Mapping of the Pim-1 oncogene in mouse t-haplotypes and its use to define the relative map positions of the tcl loci t0(t6) and tw12 and the marker tf (tufted).

Pim-1 is an oncogene activated in mouse T-cell lymphomas induced by Moloney and AKR mink cell focus (MCF) viruses. Pim-1 was previously mapped to chromosome 17 by somatic cell hybrids, and subsequently to the region between the hemoglobin alpha-chain pseudogene 4 (Hba-4ps) and the alpha-crystalline gene (Crya-1) by Southern blot analysis of DNA obtained from panels of recombinant inbred strains. We have now mapped Pim-1 more accurately in t-haplotypes by analysis of recombinant t-chromosomes. The recombinants were derived from Tts6tf/t12 parents backcrossed to + tf/ + tf, and scored for recombination between the loci of T and tf. For simplicity all t-complex lethal genes properly named tcl-tx are shortened to tx. The Pim-1 gene was localized 0.6 cM proximal to the tw12 lethal gene, thus placing the Pim-1 gene 5.2 cM distal to the H-2 region in t-haplotypes. Once mapped, the Pim-1 gene was used as a marker for further genetic analysis of t-haplotypes. tw12 is so close to tf that even with a large number of recombinants it was not possible to determine whether it is proximal or distal to tf. Southern blot analysis of DNA from T-tf recombinants with a separation of tw12 and tf indicated that tw12 is proximal to tf. The mapping of two allelic t-lethals, t0 and t6 with respect to tw12 and tf has also been a problem.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic Evidence for Two T Complex Tail Interaction (Tct) Loci in T Haplotypes

The t complex on chromosome 17 of the house mouse is an exceptional model for studying the genetic control of transmission ratio, gametogenesis, and embryogenesis. Partial haplotypes derived through rare recombination between a t haplotype and its wild-type homolog have been essential in the genetic analysis of these various properties of the t complex. A new partial t haplotype, which was derived from the complete tw71 haplotype and which is called tw71Jr1, was shown to have unexpected effects on tail length and unique recombination breakpoints. This haplotype, either when homozygous or when heterozygous with the progenitor tw71 haplotype, produced short-tailed rather than normal-tailed mice on certain genetic backgrounds. Genetic analysis of this exceptional haplotype showed that the recombination breakpoints were different from those leading to any other partial t haplotype. Based on this haplotype, a model is proposed that accounts for genetic interactions between the brachyury locus (T), the t complex tail interaction (tct) locus, and their wild-type homolog(s) that determine tail length. An important part of this model is the hypothesis that the tct locus, which enhances the tail-shortening effect of T mutations, is in fact at least two, genetically separable genes with different genetic activities. Genetic analysis of parental and recombinant haplotypes also suggests that intrachromosomal recombination involving an inverted duplicated segment can account for the variable orientation of loci within an inverted duplication on wild-type homologs of the t haplotype.     

Identification and characterization of t haplotypes in wild mice populations using molecular markers

As part of a population genetics survey of the hybrid zone between mouse subspecies Mus musculus domesticus and M. m. musculus, we identified and characterized the t haplotypes in 1068 mice from 186 different populations in a 2500 km2 area in central Jutland. On the basis of two t-specific PCR markers, 130 mice possessed this haplotype. The allele frequencies at six microsatellites on the third and fourth chromosomal inversions of the t region were sufficiently different between t-bearing and non-t-bearing mice, and linkage disequilibria sufficiently marked on the t haplotype, to be able to reconstitute the genotype of most t haplotypes. A total of three frequent and 15 rarer haplotypes were identified. These haplotypes resemble each other more than they resemble a panel of known haplotypes from a wide range of geographical regions, except for tw73, which was also extracted from Jutland. The patterns of variation at the microsatellite loci suggest that the Jutland haplotypes were derived from a small number of haplotypes, followed by recombination between complementing haplotypes. Further evidence of recombination came from complementation tests that we performed, showing the lack of concordance between the degrees of complementation and of molecular resemblance between haplotypes. This study shows that it is possible to characterize the presence and variation of t haplotypes by a population genetics approach using simple molecular markers. However recombination between t haplotypes has occurred frequently enough to obscure the links between this variation and the biological properties of distortion and lethality of the haplotypes that originally colonized Jutland.     

