A high-resolution genetic map of mouse Chromosome 15 encompassing the Dominant megacolon (Dom) locus

Dominant megacolon (Dom) is one of four mutations in the mouse that can produce a phenotype similar to Hirschsprung disease in human. The Dom gene product is not known, and no candidate region has been defined for a possible human homolog. In this publication we report mapping the Dom locus with high definition, using several intra- and interspecific crosses and a set of 16 Chr 15-specific microsatellites flanking this locus.     

The genetic map around the tail kinks (tk) locus on mouse Chromosome 9

Tail kinks (tk) is a classical mouse skeletal mutation, located on Chromosome (Chr) 9. As the first step for the positional cloning of the tk gene, we have established a genetic map of a region surrounding the tk locus by generating a backcross segregating for tk. From this backcross, 1004 progeny were analyzed for the coat-color phenotype of the proximally located dilute (d) gene and for the distally flanking microsatellite marker, D9Mit12. Fifty-six recombinants between d and tk and 75 recombinants between tk and D9Mit12 were identified, completing a panel of 130 recombinants including one double recombinant. This panel allowed us to map five microsatellite loci as well as d and Mod-1 with respect to tk. We show that one of the microsatellite markers mapped, D9Mit9, does not recombine at all with tk in our backcross. This indicates that the D9Mit9 locus will serve as a good starting point for a chromosomal walk to the tk gene.     

The locus Om,responsible for the DDK syndrome,maps close to Sigje on mouse Chromosome 11

The DDK inbred strain of mouse has a striking particularity: when DDK females are crossed to males of other strains they exhibit a reduced fertility, whereas the reciprocal crosses (non-DDK females x DDK males) are fertile (Wakasugi et al. 1967; Wakasugi 1973). The low fertility results from an early embryonic lethality, the F₁ embryos dying near the late morula-early blastocyst stage. Genetic analyses (Wakasugi 1974) and nuclear and cytoplasmic transfers (Renard and Babinet 1986; Babinet et al. 1990; Mann 1986), have shown that the failure of the embryos to develop is due to an incompatibility between a DDK maternally encoded cytoplasmic product and the non-DDK paternal genome. In order to elucidate the genetic determinism of this embryonic lethality, we have analyzed the fertility of male progeny from a backcross BALB/c females x (BALB/c x DDK)F₁ males and that of males from a set of recombinant inbred (RI) strains, established from DDK and BALB/c progenitors, when mated with DDK females. Our results indicate that a single locus, Om, is responsible for the DDK syndrome and is located on Chromosome (Chr) 11, very close to the Sigje locus.     

Mapping around the Fused locus on mouse Chromosome 17

We have established a high-resolution genetic map of the region surrounding the Fused locus as a first step towards the molecular identification and analysis of this gene. The candidate region has been covered to a large extent by YAC and P1 contigs, and has been partly characterized by pulsed-field gel analysis.     

A 2-Mb YAC/BAC-based physical map of the ovum mutant (Om) locus region on mouse chromosome 11

The embryonic lethal phenotype observed when DDK females are crossed with males from other strains results from a deleterious interaction between the egg cytoplasm and the paternal pronucleus soon after fertilization. We have previously mapped the Om locus responsible for this phenotype, called the DDK syndrome, to an approximately 2-cM region of chromosome 11. Here, we report the generation of a physical map of 28 yeast and bacterial artificial chromosome clones encompassing the entire genetic interval containing the Om locus. This contig, spanning approximately 2 Mb, was used to map precisely genes and genetic markers of the region. We determined the maximum physical interval for Om to be 1400 kb. In addition, 11 members of the Scya gene family were found to be organized into two clusters at the borders of the Om region. Two other genes (Rad51l3 and Schlafen 2) and one EST (D11Wsu78e) were also mapped in the Om region. This integrated map provides support for the identification of additional candidate genes for the DDK syndrome.     

