Genomic analysis of the H-2 complex region associated with mouse t Haplotypes

Naturally occurring t haplotypes suppress recombination over a region of mouse chromosome 17 that includes the H-2 complex. Each of these t haplotypes is associated with a specific set of H-2 alleles and can be placed into one of a limited number of complementation groups. Genetic studies have demonstrated the existence of a basic homology in genomic organization among all t haplotypes. We used an H-2 cDNA probe to investigate, at the molecular level, possible relationships among the H-2 regions of different t haplotypes. We identified a family of t haplotype-specific restriction fragments that carry DNA sequences homologous to the H-2-like genes. Surprisingly, the H-2-defined restriction patterns from all five complete t haplotypes analyzed are highly homologous, even though H-2 gene products expressed are antigenically distinct. These data lead to two major conclusions. First, all t haplotypes were derived from a small number of closely related ancestors. Second, the H-2 complex region associated with each primordial t chromosome has been maintained within at least the five present-day t haplotypes analyzed here. Hence the H-2 complex is an integral component of naturally occurring t haplotypes.     

Gene mapping within the T/t complex of the mouse. I. t-lethal genes are nonallelic

The t haplotypes of mouse chromosome 17 are natural polymorphisms in wild populations that contain mutations that affect or control such diverse functions as tail length, embryonic lethality and maturation and function of male germ cells. The major impediment to dissecting the genetics of this complex region has been its unusual property of recombination suppression in heterozygotes with wild-type chromosomes. Recently it was shown that recombination suppression does not occur in heterozygotes containing two different t haplotypes, which suggested that t chromosomes may be mismatched with respect to wild-type but share sequences that permit crossing-over between them. Thus for the first time questions of allelism and map positions of the t-lethal mutations can be addressed. We report here the results of three experiments that analyzed the t^w12 haplotype trans to either t^w5, t^w32 or t^w18. In all cases these lethal mutations were nonallelic to t^w12. These results, together with evidence for functional relatedness, suggest the t-lethals may be a gene family spread out over more than 15 centiMorgans of chromosome 17.     

Molecular probes define different regions of the mouse t complex

Four genomic clones obtained from microdissected fragments of the proximal portion of mouse chromosome 17 have been used to identify a series of t-haplotype-specific restriction fragments. Their specificity is defined by presence in eight complete t haplotypes and absence from 18 inbred strains of wild-type mice. Partial t haplotypes contain subsets of the t-specific fragments, and each can be classified according to the t-specific fragments it contains. This is the first molecular evidence that independent partial t haplotypes contain different lengths of t haplotype DNA. Recombination studies indicate that partial t haplotypes suppress recombination in proportion to the extent of t haplotype DNA they contain. Molecular analysis of partial t haplotyes shows that the t-specific fragments map to and thus define different regions of the t complex. Certain regions of t haplotype DNA defined by t-specific restriction fragments can be correlated with loci involved in the control of transmission ratio distortion.     

Recombination between two mouse t haplotypes (t w12 tf) and t Lub-1) : Mapping. of the H-2 complex relative to centromere and tufted (tf) locus

A monoclonal antibody known to recognize the H-2.m3 specificity is shown to react with the class I H-2 product of t ^Lub-1 but not t ^w12 tf mice. This reagent was used to study the segregation of the H-2 complex in the progeny of t ^Lub-1 +/t ^ww12 tf females. The most straightforward interpretation of the results presented here is that these t haplotypes carry an H-2 complex located between the centromere and tufted locus. Possible consequences of such a location with regard to the recombination between t haplotypes and chromosome 17 from laboratory mice are discussed.     

A region flanking H-2K is duplicated to a distant site in most mouse t haplotypes

Mouse t haplotypes contain at least one inversion, which encompasses the major histocompatibility complex, relative to their wild-type counterparts. A DNA probe for a single copy sequence which flanks the H-2K region in inbred strains was found to have undergone further rearrangements in the t haplotypes. In most t haplotypes, this sequence is duplicated at a distant site, and the two regions show 1 % recombination. The length of homology shared by the two sites is likely to be at least 10–15 kb. Three different alleles, as defined by restriction fragment length polymorphisms, were found for each of the two sites among different t haplotypes. These may reveal evolutionary relationships among these chromosomes.     

