An interspecific backcross linkage map of mouse chromosome 8

We have established a 67-cM molecular genetic linkage map of mouse chromosome 8 by interspecific backcross analysis. Genes that were mapped in this study include Act-6, Aprt, Aprt-ps1, Emv-2, Es-N, Hp, Insr, Mt-1, Plat, Psx-8, Ucp, and Zfp-4. New regions of homology were established between mouse chromosome 8 and human chromosomes 8 and 19. A conserved linkage group was identified between mouse chromosome 8 and human chromosome 16. The map will be useful for establishing linkage of other markers to mouse chromosome 8.     

A molecular genetic linkage map of mouse chromosome 18 reveals extensive linkage conservation with human chromosomes 5 and 18

An interspecific backcross between C57BL/6J and Mus spretus was used to generate a molecular genetic linkage map of mouse chromosome 18 that includes 23 molecular markers and spans approximately 86% of the estimated length of the chromosome. The Apc, Camk2a, D18Fcr1, D18Fcr2, D18Leh1, D18Leh2, Dcc, Emb-rs3, Fgfa, Fim-2/Csfmr, Gnal, Grl-1, Grp, Hk-1rs1, Ii, Kns, Lmnb, Mbp, Mcc, Mtv-38, Palb, Pdgfrb, and Tpl-2 genes were mapped relative to each other in one interspecific backcross. A second interspecific backcross and a centromere-specific DNA satellite probe were used to determine the distance of the most proximal chromosome 18 marker to the centromere. The interspecific map extends the known regions of linkage homology between mouse chromosome 18 and human chromosomes 5 and 18 and identifies a new homology segment with human chromosome 10p. It also provides molecular access to many regions of mouse chromosome 18 for the first time.     

An interspecific linkage map of mouse chromosome 15 positioned with respect to the centromere

We have used an interspecific backcross between C57BL/6J and Mus spretus to derive a molecular genetic linkage map of chromosome 15 that includes 25 molecular markers and spans 93% of the estimated length of chromosome 15. Using a second interspecific backcross that was analyzed with a centromere-specific marker, we were also able to position our map with respect to the chromosome 15 centromere. This map provides molecular access to many discrete regions on chromosome 15, thus providing a framework for establishing relationships between cloned DNA markers and known mouse mutations and for identifying homologous genes in mice and humans that may be involved in disease.     

A Molecular Genetic Linkage Map of Mouse Chromosome 9 with Regional Localizations for the Gsta, T3g, Ets-1 and Ldlr Loci

A 64-centiMorgan linkage map of mouse chromosome 9 was developed using cloned DNA markers and an interspecific backcross between Mus spretus and the C57BL/6J inbred strain. This map was compared to conventional genetic maps using six markers previously localized in laboratory mouse strains. These markers included thymus cell antigen-1, cytochrome P450-3, dilute, transferrin, cholecystokinin, and the G-protein alpha inhibitory subunit. No evidence was seen for segregation distortion, chromosome rearrangements, or altered genetic distances in the results from interspecific backcross mapping. Regional map locations were determined for four genes that were previously assigned to chromosome 9 using somatic cell hybrids. These genes were glutathione S-transferase Ya subunit (Gsta), the T3 gamma subunit, the low density lipoprotein receptor, and the Ets-1 oncogene. The map locations for these genes establish new regions of synteny between mouse chromosome 9 and human chromosomes 6, 11, and 19. In addition, the close linkage detected between the dilute and Gsta loci suggests that the Gsta locus may be part of the dilute/short ear complex, one of the most extensively studied genetic regions of the mouse.     

