BAC/YAC contigs from the H2-M region of mouse Chr 17 define gene order as Znf173-Tctex5-Mog-D17Tu42-M3-M2

 A yeast artificial chromosome (YAC) contig from the C57BL/6 (H2 ^b ) mouse was created from the major histocompatibility complex (Mhc, H2 in mouse) class Ib subregion, H2-M. It spans approximately 1.2 megabase (Mb) pairs and unites the previous >1.5-Mb YAC contigs (Jones et al. 1995) into a single contig, which includes 21 Mhc class I genes distal to H2-T1. A bacterial artificial chromosome (BAC) contig from the 129 (H2 ^bc ) mouse, spanning approximately 600 kilobases, was also built from Znf173 (Afp, a gene for acid finger protein), through Tctex5 (t-complex testis expressed-5) and Mog (myelin oligodendrocyte glycoprotein), to H2-M2. Twenty-four sequence-tagged site (STS) markers were newly developed, and 35 markers were mapped in the YAC/BAC contigs, which define the marker order as Cen –Znf173–Tctex5 – Mog–D17Tu42–D17Mit232–H2-M3–D17Leh525–H2-M2– Tel. The gene order of Znf173 – Tctex5 – Mog – D17Tu42 is conserved between mouse and human, showing that the middle H2-M region corresponds to the subregion of the human Mhc surrounding HLA-A. Received: 25 July 1997 / Revised: 10 September 1997     

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.GenBank accession numbers: AF057065 to AF057072 (exon 3 of H2-M4 of reported mouse strains), AF057976 to AF057985 (exon 3 of RT1.M4 of reported rat strains), AF058923 and AF058924 (exon 2 of RT1.M4 of strains PVG and BN), AY286080 to AY286092 (exon 4 of H2-M6 of reported mouse stains), and AY303772 (full-length genomic sequence of RT1.M6-1^l)     

H2-M polymorphism in mice susceptible to collagen-induced arthritis involves the peptide binding groove

 The ability to develop type II collagen (CII)-induced arthritis (CIA) in mice is associated with the major histocompatibility I-A gene and with as yet poorly defined regulatory molecules of the major histocompatibility complex (MHC) class II antigen processing and presentation pathway. H2-M molecules are thought to be involved in the loading of antigenic peptides into the MHC class II binding cleft. We sequenced H2-Ma, H2-Mb1, and H2-Mb2 genes from CIA-susceptible and -resistant mouse strains and identified four different Ma and Mb2 alleles and three different Mb1 alleles defined by polymorphic residues within the predicted peptide binding groove. Most CIA-resistant mouse strains share common Ma, Mb1, and Mb2 alleles. In contrast, H2-M alleles designated Ma-III, Ma-IV, Mb1-III, and Mb2-IV could be exclusively identified in the CIA-susceptible H2 ^r and H2 ^q haplotypes, suggesting that allelic H2-M molecules may modulate the composition of different CII peptides loaded onto MHC class II molecules, presumably presenting “arthritogenic” epitopes to T lymphocytes. Received: 8 December 1995 / Revised: 16 January 1996     

Murine MHC class Ib gene,<Emphasis Type="Italic"> H2-M2,</Emphasis> 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 -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 ₁₂ or 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 °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.The nucleotide sequences reported in this paper have been submitted to GenBank with the accession numbers AY302188–AY302217 for all H2-M2 sequences and AY302218 for RT1.M2, AY326271 for RT1.M2-2, and AY327254 for the RT1.M2 microsatellite marker     

Genomic organization of a mouse MHC class II region including theH2-M andLmp2 loci

The region encompassing theMa, Mb1, Mb2, andLmp2 genes of the mouse class II major histocompatibility complex (MHC) was sequenced. Since this region contains clusters of genes required for efficient class I and class II antigen presentation, it was interesting to search for putative additional genes in the 21 kilobase gap between theMb1 andLmp2 genes. Computer predictions of coding regions and CpG islands, exon trapping experiments, and cross-species comparison with the corresponding human sequence indicate that no additional functional gene is present in that stretch. However, computer analysis revealed the possible existence of an alternative 3 exon forMb1. Except for the fact that the mouse MHC contains twoMb genes, the genomic organization of theH2-M loci was found to be almost identical to the organization of the humanHLA-DM genes. The promoter regions of theMa andMb genes also resemble classical class II promoters, containing typical S, X, and Y boxes. Like the human genes, the threeH2-M genes displayed very limited polymorphism when we compared the cDNA sequences from six haplotypes. Finally, comparison ofDMB withMb1 andMb2, both at the genomic level and in their coding regions, suggests that theMb gene was recently duplicated, probably only in certain rodents.     

