DNA polymorphism of MHC III genes in inbred and wild mouse strains

Genes encoding the second component (C2), factor B, and complement protein C4 and Slp (sex-limited protein) are members of the major histocompatibility complex class III gene cluster. In this report we describe isolation of a mouse C2 cDNA clone and its use together with factor B and C4 cDNA clones to examine the S region in a panel of 42 haplotypes in laboratory and wild mice representing 5 species and subspecies of Mus. Conservation of the C2 factor B gene duplex was evidenced by relatively limited polymorphism associated with speciation and nucleotide sequence homology between mouse and human C2 and factor B The C4-Slp gene duplex, on the other hand, showed extensive polymorphism by DNA blot analysis. This polymorphism correlated poorly with the C2/factor B restriction fragment length polymorphism, suggesting independent evolution of these two segments of the S region. Taken together, these data will be of particular importance in studies of mouse strains with abnormal regulation of immune effector systems since the class III gene products are essential for activation of the complement cascade.     

Tissue-specific, inducible and functional expression of the E alpha d MHC class II gene in transgenic mice

We have introduced the class II E alpha d gene into (C57BL/6 X SJL) F2 mice which do not express their endogenous E alpha gene. The mRNA expression of the E alpha d gene shows the same tissue distribution as the endogenous class II genes except in the case of one mouse, which carried 19 copies of the E alpha d gene. In this mouse expression of E alpha d mRNA was seen in all tissues tested. Expression of the transgene was induced by gamma-interferon in isolated macrophages from the transgenic mice. In addition, fluorescence activated cell sorter (FACS) analysis, mixed lymphocyte response and antigen-presentation experiments showed that the product of the transferred gene is expressed on the cell surface and functions as a major histocompatibility complex restriction element. Transmission of the gene occurred only with female transgenic mice, all males were infertile or did not transmit the gene, suggesting an effect of the transferred DNA sequence on male reproductive function.     

Duplications and deletions of Vh genes in inbred strains of mice

evolution of variable region (Vh) gene family copy number and polymorphism was investigated by the analysis of the immunoglobulin heavy chain variable region (Igh-V) locus in 74 inbred strains and substrains of mice. Several strains were found to have slight differences from Igh-V haplotypes previously identified, usually of a single Vh gene family. These results indicate that the evolution of copy number in the mouse Igh-V locus proceeds largely by the accumulation of incremental changes, reflecting the clustered organization of the mouse Igh-V locus. We have found no evidence of very large or frequent duplication or deletion events indicative of rapid expansion or contraction processes. The existence of one or more particularly large Vh gene families most likely reflects random copy number variation, rather than selection for the amplification of their members. The identification of strains with recombinant Vh gene arrays demonstrates that recombination, both within and between haplotypes, appears to be the predominant mechanism generating the high restriction fragment length polymorphism in the Igh-V locus.Abbreviations used in this paper Igh-V immunoglobulin heavy chain variable region locus - Vh heavy chain variable region gene - Dh heavy chain diversity region gene - V immunoglobulin kappa light chain variable region gene - V T-cell receptor beta chain variable region gene     

Construction of recombinant lambda phages that carry the E. coli recB and recC genes

Summary A fragment of the E. coli chromosome including the recC gene has been cloned by in vitro recombinant DNA techniques into a phage vector to give the recombinant phage drecC. This was used to derive the phage drecBC by in vivo recombination. On lysogenisation of recB and recC mutants with drecBC wild type levels of UV-resistance and RecBC DNase activity were restored. Infection of E. coli with drecBC led to the synthesis of phage-coded proteins of 125 kilodaltons (kd) and 135 kd that were not synthesised on infection with the original vector, whereas a 125 kd protein but not a 135 kd protein was synthesised in similar experiments with drecC. The recombinant phages, which are unable to form plaques, presumably due to the deletion of essential phage genes during their construction, provide useful starting points from which to subclone the recB, recC, and the neighbouring thyA and argA genes individually into multiple copy plasmid vectors.     