A molecular genetic linkage map of mouse chromosome 2

Interspecific backcross mice were used to create a molecular genetic linkage map of chromosome 2. Genomic DNAs from N2 progeny were subjected to Southern blot analysis using molecular probes that identified the Abl, Acra, Ass, C5, Cas-1, Fshb, Gcg, Hox-5.1, Jgf-1, Kras-3, Ltk, Pax-1, Prn-p, and Spna-2 loci; these loci were added to the 11 loci previously mapped to the distal region of chromosome 2 in the same interspecific backcross to generate a composite multilocus linkage map. Several loci mapped near, and may be the same as, known mutations. Comparisons between the mouse and the human genomes indicate that mouse chromosome 2 contains regions homologous to at least six human chromosomes. Mouse models for human diseases are discussed.     

The murine retinoblastoma homolog maps to chromosome 14 near Es-10

Restriction fragment length variants have been exploited to map genetically Rb-1, the murine homolog of the human retinoblastoma gene. Rb-1 localized to mouse chromosome 14 on the basis of results from analysis of somatic cell hybrids. In an interspecific backcross involving Mus spretus, Rb-1 and the murine homolog of the human esterase D gene (ESD), which we refer to here as Esd, were inseparable. Furthermore, the strain distribution patterns of Rb-1 and Es-10 are the same in 31 of 32 recombinant inbred strains. Close linkage of the chromosome 14 morphological marker hairless (hr) to Rb-1 is also implied. These results localize Rb-1 on the mouse linkage map and provide close genetic markers to follow Rb-1 in somatic as well as in germline genetic experiments. Additionally, the results suggest that Es-10 is the murine homolog of ESD and provide further evidence for linkage conservation during mammalian evolution.     

A molecular genetic linkage map of mouse chromosome 13 anchored by the beige (bg) and satin (sa) loci

A molecular genetic linkage map of mouse chromosome 13 was constructed using cloned DNA markers and interspecific backcross mice from two independent crosses. The map locations of Ctla-3, Dhfr, Fim-1, 4/12, Hexb, Hilda, Inhba, Lamb-1.13, Ral, Rrm2-ps3, and Tcrg were determined with respect to the beige (bg) and satin (sa) loci. The map locations of these genes confirm and extend regions of homology between mouse chromosome 13 and human chromosomes 5 and 7, and identify a region of homology between mouse chromosome 13 and human chromosome 6. The molecular genetic linkage map of chromosome 13 provides a framework for establishing linkage relationships between cloned DNA markers and known mouse mutations and for identifying homologous genes in mice and humans that may be involved in disease processes.     

The multipoint genetic mapping of mouse chromosome 16.

Utilizing a Mus spretus/Mus domesticus (C57BL/10) interspecific backcross, we have constructed a multipoint genetic map of mouse chromosome 16 that extends 43.2 cM from the proximal Prm-1 locus to the distal Ets-2 locus. The genetic map incorporates three new markers: D16Smh6, a random genomic clone; Pgk-1ps1, a phosphoglycerate kinase pseudogene; and the growth-associated protein Gap43. The map position of Gap43 indicates the presence, on mouse chromosome 16, of a significant-size conserved linkage group with human chromosome 3.     

Localization of the murine macrophage colony-stimulating factor gene to chromosome 3 using interspecific backcross analysis

The chromosomal location of the murine macrophage colony-stimulating factor (Csfm) gene was determined by interspecific backcross analysis. We mapped Csfm to mouse chromosome 3, 2.5 cM distal to Ngfb and Nras and 1.3 cM proximal to Amy-2. CSFM maps to human chromosome 5q, while AMY2, NGFB, and NRAS map to human chromosome 1p. The chromosomal location of Csfm thus disrupts a previously identified conserved linkage group between mouse chromosome 3 and human chromosome 1. The location of Csfm also identifies yet another mouse chromosome that shares synteny with human chromosome 5q, a region involved in several different types of myeloid disease.     

