Genetic mapping of the mouse X chromosome in the region homologous to human Xq27–Xq28

The four loci Gabra3, DXPas8, CamL1, and Bpa, located near the murine X-linked visual pigment gene (Rsup), have been ordered using 248 backcross progeny from an interspecific mating of (B6CBA-A^w-J/A-Bpa) and Mus spretus. One hundred twenty backcross progeny have been analyzed at seven anchor loci spanning the X chromosome and form a regional mapping panel. An additional 128 progeny have been screened for recombination events between Cf-9 and Dmd. Eighteen recombinants between these loci have been detected in the 248 animals; all of the recombinants were screened at the other anchor loci to identify any double crossovers. Pedigree analysis using these recombinants strongly favors a gene order of (Cf-9)-Gabra3-(DXPas8, Bpa)-CamL1-(Rsvp, P3, Cf-8)-Dmd for the loci studied. Synteny with human Xq27–Xq28 is retained, although the relative order of some loci may differ between the two species.     

Genetic mapping on the mouse X chromosome of human cDNA clones for the fragile X and Hunter syndromes.

Murine X-linked genes corresponding to the human Fragile X (FMR1) and Hunter syndrome (IDS) loci have been mapped in an interspecific backcross between B6CBA-Aw-J/A-Bpa and Mus spretus using human cDNA clones. Pedigree analysis of recombinants from a total of 248 backcross progeny favors a gene order of (Cf-9, Mcf-2)-(Fmr-1)-Ids-Gabra3-Rsvp. Gene order is conserved between the species, although no fragile site has been detected in the mouse in this region of the murine X chromosome.     

Extension of the physical map in the region of the mouse X chromosome homologous to human Xq28 and identification of an exception to conserved linkage.

We have extended our pulsed-field gel map of the region of the mouse X chromosome homologous to human Xq28 to include the loci Gdx (DXS254Eh), P3 (DXS253Eh), G6pd, Cf-8, and F8a. Gdx, P3, and G6pd are demonstrated to be physically linked to the X-linked visual pigment locus (Rsvp) within a maximal distance of 340 kb, while G6pd and Cf-8 are approximately 900 kb apart. These studies favor a gene order of cen-Rsvp-Gdx-P3-G6pd-(Cf-8)-tel and extend the physical map of this region to 5 million bp. In conjunction with previous physical mapping studies in both mouse and human, the results suggest conserved linkage for loci in this region of the mouse X chromosome and human Xq28. However, employing pulsed-field gel electrophoresis and genetic pedigree analysis of interspecific backcross progeny, we have found close linkage of a clone encoding a mouse homolog for human factor VIII-associated gene A (F8A) to DXPas8, thus revealing the first exception to conserved gene order between murine and human loci in the region.     

Physical mapping of the loci Gabra3, DXPas8, CamL1, and Rsvp in a region of the mouse X chromosome homologous to human Xq28.

Using pulsed-field gel electrophoresis, a 3 million-bp physical map containing the X-linked loci Gabra3, DXPas8, CamL1, and Rsvp has been constructed for a segment of the mouse X chromosome homologous to human Xq28. Detailed mapping was performed using single and double digestions with rare-cutter restriction enzymes. Gabra3 and DXPas8 have been shown to be physically linked within a maximal distance of 1600 kb, DXPas8 and CamL1 within 750 kb, and CamL1 and Rsvp within 450 kb. In addition, several CpG islands have been detected in the region encompassing CamL1 and Rsvp. These studies confirm a gene order of cen-Gabra3-DXPas8-CamL1-Rsvp-tel determined by genetic mapping in interspecific backcrosses (A.S. Ryder-Cook et al., 1988, EMBO J. 7: 3017-3021; G.E. Herman et al., 1991, Genomics 9: 670-677). Physical distances for the loci studied agree with the calculated genetic distances. Assuming that there is conserved linkage between man and mouse in the region, the physical mapping data presented here may help to clarify the uncertain gene order for some human Xq28 loci.     

Close linkage of the murine locus bare patches to the X-linked visual pigment gene: implications for mapping human X-linked dominant chondrodysplasia punctata

The murine X-linked dominant mutation bare patches (Bpa) has a phenotype similar to and is likely homologous to human X-linked dominant chondrodysplasia punctata (CDPX2). Classic two-point linkage analysis in the mouse with distant markers suggested that Bpa maps near glucose-6-phosphate dehydrogenase (G6pd). We have confirmed the regional localization using interspecific matings with Mus spretus. We have also detected a restriction fragment length polymorphism (RFLP) at the murine X-linked visual pigment (Rsvp) locus in inbred Bpa females using the restriction enzyme PstI. Cumulative data from segregation of alleles using the PstI RFLP and analysis of interspecific backcross progeny at the Rsvp locus suggest that Bpa is tightly linked to Rsvp. Thus, the human CDPX2 gene probably maps within Xq27-Xq28 and not within Xp22.3-Xpter, where deletions associated with X-linked recessive chondrodysplasia punctata (CDPX) have been noted. This strategy should be applicable to the fine mapping of other dominant murine mutations.     