ENU-induced allele of brachyury (Tkt1) exhibits a developmental lethal phenotype similar to the original brachyury (T) mutation

New alleles of brachyury (Tkt1, Tkt4) were induced in the mouse complete tw5 haplotype by ethylnitrosourea (ENU). Like the original brachyury (T) mutation, the new alleles cause a short-tailed phenotype in heterozygotes, and interact with the t complex tail interaction factor (tct) in trans to cause phenotypically tailless mice. Because ENU is mainly a point mutagen, it is important to determine that the new alleles are homozygous embryonic lethal mutations like the original T allele, and to characterize their embryonic lethal phenotype. Moreover, the Tkt1 mutation maps to an inverted position relative to quaking (qk) in t haplotypes as compared with its position on normal chromosome 17. The Tkt1 allele was separated from the resident tw5 lethal gene, tclw5, by recombination, allowing embryology studies to be performed. Embryological analyses show that the Tkt1 allele is nearly identical to the classic T allele. At 9 and 10 days of development, homozygous Tkt1/Tkt1 embryos are grossly abnormal with properties including 1) irregular, disorganized somite pairs, 2) a shortened posterior end of the embryo, 3) an irregular neural tube, and 4) an abnormal notochord. In addition, 10 day-old abnormal embryos have anterior limb buds that point dorsally rather than ventrally, and are smaller than normal littermates. We conclude that the Tkt1 mutation is a valuable allele for both mapping and molecular characterization of the brachyury locus.     

Genetic Exchange across a Paracentric Inversion of the Mouse T Complex

Mouse t haplotypes are distinguished from wild-type forms of chromosome 17 by four nonoverlapping paracentric inversions which span a genetic distance of 20 cM. These inversion polymorphisms are responsible for a 100-200-fold suppression of recombination which maintains the integrity of complete t haplotypes and has led to their divergence from the wild-type chromosomes of four species of house mice within which t haplotypes reside. As evidence for the long period of recombinational isolation, alleles that distinguish all t haplotypes from all wild-type chromosomes have been established at a number of loci spread across the 20-cM variant region. However, a more complex picture emerges upon analysis of other t-associated loci. In particular, "mosaic haplotypes" have been identified that carry a mixture of wild-type and t-specific alleles. To investigate the genetic basis for mosaic chromosomes, we conducted a comprehensive analysis of eight t complex loci within 76 animals representing 10 taxa in the genus Mus, and including 23 previously characterized t haplotypes. Higher resolution restriction mapping and sequence analysis was also performed for alleles at the Hba-ps4 locus. The results indicate that a short tract of DNA was transferred relatively recently across an inversion from a t haplotype allele of Hba-ps4 to the corresponding locus on a wild-type homolog leading to the creation of a new hybrid allele. Several classes of wild-type Hba-ps4 alleles, including the most common form in inbred strains, appear to be derived from this hybrid allele. The accumulated data suggest that a common form of genetic exchange across one of the four t-associated inversions is gene conversion at isolated loci that do not play a role in the transmission ratio distortion phenotype required for t haplotype propagation. The implications of the results pose questions concerning the evolutionary stability of gene complexes within large paracentric inversions and suggest that recombinational isolation may be best established for loci residing within a short distance from inversion breakpoints.     

Genetic analysis of the proximal portion of the mouse t complex: evidence for a second inversion within t haplotypes

Genomic sequences derived from the mouse t complex by a microdissection cloning technique have been used as tools to obtain high resolution genetic maps of the wild-type and t haplotype forms of the most proximal portion of chromosome 17. Genetic mapping was performed through a recombinant inbred strain analysis and an analysis of partial t haplotypes. The accumulated data demonstrate the existence of a large inversion of genetic material, encompassing the loci of T and qk, within the proximal portion of t haplotypes. This newly described proximal inversion and the previously described distal inversion provide an explanation for the suppression of recombination observed along the length of t haplotype DNA in heterozygous mice.     