Sexual preference of meiotic recombination within the H-2 complex

The recombination frequency between the H-2K and H-2D marker loci in male mice was measured using heterozygotes that carry the H-2 ^wm7 haplotype derived from the Japanese wild mouse and common H-2 haplotypes derived from inbred mice. Previous mating experiments in which backcross progeny of heterozygous females were screened demonstrated that the H-2 ^2m7 displays marked enhancement of recombination within the H-2 complex. In contrast to recombination in female mice, no enhancement of recombination was observed during male meiosis in the present study. Thus, it appeared that enhancement of recombination is specific to female mice. A genealogical study of recombination indicated that the postmeiotic stage is not involved in the generation of sexual preference of enhancement of recombination, suggesting that the preference is meiotic-drive and that a female-specific mechanism is involved in meiotic recombination mediated by the H-2 ^wm7 haplotype.     

A major testicular cell protein specified by a mouse T/t complex gene.

The technique of two-dimensional gel electrophoresis was used to identify a major testicular cell protein, p63/6.9, which is specified by a gene (p63) within the mouse T/t complex on chromosome 17. A wild-type gene causes the expression of one form of this protein, p63/6.9b. All lethal and semilethal t haplotypes derived from wild mice cause the expression of an apparently identical alternate allelic form of the p63/6.9 protein. This protein, p63/6.9a, represents the first t haplotype-specific molecule to be biochemically identified. A dominant haplotype (T^Hp) acts as a null allele of the p63 gene; this unique behavior provides additional evidence for the interpretation of T^Hp as a deletion within the T/t region of chromosome 17. Limited proteolysis of viable testicular cells causes selective cleavage of the p63/6.9 proteins, relative to other detergent-soluble testicular cell proteins known to be internal. This result strongly suggests that p63/6.9 proteins are located on the cell surface. Qualitative and quantitative estimates indicate that p63/6.9 is one of the most prominent proteins on the testicular cell surface. p63/6.9 is expressed in all other mouse cell types analyzed but at greatly reduced levels. Partial t haplotypes obtained from infrequent recombination events were used to map the p63 gene close to the dominant mutation T and separate from the lethal factors of t haplotypes. A 100% correlation was observed between the expression of p63/6.9a and the genetic presence of the tail interaction factor of t haplotypes. The significance of this correlation in terms of the evolution of t haplotypes among wild mice is discussed.     

An unstable family of large DNA elements in the center of the mouse t complex

We have cloned 363 kb (× 10³ bases) from a novel, locally dispersed family of 11 large DNA elements, called T66 elements, within the center of complete mouse t haplotypes. Homologies among individual members of the T66 family are observed along a repeated unit of at least 75 kb in length. Individual T66 homology units are classified into three subfamilies through hybridization studies with a series of diagnostic subfamily-specific probes. The organization and number of elements in wild-type forms of chromosome 17 are very different from those found within t haplotype forms of this chromosome. The number of T66 elements present within individual chromosomes is highly polymorphic among both inbred strains of mice and among independently derived t haplotypes. Wild-type chromosomes have between five and nine T66 elements distributed between two loci that are separated by a genetic distance of at least three map units, whereas t haplotypes have between 9 and 11 T66 elements within a single cluster. Many of the rare recovered products of recombination between a t haplotype and a wild-type form of chromosome 17 have resulted from recombination within or near the T66 regions present on each chromosome. Molecular and genetic data lead to the speculation that portions of individual T66 homology units could be involved in t haplotype effects on sperm differentiation.     

Evolutionary relationships between the t and H-2 haplotypes in the house mouse

Thirty-three mouse strains carrying t haplotypes were typed with a large battery of monoclonal and polyclonal antibodies specific for class I and class II antigens controlled by the H-2 complex. Among these t haplotypes were representatives of the six complementation groups defined previously and of eight new groups defined by us recently. The typing resulted in the identification of the H-2 haplotypes of these strains and of their alleles at K, D, A, and E loci. Nineteen of the 33 strains proved to carry a mutation that prevents the expression of the E molecule on the cell surface. All H-2 haplotypes of the t strains are related in terms of sharing certain antigenic determinants, most of which have not, as yet, been found in inbred strains or in wild mice that do not carry t haplotypes. According to the degree of serological relatedness, the haplotypes can be arranged into a pedigree presumably reflecting the evolutionary history of the t chromosomes. The ancestral t chromosome from which the 33 chromosomes derive was presumably present in the mouse population before the divergence of the Mus musculus and Mus domesticus species. The E° mutation, too, is apparently ancient because it occurs in different branches of the evolutionary tree.     