A multilocus linkage map of mouse chromosome 8

We present a genetic linkage map of mouse chromosome 8 that spans 53 cM and includes eight cloned loci. This map was derived from analysis of 100 progeny of an interspecific backcross between Mus spretus and Mus musculus domesticus. Genes that were mapped in this analysis include L7, Plat, Lpl, Ucp, Es, Mt-1, Um, and Tat. This analysis positions a new extremely proximal marker on chromosome 8, which is discussed as a potential candidate gene for the nervous locus. These linkage data will be useful for the mapping of additional loci on chromosome 8.     

A molecular genetic linkage map of mouse chromosome 4 including the localization of several proto-oncogenes

We have constructed a 64-cM molecular genetic linkage map of mouse chromosome 4 using interspecific backcross animals derived from mating C57BL/6J and Mus spretus mice. Several proto-oncogenes and common sites of viral integration have been assigned regional locations on chromosome 4 including Mos, Lyn, Jun, Lmyc, Lck, Fgr, and Dsi-1. Additional loci mapped in this study to chromosome 4 were Tsha, Mup-1, Rrm2-ps1, Ifa, and Anf. A comparison of our mapping data with inbred strain mapping data did not show any evidence for inversions or deletions on chromosome 4. New regions of synteny were defined between mouse chromosome 4 and human chromosomes 1 and 8; a region of homology was found between mouse chromosome 4 and human chromosome 6. This linkage map will provide a framework for identifying homologous genes in mice and humans that may be involved in various disease processes.     

A molecular genetic linkage map of mouse chromosome 7

The homology between mouse chromosome 7 and human chromosomes 11, 15, and 19 was examined using interspecific backcross animals derived from mating C3H/HeJ-gld/gld and Mus spretus mice. In an earlier study, we reported on the linkage relationships of 16 loci on mouse chromosome 7 and the homologous relationship between this chromosome and the myotonic dystrophy gene region on human chromosome 19. Segregation analyses were used to extend the gene linkage relationships on mouse chromosome 7 by an additional 21 loci. Seven of these genes (Cyp2a, D19F11S1h, Myod-1, Otf-2, Rnu1p70, Rnu2pa, and Xrcc-1) were previously unmapped in the mouse. Several potential mouse chromosome 7 genes (Mel, Hkr-1, Icam-1, Pvs) did not segregate with chromosome 7 markers, and provisional chromosomal assignments were made. This study establishes a detailed molecular genetic linkage map of mouse chromosome 7 that will be useful as a framework for determining linkage relationships of additional molecular markers and for identifying homologous disease genes in mice and humans.     

Recombinant Inbred Strain and Interspecific Backcross Analysis of Molecular Markers Flanking the Murine Agouti Coat Color Locus

Recombinant inbred strain and interspecific backcross mice were used to create a molecular genetic linkage map of the distal portion of mouse chromosome 2. The orientation and distance of the Ada, Emv-13, Emv-15, Hck-1, Il-1a, Pck-1, Psp, Src-1 and Svp-1 loci from the beta 2-microglobulin locus and the agouti locus were established. Our mapping results have provided the identification of molecular markers both proximal and distal to the agouti locus. The recombinants obtained provide valuable resources for determining the direction of chromosome walking experiments designed to clone sequences at the agouti locus. Comparisons between the mouse and human genome maps suggest that the human homolog of the agouti locus resides on human chromosome 20q. Three loci not present on mouse chromosome 2 were also identified and were provisionally named Psp-2, Hck-2 and Hck-3. The Psp-2 locus maps to mouse chromosome 14. The Hck-2 locus maps near the centromere of mouse chromosome 4 and may identify the Lyn locus. The Hck-3 locus maps near the distal end of mouse chromosome 4 and may identify the Lck locus.     