A high-resolution genetic map around waltzer on mouse Chromosome 10 and identification of a new allele of waltzer

A new autosomal recessive mouse mutation characterized by deafness and circling behavior was recovered during mutagenesis experiments with chlorambucil (CHL). On the basis of allelism tests and linkage analyses, this mutation appears to represent a new allele of waltzer (v) that maps to mouse Chromosome (Chr) 10. We have designated this new allele, Albany waltzer (v ^Alb ). A high-resolution map of the region around v was constructed from data from two intersubspecific backcrosses involving Mus musculus castaneus. The analysis of 648 backcross mice has allowed v ^Alb to be localized 1.1 ± 0.4 cM distal to D10Mit60 and 0.2 ± 0.2 cM proximal to a cluster of four markers, D10Mit172, D10Mit112, D10Mit48, and D10Mit196. An independent backcross was used to confirm the map order and distances in the v ^Alb backcross. The two linkage maps were consistent, indicating that the lesion in v ^Alb , which is presumed to be a deletion based on the known action of CHL, is small and has not significantly altered the map at this level of detection. Additionally, three genes (Ros1, Grik2, and Zfa) were eliminated as possible candidates for v ^Alb , and several SSLP markers were separated genetically. Received: 3 July 1996 / Accepted: 13 August 1996     

High-resolution genetic map and YAC contig around the mouse neurological locus reeler

Mutations at the recessive reeler locus (rl) on mouse Chromosome (Chr) 5 result in abnormal development of multiple central nervous system components, including the cerebral and cerebellar cortices. These abnormalities are characterized by highly disorganized laminar structures thought to have arisen from a post-migration failure of neuronal organization events that are probably mediated through cell-cell interactions. As a result of a mutagenesis scheme designed to generate visible recessive mutations induced by the drug chlorambucil, we had previously recovered a new allele of the reeler locus (rl ^Alb ) that is likely to involve a deletion based on the known mechanisms of chlorambucil action. We have constructed a high-resolution genetic map from two intercrosses segregating this allele. Our first cross, in which the mutation was outcrossed to the 101 strain prior to intercrossing, consisted of 196 meioses and resulted in the positioning of four loci proximal to rl, with D5Mit1 being the closest (2.6±1.1 cM). The second cross consisted of intercrossing rl heterozygotes derived from an outcross to the C57BL/6 strain. A total of 318 mice (636 meioses) gave rise to a panel of 41 recombinants, which were used to map a total of 14 loci within a 6.4-cM interval bounded by D5Mit1 and the En-2 gene. A yeast artificial chromosome contig consisting of clones containing two of these loci, D5Mit72 (located 0.31 cM distal to rl), and D5Mit61 (no recombinants with rl), has been assembled and is being used to locate the rl gene.     

A high-resolution linkage map of the lethal spotting locus: a mouse model for Hirschsprung disease

Mice homozygous for the lethal spotting (ls) mutation exhibit aganglionic megacolon and a white spotted coat owing to a lack of neural crest-derived enteric ganglia and melanocytes. The ls mutation disrupts the migration, differentiation, or survival of these neural crest lineages during mammalian development. A human congenital disorder, Hirschsprung disease (HSCR), is also characterized by aganglionic megacolon of the distal bowel and can be accompanied by hypopigmentation of the skin. HSCR has been attrrbuted to multiple loci acting independently or in combination. The ls mouse serves as one animal model for HSCR, and the ls gene may represent one of the loci responsible for some cases of HSCR in humans. This study uses 753 N₂ progeny from a combination of three intersubspecific backcrosses to define the molecular genetic linkage map of the ls region and to provide resources necessary for positional cloning. Similar to some cases of HSCR, the ls mutation acts semidominantly, its phenotypic effects dependent upon the presence of modifier genes segregating in the crosses. We have now localized the ls mutation to a 0.8-cM region between the D2Mit113 and D2Mit73/D2Mit174 loci. Three genes, endothelin-3 (Edn3), guanine nucleotide-binding protein -stimulating polypeptide 1 (Gnas), and phosphoenolpyruvate carboxykinase (Pck1) were assessed as candidates for the ls mutation. Only Edn3 and Gnas did not recombine with the ls mutation. Mutational analysis of the Edn3 and Gnas genes will determine whether either gene is responsible for the neural crest deficiencies observed in ls/ls mice.Both authors contributed equally to this research.     