An H-2K gene of the t w32mutant at the T/t complex is a close parent of an H-2K qgene

Two recombinant mice have been recovered from the progeny of Ttf/t ^w32+ animals. They have lost the t^w32 lethality factor(s) and gained tufted, presumably from the T chromosome. Southern blot analysis of class I genes of these two new partial t ^PA027 and t ^PA286 haplotypes indicates that they have retained at least part of the major histocompatibility complex of the t ^w32 chromosome (H-2 haplotype H-2 ^w28). We have prepared a phage library of Eco RI-digested DNA from homozygous t ^PA027 animals. Upon screening the library with a cDNA probe specific for H-2K genes, we isolated a class I gene displaying all of the distinctive features of a genuine H-2K gene, and which could thus be defined as an H-2K ^w28 gene. The H-2K ^w28 gene is 92–95% homologous to H-2K ^band H-2K ^dgenes and differs significantly from the other class I genes sequenced so far. Homology with the H-2K ^bsequence reaches nearly 100% in the 3 part of the H-2K ^w28 gene. Moreover, the homology with an H-2K ^qcDNA sequence reaches 99.8%. Several hypotheses can account for the near identity of H-2K ^b, H-2K ^q,and H-2K ^w28 gene sequences: either recombination between H-2 ^w28 and H-2 ^band H-2 ^qsequences occurred before or at the.time the strain was established, or the class I genes of the t ^w32 chromosome and the H-2 ^band H-2 ^qgenes found in inbred strains of mice have separated from each other rather recently.     

Limits of the distal inversion in the t complex of the house mouse: Evidence from linkage disequilibria

The suppression of crossing-over and the consequent linkage disequilibrium of genetic markers within the t complex of the house mouse is caused by two large and two short inversions. The inversions encompass a region that is some 15 centiMorgans (cM) long in the homologous wild-type chromosome. The limits of the proximal inversions are reasonably welldefined, those of the distal inversions much less so. We have recently obtained seven new DNA markers (D17Tu) which in wild-type chromosomes map into the region presumably involved in the distal inversions of the t chromosomes. To find out whether the corresponding loci do indeed reside within the inversions, we have determined their variability among 26 complete and 12 partial t haplotypes. In addition, we also tested the same collection of t haplotypes for their variability at five D17Leh, Hba-ps4, Pim-1, and Crya-1 loci. The results suggest that the distal end of the most distal inversion lies between the loci D17Leh467 and D17Tu26. The proximal end of the large distal inversion was mapped to the region between the D17Tu43 and Hba-ps4 loci, but this assignment is rather ambiguous. The loci Pim-1, Crya-1, and the H-2 complex, which have been mapped between the Hba-sp4 and Grr within the large distal inversion, behave as if they recombine from time to time with their wildtype homologs.     

Effects of chimaerism for two T/t complex mutations on sperm function

Mouse chimaeras produced by aggregation of embryos heterozygous for two different recessive mutations at the T/t complex have been analyzed by breeding to explore the basis for the phenomena of male transmission ratio distortion and sterility associated with these genes. Whereas males of genotype t^w2/t^w5 are always sterile, male chimaeras of the type +/t^w2 ? +/t^w5 are normally fertile; furthermore, they transmit each t mutation to the same very high extent seen in ordinary (+/t) heterozygotes. Since spermatogenic cells derived from either the +/t^w2 and +/t^w5 genotypes thus function quite independently of one another in mosaic testes, it can be concluded that sterility, and presumably distorted transmission ratio as well, depends on specific interactions between T/t alleles in diploid spermatogenic cells or their individual meiotic descendants.     

Definitive chromosomal location of the H-2 complex by in situ hybridization to pachytene chromosomes

Chromosome 17 of the mouse carries the H-2 complex and the T/t complex. An understanding of the organization of this region and an accurate genetic map of chromosome 17 would be of great value for both immunologists and developmental biologists. Until now the only maps available have been derived solely from recombinational studies using several translocations, an inherently inaccurate method. We have found the definitive location of the H-2 complex by the use of in situ hybridization. Our results show that both the T/t complex and the H-2 complex map to positions far more distal than the generally accepted map positions. This proves that recombination in Robertsonian chromosomes underestimates physical map distances on chromosome 17.     

