Mammalian Genome

Marschall, Susan ; Huffstadt, Ulrike ; Balling, Rudi ; Hrabě de Angelis, Martin

doi: 10.1007/s003359901090pmid: 10430662

Since the mouse has become the most detailed model system to investigate the genetics and pathogenesis of human diseases, large numbers of new mouse strains have and continue to be produced. In nearly all animal facilities, the maintenance of breeding colonies is limited and mouse strains have to be archived in an efficient way. This study was undertaken to test the reliability of recovering mouse lines by use of cryopreserved spermatozoa from individual male mice. In contrast to many studies, spermatozoa and oocytes were derived from the same genetic background. 30 C3HeB/FeJ males belonging to three different categories (wild-type, F1-generation of ENU-treated males, and defined mutants) were recovered by producing at least 20 offspring from each donor. Independent of the experimental group, every single male was successfully recovered. Archiving mouse strains by cryopreservation of spermatozoa may, therefore, offer a reliable way to preserve genetically valuable mouse strains and provides an efficient management strategy for animal facilities.

Suto, Jun-ichi ; Yamanaka, Harumichi ; Sekikawa, Kenji

doi: 10.1007/s003359901091pmid: 10430663

Nearly all F1 male mice with Dh/+ genotype between DDD female and DH–Dh/+ male die within a few days after birth; however, this is not observed in the reciprocal cross. The F1 Dh/+ males usually exhibit growth retardation prior to death. To identify the putative genetic locus or loci in DDD genome that cause the abnormalities in the presence of the Dh, a linkage analysis was carried out in backcross progeny of a cross of (DDD female × DH–+/+ male) F1 female × DH–Dh/+ male. Appearance of growth retardation was examined from the day of birth, and both growth-retarded and normally weaned Dh/+ males were genotyped for microsatellite marker loci spanning autosomes and the X Chromosome (Chr). Significant evidence for linkage was identified on the distal edge of the X Chr, near the microsatellite marker of DXMit135. Furthermore, among mice from DDD female × reciprocal F1 Dh/+ male produced between DH–Dh/+ and progenitor strains (C57BL/6J, C3H/HeJ and BALB/cA), only the progeny from ♀DDD ×♂(♀DH–Dh/+×♂C3H/HeJ) F1 Dh/+ male did not show any lethality and/or growth retardation. Thus, the lethality in F1 Dh/+ males accompanied by growth retardation is caused by the interactions between the Dh gene, X Chr, and Y Chr. Based on the CAG repeat sequence length polymorphism among Mus musculus musculus Sry gene, C3H/HeJ was different from C57BL/6J, BALB/cA, and DH. These data suggest that there are at least two functional types of Y Chr in Mus musculus musculus.

Persson, Kent ; Heby, Olle ; Berger, Franklin G.

doi: 10.1007/s003359901092pmid: 10430664

S-Adenosylmethionine decarboxylase (AdoMetDC) is a key enzyme in the biosynthesis of polyamines. We have previously identified a mouse AdoMetDC gene that exhibits the hallmarks of a retroposon; that is, it has no introns, is flanked by direct repeats, and has a poly(dA) tract at its 3′-end. This gene, termed Amd-2, is not a processed pseudogene; rather, it is transcribed in a variety of mouse tissues and encodes a functional enzyme. In the current report, we present the sequence of a 6.7-kb genomic segment of the Amd-2 locus. Several sequences of interest, including an intercisternal A particle (IAP) element, a transposon-related sequence, and several expressed sequence tags (ESTs), were found within or near Amd-2. We also show, through analysis of an interspecific backcross, that Amd-2 is located on Chr 12, tightly linked to the gene (Odc) that encodes ornithine decarboxylase, another key enzyme in polyamine synthesis. Finally, we show that Amd-2 is present among several divergent species of the genus Mus. Thus, the integration event that generated Amd-2 may have occurred early during Mus evolution.

Norsworthy, Peter J. ; Taylor, Philip R. ; Walport, Mark J. ; Botto, Marina

doi: 10.1007/s003359901093pmid: 10430665

Binding of C1q to cell surfaces has been shown to mediate a number of biological activities including enhancement of phagocytosis and stimulation of superoxide production. Several C1q binding proteins have been proposed as candidate receptors for these functions. The 126-kDa human C1q membrane receptor, termed C1qRp, has recently been cloned. This molecule is believed to play a role in the enhancement of phagocytosis in monocytes and macrophages, and its expression has been shown to be restricted to cells of the myeloid lineage, endothelial cells, and platelets. Here we report the isolation and genomic characterization of the murine homolog of C1qRp. Degenerate oligonucleotide primers based on the published human sequence were used to amplify a region of the murine homolog spanning from the carbohydrate recognition domain to the fourth epidermal growth factor (EGF) domain. This fragment was used as a probe to isolate the murine gene from a 129/Sv genomic λ library. The predicted primary protein sequence displayed 68.1% identity with the human homolog. All the major structural domains were conserved between the two molecules. The coding sequence of the murine gene was contained within two exons separated by a small intron of approximately 250 bp. The structure of the human gene was found to be similar, with the position of the intron conserved. Cloning of the murine C1qRp will facilitate further investigation of the physiological function of this molecule.