On naming H2 haplotypes: functional significance of MHC class Ib alleles

George D. Snell began defining and naming the H2 haplotypes many years ago by histogenetic typing. Since then, a few haplotypes have been given an additional letter, such as bc for strain 129, to show that they are minor variants from the prototype (b). But by and large, differences in nonclassical class I antigens have been known (only?) to those in the field without being acknowledged by a separate haplotype symbol. Thus, strains BALB/c and NZB/BlNJ are both considered H2 ^d and strains C3H/HeJ and B10.BR are both called H2 ^k, although each pair differs in the TL and Qa1 antigens. In parallel with the interest in nonclassical class I antigens, the need for an appropriate haplotype nomenclature is growing. The haplotypes that require splitting are b, d, k, q, and s; the symbol bc should be retained and used, and, for the other haplotypes, the suffix 2 denotes a Qa1 ^a haplotype with highly TL-positive thymocytes.     

Cotton rat<Emphasis Type="Italic"> Sihi-</Emphasis>M3 is a minimally oligomorphic<Emphasis Type="Italic"> Mhc</Emphasis> I-b molecule that binds the chemotactic peptide fMLF under stringent conditions

The leading model for class I-b evolution suggests non-polymorphic I-b genes evolve by gene duplication from polymorphic I-a genes. We recently found N-formyl peptide-specific orthologs of the class I-b gene H2-M3 in the rodent subfamily Sigmodontinae. To test if sigmodont M3 is a I-b gene, we sequenced M3 from wild cotton rats (Sigmodon hispidus) diverse at the class II locus, Sihi-DQA. These haplotypes carry a single allele of M3 that closely resembles H2-M3. However, peptide-binding assays showed that cotton rat M3 bound the chemotactic N-formylpeptide fMLF better than did rat or mouse M3. The Ala116Lys substitution in cotton rat M3 might enhance binding of fMLF and is one of eight residues of M3 that interact with ligand residues P3 and P4 and that are positively selected, with a d_N/d_S ratio of 1.8. Thus, M3 is a class I-b gene in both sigmodontine and murine murids, but positive selection operates on a small subset of residues in the traditionally defined antigen recognition site.Electronic Supplementary Material Supplementary material is available in the online version of this article at     

BAC clones and STS markers near the distal breakpoint of the fourth t-inversion, In(17)4d, in the H2-M region on mouse Chromosome 17

The H2-M region is the most distal part of the mouse major histocompatibility complex (Mhc) and is likely to include the distal breakpoint of the fourth t-inversion, In(17)4d. The conserved synteny breakpoint between mouse and human is located in the H2-M region between D17Leh89, a putative olfactory receptor gene, and Pgk2 (phosphoglycerate kinase 2). To analyze the H2-M region, we screened a mouse bacterial artificial chromosome (BAC) library, using the D17Mit64, D17Tu49, D17Leh89, D17Leh467, and Pgk2 markers. Thirty-eight BAC clones were obtained and mapped in five clusters, and 25 sequence-tagged site (STS) markers were newly developed. The regions surrounding D17Tu49 and D17Leh467 are abundant in L1 repeat sequences and may, therefore, be candidates for the breakpoints of conserved synteny and t-inversion. D17Leh89 was linked to D17Mit64 by two contiguous BAC clones. The Aeg1 (acidic epididymal glycoprotein 1) and Aeg2 genes were mapped close to Pgk2, on the same BAC clones. The genetic length between D17Leh89–D17Mit64 and Pgk2–Aeg can be estimated as 0.5–0.7 centiMorgan (cM), and the most distal class I gene, H2-M2, can be placed 0.3–1.0 cM proximal to the t-inversion breakpoint. A recombinational hotspot is suggested to be located between Aeg and Tpx1 in an interspecific cross of (C57BL/6J ×Mus spretus). Received: 23 July 1997 / Accepted: 13 November 1997     

Class I and class II restriction pattern polymorphisms associated with independently derived RT1 haplotypes in inbred rats

This communication reports the DNA level identification of class I and class II sequences associated with 20 RT1 haplotypes which have been assigned previously to eight RT1 groups. Sixteen to 22 bands in genomic blots hybridized with the mouse pH-2III class I cDNA probe. Only the three RT1 ^khaplotypes associated with identical class I restriction fragment patterns. Differences in restriction bands between putatively identical RT1 haplotypes were either less than or equal to 6%, or greater than 50%, suggesting a relatively high level of recombination between serologically identified RT1.A genes and the majority of class I sequences. Restriction fragment patterns associated with three RT1 ^uhaplotypes differed by less than 6%. However, intra-RT1 ^a,intra-RT1 ^b,and intra-RT1 ^lrestriction fragment differences were between 50 and 64%. In specific cases, different RT1 haplotypes associated with identical class I restriction patterns, e.g., RT1 ^m(MNR) and RT1 ^d(MR); higher resolution confirmed the difference (two bands) between RT1 ^mand RT1 ^d.Results of hybridization with the human DC₁ probe confirmed that the AVN RT1 ^aand NSD RT1 ^bhaplotypes were generated by recombinations within the vicinity of the RT1.B : RT1.D regions. These results demonstrate that a previous classification of RT1 haplotypes was incomplete and did not include the majority of class I and class II sequences which distinguish RT1 haplotypes.     