A gene product of the mouse t complex with chemical properties of a cell surface-associated component of the extracellular matrix

p63/6.9 is a major testicular cell protein coded for by a gene, called Tcp-1, within the mouse t complex. All wild-type chromosomes carry the Tcp-1^b allele which codes for a basic form of this protein, while all complete mutant t haplotypes carry the Tcp-1^a allele which codes for an acidic form of this protein. Genetic studies have demonstrated a correlation between the Tcp-1 gene and certain t haplotype effects on sperm differentiation and maturation. In this report, an initial biochemical analysis of the p63/6.9 protein is presented. The data provide evidence that p63/6.9 is closely associated with the external surface of testicular cells but not as an integral membrane component. Some properties of the testicular form of this t complex gene product are similar to those reported for the matrix proteins fibronectin and laminin. The possibility is suggested that primary effects of t haplotypes on sperm differentiation could be exerted through the extracellular matrix. p63/6.9 is also present at a lower level within the cytoplasm and membranes of F9 teratocarcinoma cells. It appears that the level of p63/6.9 synthesis and the exact nature of p63/6.9 intra- and/or intermolecular interactions are under tissue-specific control.     

H-2 typing of mutants of thet 6 haplotype in the mouse

Mutantt haplotypes derived from thet ⁶ haplotype were typed forH-2. The mutantt ^h2 that arose fromt ⁶ due to crossing over in the region betweenT andtf had, as expected, lost theH-2 haplotype characteristic oft ⁶. The haplotypest ^h17,t ^h18, andt ^p1, which also arose by recombination, but which represent the complementary crossover products, including the distal part of thet ⁶ haplotype, carried the sameH-2 type ast ⁶. This suggests that crossing over betweentf andH-2 is suppressed int ^h17 andt ¹⁸. This in turn suggests that mutantt haplotypes suppress crossing over for that part of thet chromatin that they still retain.The origin oft ^h7, which apparently did not include any crossover distal toT, and which retains the crossover-suppressing property oft ⁶, retains thet ⁶ H-2 type. Unexpectedly, J ^h20 , which expressestf and was at first thought to have arisen due to crossing over, also retains theH-2 type oft ⁶. This provides part of the evidence thatt ^h20 arises fromt ⁶ not by crossing over, but by a small deletion, and hence that duplication and deletion are possible modes of origin of mutantt haplotypes.Abbreviations used in this paper are t haplotype mutant haplotype of the chromosome 17, often designated J allele - T Brachyury mutant - T/+ short-tailed mouse - T/T lethal during embryogenesis - T-int T interaction (characteristic oft haplotypes that interact in heterozygotes withT to produce a tailless mouse) - tf locus homozygotes showing waves of hair loss - Kb knobby, which produces a knobbly tailed heterozygote, homozygous lethal - titer reciprocal of serum dilution giving 50% kill     

LOW FREQUENCY OF t HAPLOTYPES IN NATURAL POPULATIONS OF HOUSE MICE (MUS MUSCULUS DOMESTICUS)

t haplotypes are a naturally occurring, autosomal, meiotic-drive system found on chromosome 17 of the house mouse. They show non-Mendelian transmission from heterozygous +/t males, such that 90% or more of the male's offspring inherit the t-bearing chromosome. Although they are expected to become rapidly fixed, surveys of natural populations typically report low overall frequencies of only ~15–25% +/t heterozygotes. Generally, such studies of t haplotypes in wild populations have sampled only small numbers of individuals due to the need to genotype mice by breeding, thus we have conducted a large survey of wild mice, Mus musculus domesticus, using DNA markers to examine the frequency and distribution of t haplotypes in natural populations. The overall frequency of +/t heterozygotes from our entire sample was 0.062, which is much lower than all previous estimates of t haplotype frequency. t haplotypes were patchily distributed and rare, and were present in only 46% of the populations we sampled. There were no significant sex-specific differences in the frequency of t haplotypes. Our data suggest that the frequency of +/t heterozygotes in independent populations varies with respect to population size and stability: t haplotypes were at low frequency in all large, relatively persistent populations, whereas they were at more variable, and often higher, frequencies in small, temporally unstable populations. The extinction and recolonization of many of the smaller populations may contribute to the greater variation in t haplotype frequency observed, and small populations may be important reservoirs of t haplotypes in the wild. The highest frequencies of t haplotypes were obtained from populations with semilethal, or complementing lethal, t haplotypes, where t/t homozygous mice were present.     

The CIS-TRANS Test Shows No Evidence for a Functional Relationship between Two Mouse t Complex Lethal Mutations: Implications for the Evolution of t Haplotypes

Mouse t haplotypes often carry embryonic lethal mutations. Sixteen complementation groups are known, but the viability of the heterozygotes between them is often less than 100%. It has been reported that cis heterozygotes of two lethal mutations showed better viability than trans heterozygotes. This could indicate that the mutations were part of the same functional unit, even though they map up to 15 cM apart. However, the tw5 and tw12 haplotypes in our colony did not show a statistically significant decrease in viability when combined in trans. The cis-trans analysis was repeated using two independent chromosomes, derived by recombination between the tw5 and the tw12 haplotypes to provide the two lethal mutations in cis. Two independent chromosomes, representing the reciprocal recombination event, supplied the corresponding wild-type alleles in cis. These chromosomes were combined in the four pairwise combinations, and male/female reciprocal crosses were done. The cis heterozygotes showed a decrease, rather than an increase, in viability in seven of the eight cases. These results probably reflect effects of unrelated background genes. The lethal mutations, instead of being functionally related, may have occurred in a random, unrelated set of genes and may confer a selective advantage to t haplotypes found in wild populations.     