Functional Analysis of Mutations of Murine Chromosome 17 with the Use of Tertiary Trisomy

Analysis of the functional nature of mutations can be based on comparisons of their manifestation in organisms with a deletion or duplication of a particular chromosome segment. With the use of reciprocal translocation T(16;17)43H, it is feasible to produce mice with tertiary trisomy of the proximal region of chromosome 17. The mutations on chromosome 17 we tested included brachyury (T), hairpin tail (Thp), kinky (Fuki), quaking (qk), tufted (tf), as well as tct (t complex tail interaction), and tcl (t complex lethal) that are specific to t haplotypes. The set of dominant and recessive mutations was assigned to two groups: one obligatory, manifesting itself in the phenotype independently of the number of normal alleles in di- and trisomics, and the other facultative, phenotypically manifesting itself depending upon the dosage of mutant alleles. A model was derived from analysis of the interaction of the T and Thp mutations with t haplotypes. It seeks to explain the morphogenetic effects of the mutations observed in mice of different genotypes. The tir gene is postulated to reside on chromosome 17 within its framework. It is suggested that the gene dosage ratio at the tir and tct loci determines tail length.     

Functional analysis of mutations on murine chromosome 17 using tertiary trisomy

Analysis of the functional nature of mutations can be based on their manifestation in organisms with a deletion or a duplication of a particular chromosome segment. With the use of reciprocal translocation T(16;17)43H it is feasible to produce mice with tertiary trisomy for proximal region of chromosome 17. The mutations on chromosome 17 we tested included brachyury (T), hairpin tail (Thp), kinky (Fuki), quaking (qk), tufted (tf), as well as tct (t-complex tail interaction) and tcl (t complex lethal), that are specific for t haplotypes. The set of dominant and recessive mutations was assigned to two groups, one obligatory manifesting itself in the phenotype independently of the number of normal alleles in di- and trisomics, and the other facultative, phenotypically manifesting itself, depending upon the dosage of mutant alleles. A model was derived from analysis of the interaction of the T and Thp mutations with t haplotypes which is to explain the morphogenetic effects of the mutations observed in mice of different genotypes. The tir gene is postulated to reside on chromosome 17 within its framework. It is suggested that the gene dosage ratio at the tir and tct loci determines tail length.     

Haplotypes That Are Mosaic for Wild-Type and T Complex-Specific Alleles in Wild Mice

Two outstanding problems pertaining to the population dynamics and evolution of the t complex in mice concern the frequency of t haplotypes in the wild and the degree to which these haplotypes recombine with their wild-type homologs. To address these problems, the frequency and distribution of several t complex-associated restriction fragment variants in wild mice were estimated. Sixty-four versions of chromosome 17 from wild-derived Mus musculus musculus and Mus musculus domesticus were examined with DNA probes for six loci within the t complex that exhibit restriction fragment variation. All six probes detect variants that have heretofore been found exclusively associated with the t complex. Haplotype analysis of wild-derived chromosomes revealed a high frequency (45.3%) of "mosaic" haplotypes with a mixture of t-specific and wild-type variants and only one haplotype with t-specific variants at all six loci. When 12 well-characterized t haplotypes isolated from diverse geographic regions were analyzed, only three had a complete set of t-specific restriction fragments for the six loci examined. The preponderance of mosaic haplotypes in both groups of mice can be explained by any one of the following hypotheses: genetic recombination between t haplotypes and their wild-type homologs, the persistence in wild populations of haplotypes that have descended from ancestral partial t haplotypes, or that the restriction fragment variants fixed in the ancestral t haplotype were also fixed in some wild-type haplotypes. There is evidence to support all three of these hypotheses in our data. The allelic composition of some mosaic haplotypes indicates that they may have been formed by segmental recombination, either double crossing over or gene conversion, rather than by simple single crossovers. The occurrence of indistinguishable mosaic haplotypes in both M. m. musculus and M. m. domesticus suggests that these haplotypes are ancestral rather than recently derived.     

Genetic and Molecular Analysis of the Proximal Region of the Mouse T-Complex Using New Molecular Probes and Partial T-Haplotypes

The t-complex is located on the proximal third of chromosome 17 in the house mouse. Naturally occurring variant forms of the t-complex, known as complete t-haplotypes, are found in wild mouse populations. The t-haplotypes contain at least four nonoverlapping inversions that suppress recombination with the wild-type chromosome, and lock into strong linkage disequilibrium loci affecting normal transmission of the chromosome, male gametogenesis and embryonic development. Partial t-haplotypes derived through rare recombination between t-haplotypes and wild-type homologs have been critical in the analysis of these properties. Utilizing two new DNA probes. Au3 and Au9, and several previously described probes, we have analyzed the genetic structure of several partial t-haplotypes that have arisen in our laboratory, as well as several wild-type chromosomes deleted for loci in this region. With this approach we have been able to further our understanding of the structural and dynamic characteristics of the proximal region of the t-complex. Specifically, we have localized the D17Tul locus as most proximal known in t-haplotypes, achieved a better structural analysis of the partial t-haplotype t6, and defined the structure and lethal gene content of partial t-haplotypes derived from the lethal tw73 haplotype.     

