Fine structure physical mapping of the region of mouse chromosome 10 homologous to human chromosome 21.

Comparative mapping of human and mouse DNA for regions of genetic homology between human Chromosome 21 and the mouse genome is of interest because of the possibility of developing mouse models of human trisomy 21 (Down syndrome), understanding chromosome evolution, and isolating novel sequences conserved between the two species. At least two mouse chromosomes are known to carry sequences homologous to those on human Chromosome 21: mouse Chromosome 16 (D21S16h, D21S13h, D21S52h, App, Sod-1, Mx-1, Ets-2, Prgs,Ifnar) and mouse Chromosome 17 (D21S56h, Crya-1, and Cbs). Recently, five additional genes have been mapped within region 21q22 of human Chromosome 21:PFKL, CD18, COL6A1, COL6A2, and S100B. To assign these sequences to specific mouse chromosomes, we used human cDNA probes for COL6A1, COL6A2, CD18, and PFKL and a rat brain cDNA probe for S100B in conjunction with a panel of seven Chinese hamster-mouse somatic cell hybrids segregating mouse chromosomes. The specific chromosome complements of the hybrid cell lines and the presence or absence of hybridizing mouse sequences in their DNAs allow us to assign all five sequences to mouse Chromosome 10, with the assignment of Pfkl reported here for the first time. Analysis of genomic mouse DNA fragments produced by digestion with rare-cutting restriction enzymes and separated using pulsed-field gel electrophoresis allows us to construct a fine-structure physical map of two segments of the region of Chromosome 10 containing these five markers. The five loci span at least 1900 kb of mouse DNA and are consistent with the human order: Pfkl-Cd-18-Col6a-1-Col6a-2-S100b.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-resolution comparative mapping of pig Chromosome 4, emphasizing the FAT1 region

The first quantitative trait locus (QTL) in pigs, FAT1, was found on Chromosome 4 (SSC4) using a Wild Boar intercross. Further mapping has refined the FAT1 QTL to a region with conserved synteny to both human Chromosomes 1 and 8. To both improve the comparative map of the entire SSC4 and to define the specific human chromosome region with conserved synteny to FAT1, we have now mapped 103 loci to pig Chromosome 4 using a combination of radiation hybrid and linkage mapping. The physical data and linkage analysis results are in very good agreement. Comparative analysis revealed that gene order is very well conserved across SSC4 compared to both HSA1 and HSA8. The breakpoint in conserved synteny was refined to an area of about 23 cR on the q arm of SSC4 corresponding to a genetic distance of less than 0.5 cM. Localizations of the centromeres do not seem to have been conserved between the two species. No remnants of the HSA1 centromere were detected on the corresponding region on SSC4 and traces from the centromeric region of SSC4 cannot clearly be revealed on the homologous region on HSA8. This refined SSC4 map and the comparative analysis will be a great aid in the search for the genes underlying the FAT1 locus.     

Re-localization of Actsk-1 to mouse Chromosome 8, a new region of homology with human Chromosome 1

We present here the genetic mapping of the -skeletal actin locus (Actsk-1) on mouse Chromosome (Chr) 8, on the basis of the PCR analysis of a microsatellite in an interspecific backcross. Linkage and genetic distances were established for four loci by analysis of 192 (or 222) meiotic events and indicated the following gene order: (centromere)-Es-1-11.7 cM-Tat-8.3 cM-Actsk-1-0.5 cM-Aprt. Mapping of ACTSK to human Chr 1 and of TAT and APRT to human Chr 16 demonstrates the existence of a new short region of homology between mouse Chr 8 and human Chr 1. Intermingling on this scale between human and mouse chromosomal homologies that occurred during evolution creates disorders in comparative linkage studies.     

Use of comparative physical and sequence mapping to annotate mouse chromosome 16 and human chromosome 21

Distal mouse chromosome 16 (MMU16) shares conserved linkage with human chromosome 21 (HSA21), trisomy for which causes Down syndrome (DS). A 4.5-Mb physical map extending from Cbr1 to Tmprss2 on MMU16 provides a minimal tiling path of P1 artificial chromosomes (PACs) for comparative mapping and genomic sequencing. Thirty-four expressed sequences were positioned on the mouse map, including 19 that were not physically mapped previously. This region of the mouse:human comparative map shows a high degree of evolutionary conservation of gene order and content, which differs only by insertion of one gene (in mouse) and a small inversion involving two adjacent genes. "Low-pass" (2.2x) mouse sequence from a portion of the contig was ordered and oriented along 510 kb of finished HSA21 sequence. In combination with 68 kb of unique PAC end sequence, the comparison provided confirmation of genes predicted by comparative mapping, indicated gene predictions that are likely to be incorrect, and identified three candidate genes in mouse and human that were not observed in the initial HSA21 sequence annotation. This comparative map and sequence derived from it are powerful tools for identifying genes and regulatory regions, information that will in turn provide insights into the genetic mechanisms by which trisomy 21 results in DS.     

