Mammalian Genome

Smyth, Ian; Agtmael, Tom; Jackson, Ian

doi: 10.1007/s00335-004-4001-9pmid: 15366370

Storchová, Radka; Gregorová, Soňa; Buckiová, Daniela; Kyselová, Vendula; Divina, Petr; Forejt, Jiří

doi: 10.1007/s00335-004-2386-0pmid: 15366371

Hybrid sterility is a common postzygotic reproductive isolation mechanism that appears in the early stages of speciation of various organisms. Mus musculus musculus and Mus musculus domesticus represent two recently separated mouse subspecies particularly suitable for genetic studies of hybrid sterility. Here we show that the introgression of Chr X of M. m. musculus origin (PWD/Ph inbred strain, henceforth PWD) into the genetic background of the C57BL/6J (henceforth B6) inbred strain (predominantly of M. m. domesticus origin) causes male sterility. The X-linked hybrid sterility is associated with reduced testes weight, lower sperm count, and morphological abnormalities of sperm heads. The analysis of recombinant Chr Xs in sterile and fertile males as well as quantitative trait locus (QTL) analysis of several fertility parameters revealed an oligogenic nature of the X-linked hybrid sterility. The Hstx1 locus responsible for male sterility was mapped near DXMit119 in the central part of Chr X. To ensure full sterility, the PWD allele of Hstx1 has to be supported with the PWD allelic form of loci in at least one proximal and/or one distal region of Chr X. Mapping and cloning of Hstx1 and other genes responsible for sterility of B6–XPWDYB6 males could help to elucidate the special role of Chr X in hybrid sterility and consequently in speciation.

Lee, Daekee; Cross, Sally; Strunk, Karen; Morgan, Joanne; Bailey, Candice; Jackson, Ian; Threadgill, David

doi: 10.1007/s00335-004-2384-2pmid: 15366372

Mice heterozygous for the N-ethyl-N-nitrosourea-induced Waved-5 (Wa5) mutation, isolated in a screen for dominant, visible mutations, exhibit a wavy coat similar to mice homozygous for the recessive Tgfa wa1 or Egfr wa2 alleles. In this study, we show that Wa5 is a new allele of Egfr (Egfr Wa5 ) containing a missense mutation within the coding region for the highly conserved DFG motif of the tyrosine kinase domain. In vivo analysis of placental development, modification of Apc Min tumorigenesis, and levels of EGF-dependent EGFR phosphorylation demonstrates that Egfr Wa5 functions as an antimorphic allele, recapitulating many abnormalities associated with reduced EGFR activity. Furthermore, Egfr wa5 enhances Egfr Wa2 compound or Tgfa tm1Dcl double mutants exposing additional EGFR-dependent phenotypes. In vitro characterization shows that the antimorphic property of Egfr Wa5 is caused by a kinase-dead receptor acting as a dominant negative.

Staelens, Jan; Puimège, Leen; Mahieu, Tina; Pynaert, Gwenda; Hochepied, Tino; Vandenabeele, Annelies; Grooten, Johan; Kontoyiannis, Dimitris; Roy, Frans; Kollias, George; Libert, Claude

doi: 10.1007/s00335-004-3002-zpmid:

Comstock, Kenine; Lingaas, Frode; Kirkness, Ewen; Hitte, Christophe; Thomas, Rachael; Breen, Matthew; Galibert, Francis; Ostrander, Elaine

doi: 10.1007/s00335-004-2365-5pmid: 15366374

A high-density map of the region of canine Chromosome 5 (CFA5) surrounding the evolutionary breakpoint between human Chromosomes 1p32 and 17p11 was constructed by integrating a radiation hybrid map including 41 microsatellites, 10 BACs, and 59 genes and a linkage map including 18 markers. A collection of canine genomic survey sequences providing 1.5× coverage was used to identify dog orthologs of human genes, proving instrumental in the development of this map. Of particular interest is the canine BHD gene, within which we have previously described a single nucleotide polymorphism associated with Hereditary Multifocal Renal Cystadenocarcinoma and Nodular Dermatofibrosis (RCND) in German Shepherd dogs. The corresponding region of the human genome is particularly gene rich, containing genes involved in development, metabolism, and cancer that are likely to be of interest in future mapping studies. This current mapping effort on CFA5 expands the degree to which initial findings of linkage in canine families can be followed by successful positional cloning efforts and increases the value of the human genome sequence for defining candidate genes. Moreover, this study demonstrates the utility of genomic survey sequences when combined with accurate genome maps for rapid mapping of disease susceptibility loci.