Heritability of the maternal meiotic drive system linked to Om and high-resolution mapping of the Responder locus in mouse

Matings between (C57BL/6 x DDK)F(1) females and C57BL/6 males result in a significant excess of offspring inheriting maternal DDK alleles in the central region of mouse chromosome 11 due to meiotic drive at the second meiotic division. We have shown previously that the locus subject to selection is in the vicinity of D11Mit66, a marker closely linked to the Om locus that controls the preimplantation embryo-lethal phenotype known as the "DDK syndrome." We have also shown that observation of meiotic drive in this system depends upon the genotype of the sire. Here we show that females that are heterozygous at Om retain the meiotic drive phenotype and define a 0.32-cM candidate interval for the Responder locus in this drive system. In addition, analysis of the inheritance of alleles at Om among the offspring of F(1) intercrosses indicates that the effect of the sire is determined by the sperm genotype at Om or a locus linked to Om.     

Low resolution mapping around the flavivirus resistance locus (Flv) on mouse Chromosome 5

Although the phenomenon of innate resistance to flaviviruses in mice was recognized many years ago, it was only recently that the genetic locus (Flv) controlling this resistance was mapped to mouse Chromosome (Chr) 5. Here we report the fine mapping of the Flv locus, using 12 microsatellite markers which have recently been developed for mouse Chr 5. The new markers were genotyped in 325 backcross mice of both (C3H/HeJxC3H/ RV)F₁xC3H/HeJ and (BALB/cxC3H/RV)F₁xBALB/c backgrounds, relative to Flv. The composite genetic map that has been constructed identifies three novel microsatellite loci, D5Mit68, D5Mit159, and D5Mit242, tightly linked to the Flv locus. One of those loci, D5Mit159, showed no recombinations with Flv in any of the backcross mice analyzed, indicating tight linkage (<0.3 cM). The other two, D5Mit68 and D5Mit242, exhibited two and one recombinations with Flv (0.6 and 0.3 cM) respectively, defining the proximal and distal boundaries of a 0.9-cM segment around this locus. The proximal flanking marker, D5Mit68, maps to a segment on mouse Chr 5 homologous to human Chr 4. This, together with the previous data produced by our group, locates Flv to a region on mouse Chr 5 carrying segments that are conserved on either human Chr 4, 12, or 7, but present knowledge does not allow precise identification of the syntenic element.     

A locus for radiation-induced gastroschisis on mouse Chromosome 7

Gastroschisis (abdominal wall defects) occurs with a high frequency in the mouse inbred strain HLG compared with C57BL/6J mice. The risk of gastroschisis increases significantly after exposure to irradiation with X-rays during preimplantation development and follows a recessive mode of inheritance for the HLG susceptibility alleles. We have used a backcross strategy and genome-wide microsatellite typing to chromosomally map this trait. A suggestive linkage for a locus responsible for radiation-induced gastroschisis (Rigs1) was found in a region of mouse Chromosome 7. Received: 13 May 1998 / Accepted: 6 August 1998     

A high-resolution map of the brown (b,Tyrp1) deletion complex of mouse Chromosome 4

For over 40 years germ-cell mutagenesis experiments have generated many new mutations at the brown (b or Tyrp1) locus on mouse Chromosome (Chr) 4. These mutations, many of which are deletions, were recovered by the specific-locus mutagenesis technique. Previous analysis of a panel of brown deletions, generated at Oak Ridge, has enabled both a preliminary molecular and a functional map around the locus to be generated. We have used a panel of hybrid DNA from 25 Oak Ridge deletions, where the deleted chromosome was heterozygous with a Mus spretus chromosome, to map polymorphic markers including microclones, microsatellites, and cloned DNA markers. We have generated a fine structure map, based on 25 new markers, of an 8.5-cM region surrounding the brown locus. This map will prove useful in future mapping studies of this region and in the isolation of the genes that lie within it.     