Multilocus molecular mapping of the mouse X chromosome

Using restriction fragment length polymorphisms (RFLPs) and enzymatic variants between distantly related mouse species, we have assigned three genes to the mouse X chromosome and concurrently mapped a total of eight genes spanning an estimated 50 cM of the chromosome. Segregation of RFLPs in over 200 male progeny from interspecies backcrosses between the inbred strain C57BL/6JRos and either wild-derived Mus musculus or Mus spretus was followed for the murine genes Timp (tissue inhibitor of metalloproteinases), Cf-8 (coagulation factor VIII), and Rsvp (red-sensitive visual pigment) and the known X-linked markers Otc, Hprt, Cf-9, G6pd, and Ags. From the centromere, the gene order was defined as Otc, Timp, Hprt, Cf-9, (Cf-8/Rsvp/G6pd), Ags, by minimizing the number of multiple recombinational events. No significant differences in map order or frequency of recombination were observed between the two backcross series studied. The use of Southern analysis has allowed us to add new genes to the map in a cumulative manner, and as probes become available, additional markers can be mapped, using the same set of mice, by utilizing existing blots or resampling the DNAs. The use of probes for functional genes has allowed us to directly compare the X chromosomes of mouse and man and has provided insight into chromosomal rearrangements which have occurred during the evolutionary divergence of these species, as well as to define the extent of linkage homologies.     

Identification of amplified restriction fragment polymorphism (AFLP) markers tightly linked to the tomato Cf-9 gene for resistance to Cladosporium fulvum

Using the technique of amplified restriction fragment polymorphism (AFLP) analysis, and bulked segregant pools from F₂ progeny of the cross Lycopersicon esculentum (Cf9)× L. pennellii , approximately 42 000 AFLP loci for tight linkage to the tomato Cf-9 gene for resistance to Cladosporium fulvum have been screened. Analysis of F₂ recombinants identified three markers which co-segregated with Cf-9 . The Cf-9 gene has recently been isolated by transposon tagging using the maize transposon Dissociation ( Ds ). Analysis of plasmid clones containing Cf-9 shows that two of these markers are located on opposite sides of the gene separated by 15.5 kbp of intervening DNA. AFLP analysis provides a rapid and efficient technique for detecting large numbers of DNA markers and should expedite plant gene isolation by positional cloning and the construction of high-density molecular linkage maps of plant genomes.     

Mapping of the glycine receptor alpha 2-subunit gene and the GABAA alpha 3-subunit gene on the mouse X chromosome.

We have mapped the gene for the alpha 2-subunit of the inhibitory glycine receptor (Glra2) to the telomeric end of the mouse X chromosome by backcross analysis of a Mus musculus/Mus spretus interspecific cross. In addition, we have extended the mapping of the GABAA alpha 3-subunit receptor gene (Gabra3). A deduced gene order of cen-Cybb-Hprt-DXPas6-Gabra3-Rsvp-Gdx/Cf-8- Dmd-Pgk-1-DXPas2-Plp-DXPas1-Glra2-tel places Gabra3 proximal to the visual pigment gene Rsvp and Glra2 in the region of loci for hypophosphatemia (Hyp), steroid sulfatase (Sts), and the E1 alpha-subunit of pyruvate dehydrogenase (Pdha1). This establishes the XF region of the mouse X chromosome as homologous with the Xp22.1-p22.3 region of the human X chromosome and indicates the presence of an evolutionary breakpoint in the region of Xp21.3.     

Mapping of FMR1, the gene implicated in fragile X-linked mental retardation, on the mouse X chromosome

A genetic map of the Cf-9 to Dmd region of the mouse X chromosome has been established by typing 100 offspring from a Mus musculus x Mus spretus interspecific backcross for the four loci Cf-9, Cdr, Gabra3, and Dmd. The following order and genetic distances in centimorgans were determined: (Cf-9)-2.4 +/- 1.7-(Cdr)-2.0 +/- 1.4-(Gabra3)-4.1 +/- 2.0-(Dmd). Six backcross offspring carrying X chromosomes with recombination events in the Cdr-Dmd region were identified. These recombination events were used to define the position of Fmr-1, the murine homologue of FMR1, which is the gene implicated in the fragile X syndrome in man, and that of DXS296h, the murine homologue of DXS296. Both Fmr-1 and DXS296h were mapped into the same recombination interval as Gabra3 on the mouse X chromosome. These findings provide strong support for the concept that the order of loci lying in the Cf-9 to Gabra3 segment of the X chromosome is highly conserved between human and mouse.     

