Polymorphism and conservation of the genes encoding Qa1 molecules.

To evaluate the polymorphism and conservation of the major histocompatibility complex class Ib molecule Qa1 in wild mouse populations, we determined the nucleotide sequence of exons 1-3 of Qa1 of eight mouse haplotypes derived from wild mice, including Mus musculus domesticus, M. m. castaneus, M. m. bactrianus, and M. spretus, as well as two t haplotypes. Our data identify eight new alleles of Qa1. Taken together with previously published data on Qa1 among the common laboratory inbred strains, and in agreement with cytotoxic T-lymphocyte, serological, and biochemical data, these results further confirm the existence of two families of Qa1 molecules, Qa1(a)-like and Qa1(b)-like, and illuminate the extreme conservation of the peptide-binding region of these molecules, even across species.

Good copy, bad copy: choosing animal models for HLA-linked diseases.

Recent large-scale sequencing and comparative analyses of the major histocompatibility complex (Mhc) provide a novel view of this long-studied region. The main insight is that even though Mhcs are defined by the presence of the Mhc class I and II genes, the regions encoding class I/II histocompatibility antigens are the least conserved among the species; hence the difficulty of modeling the human class I/II-linked diseases. Fortunately, the majority of the genes in the Mhc, the non-class I/II genes, are conserved among the investigated mammals. The full set of Mhc genes in their evolutionary context presents new possibilities to study Mhc-linked diseases by allowing systematic evaluation of the various experimental animals and approaches.

Active MHC class Ib genes in rat are pseudogenes in the mouse.

The most telomeric class I region of the MHC in rat and mouse is the M region, which contains about 20 class I genes or gene fragments. The central part carries three class I genes- M4, M5, and M6-which are orthologous between the two species. M4 and M6 are pseudogenes in the mouse but transcribed, intact genes in the rat. To analyze the pseudogene status for the mouse genes in more detail, we have sequenced the respective exons in multiple representative haplotypes. The stop codons are conserved in all mouse strains analyzed, and, consistent with the pseudogene status, all strains show additional insertions and deletions, taking the genes further away from functionality. Thus, M4 and M6 indeed have a split status. They are silent in the mouse but intact in the closely related rodent, the rat.

Murine MHC class Ib gene, H2-M2, encodes a conserved surface-expressed glycoprotein.

We have determined the genomic sequence of H2-M2 in seven haplotypes from nine inbred strains of mice and in five wild-derived haplotypes. Except for the spretus haplotype sp1 with a premature stop codon, we found only limited polymorphism. Four of the five amino acid substitutions in the alpha-helices are at positions that would point out from the antigen-binding groove, indicating that the polymorphism might influence receptor recognition rather than antigen binding. The rat homologue, RT1.M2(lv1), has 89% identity to H2-M2 at the nucleotide level and 91% at the amino acid level, and it also encodes an intact MHC class I glycoprotein. Chimeric proteins with alpha(1)alpha(2) or alpha(3)-transmembrane domains encoded by H2-Q9 were detectable on the surface of transfectants with monoclonal antibodies against Qa2, and the full-length M2 protein, labeled by fusion with green fluorescent protein, was detectable with S19.8 monoclonal antibodies. The H2-M2 protein was thus expressed on the cell surface, even in TAP-deficient RMA-S cells at 37 degrees C, suggesting that it is TAP-independent. We conclude that H2-M2 is a conserved mouse class Ib gene that is translated to a surface-expressed MHC class I molecule with a function still to be elucidated.

Species-specific class I gene expansions formed the telomeric 1 mb of the mouse major histocompatibility complex.