Physical map and expression profile of genes of the telomeric class I gene region of the rat MHC

The rat is an important model for studying organ graft rejection and susceptibility to certain complex diseases. The MHC, the RT1 complex, plays a decisive role in controlling these traits. We have cloned the telomeric class I region of the RT1 complex, RT1-C/E/M, of the BN inbred rat strain in a contig of overlapping P1-derived artificial chromosome clones encompassing approximately 2 Mb, and present a physical map of this MHC region. Forty-five class I exon 4-hybridizing BAM:HI fragments were detected, including the previously known rat class I genes RT1-E, RT-BM1, RT1-N, RT1-M2, RT1-M3, and RT1-M4. Twenty-six non-class I genes known to map to the corresponding part of the human and mouse MHC were tested and could be fine mapped in the RT1-C/E/M region at orthologous position. Four previously known microsatellite markers were fine mapped in the RT1-C/E/M region and found to occur in multiple copies. In addition, a new, single-copy polymorphic microsatellite has been defined. The expression profiles of several class I genes and the 26 non-class I genes were determined in 13 different tissues and exhibited restricted patterns in most cases. The data provide further molecular information on the MHC for analyzing disease susceptibility and underline the usefulness of the rat model.     

Expressed Peromyscus maniculatus (Pema) MHC class I genes: evolutionary implications and the identification of a gene encoding a Qa1-like antigen

To gain insight into the evolution of rodent major histocompatibility complex (MHC) class I genes and identify important (conserved) nonclassical class I (class Ib) gene products and residues in these proteins, sixPeromyscus maniculatus MHC (Pema) class I cDNA clones were isolated and sequenced. FivePema class I cDNAs appeared most similar to mouse and rat classical class I (class Ia) genes. One exhibited highest similarity to anH2 class Ib gene,H2-T23 (encoding the Qa1 antigen). Phylogenetic trees constructed withPema, RT1, andH2 class I sequences suggested that the lineages of some rodent class Ib genes (e.g.,T23 andT24) originated prior toMus andPeromyscus speciation [>50 million years (My) ago]. Sequences of four Qa1-like proteins from three species permitted the identification of ten Qa1-specific amino acids. On the basis of molecular modeling, three residues showed the potential to interact with T-cell receptors and three residues (all corresponding to polymorphic positions among H2 class Ia proteins) were predicted to influence antigen binding. The recognition of mouse Qa1 proteins by a subset of T-cells in influenced by a locus,Qdm, which encodes the H2-D leader peptide. One of thePema class I cDNA clones classified asH2-K, D/L-like (class Ia) is predicted to encode an identical peptide, implying that an antigen binding protein (Qa1) and the antigen to which it binds (the product ofQdm) has been conserved for over 50 My. The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers U12822 (Pm13), U12885 (Pm41), U12886 (Pm52), U12887 (Pm62), U16846 (Pm11), and U16847 (Pm53)     

Charactreization of polymorphism within the H-2M MHC class II loci

The products of the class II-like H2-M genes of the major histocompatibility complex are required for class II antigen processing. We sequenced H2-Ma and Mb from several mouse strains to determine whether these genes are polymophic, like H2-O. Both Mb loci appear to be transcribed and are distinct from each other. Mb1 and Mb2 differ by about 11% at the nucleotide level and are most dissimilar in their second exons (corresponding to the 1 domain). Relative to the published Mb 1 ^d haplotype sequence, the products of the b, g7, f, and k2 alleles of Mb 1 from Mus musculus domesticus and the separate mouse species Mus spretus differ by only one to four amino acids. The majority of the changes occured in the second exon of Mb 1, in contrast to HLA-DMB, the human orthologue. Little polymorphism was seen for Mb 2, and Ma was invariant in all strians tested. The similarity of the g7 allele to those from other haplotypes makes it unlikely that the M class II genes play a role in the autoimmune diabetes of NOD strain mice. The M genes are regulated in a manner similar to classical class II genes, in that they are upregulated by IFN-gd in mcrophages, and to a lesser extend by IL4 in B cells. When modeled on the crystal structure of the HLA-DR1 class II molecule, nearly all of the differences between M1 and M2 affect residues facing away from the putative peptide binding groove.     