EVOLUTION AT THE MOUSE t COMPLEX: WHY IS THE t HAPLOTYPE PRESERVED AS AN INTEGRAL UNIT?

Abstract Segregation distorters are selfish genetic elements that bias Mendelian segregation in their favor. All well-known segregation distortion systems consist of one or more "distorter" loci that act upon a "responder" locus. At the t complex of the house mouse, segregation distortion is brought about by the harmful effect of t alleles at a number of distorter loci on the wild-type variant of the responder locus. The responder and distorter alleles are closely linked by a number of inversions, thus forming a coherent t haplotype. It has been conjectured that the close integration of the various components into a "complete" t haplotype has been crucial for the evolutionary success of these selfish genetic elements. By means of a population genetical metapopulation model, we show that this intuition may be unfounded. In fact, under most circumstances an "insensitive" t haplotype retaining only the responder did invade and reach a high frequency, despite the fact that this haplotype has a strong segregation disadvantage. For certain population structures, the complete t haplotype was even competitively excluded by partial t haplotypes with lower segregation ratios. Moreover, t haplotypes carrying one or more recessive lethals only prevailed over their nonlethal counterparts if the product of local population size and migration rate ( Nm ) was not much smaller or larger than one. These phenomena occurred for rather realistic fitness, segregation, and recombination values. It is therefore quite puzzling that partial t haplotypes are absent from natural house mousepopulations, and that t haplotypes carrying recessive lethals prevail over nonlethal t haplotypes.     

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.     

Mouse Brachyury the Second (T2) is a gene next to classical T and a candidate gene for tct.

The mouse Brachyury the Second (T2) gene is 15 kb away from classical Brachyury (T). A mutation in T2 disrupts notochord development, pointing to the existence of a second T/t complex gene involved in axis development. T2 encodes a novel protein that is disrupted by an insertion in T2(Bob) mice. Sequence analysis of T2 from several t haplotypes shows that they all share the same changed stop codon, and, thus, T2 is a candidate gene for the t complex tail interaction factor. T1, T2, and the unlinked t-int are distinct and unrelated loci, and mutations in these genes do not complement one another genetically. Either their products interact in the same pathway during the genesis of the embryonic axis, or the T/t region itself is truly complex.     

Phylogenetic analysis of the alpha-globin pseudogene-4 (Hba-ps4) locus in the house mouse species complex reveals a stepwise evolution of t haplotypes [published erratum appears in Mol Biol Evol 1994 Jan;11(1):158]

A parsimony analysis was performed on restriction sites at the Hba-ps4 pseudogene locus within one of four inversions associated with mouse t haplotypes. The results suggest that all t haplotypes form a monophyletic group and that the in (17)4 inversion originated before the radiation of the Mus musculus species complex but after the divergence of the lineages leading to M. spretus, M. abbotti, and M. hortulanus. A time frame based on the evolutionary rate of mouse pseudogenes places the origin of this t haplotype inversion at 1.5 Mya, or approximately 1.5 Myr after the origin of the more proximal t complex inversion, in (17)2. The accumulated evidence indicates that complete t haplotypes have been assembled in a stepwise manner, with each of these inversions occurring on separate chromosomal lineages and at different evolutionary times. In addition, the evolutionary relationships of pseudogene sequences resulting from genetic exchange between wild-type and t haplotype alleles were examined. Analysis of sequences from the 5' and 3' sides of a putative site of recombination resulted in cladograms with different topologies. The implications for hypotheses concerning the evolutionary forces acting on t haplotypes and their rapid propagation throughout worldwide populations of mice are discussed.      

