here we show that p3-13 of the 65-kD heat-shock protein (hsp65) of Mycobacterium leprae and M. tuberculosis binds not only to HLA-DR17(3) but also to some chimpanzee and rhesus macaque class II-positive cells. Comparison of the corresponding human, chimpanzee, and rhesus macaque Mhc-DRB1*03 lineage members revealed the presence of uniquely shared amino acid residues, at positions 9-13 and 26-31, of the antigen-binding site that are critical for p3-13 binding. In addition it is shown that several nonhuman primate antigen-presenting cells that bind p3-13 can activate HLA-DR17-restricted T cells. Certain amino acid replacements, however, in Mhc-DRB1*03 lineage members did not influence peptide binding or T cell recognition. Therefore, these studies demonstrate that some polymorphic amino acid residues (motifs) within the antigen-binding site of MHC class II molecules that are crucial for peptide binding and recognition by the T cell receptor have been conserved for over 30 million years.

Major histocompatibility complex class II DQ diversity in rhesus macaques.

By the use of restriction fragment length polymorphism analysis 10 Taq I fragments could be identified for the MhcMamu-DQA1 region. A strong correlation exists between the occurrence of Mamu-DQA1/Taq I fragments and Mamu-DQA1 allelic sequence variation. Most restriction fragments correspond with a unique Mamu-DQA1 allele, with one exception being the Taq I 4.5 kb fragment that is associated with two Mamu-DQA1 alleles. The RFLP technique allowed the identification of 15 Mamu-DQB1/Taq I restriction fragments, whereas sequence analysis has permitted the characterization of at least 20 different Mamu-DQB1 alleles. In this communication two unpublished Mamu-DQB1 sequences are described. For Mamu-DQB1, on only four occasions was it possible to demonstrate a correlation between a certain fragment and an allelic sequence. These analyses, performed on material from truly homozygous animals, allowed us to define which combinations of Mamu-DQA1 and -DQB1 molecules form heterodimers at the cell surface. In addition, these studies are helpful in typing non-human primate species that are used in biomedical research.

Evolutionary stability of transspecies major histocompatibility complex class II DRB lineages in humans and rhesus monkeys.

Sequence analysis of rhesus monkey (Macaca mulatta) polymorphic second exon of major histocompatibility complex class II DRB subregion genes demonstrates the existence of at least 34 alleles. Some of these rhesus monkey alleles are very similar (or nearly identical) to HLA-DRB alleles. These data demonstrate that members of the lineages for Mhc-DRB1*03, -DRB1*04, -DRB1*10, and the loci of Mhc-DRB3, -DRB4, -DRB5, and -DRB6 predate speciation of man and rhesus monkey and were already present 25 million years ago. Calculation of evolutionary rates suggests that the various allele lineages have differential stabilities. Furthermore, the data indicate that distinct species may not have inherited or lost transspecies Mhc-DRB lineages in evolution, because several allele lineages in rhesus monkeys appear to be absent in humans and vice versa.

RFLP analysis of the rhesus monkey MHC class II DR subregion.

Restriction fragment length polymorphism (RFLP) analysis was performed on a panel of 39 serologically typed DR homozygous monkeys. DNA was digested with the restriction enzyme TaqI and hybridizations were carried out with a human leukocyte antigen (HLA)-DR beta 3'UT-specific probe. In addition a panel of 18 monkeys was analyzed comprising experimental autoimmune encephalomyelitis (EAE) susceptible and nonsusceptible animals. The number of DRB/TaqI fragments detected for the various DR specificities varied from two to six, suggesting that the number of DRB genes per haplotype is not constant. RFLP typing allows that most serologically defined DR specificities can be subdivided. This knowledge was applied to define the DR specificities of the animals used for EAE experiments.

Two alleles detected for HLA-DZ alpha on the basis of a polymorphic restriction site in the third exon.

The restriction enzyme ApaI has been used to define Restriction Fragment Length Polymorphism (RFLP) within the DZ alpha gene. Digestion of genomic DNA of 96 individuals with ApaI reveals the existence of two different patterns. Both homozygous and heterozygous individuals were detected. Hardy-Weinberg analysis indicates that DZ alpha is part of a di-allelic system with allele frequencies of 50%. DZ alpha polymorphism in the population studied does not correlate with serologically determined class I and HLA-DR, DQ and cellular DP typing data. A limited family study demonstrates that DZ alpha polymorphism segregates with HLA-class II phenotypes.