Considerable haplotypic diversity in the RT1-CE class I gene region of the rat major histocompatibility complex

The major histocompatibility complex (MHC) class I region extending between the Bat1 and Pou5f1 genes shows considerable genomic plasticity in mouse and rhesus macaque but not in human haplotypes. In the rat, this region is known as the RT1-CE region. The recently published rat MHC sequence gave rise to a complete set of class I gene sequences in a single MHC haplotype, namely the RT1ⁿ haplotype of the widely used BN inbred strain. To study the degree of genetic diversity, we compared the RT1-CE region-derived class I genes of the RT1ⁿ haplotype with class I sequences of other rat haplotypes. By using phylogenetic tree analyses, we obtained evidence for extensive presence and absence polymorphisms of single loci and even small subfamilies of class I genes in the rat. Alleles of RT1-CE region class I genes could also be identified, but the rate of allelic nucleotide substitutions appeared rather low, indicating that the diversity in the RT1-CE region is mainly based on genomic plasticity.     

Major histocompatibility complex class I genes of Peromyscus leucopus

Class I genes of the Peromyscus leucopus major histocompatibility complex (MhcPele) were examined by Southern blot hybridization, genomic cloning, and DNA sequencing. At least three distinct subtypes of Pele class I genes were discerned, which we have designated Pele-A, B, and C. The nucleotide sequences of exon 5-containing regions (encoding the transmembrane domain) suggested that Pele-A genes are homologs of mouse H-2K, D, L, and Q genes and that Pele-B genes correspond to mouse Tla genes. The Pele-C genes appeared similar to mouse M1 genes. The number of unique genes in each subtype cloned from an individual P. leucopus were 20 for Pele-A, 13 for Pele-B, and 2 for Pele-C. Three genomic clones showed cross-hybridization to both Pele-A and Pele-B gene-specific probes. Six genomic clones remained unclassified as they did not cross-hybridize to exon 5-containing probes from Pele-A, B, or C genes. The homology between the transmembrane domains of Pele class I gene subtypes was found to be similar to that observed between the transmembrane domains of H-2 subtypes (or groups). Interspecific similarity of exon 5 was found to be 81%–88% between Pele class I genes and their H-2 counterparts.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M33983-5.     

Hierarchy in the assembly of HLA-B27 and HLA-Cw3 molecules in transgenic mice

Cell surface expression of human class I molecules in transgenic mice is dependent upon the available pool of ₂-microglobulin (₂m) and the affinity between mouse ₂m and human class I molecules. HLA-B27 and HLA-Cw3 transgenes can be expressed in mouse strains of the H-2 haplotypes b,f,k, and s which encode two endogenous class I genes mapping to H-2K and H-2D. The human class I genes cannot be expressed on H-2 ^dand H-2 ^qhaplotypes which encode three endogenous class I molecules (K,D,L). This suggests that there may be only enough mouse ₂m molecules to support three class I molecules. When both the HLA-B27 and HLA-Cw3 genes are introduced into H-2 ^bmice, only HLA-Cw3 reaches the cell surface. This suggests that HLA-Cw3 has a higher affinity than HLA-B27 for mouse ₂m. The possible implications of our findings regarding the assembly, transport, and expression of class I MHC molecules in vivo are discussed.     

Role of nonclassical class I genes of the chicken major histocompatibility complex Rfp-Y locus in transplantation immunity

The chicken major histocompatibility complex (MHC) genes are organized into two genetically independent clusters which both possess class I and class II genes: the classical B complex and the Restriction fragment pattern-Y (Rfp-Y) complex. In this study, we have examined the role of Rfp-Y genes in transplantation immunity. For this we used three sublines, B19H1, B19H2 and B19H3, derived from a line fixed for B19. Southern blots, PCR-SSCP assays using primers specific for Rfp-Y genes, and Rfp-Y class I allele-specific sequencing show that the polymorphisms observed in B19H1, B19H2 and B19H3 are due to the presence of three different Rfp-Y haplotypes. The Rfp-Y class I (YF) alleles in these three haplotypes are highly polymorphic, and RT-PCR shows that at least two YF loci are expressed in each subline. The three sublines show Rfp-Y-directed alloreactivity in that Rfp-Y-incompatible skin grafts are rejected within 15 days, a rate intermediate between that seen in B-incompatible rejection (7 days) and that observed for grafts within the sublines (20 days). We conclude that Rfp-Y has an intermediate role in allograft rejection, likely to be attributable to polymorphism at the class I loci within this region.The sequence data reported are available in the GenBank database under the accession numbers AY257165 (YFVw*15), AY257166 (YFVw*16), AY257167 (YFVIw*15), AY257168 (YFVIw*17), AY257169 (YFw*16), and AY257170 (YFw*17)