Polymorphism of minor histocompatibility genes in wild mice

H-2^b-restricted cytolytic T lymphocytes (CTL) were generated against H-1, H-3, and H-4 antigens and tested against target cells of F₁ hybrids between wild mice and inbred H-2 ^b mice. The congenic strain combinations for the CTL production were such that they tested one allele each at the H-1 and H-4 loci and four alleles at the H-3 locus. Most of the wild mice tested came from Southern Germany, but a few mice came from other European countries and Egypt and Israel. Virtually all wild mice typed as positive with CTL directed against H-3^b and H-4^b antigens; 32% of the F₁ hybrids tested reacted with anti-H-1^cCTL and 9% reacted with anti-H-3^d CTL. The positive results were not caused by cross-reaction with allogeneic H-2 antigens controlled by the major histocompatibility complex (Mhc) genes of the wild mice. At least some of the H-3 and H-4 antigens detected by the CTL in the F₁ hybrid were not identical with antigens of the immunizing strains. These results suggest a relatively low degree of polymorphism of the tested minor H loci in wild mice and further support the notion that minor H loci are unrelated to the Mhc.     

MHC class II A alpha and E alpha molecules determine the clonal deletion of V beta 6+ T cells. Studies with recombinant and transgenic mice

Interactions between MHC class II genes and minor lymphocyte stimulating (Mls) associated products are responsible for clonally deleting self-reactive T cells in mice. Here we demonstrate the role of the intact I-A and I-E molecules as well as the individual A alpha and E alpha chains in the deletion of cells bearing the V beta 6 TCR. DBA/1 (H-2q, Mls-1a) mice were crossed with various inbred congenic, recombinant, and transgenic strains and the F1's were screened for V beta 6 expression. All I-E+ strains were fully permissive in deleting V beta 6+ T cells. I-E- strains expressing I-A b,f,s,k,p permitted only partial deletion, while I-Aq strains showed no deletion. Recombinant I-Aq and I-Af strains which expressed E kappa alpha chain in the absence of E beta chain showed a decrease in V beta 6+ T cells as compared to their H-2q and H-2f counterparts. Furthermore, transgenic mice expressing E kappa alpha Aq beta gene in an H-2q haplotype (E kappa alpha Aq beta?) gave similar results to that of the recombinants in deleting V beta 6 T-cells. The role of the 1-A molecule was also shown by the partial deletion of V beta 6+ T cells in H-2q mice expressing transgenic I-Ak molecules. These results demonstrate that the E alpha chain is important in the deletion of V beta 6 T-cells in Mls-1a mice. The role of A alpha chain is also implied by the permissiveness of E kappa alpha Aq beta but not Aq alpha Aq beta molecules in the deletion of V beta 6+ T cells.     

Structural comparisons of serologically identical IA- and IE-encoded antigens from inbred and wild mice

The IA and IE products of B10.S(9R), B10.A, B10.KPB128, and B10.GAA37 were analyzed for primary structural variations by comparative tryptic peptide mapping. The A,A , andE products of B10.S(9R) and B10.A differed in about 40% of their acid-soluble tryptic peptides, indicating that intra-I-region recombinant strain B10.S(9R) received the genes encoding A, A, and E from theH- 2 ^s parental chromosome rather than fromH- 2 ^a . The tryptic peptides of E chains from B10.S(9R) and B10.A were indistinguishable, suggesting that B10.S(9R) received the gene encoding the E chain from theH- 2 ^a parental chromosome. Consistent with the results of others, these data suggest that the genes encodingA ,A and E chains are centromeric to theIJ subregion, while the gene encoding E chains is telomeric toIJ. The I-region products of two congenic lines carrying wild-derivedH- 2 haplotypes on a C57BL/10 background, designated B10.KPB128 and B10.GAA37, are serologically indistinguishable from those of B10.S(9R). The IA and IE products of B10.S(9R) were compared with those of B10.GAA37 and B10.KPB128 to determine the structural similarity of serologically identical products from allopatric populations of wild mice. The A,A , and E products of B10.S(9R) were indistinguishable from those of B10.GAA37 and B10.KPB128 by comparative tryptic peptide mapping. The E chains of these three lines differed in one or two of their acid-soluble tryptic peptides. The results indicate that the IA-encoded products of these three lines are structurally very similar and may be identical suggesting that some alleles of the A, A, and E chains may be maintained in stable linkage associations in allopatric populations of wild mice. The minor structural variations detected in the E chains of these three congenic lines indicate that the E chain is encoded by chromosome 17 and suggest that allelic E chains exhibit considerably less structural variability than other I-region encoded antigens.     

