Definition of mouse chromosome 1 and 3 gene linkage groups that are conserved on human chromosome 1: Evidence that a conserved linkage group spans the centromere of human chromosome 1

Comparative mapping between the human and the mouse genomes allows characterization of linkage groups that have been conserved over evolution. In this study, genes previously localized to adjacent regions of human chromosome 1 were mapped to discrete regions on distal mouse chromosomes 1 and 3 using an interspecific cross. Linkage analysis in mouse defined two groups in which the gene order appears to be the same as that in humans: 15 genes localized between human chromosome 1q21 and 1q32 were found to span 29.5 cM on distal mouse chromosome 1; 6 genes localized between human chromosome 1q21 and 1p22 spanned 15.6 cM on distal mouse chromosome 3. These data suggest that gene order within large chromosome segments may remain stable over long periods of evolution and that the position of the centromere may reflect a late event in the evolution of higher eukaryotic organisms. These studies provide a model for examination of specific evolutionary events.     

Chromosome mapping of the rod photoreceptor cGMP phosphodiesterase beta-subunit gene in mouse and human: tight linkage to the Huntington disease region (4p16.3).

The retinal degeneration mouse (gene symbol, rd) is an animal model for certain forms of human hereditary retinopathies. Recent findings of a nonsense mutation in the rd mouse PDE beta-subunit gene (Pdeb) prompted us to investigate the chromosome locations of the mouse and human genes. We have utilized backcross analysis in mice to verify and define more precisely the location of the Pdeb locus 6.1 +/- 2.3 cM distal of Mgsa on mouse chromosome 5. We have determined that the human gene (PDEB) maps to 4p16.3, very close to the Huntington disease (HD) region. Analysis of the comparative map for mice and humans shows that the mouse homologue of the HD gene will reside on chromosome 5. Linkage of the mouse Pdeb locus with other homologues in the human 4p16.3 region is maintained but gene order is not, suggesting at least three possible sites for the corresponding mouse HD gene.     

A linkage map of mouse chromosome 19: definition of comparative mapping relationships with human chromosomes 10 and 11 including the MEN1 locus.

A linkage map of mouse Chromosome (Chr) 19 was constructed using an interspecific cross and markers defined by restriction fragment length variants. The map includes 20 markers, 9 of which had not been mapped previously in the mouse. The data further defined the relationship between genes on mouse Chr 19 and those on the long arm of human Chr 10 and the pericentric region of the long arm of human Chr 11. The comparative mapping analysis suggests that the proximal segment of mouse Chr 19 may contain the MEN1 locus and that the current study has identified additional genes that may be useful for positional cloning of this putative tumor suppressor gene.     

Mapping of recombinant retrovirus integration sites that cause expression of the viral genome in murine embryonal carcinoma cells

Murine embryonal carcinoma (EC) cells do not normally express Moloney murine leukemia virus genes. Earlier, rare EC cell lines were isolated that expressed proviral neomycin resistance (neo) gene. This expression was dependent on cellular enhancer or promoter sequences that flank the proviral integration site. Four such integration sites, designated as Mint (for Moloney murine leukemia virus integration and expression sites in EC cells), have been mapped on mouse chromosomes. Minta, Mintb, Mintc and Mintd are unlinked and mapped on different chromosomes (Chr), Chr 10, Chr 1, Chr 5 and the X Chr, respectively. None of these loci appear to be linded to any known Mo-MuLV proviral integration sites previously mapped. These enhancer and promoter loci may represent a new set of genes active in undifferentiated embryonic cells.The terminology for Mint genes has been discussed with and approved by the International Committee on Standard Genetic Nomenclature for Mice (M.T. Davisson, The Jackson Laboratory, Bar Harbor, Me.).     

Cloning of the human and mouse type X collagen genes and mapping of the mouse type X collagen gene to chromosome 10.

Type X collagen, a homotrimer of alpha 1 (X) polypeptide chains, is specifically expressed by hypertrophic chondrocytes in regions of cartilage undergoing endochondral ossification. We have previously described the isolation of a small fragment of the human type X collagen gene (COL10A1) and its localization to the q21-q22 region of human chromosome 6 [Apte, S., Mattei, M.-G. & Olsen, B. R. (1991) FEBS Lett. 282, 393-396]. Using this fragment as a probe to screen genomic libraries, we report here the isolation of human and mouse genomic clones which contain the major part of the human and mouse type X collagen genes. In both species, the 14-kb genomic clones which were isolated contain a long open reading frame (greater than 2000 bp in length) which codes for the entire C-terminal non-collagenous (NC1) domain, the entire collagenous (COL) domain and part of the N-terminal non-collagenous (NC2) domain of the alpha 1(X) collagen chain. The human genomic clone contains the major part of the COL10A1 gene, in addition to the region we have previously cloned, and is highly similar to the corresponding portions of the mouse genomic clone (84.5% similarity at the nucleotide level, and 86.1% at the level of the conceptual translation product). The identification of the mouse genomic clone as the alpha 1(X) collagen gene (Col10a1) was confirmed by in situ hybridization of a fragment of the mouse genomic clone to sections from newborn mice. Hybridization was restricted to the hypertrophic chondrocytes of developing chondroepiphyses, being absent in small chondrocytes and in other tissues. Using interspecific backcross analysis, the locus for the mouse alpha 1 (X) collagen gene was assigned to chromosome 10. The cloning and chromosomal mapping of the human and mouse alpha 1 (X) collagen genes now permit the investigation of the possible role of type X collagen gene defects in the genesis of chondrodysplasias in both species and provide data essential for the generation of transgenic mice deficient in type X collagen.     

A proximal mouse chromosome 9 linkage map that further defines linkage groups homologous with segments of human chromosomes 11, 15, and 19.

A 42-cM map of proximal mouse chromosome 9, including eight loci defined by restriction fragment length variants, has been generated. Linkage was established by haplotype analyses of 114 interspecific backcross mice and indicated the following gene order: (centromere) Pvs-5.3 cM-Icam-1/Ldlr-18.4 cM-Thy-1-1.8 cM-Ncam-0.9 cM-Hexa-7.9 cM-Gsta-7.9 cM-Trf. Three of these loci, Pvs, Icam-1, and Hexa, have not been mapped previously. Together with previous mapping studies the current results suggested that chromosomal segments of mouse chromosomes 7 and 9 and chromosomal segments of human chromosomes 11, 15, and 19 derive from a single putative primordial chromosome. The studies support the postulate that detailed analysis of chromosome organization will be useful in defining events in mammalian evolution.     

Establishment of a molecular genetic map of distal mouse chromosome 1: further definition of a conserved linkage group syntenic with human chromosome 1q

A linkage map of distal mouse chromosome 1 was constructed by restriction fragment length polymorphism analysis of DNAs from seven sets of recombinant inbred (RI) strains. The data obtained with seven probes on Southern hybridization combined with data from previous studies suggest the gene order Cfh, Pep-3/Ren-1,2, Ly-5, Lamb-2, At-3, Apoa-2/Ly-17,Spna-1. These results confirm and extend analyses of a large linkage group which includes genes present on a 20-30 cM span of mouse chromosome 1 and those localized to human chromosome 1q21-32. Moreover, the data indicate similar relative positions of human and mouse complement receptor-related genes REN, CD45, LAMB2, AT3, APOA2, and SPTA. These results suggest that mouse gene analyses may help in detailed mapping of human genes within such a syntenic group.