A Comprehensive Genetic Map of Murine Chromosome 11 Reveals Extensive Linkage Conservation between Mouse and Human

Interspecific backcross animals from a cross between C57BL/6J and Mus spretus mice were used to generate a comprehensive linkage map of mouse chromosome 11. The relative map positions of genes previously assigned to mouse chromosome 11 by somatic cell hybrid or genetic backcross analysis were determined (Erbb, Rel, 11-3, Csfgm, Trp53-1, Evi-2, Erba, Erbb-2, Csfg, Myhs, Cola-1, Myla, Hox-2 and Pkca). We also analyzed genes that we suspected would map to chromosome 11 by virtue of their location in human chromosomes and the known linkage homologies that exist between murine chromosome 11 and human chromosomes (Mpo, Ngfr, Pdgfr and Fms). Two of the latter genes, Mpo and Ngfr, mapped to mouse chromosome 11. Both genes also mapped to human chromosome 17, extending the degree of linkage conservation observed between human chromosome 17 and mouse chromosome 11. Pdgfr and Fms, which are closely linked to II-3 and Csfgm in humans on chromosome 5, mapped to mouse chromosome 18 rather than mouse chromosome 11, thereby defining yet another conserved linkage group between human and mouse chromosomes. The mouse chromosome 11 linkage map generated in these studies substantially extends the framework for identifying homologous genes in the mouse that are involved in human disease, for elucidating the genes responsible for several mouse mutations, and for gaining insights into chromosome evolution and genome organization.     

Development and applications of a molecular genetic linkage map of the mouse genome

Interspecific mouse backcrosses provide almost limitless genetic variation for gene mapping. We have used interspecific backcrosses to develop the first comprehensive molecular genetic linkage map of the mouse genome. More than 600 loci have been positioned on the map; the current average map resolution is less than 3 cM. Since all loci were mapped using a single backcross panel, gene order can be determined unambiguously. With this level of resolution, it is now possible to position any new locus on the linkage map with virtually 100% certainty. In this article, we review how interspecific linkage maps are constructed, the salient features of our linkage map, and some of the many applications of interspecific linkage maps, in general, for future research.     

Synteny on mouse chromosome 5 of homologs for human DNA loci linked to the Huntington disease gene

Comparative mapping in man and mouse has revealed frequent conservation of chromosomal segments, offering a potential approach to human disease genes via their murine homologs. Using DNA markers near the Huntington disease gene on the short arm of chromosome 4, we defined a conserved linkage group on mouse chromosome 5. Linkage analyses using recombinant inbred strains, a standard outcross, and an interspecific backcross were used to assign homologs for five human loci, D4S43, D4S62, QDPR, D4S76, and D4S80, to chromosome 5 and to determine their relationships with previously mapped markers for this autosome. The relative order of the conserved loci was preserved in a linkage group that spanned 13% recombination in the interspecific backcross analysis. The most proximal of the conserved markers on the mouse map, D4S43h, showed no recombination with Emv-1, an endogenous ecotropic virus, in 84 outcross progeny and 19 recombinant inbred strains. Hx, a dominant mutation that causes deformities in limb development, maps approximately 2 cM proximal to Emv-1. Since the human D4S43 locus is less than 1 cM proximal to HD near the telomere of chromosome 4, the murine counterpart of the HD gene might lie between Hx and Emv-1 or D4S43h. Cloning of the region between these markers could generate new probes for conserved human sequences in the vicinity of the HD gene or possibly candidates for the murine counterpart of this human disease locus.     

Cross-referencing radiation hybrid data to the recombination map: lessons from mouse chromosome 18

We are building a framework map of known-order anchor markers between the mouse T31 radiation hybrid (RH) panel and the recombination map based on The Jackson Laboratory (TJL) interspecific backcross panels using the established genetic order to evaluate and strengthen the RH results. In making this map comparison, we have elucidated several problems inherent in RH mapping and minimized these by careful attention to data gathering and interpretation methods. We describe lessons and pitfalls of developing radiation hybrid maps, using the example of mouse Chromosome 18, for which we have built a framework map of microsatellite anchor loci spanning the entire chromosome at significant LOD with no gaps. Sixty-five D18Mit- simple sequence length polymorphism (SSLP) markers form a continuous linkage along the T31 RH Chromosome 18 (RH map length 1598 cR, genetic length 41 cM) with all LODs greater than 6. These markers are also placed on TJL interspecific backcrosses, and the order of the markers in the two systems is in complete agreement. We are continuing to cross-reference the RH data to TJL backcross data for the other mouse chromosomes to improve further the power of RH mapping and to integrate more precisely the extensive existing recombination mapping data for the mouse with the incoming radiation hybrid map data.     