Recombination and mutation of class II histocompatibility genes in wild mice

We have compared the tryptic peptide fingerprints of the A alpha, A beta, E alpha, and E beta subunits encoded by four wild-derived H-2 complexes expressing A molecules closely related to Ak. The A molecules encoded by these Ak-related mice have A alpha and A beta subunits that differ from A alpha k and A beta k by less than 10% of their tryptic peptides. Comparisons among the four wild-derived A molecules suggested that these contemporary A alpha and A beta alleles arose by sequential mutational events from common ancestor A alpha and A beta alleles. These results suggest that A alpha and A beta may co-evolve as an A beta A alpha gene duplex in wild mice. Tryptic peptide fingerprint comparisons of the E beta gene linked to these Ak-related A beta A alpha gene duplexes indicate that two encode E beta d-like subunits, whereas another encodes an E beta s-like subunit. These results strongly suggest that the A beta A alpha duplex and E beta recombine in wild mouse populations. The significantly different evolutionary patterns exhibited by the class II genes encoding A vs E molecules are discussed.     

Influenza virus-susceptible mice carry Mx genes with a large deletion or a nonsense mutation.

The interferon-regulated mouse Mx gene encodes the 72-kilodalton nuclear Mx protein that selectively inhibits influenza virus replication. Mice carrying Mx+ alleles synthesize Mx protein and resist influenza virus infection, whereas mice homozygous for Mx- alleles fail to synthesize Mx protein and, as a consequence, are influenza virus susceptible. Southern blot analysis allowed us to define the following three distinct Mx restriction fragment length polymorphism (RFLP) types among classical inbred strains: RFLP type 1 in the Mx+ strains A2G and SL/NiA, RFLP type 2 in BALB/c and 33 other Mx- strains, and RFLP type 3 in CBA/J and 2 other Mx- strains. cDNA clones of Mx mRNAs from BALB/c and CBA/J cells were isolated, and their sequences were compared with that of the wild-type Mx mRNA of strain A2G. Mx mRNA of BALB/c mice has 424 nucleotides absent from the coding region, resulting in a frame shift and premature termination of Mx protein. The missing sequences correspond exactly to Mx exons 9 through 11. These three exons, together with some flanking intron sequences, are deleted from the genomes of all Mx RFLP type 2 strains. The Mx- phenotype of the Mx RFLP type 3 strain CBA/J is due to a point mutation that converts the lysine codon in position 389 to a termination codon. Mx RFLP type 3 strains have an extra HindIII site which maps to an intron and thus probably does not affect the coding capacity of Mx mRNA. We further show that the Mx mRNA levels in interferon-treated BALB/c and CBA/J cells are about 15-fold lower than in similarly treated Mx+ cells. This is probably due to decreased metabolic stabilities of the mutant mRNAs.     

Transgenic HLA-DR alpha faithfully reconstitutes IE-controlled immune functions and induces cross-tolerance to E alpha in E alpha 0 mutant mice

We have constructed transgenic mice that express the human class II MHC molecule HLA-DR alpha on a genetic background in which the equivalent endogenous gene, H-2 IE alpha, is not expressed. In these mice, DR alpha complemented the E beta chain such that tissue-specific expression of an interspecies hybrid DR alpha-E beta heterodimer was obtained. Despite 25% amino acid differences between DR alpha and E alpha, immune responsiveness to IE-controlled antigens, clonal deletion of IE-reactive T cells, and alloantigenicity were quantitatively and qualitatively indistinguishable in IE-positive mice and in mice that had integrated at least four copies of the transgene. These results demonstrate a remarkable degree of structural, regulatory, and functional conservation. They also suggest that tolerance induction involves only discrete portions of MHC molecules.     

Mapping of Igk-V genes using backcrossed laboratory and wild mice

In the mouse, the genes coding for the Ly-2 antigen, the chain of the T-cell receptor, and the immunoglobulin kappa light chain have been located on chromosome 6. Although a tentative order has been proposed for these genes, very few data have been reported concerning their genetic distance. To address this question, we have produced backcross mice between SJL and MAI (a wild-derived strain belonging to the Mus musculus), since these mice segregate for the Ly-2 and Igk-C proteins and for the Igk-V24, Igk-V21, Igk-V10, Igk-V8, and Igk-V4 genes. Twelve recombinants were obtained from 163 backcross mice studied. Two mice showed a recombination between the (Igk-V24, Igk-V10, Igk-V8, Igk-V4) and the (Ly-2, Igk-C, Igk-V21) groups, and ten mice displayed a recombination between the (Igk-V24, Igk-V10, Igk-V8, Igk-V4) group and the Tcrb-C loci. These data imply the following gene order: Tcrb-C .... (Igk-V24, Igk-V10, Igk-V8, Igk-V4) .... (Igk-V21, Igk-C, Ly-2). They indicate a distance of 6.1 cM between Tcrb-C and (Igk-V24, Igk-V10, Igk-V8, Igk-V4) and 1.2 cM between Igk-V24, Igk-V10, Igk-V8, Igk-V4 and the (Igk-V21, Igk-C, Ly-2) groups.     