We have determined the complete sequence of 951,695 bp from the class I region of H2, the mouse major histocompatibility complex (Mhc) from strain 129/Sv (haplotype bc). The sequence contains 26 genes. The sequence spans from the last 50 kb of the H2-T region, including 2 class I genes and 3 class I pseudogenes, and includes the H2-M region up to Gabbr1. A 500-kb stretch of the H2-M region contains 9 class I genes and 4 pseudogenes, which fall into two subfamilies, M1 and M10, distinct from other mouse class I genes. This M1/M10 class I gene-cluster is separated from the centromeric H2-T and the telomeric H2-M4, -5 and -6 class I genes by "nonclass I genes". Comparison with the corresponding 853-kb region of the human Mhc, which includes the HLA-A region, shows a mosaic of conserved regions of orthologous nonclass I genes separated by regions of species-specific expansion of paralogous Mhc class I genes. The analysis of this mosaic structure illuminates the dynamic evolution of the Mhc class I region among mammals and provides evidence for the framework hypothesis.

Functional expression of murine V2R pheromone receptors involves selective association with the M10 and M1 families of MHC class Ib molecules.

The vomeronasal organ (VNO) of the mouse has two neuronal compartments expressing distinct families of pheromone receptors, the V1Rs and the V2Rs. We report here that two families of major histocompatibility complex (MHC) class Ib molecules, the M10 and the M1 families, show restricted expression in V2R-expressing neurons. Our data suggest that neurons expressing a given V2R specifically co-express one or a few members of the M10 family. Biochemical and immunocytochemical analysis demonstrates that in VNO sensory dendrites M10s belong to large multi-molecular complexes that include pheromone receptors and beta2-microglobulin (beta2m). In cultured cells, M10s appear to function as escort molecules in transport of V2Rs to the cell surface. Accordingly, beta2m-deficient mice exhibit mislocalization of V2Rs in the VNO and a specific defect in male-male aggressive behavior. The functional characterization of M10 highlights an unexpected role for MHC molecules in pheromone detection by mammalian VNO neurons.

QUOD ERAT FACIENDUM: sequence analysis of the H2-D and H2-Q regions of 129/SvJ mice.

The H2-D and -Q regions of the mouse major histocompatibility complex ( Mhc or H2) have been sequenced from strain 129/SvJ (haplotype bc), revealing a D/Q region different from all other investigated haplotypes, including the closely related b haplotype. The 300-kb class I-rich region consists of the classical class I, H2-D, and 11 non-classical class I genes. The Q region was formed by two series of tandem duplications. Comparison of the segment between the D and Q1 genes with the H2-K region provides evidence that class I genes were translocated from the K region to the D region, and gives a new explanation for the weak locus specificity of the H-Kand H2-Dalleles.

Does the rat have an H2-D orthologue next to Bat1?

Unlike all other mammalian species, which have only one class I region, rat and mouse possess a second class I region on the centromeric side of the MHC. The mouse has class Ia genes in both the centromeric H2-K and the telomeric H2-D region, whereas the rat has class Ia genes only in the centromeric RT1.A region. Bat1 is the last gene of the class III region in the mouse, and H2-D was mapped 10 kb telomeric of Bat1. To determine whether the rat possesses an H2-D orthologue, we sequenced a cosmid clone that contains rat Bat1 and an adjacent class I gene, RT1.46 (l). Homology searches suggest a transition in the rat sequence with a proximal stretch containing Nfkbil1, ATP6G, and Bat1, which is homologous to the mouse H2-D region, and a more-distal stretch, which contains the class I gene and has many similarities to mouse H2-Q region sequences. Downstream of Bat1 is a sequence stretch with great similarity to intron 3 of H2-D, which is not present in any of the rat class I genes but is found in mouse H2-K, D-, and - Q region genes. Numerous repetitive elements indicate that the region is prone to repeat-mediated rearrangements. A putative H2-D orthologue may have been present at this location and lost by genomic rearrangements, leaving the short intronic sequence behind. The class I gene RT1.46 (l) has an open reading frame, but it is unlike H2-D due to a unique 5'UTR shared with H2-Q1 and Q2, the absence of the B2 SINE repeat characteristic of H2-D/L, and the apparent lack of surface expression. We conclude that at least the LEW rat (RT1 (l)) does not possess an H2-D orthologue.