Kispert, Andreas ; Stöger, Reinhard J. ; Caparros, Marta ; Herrmann, Bernhard G.

doi: 10.1007/s003359901094pmid: 10430666

A variant form of mouse Chromosome (Chr) 17, the t-haplotype, contains several loci responsible for transmission ratio distortion in males. Sperm carrying the responder locus (Tcr) have a high probability of fertilizing eggs at the expense of wild-type sperm, provided that distorter loci (Tcd-1 to Tcd-5) are expressed during spermatogenesis. Tcr has been mapped to the Leh66b region within a maximum of 155 kb. In the search for genes in the genomic region Leh66EI, we have identified the mouse homolog of human ribosome S6 kinase 3 (RSK3) on cosmid DNA. The complete mouse Rsk3 gene is encoded in the region Leh66a of t-haplotypes and Leh66EI of the wild-type chromosome. It consists of at least 13 exons spanning over more than 120 kb. Rsk3 is expressed in embryos and in several adult organs including testis. Cosmids covering 100 kb of the Leh66b region or 120 kb of the Leh66a region were isolated. Rsk3 covers about 65 kb of the Leh66b region and appears to be incomplete at its 5′-end. A correlation of the physical map provided here with the genetic mapping of Tcr reported previously suggests that Tcr is most likely encoded within a fragment of 30 kb upstream or 20 kb downstream of Rsk3. These data will facilitate the isolation of Tcr, a prerequisite for understanding transmission ratio distortion in mouse.

Priat, Catherine ; Jiang, Zhihua H. ; Renier, Corinna ; André, Catherine ; Galibert, Francis

doi: 10.1007/s003359901095pmid: 10430667

In total, 463 canine gene markers were identified and characterized to serve as reagents in canine genome map projects. These markers are distributed over 221 canine gene markers, 139 TOASTs (Traced Orthologous Sequence Tags), 27 canine TOASTs, and 76 huESTs (human Expressed Sequence Tags). Out of 310 canine gene markers, 59%–84% were successfully amplified on dog DNA, the highest rates of success being observed when the exon/intron structure is known. Concerning TOASTs and human ESTs, of the 225 and 300 markers analyzed, 62% and 25% respectively were able to produce a dog positive amplification. As part of an ongoing project to map the canine genome using a dog/hamster radiation hybrid panel, these markers were tested for their specificity on dog versus hamster DNA. Thus 61%, 21%, and 12% of dog gene markers, TOASTs, and huESTs met the criteria required for radiation hybrid mapping, respectively. All of these 463 canine gene markers, however, are available and will be of value to any other mapping strategies.

Werner, Petra ; Mellersh, Cathryn S. ; Raducha, Michael G. ; DeRose, Susan ; Acland, Gregory M. ; Prociuk, Ulana ; Wiegand, Neil ; Aguirre, Gustavo D. ; Henthorn, Paula S. ; Patterson, Donald F. ; Ostrander, Elaine A.

doi: 10.1007/s003359901096

Hawken, Rachel J. ; Murtaugh, Jeremy ; Flickinger, Gail H. ; Yerle, Martine ; Robic, Anne ; Milan, Denis ; Gellin, Joel ; Beattie, Craig W. ; Schook, Lawrence B. ; Alexander, Leeson J.

doi: 10.1007/s003359901097pmid: 10430669

Elo, Kari T. ; Vilkki, Johanna ; de Koning, Dirk-Jan ; Velmala, Riikka J. ; Mäki-Tanila, Asko V.

doi: 10.1007/s003359901098pmid: 10430670

A multiple-marker mapping approach was used to search for quantitative trait loci (QTLs) affecting production, health, and fertility traits in Finnish Ayrshire dairy cattle. As part of a whole-genome scan, altogether 469 bulls were genotyped for six microsatellite loci in 12 families on Chromosome (Chr) 23. Both multiple-marker interval mapping with regression and maximum-likelihood methods were applied with a granddaughter design. Eighteen traits, belonging to 11 trait groups, were included in the analysis. One QTL exceeded experiment level and one QTL genome level significance thresholds. Across-families analysis provided strong evidence (Pexperiment= 0.0314) for a QTL affecting live weight. The QTL for live weight maps between markers BM1258 and BoLA DRBP1. A QTL significant at genome level (Pgenome= 0.0087) was mapped for veterinary treatment, and the putative QTL probably affects susceptibility to milk fever or ketosis. In addition, three traits exceeded the chromosome 5% significance threshold: protein percentage of milk, calf mortality (sire), and milking speed. In within-family analyses, protein percentage was associated with markers in one family (LOD score = 4.5).

Festing, Michael F.W. ; Simpson, Elizabeth M. ; Davisson, Muriel T. ; Mobraaten, Larry E.

doi: 10.1007/s003359901099pmid: 10430671