Certain chromosomal regions in Streptomyces glaucescens tend to carry amplifications and deletions

Summary Streptomycetes are subject to a high degree of genetic instability. One manifestation of this phenomenon is the occurrence of tandemly reiterated DNA stretches within the chromosome. We describe the analysis of ten reiterated sequences observed in various ethidium bromide-treated streptomycin-sensitive and melanin-negative mutant strains of Streptomyces glaucescens. The repeated DNA units were 2.9 to 35 kb in lenght. No two sequences were identical. The amplified sequences occupied up to 45% of the total genomic DNA. Structural analysis of the cloned repeated DNA stretches by means of restriction enzymes and by cross hybridization revealed the presence of two chromosomal areas rich in DNA reiterations. In some cases reiterated regions were accompanied by nearby rearrangements.     

MHC evolution in three salmonid species: a comparison between class II alpha and beta genes

The genes of the major histocompatibility complex (MHC) are amongst the most variable in vertebrates and represent some of the best candidates to study processes of adaptive evolution. However, despite the number of studies available, most of the information on the structure and function of these genes come from studies in mammals and birds in which the MHC class I and II genes are tightly linked and class II alpha exhibits low variability in many cases. Teleost fishes are among the most primitive vertebrates with MHC and represent good organisms for the study of MHC evolution because their class I and class II loci are not physically linked, allowing for independent evolution of both classes of genes. We have compared the diversity and molecular mechanisms of evolution of classical MH class II α and class II β loci in farm populations of three salmonid species: Oncorhynchus kisutch, Oncorhynchus mykiss and Salmo salar. We found single classical class II loci and high polymorphism at both class II α and β genes in the three species. Mechanisms of evolution were common for both class II genes, with recombination and point mutation involved in generating diversity and positive selection acting on the peptide-binding residues. These results suggest that the maintenance of variability at the class IIα gene could be a mechanism to increase diversity in the MHC class II in salmonids in order to compensate for the expression of one single classical locus and to respond to a wider array of parasites.     

Use of the MHC for mate choice in wild house mice (Mus domesticus)

The mechanisms maintaining natural diversity at the major histocompatibility complex (MHC) are not well understood. To increase knowledge of one potential mechanism, I examined the use of MHC genes for mate choice by wild house mice in a controlled laboratory setting. Three rearing groups of wild test mice were produced: non‐fostered control mice, mice fostered into families of an inbred laboratory mouse strain, and mice fostered into families of a second, MHC‐congenic mouse strain. Mature test mice were given a choice of two opposite‐sex stimulus mice from the two MHC‐congenic strains used for fostering, and were scored for several measures of preference. The results were non‐significant in general, but females of two rearing groups spent significantly more time with mice of one MHC‐type, and in most rearing groups, mice tended to spend more time with this same MHC‐type. Other results showed that male test mice ejaculated indiscriminantly and that female wild mice mated to ejaculation more often in longer length trials, but showed no significant preferences. In this study, fostering seemed to have little or no effect on MHC‐based mate preferences of wild house mice, and wild mice did not appear to be using the MHC to avoid inbreeding. However, some wild female mice used the MHC to choose potential mates. This revised version was published online in July 2006 with corrections to the Cover Date.     

Rapid expansion of killer cell immunoglobulin-like receptor genes in primates and their coevolution with MHC Class I genes

The gene family of killer cell immunoglobulin-like receptors (KIRs) in primates provides the first line of defense against virus infection and tumor transformation. Interacting with MHC class I molecules, KIRs can regulate the cytotoxic activity of natural killer (NK) cells and distinguish the tumor and virus infected cells from normal body cells. Phylogenetic analysis and comparison of domain structures identified three major groups of KIR genes (group I, II, and III genes). These groups of KIR genes, generated by a series of gene duplications, have acquired different MHC-binding specificity. Inference of ancestral KIR sequences suggested that the functional divergence of group I genes from group II genes occurred by positive selection at the MHC-binding sites after duplication. Our evolutionary study has shown that group I genes diverged from group II genes about 17 million years ago (Mya) apparently after separation of hominoids from Old World (OW) monkeys. Around the same time, gene duplication generating the class I MHC-C locus appears to have occurred. These findings suggest that KIR and MHC class I genes have coevolved as an interacting system. The KIR gene family has experienced a rapid expansion in primate species. The rate of expansion of this gene family seems to be one of the highest among all hominoid gene families. The KIR gene family is also subject to birth-and-death evolution.