Kim, Kwan-Suk; Kim, Jong-Joo; Dekkers, Jack; Rothschild, Max

doi: 10.1007/s00335-004-2341-0pmid: 15366375

The polar overdominance model of inheritance was proposed to explain the non-Mendelian expression of callipyge muscular hypertrophy in sheep. The callipyge locus (CLPG) maps to the distal portion of ovine Chromosome 18 within the DLK1– GTL2 region and corresponds to human Chromosome 14q32, where uniparental disomy (UPD) of the region is associated with multiple congenital anomalies, including growth retardation and obesity. We investigated the porcine DLK1– GTL2 region in a cross of two pig breeds to determine if the callipyge polar overdominance is present in another species. Analyses of the parental origin of DLK1 polymorphism in the F2 offspring found that paternal inheritance of DLK1 allele 2 and maternal inheritance of the allele 1 was significantly associated with decreased fat deposition and increased lean muscle mass, while the opposite parental inheritance of these alleles was associated with slower prenatal and postnatal growth. These results suggest that the polar overdominance mode of inheritance is present in the pig chromosomal region that is homologous to the CLPG locus in sheep. Further study in pigs can provide important insights into understanding the molecular regulation of imprinted genes that are associated with human UPD14 and sheep callipyge phenotypes.

Rabie, Tarik; Crooijmans, Richard; Morisson, Mireille; Andryszkiewicz, Joanna; Poel, Jan; Vignal, Alain; Groenen, Martien

doi: 10.1007/s00335-004-2362-8pmid: 15366376

The mapping resolution of the physical map for chicken Chromosome 4 (GGA4) was improved by a combination of radiation hybrid (RH) mapping and bacterial artificial chromosome (BAC) mapping. The ChickRH6 hybrid panel was used to construct an RH map of GGA4. Eleven microsatellites known to be located on GGA4 were included as anchors to the genetic linkage map for this chromosome. Based on the known conserved synteny between GGA4 and human Chromosomes 4 and X, sequences were identified for the orthologous chicken genes from these human chromosomes by BLAST analysis. These sequences were subsequently used for the development of STS markers to be typed on the RH panel. Using a logarithm of the odds (LOD) threshold of 5.0, nine linkage groups could be constructed which were aligned with the genetic linkage map of this chromosome. The resulting RH map consisted of the 11 microsatellite markers and 50 genes. To further increase the number of genes on the map and to provide additional anchor points for the physical BAC map of this chromosome, BAC clones were identified for 22 microsatellites and 99 genes. The combined RH and BAC mapping approach resulted in the mapping of 61 genes on GGA4 increasing the resolution of the chicken–human comparative map for this chromosome. This enhanced comparative mapping resolution enabled the identification of multiple rearrangements between GGA4 and human Chromosomes 4q and Xp.

Ward, Tara; Valberg, Stephanie; Adelson, David; Abbey, Colette; Binns, Matthew; Mickelson, James

doi: 10.1007/s00335-004-2369-1pmid: 15366377

Comparative biochemical and histopathological evidence suggests that a deficiency in the glycogen branching enzyme, encoded by the GBE1 gene, is responsible for a recently identified recessive fatal fetal and neonatal glycogen storage disease (GSD) in American Quarter Horses termed GSD IV. We have now derived the complete GBE1 cDNA sequences for control horses and affected foals, and identified a C to A substitution at base 102 that results in a tyrosine (Y) to stop (X) mutation in codon 34 of exon 1. All 11 affected foals were homozygous for the X34 allele, their 11 available dams and sires were heterozygous, and all 16 control horses were homozygous for the Y34 allele. The previous findings of poorly branched glycogen, abnormal polysaccharide accumulation, lack of measurable GBE1 enzyme activity and immunodetectable GBE1 protein, coupled with the present observation of abundant GBE1 mRNA in affected foals, are all consistent with the nonsense mutation in the 699 amino acid GBE1 protein. The affected foal pedigrees have a common ancestor and contain prolific stallions that are likely carriers of the recessive X34 allele. Defining the molecular basis of equine GSD IV will allow for accurate DNA testing and the ability to prevent occurrence of this devastating disease affecting American Quarter Horses and related breeds.