Meiotic drive at the Om locus in wild-derived inbred mouse strains

Meiotic drive is an evolutionary force in which natural selection is uncoupled from organismal fitness. Recently, it has been proposed that meiotic drive and genetic drift represent major forces in the evolution of the mammalian karyotype. Meiotic drive involves two types of genetic elements, Responders and Distorters , the latter being required to induce transmission ratio distortion at the former. We have previously described the Om meiotic drive system in mouse chromosome 11. To investigate the natural history of this drive system we have characterized the alleles present at the distorter in wild-derived inbred strains. Our analysis of transmission of maternal alleles in both classical and wild-derived inbred strains indicated that driving alleles are found at high frequency in natural populations and that the existence of driving alleles predates the split between the Mus spicilegus and M. musculus lineages.  © 2005 The Linnean Society of London, Biological Journal of the Linnean Society , 2005, 84 , 487–492.     

A genetic and physical map of bovine Chromosome 11

A genetic map of bovine Chromosome (Chr) 11 (BTA11, synteny group U16) has been constructed from 330 animals belonging to 21 families, which constitute the international bovine reference panel (IBRP). This map is based on 13 polymorphic microsatellite markers, two of which were chosen in previously published maps. Three markers have been isolated from cosmids. Two of the three cosmids have been physically localized by fluorescence in situ hybridization (FISH), to anchor the genetic map on the chromosome. In addition, a biallelic polymorphism in the -lactoglobulin gene (LGB) has been genetically positioned relative to the microsatellite markers. The most probable order of the markers is: cen-INRA044-BM716-INRA177-(TGLA 327, INRA198, INRA131)-INRA111-INRABERN169-(INRA115, INRA032)-INRA108-INRABERN162-INRA195-LGB. T The total linkage group spans 126 cM, which probably corresponds to most of the chromosome length. The average intermarker distance is about 10.5 cM, allowing the potential detection of a genetic linkage with any Economic Trait Loci (ETL) of this chromosome.     

A multipoint linkage map around the locus for myotonic dystrophy on chromosome 19

Employing 16 polymorphic DNA markers as well as the chromosome 19 centromere heteromorphism, we have performed a genetic linkage study in 26 families with myotonic dystrophy. Fourteen of these markers had been assigned previously to one of five different intervals of the 19cen-19q13.2 segment by using somatic cell hybrids. For the long arm of chromosome 19, a genetic map that encompasses 9 polymorphic markers and the DM gene has been constructed. Our studies indicate that the DM and CKMM genes map distal to the ApoC2-ApoE gene cluster and to the anonymous polymorphic markers D19S15 and D19S16, but proximal to the D19S22 marker. The orientation of DM and CKMM remains to be determined.     

Genetic map of the region surrounding the retrovirus restriction locus,Fv1, on mouse Chromosome 4

The Friend virus susceptibility-1 (Fvl) gene maps to mouse Chromosome (Chr) 4 close to a cluster of four endogenous murine leukemia viruses (MLVs). To investigate the feasibility of cloning Fvl by a positional approach, we have performed an extensive genetic analysis of this region of Chr 4. We have typed 368 backeross mice for the four proviruses, Nppa, Lck, and D4Smh6b. Recombinant animals were screened in a hierarchical fashion with a variety of other markers, including Fvl and the isozyme marker Gpd1. A detailed genetic map of the region surrounding Fvl was derived. Three markers, Xmv9, Nppa, and Iap3rc11, were identified that showed no recombination with Fvl. By combining backcross and recombinant inbred strain data, we estimated that Xmv9 and Nppa must lie within 0.6 cM of one another and Fvl.