High-resolution mapping and recombination interval analysis of mouse Chromosome 17

Analysis of homologous recombination in eukaryotes has shown that some meiotic crossing-over occurs preferentially at specific genomic sites of limited physical distance called recombinational hotspots. In the mouse, recombinational hotspots have only been defined in the major histocompatibility complex (MHC) on chromosome (Chr) 17. In an attempt to examine whether hotspots are unique to the MHC or are present throughout the genome, high-resolution linkage maps of Chr 17 based on five backcrosses involving different inbred strains have been generated. These maps separate many markers that were previously shown at the same map position and allow a detailed analysis of recombination patterns across Chr 17. Corresponding recombination intervals in these maps have been compared for the identification of intervals with very little or no recombination in certain genetic crosses and considerable recombination in other genetic crosses. This approach has been termed Recombination Interval Analysis. Possible haplotype-dependent non-MHC hotspots, as well as previously identified MHC hotspots, have been detected by interval analysis. Received: 1 December 1997/ Accepted: 27 February 1998     

High-resolution mapping of mouse Chromosome 8 identifies an evolutionary chromosomal breakpoint

The central region of mouse Chromosome (Chr) 8, containing the myodystrophy (myd) locus, is syntenic with human Chr 4q28-qter. The human neuromuscular disorder facioscapulohumeral muscular dystrophy (FSHD) maps to Chr 4q35, and myd has been proposed as a mouse homolog of FSHD. We have employed a comparative mapping approach to investigate this relationship further by extending the mouse genetic map of this region. We have ordered 12 genes in a single cross, 8 of which have human homologs on 4q28-qter. The results confirm a general relationship between the most distal genes on human 4q and the most proximal genes in the mouse 8 syntenic region. Despite chromosomal rearrangements of syntenic groups in this region, conservation of gene order is maintained between the group of genes in the human telomeric region of 4q35 and MMU8. Furthermore, this conserved telomeric HSA4q35 syntenic group maps proximal to the myd mutation and is flanked by genes with homologs on HSA8p22. At the proximal boundary of the MMU8 linkage group we have identified a single 300-kb YAC containing the genes Frgl and Pcml, which have human homologs on 4q35 and 8p22, respectively. Thus, this YAC spans an evolutionary chromosomal breakpoint. As well as providing clues about chromosomal evolution, this map of the FSHD syntenic mouse region should prove invaluable in the isolation of candidate genes for this disease. Received: 20 January 1998 / Accepted: 10 April 1998     

Sequence-ready physical map of the mouse Chromosome 16 region with conserved synteny to the human Velocardiofacial syndrome region on 22q11.2

Proximal mouse Chromosome (Chr) 16 shows conserved synteny with human Chrs 16, 8, 22, and 3. The mouse Chr 16/human Chr 22 conserved synteny region includes the DiGeorge/Velocardiofacial syndrome region of human Chr 22q11.2. A physical map of the entire mouse Chr 16/human Chr 22 region of conserved synteny has been constructed to provide a substrate for gene discovery, genomic sequencing, and animal model development. A YAC contig was constructed that extends ca. 5.4 Mb from a region of conserved synteny with human Chr 8 at Prkdc through the region conserved with human Chr 3 at DVL3. Sixty-one markers including 37 genes are mapped with average marker spacing of 90 kb. Physical distance was determined across the 2.6-Mb region from D16Mit74 to Hira with YAC fragmentation. The central region from D16Jhu28 to Igl-C1 was converted into BAC and PAC clones, further refining the physical map and providing sequence-ready template. The gene content and borders of three blocks of conserved linkage between human Chr 22q11.2 mouse Chr 16 are refined. Received: 4 November 1998 / Accepted: 21 December 1998     

Genetic and physical mapping of the biglycan gene on the mouse X Chromosome

A human cDNA for biglycan (BGN) has recently been mapped to proximal Xq28. We have mapped the murine locus, Bgn, approximately 50 kb distal to DXPas8, using a combination of genetic mapping in an interspecific backcross of B6CBA-A ^w-J/A-Bpa x Mus spretus and physical mapping using pulsed field gel electrophoresis and analysis of murine yeast artificial chromosomes (YACs) containing both DXPas8 and Bgn. Our mapping studies also appear to exclude Bgn as a candidate gene for the bare patches (Bpa) mutation and for the homologous human disorder X-linked dominant chondrodysplasia punctata (CDPX2).     

High-resolution physical mapping in Pennisetum squamulatum reveals extensive chromosomal heteromorphism of the genomic region associated with apomixis

Gametophytic apomixis is asexual reproduction as a consequence of parthenogenetic development of a chromosomally unreduced egg. The trait leads to the production of embryos with a maternal genotype, i.e. progeny are clones of the maternal plant. The application of the trait in agriculture could be a tremendous tool for crop improvement through conventional and nonconventional breeding methods. Unfortunately, there are no major crops that reproduce by apomixis, and interspecific hybridization with wild relatives has not yet resulted in commercially viable germplasm. Pennisetum squamulatum is an aposporous apomict from which the gene(s) for apomixis has been transferred to sexual pearl millet by backcrossing. Twelve molecular markers that are linked with apomixis coexist in a tight linkage block called the apospory-specific genomic region (ASGR), and several of these markers have been shown to be hemizygous in the polyploid genome of P. squamulatum. High resolution genetic mapping of these markers has not been possible because of low recombination in this region of the genome. We now show the physical arrangement of bacterial artificial chromosomes containing apomixis-linked molecular markers by high resolution fluorescence in situ hybridization on pachytene chromosomes. The size of the ASGR, currently defined as the entire hemizygous region that hybridizes with apomixis-linked bacterial artificial chromosomes, was estimated on pachytene and mitotic chromosomes to be approximately 50 Mbp (a quarter of the chromosome). The ASGR includes highly repetitive sequences from an Opie-2-like retrotransposon family that are particularly abundant in this region of the genome.