Efficient linkage of 10 loci in the proximal region of the mouse X chromosome

Interspecific Mus species crosses were used to construct a multilocus genetic map of the mouse X chromosome that extends for more than 50 cM. In these studies, we established the segregation of eight loci in more than 200 backcross progeny from crosses of M. musculus and M. spretus with a common inbred strain (C57BL/6JRos). Genetic divergence at the level of the nucleotide sequences makes these crosses a useful cumulative genetic resource for mapping additional genes defined by genomic or cDNA probes in a highly efficient manner. We have therefore devised a mapping strategy that uses a subset of these backcrosses that are recombinant between successive anchor loci to both localize and order an additional set of six genes without necessarily resorting to an analysis of the entire backcross series. Using this approach, we have defined the linkage of cytochrome b245 beta-chain (Cybb), synapsin (Syn-1), and two members of the X-linked lymphocyte-regulated gene family (Xlr-1, Xlr-2), as well as DXSmh141 and DXSmh172, two loci defined by random genomic probes. All six loci have been localized to the proximal portion of the mouse X chromosome and their order has been defined as Cybb, Otc, Syn-1/Timp, DXSmh141/Xlr-1, DXSmh172, Hprt, Xlr-2, Cf-9. Gene order was established by minimizing multiple recombination events across the region spanning an estimated 20 cM of the proximal X chromosome. The possible significance of the Xlr loci is discussed with respect to other X-chromosome loci that regulate the immune response.     

Genetic mapping of the X-linked dominant mutations striated (Str) and bare patches (Bpa) to a 600-kb region of the mouse X Chromosome: implications for mapping human disorders in Xq28

Striated (Str) and bare patches (Bpa) are X-irradiation-induced, X-linked dominant mouse mutations that are lethal prenatally in hemizygous males. To map the Str mutation, we generated a backcross involving Mus castaneus. Pedigree analysis of 193 affected female and normal male progeny from the cross places Str extremely close to DXMIT1 and favors a gene order of (Cf-9)-Ids-Gabra3-DXS1104h-(Str, DXMIT1)-F8a-DXPas8-DXBay6-DXMIT6 for the loci studied. This region of the mouse X Chromosome (Chr) is syntenic with proximal human Xq28. Based on the mode of inheritance and clinical phenotype, Str may be a homolog of human familial incontinentia pigmenti (IP2). Further refinement of our genetic mapping of bare patches positions that locus between DXS1104h and DXPas8 in the same region as Str, raising the possibility that Bpa and Str may be allelic or are due to mutations in overlapping contiguous genes.     

Linkage of a gene for neural cell adhesion molecule, L1 (CamL1) to the Rsvp region of the mouse X chromosome

L1 is a glycoprotein with an apparent molecular weight of 200 kDa in the developing fetus and adult central nervous system. In the peripheral nervous system, it has a molecular weight of 230 kDa. The L1 protein appears to be encoded by a single gene that has been located on the human X chromosome by in situ hybridization. In this paper we describe restriction variation in genomic DNA Southern analysis between Mus species for the K13 cDNA probe for the L1 neural cell adhesion molecule. We have designated the locus described by this variation as cell adhesion molecule L1, CamL1. The X chromosome linkage and the relative position on the X chromosome coincident with the genes Rsvp/G6pd/Cf-8 were defined in backcross matings involving M. spretus and M. musculus.     

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.     

Determination of a molecular map position for Hyp using a new interspecific backcross produced by in vitro fertilization.

We have established a Mus spretus/Mus musculus domesticus interspecific backcross segregating for two X-linked mutant genes, Ta and Hyp, using in vitro fertilization. The haplotype of the recombinant X chromosome of each of 241 backcross progeny has been established using the X-linked anchor loci Otc, Hprt, Dmd, Pgk-1, and Amg and the additional probes DXSmh43 and Cbx-rs1. The Hyp locus (putative homologue of the human disease gene hypophosphatemic rickets, HYP) has been incorporated into the molecular genetic map of the X chromosome. We show that the most likely gene order in the distal portion of the mouse X chromosome is Pgk-1-DXSmh43-Hyp-Cbx-rs1-Amg, from proximal to distal. The distance in centimorgans (mean +/- SE) between DXSmh43 and Hyp was 2.52 +/- 1.4 and that between Hyp and Cbx-rs1 was 1.98 +/- 1.39. Thus closely linked flanking markers for the Hyp locus that will facilitate the molecular characterization of the gene itself have been defined.     

Localization of the di gene in the fourth linkage group in Rattus norvegicus rats

Based on the backcross progeny analysis of rats Rattus norvegicus matings (August X Brattleboro)F1 X Brattleboro, the gene di has been localized in the fourth linkage group at a distance of 26.8 +/- 1.7 cM from the non-agouti loci and 11.4 +/- 4.7 cM from the Svp-1 loci. The gene order proposed is a--Svp-1--di.     