Genetic structure and origin of t haplotypes of mice, analyzed with H-2 cDNA probes

We investigated the genetic organization and evolutionary origin of t chromosomes of mice by examining the restriction fragment patterns of DNA from t haplotypes and normal chromosomes with cDNA probes to H-2 class I genes. On genomic DNA blots, the restriction fragments containing H-2-related sequences were highly variable among different inbred strains of mice, whereas they were very similar among different t haplotypes even when the t haplotypes carried serologically different H-2 haplotypes. These observations suggest that all t haplotypes have a common origin and are not products of independent mutational events. We also mapped the position of several restriction fragments characteristic of t DNA by using a battery of recombinant t haplotypes, defined with respect to their t-lethal factors and H-2 haplotypes. We thus show that restriction fragments containing H-2-related sequences map to the left of the H-2 class I genes in t chromosomes, a region in which the tw32 b-lethal factor also maps. The cloning of these fragments can be expected to provide an entry for the structural analysis of t DNA.     

The mouse plasminogen locus maps to the recombination breakpoints of the t Lub2and Tt Orlpartial t haplotypes but is not at the t w73locus

The mouse plasminogen (Plg) locus maps to a region of chromosome (Chr) 17 which is inverted in the t haplotype Chromosomal variant. Here we investigate the genomic organization of the Plg locus in structurally variant forms of Chr 17; wild-type (+), t haplotype (t), and two partial t haplotypes Tt ^Orland t ^Lub2which arose by recombination between + and t chromosomes. Our analysis suggests that the t haplotype chromosomal variant contains extra, inverted copies of the Plg locus, and that a single locus is present in the wild-type variant. Changes in the Plg locus in Tt ^Orland t ^Lub2suggest that they arose by homologous recombination across elements in the Plg locus having the same orientation in the wild-type and t haplotype chromosomes. One hundred ten kb around the wild-type Plg genomic locus have been cloned and the proximal breakpoint of a deletion in the t ^Lub2chromosome has been localized to a fragment 30 kb downstream of the Plg gene. The t ^Lub2deletion has been shown to delete a gene named t ^w73that affects blastocyst implantation, a process probably requiring proteases such as plasminogen. However, the mapping of Plg relative to the t ^Lub2deletion and mRNA analysis of plasminogen in t ^w73heterozygotes suggests that Plg does not lie at the t ^w73locus.     

Structural and genetic properties of the Eb recombinational hotspot in the mouse

The Eb gene of the mouse contains a recombinational hotspot which plays a predominant role in meiotic crossing-over within the I region of the mouse major histocompatibility complex (MHC). The nucleotide sequences of five recombinants derived from H-2 ^k /H-2 ^b heterozygotes at the Eb locus placed the sites of recombination in each recombinant haplotype within a 2.9 kilobase (kb) segment located fully within the second intron of the Eb gene. Further resolution of the crossover sites was not possible since the nucleotide sequences of the parental and recombinant haplotypes are identical within this segment. The molecular characterization of these five recombinants considered in conjunction with three previously reported intra-Eb recombinants indicates that there are at least two distinct sites of recombination within the Eb recombinational hotspot. In a related study, an examination of the nucleotide sequence of the H-2 ^p allele of the Eb gene revealed a major genetic rearrangement in the 5' half of the intron in this haplotype. A 597 base pair (bp) nucleotide sequence found in the H-2 ^p haplotype is replaced by a 1634 bp segment found in the H-2 ^b and H-2 ^k haplotypes. Sequence analysis of this 1634 bp segment shows strong nucleotide sequence similarity to retroposon long terminal repeat (LTR), env, and pol genes indicating that this segment of the second intron has evolved through retroposon insertion. The location of these retroposon sequences within the 2.9 kb recombination segment defined by the five H-2 ^k /H-2 ^b recombinant haplotypes suggests a possible relationship between these retroviral elements and site-specific recombination within the second intron of the Eb gene. Offprint requests to: H. C. Passmore