Characterization of novel partial t-haplotypes tM1, tM2, tM3, tM4]

The results of genetic analysis of the effects of four novel partial mouse TM-haplotypes are presented in this work. Fertility and viability of tM/tM homozygotes and tM/t6 compounds, transmission ratio distortion (trd) in males heterozygous for tM, suppression of recombination and taillessness effects were studied. Three novel t-haplotypes tM1,2,4 are viable and heterozygous for these haplotypes males T/tM show low trd (20-30%). Comparison of these data and the t6-haplotype structure suggests that the tM1,2,4-haplotypes were derived as a result of recombination events in the non-inverted T-complex fragment located between two inversions. The tM3-haplotype is semilethal and heterozygous T/tM3 males show the trd equal to that of t6-heterozygotes. Homozygous tM3/tM3 and tM3/t6 male compounds are fertile or subfertile. Potential recombination ways of derivation of tM3 are discussed.     

Gene mapping within the T/t complex of the mouse. II. Anomalous position of the H-2 complex in t haplotypes

Naturally occurring t haplotypes are chromosome 17 polymorphisms that suppress genetic recombination in t/+ heterozygotes over a long distance that includes the H-2 complex. There is strong linkage disequilibrium between t haplotypes and H-2 haplotypes; over 20 independently isolated t chromosomes representing eight different complementation groups share only four H-2 haplotypes. Thus t haplotypes and their associated H-2 loci are inherited en bloc as a “supergene” complex, whose frequency is driven in wild mouse populations by their high transmission from male t heterozygotes. This phenomenon must therefore serve as an important regulator of H-2 polymorphisms. Genes within the region of recombination suppression in t haplotypes have been mapped by crossing-over that occurs readily between two different t haplo-types situated in trans, and by this means we show here that the H-2 complex occupies an anomalous position in t haplotypes, mapping proximal to the locus of tf closely flanked by t-lethal mutations.     

Genetic mapping of the locus controlling structural variations of murine C3 in the chromosome 17.

Backcross progeny, (NC X TF/GnLe)F1 X TF/GnLe, was tested for C3 allotype controlled by C3-1 and the expression of mutant gene tf, repeated loss and regrowth of hair. The recombination frequency between these two loci both located in chromosome 17 of the mouse was 24%. Taken together with our previous linkage data, C3-1 is now localized to a position 11 cm more distal than H-2 on chromosome 17.     

Genetic Analysis of a Mouse t Complex Locus That Is Homologous to a Kidney Cdna Clone

A mouse kidney cDNA clone, pMK174, identifies restriction fragment length polymorphisms (RFLPs) that map to two unlinked loci. One, designated D17Rp17, has been mapped near quaking, (qk), on chromosome 17 using three sets of recombinant inbred (RI) strains. A study of several t haplotypes resulted in the identification of t-specific alleles of D17Rp17 that map to the proximal half of the t complex. Neither t-specific nor wild-type D17Rp17 alleles are present in chromosomes carrying either the T Orleans (TtOrl) or the T hairpin tail (Thp) deletions. Comparison with other molecular markers indicates that pMK174 identifies a new proximal t complex locus, Rp17. The second locus identified by pMK174, termed D4Rp18, is tentatively assigned to chromosome 4 by mouse-Chinese hamster somatic cell hybrid analysis.     

Nonhomologous Pairing in Mice Heterozygous for a t Haplotype Can Produce Recombinant Chromosomes with Duplications and Deletions

We have investigated the structure and properties of a chromosomal product recovered from a rare recombination event between a t haplotype and a wild-type form of mouse chromosome 17. Our embryological and molecular studies indicate that this chromosome (twLub2) is characterized by both a deletion and duplication of adjacent genetic material. The deletion appears to be responsible for a dominant lethal maternal effect and a recessive embryonic lethality. The duplication provides an explanation for the twLub2 suppression of the dominant T locus phenotype. A reanalysis of previously described results with another chromosome 17 variant called TtOrl indicates a structure for this chromosome that is reciprocal to that observed for twLub2. We have postulated the existence of an inversion over the proximal portion of all complete t haplotypes in order to explain the generation of the partial t haplotypes twLub2 and TtOrl. This proximal inversion and the previously described distal inversion are sufficient to account for all of the recombination properties that are characteristic of complete t haplotypes. The structures determined for twLub2 and TtOrl indicate that rare recombination can occur between nonequivalent genomic sequences within the inverted proximal t region when wild-type and t chromosomes are paired in a linear, nonhomologous configuration.