Linkage analysis of the murine Hyal-1 locus on chromosome 9

We have recently described a new locus, Hyal-1, which determines hyaluronidase variants in mouse serum. On the basis of segregation in recombinant inbred and congenic strains, Hyal-1 was tentatively assigned to chromosome 9 (Fiszer-Szafarz and De Maeyer, '89). In the present study we have performed a linkage analysis of Hyal-1 using 156 backcross progeny of an interspecies cross of laboratory mice and Mus Spretus. Linkage was tested to two anchor loci on chromosome 9: d (dilute, a coat color locus) and Bgl-s (a locus controlling beta-galactosidase activity). The gene order (from centromere) with intervening percentage recombination is d-16.6 (+/- 2.9)-Hyal-1-10.9 (+/- 2.4)-Bgl-s, indicating close linkage to H-7 and Fv-2.     

Genetic maps of mouse chromosome 17 including 12 new anonymous DNA loci and 25 anchor loci.

An interspecific backcross between lab mice and Mus spretus was used to construct a multilocus map of Chromosome 17 consisting of 12 new anonymous loci and 9 anchor loci. In addition, 7 anonymous DNA loci were added to the Chr 17 map for the BXD strains. Although we were able to identify readily the most likely gene order in the interspecific backcross, we found no evidence for an unambiguous gene order using the BXD recombinant inbred strains. Comparison of the interspecific backcross map and the BXD RI strain map revealed evidence in the interspecific backcross for a longer total genetic length, enhanced recombination distal to H-2, a segment showing suppressed recombination, and strong interference.     

Exclusion of Sox9 as a candidate for the mouse mutant Tail-short

The Sry-related gene Sox9 has been proposed as the gene responsible for the mouse skeletal mutant Tail-short (Ts), on the basis of its expression in skeletogenic mesenchymal condensations in the mouse embryo and its chromosomal location in the region of Ts on distal Chromosome (Chr) 11. We present here detailed mapping of Ts locus relative to the Sox9, using an intersubspecific cross. Among 521 backcross progeny, 16 recombinants were detected between Sox9 and Ts, suggesting a separation of 3.5 ± 0.01 cM, and excluding Sox9 as a candidate for Ts. A further nine recombinants were detected between Ts and the polycomb-like gene M33, suggesting that these loci are separated by 1.8 ± 0.011 cM. Six microsatellite markers were co-localized to the Ts locus, providing reagents for positional cloning of Ts. Received: 13 December 1995 / Accepted: 3 March 1996     

Genetic variation at the tomato Cf-4/Cf-9 locus induced by EMS mutagenesis and intralocus recombination

The interaction between tomato (Lycopersicon esculentum) and the leaf mold pathogen Cladosporium fulvum is an excellent model for investigating disease resistance gene evolution. The interaction is controlled in a gene-for-gene manner by Cf genes that encode type I transmembrane extracellular leucine-rich repeat glycoproteins that recognize their cognate fungal avirulence (Avr) proteins. Cf-4 from L. hirsutum and Cf-9 from L. pimpinellifolium are located at the same locus on the short arm of tomato chromosome 1 in an array of five paralogs. Molecular analysis has shown that one mechanism for generating sequence variation in Cf genes is intragenic sequence exchange through unequal crossing over or gene conversion. To investigate this we used a facile genetic selection to identify novel haplotypes in the progeny of Cf-4/Cf-9 trans-heterozygotes that lacked Cf-4 and Cf-9. This selection is based on the ability of Avr4 and Avr9 to induce Cf-4- or Cf-9-dependent seedling death. The crossovers were localized to the same intergenic region defining a recombination hotspot in this cross. As part of a structure-function analysis of Cf-9 and Cf-4, nine EMS-induced mutant alleles have been characterized. Most mutations result in single-amino-acid substitutions in their C terminus at residues that are conserved in other Cf proteins.     

A genetic linkage map of rat chromosome 9 with a new locus for variant activity of liver aldehyde oxidase.

A genetic linkage map of rat chromosome 9 consisting of five loci including a new biochemical marker representing a genetic variation of the activity of the liver aldehyde oxidase, (Aox) was constructed. Linkage analysis of the five loci among 92 backcross progeny of (WKS/Iar x IS/Iar)F1 x WKS/Iar revealed significant linkages between these loci. Minimizing crossover frequency resulted in the best gene order: Aox-D9Mit4-Gls-Cryg-Tp53l1. The homologues of the Cryg, Gls, and Aox genes have been mapped on mouse chromosome 1 and human chromosome 2q. The present findings provide further evidence for the conservation of synteny among these regions of rat, mouse, and human chromosomes.