A linkage map of mouse Chromosome 1 using an interspecific cross segregating for the gld autoimmunity mutation

An interspecific backross was used to define a high resolution linkage map of mouse Chromosome (Chr) 1 and to analyze the segregation of the generalized lymphoproliferative disease (gld) mutation. Mice homozygous for gld have multiple features of autoimmune disease. Analysis of up to 428 progeny from the backcross [(C3H/HeJ-gld x Mus spretus)F₁ x C3H/HeJ-gld] established a map that spans 77.6 cM and includes 56 markers distributed over 34 ordered genetic loci. The gld mutation was mapped to a less than 1 cM segment on distal mouse Chr 1 using 357 gld phenotype-positive backcross mice. A second backcross, between the laboratory strains C57BL/6J and SWR/J, was examined to compare recombination frequency between selected markers on mouse Chr 1. Significant differences in crossover frequency were demonstrated between the interspecific backcross and the inbred laboratory cross for the entire interval studied. Sex difference in meiotic crossover frequency was also significant in the laboratory mouse cross. Two linkage groups known to be conserved between segments of mouse Chr 1 and the long arm of human Chrs 1 and 2 where further defined and a new conserved linkage group was identified that includes markers of distal mouse Chr 1 and human Chr 1, bands q32 to q42.     

Mapping of mouse intracisternal A-particle proviral markers in an interspecific backcross

We present a linkage map of intracisternal A-particle (IAP) proviral loci. The IAP family consists of 2000 endogenous proviral elements that are widely dispersed in the mouse genome. The map was constructed by using an interspecific backcross and markers defined by oligonucleotide probes specific for subclasses of expressed IAP elements. In genomic DNA from C57BL/6J mouse, these probes each detected from 12 to 44 HindIII restriction fragments that represent junctions between proviral and 5-flanking DNA. The fragments have characteristic strain distribution patterns (SDPs) that are particularly polymorphic in the DNAs of C57BL/6J and Mus spretus mice used for the backcross. IAP loci were placed on the map by comparison of their distribution patterns with those of known genetic markers in the backcross. The map includes 51 IAP loci that have not been previously mapped and 23 IAP proviruses that had been previously mapped in recombinant inbred (RI) strains. Comparable map positions were obtained with the IAP markers in the interspecific backcross and the RI strains. The mapped IAP loci were widely dispersed on the X Chromosome (Chr) and all of the autosomes except Chrs 9 and 19, providing useful genetic markers for linkage studies.     

Chromosome mapping of the murine syndecan gene.

The chromosomal localization of the murine syndecan gene was determined by analysis of DNA from a panel of mouse-hamster cell hybrids containing various mouse chromosomes, detection of immunoreactive syndecan in culture medium of these cells, and linkage analysis of a mouse interspecific backcross. Southern analysis of the mouse-hamster cell hybrid DNA shows two distinct hybridizing sequences, one on mouse Chromosome 12 and the other on the X chromosome. Localization of the syndecan gene to mouse Chromosome 12 was determined by detection of immunoreactive syndecan in the culture medium of cell hybrids containing mouse Chromosome 12. Hybrids containing other mouse chromosomes were negative. Linkage analysis by Southern hybridization of DNA from a mouse interspecific backcross using a syndecan-specific probe localized the syndecan gene locus, Synd, to the proximal end of Chromosome 12, tightly linked to the Pomc-1 and Nmyc loci. The syndecan gene is likely on human Chromosome 2 because this region shows conservation of synteny between mouse and human chromosomes.