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.     

Mapping of the mouse 86-kDa heat-shock protein expressed gene (Hsp86-1) on chromosome 12 and related genes on chromosomes 3, 4, 9, and 11

The HSP86 gene family in BALB/c, AKR/J, C58/J, and NFS/N inbred mice comprises an intron-containing expressed gene and, depending on the strain, two to four other HSP86-related members that are apparently processed pseudogenes. The expressed gene locus, Hsp86-1, was identified by its sequence identity with the mouse HSP86 cDNA coding region together with the presence of an intron at the same position as in the homologous human gene. Hsp86-1 was mapped 11.6 cM from the immunoglobulin heavy chain gene IgH on Chromosome 12 using an intersubspecies backcross. Two of the other loci that were common to all inbred strains tested, designated Hsp86-ps1 and Hsp86-ps2, were mapped to positions on Chromosomes 11 and 3, respectively. An HSP86-related locus specific to NFS/N and C58/J mice, designated Hsp86-ps3, was mapped on Chromosome 9. Also, an HSP86-related locus that was unique to NFS/N mice, designated Hsp86-ps4, was mapped to Chromosome 4.     

Localisation of the gene for the major intrinsic protein of eye-lens-fibre cell membranes to mouse chromosome 10 by in situ hybridisation.

The gene encoding the major intrinsic protein (Mip) of eye-lens-fibre cell membranes has been assigned to region D1 of mouse Chromosome 10 by in situ hybridisation of a cDNA for rat MIP to G-banded metaphase chromosomes. The mouse Mip gene maps within or near to a segment homoeologous with human chromosome 12q and may be linked to the Cat locus at the distal end of mouse Chromosome 10.     

Structure of the murine E-selectin ligand 1 (ESL-1) gene and assignment to Chromosome 8

A 150-kDa glycoprotein designated in the mouse as E-selectin ligand-1 (ESL-1; gene symbol Selel) was first isolated based on its ability to function as a ligand for E-selectin. The gene appears equivalent to that for membrane glycoprotein MG160 encoded in the human by the locus for Golgi apparatus protein 1 (GLG1). ESL-1 is also highly homologous to the chicken cysteine-rich fibroblast growth factor receptor (CFR). We describe the genomic structure and chromosomal localization of the Selel locus. The gene is encoded by 27 exons and extends over approximately 75 kb. It maps to murine Chromosome (Chr) 8 in a region homologous to human Chr 16q where the GLG1 locus maps, further indicating that Selel and GLG1 are mouse and human equivalents of the same gene. Received: 21 April 1999 / Accepted: 12 July 1999     

A serum protein polymorphism determinant on chromosome 9 of Mus musculus

Summary Genetic polymorphism for a previously undescribed serum protein has been found among inbred strains of Mus musculus. The new serum protein locus, gene symbol Sep-1, has been located on Chromosome 9, gene order Lap-1-Sep-1-Mpi-1-d-Mod-1, by utilizing information obtained from 52 recombinant inbred strains together with standard genetic backcrosses. The strain distribution pattern for this locus, supernatant malic enzyme, and transferrin, also on Chromosome 9, are given for 67 inbred strains. Because the genotype of SEP-1 can be determined for individual mice without killing them, Sep-1 is a very useful gene in linkage studies and experimental biology.     

Deconstruction of the (paleo)polyploid grapevine genome based on the analysis of transposition events involving NBS resistance genes

Plants have followed a reticulate type of evolution and taxa have frequently merged via allopolyploidization. A polyploid structure of sequenced genomes has often been proposed, but the chromosomes belonging to putative component genomes are difficult to identify. The 19 grapevine chromosomes are evolutionary stable structures: their homologous triplets have strongly conserved gene order, interrupted by rare translocations. The aim of this study is to examine how the grapevine nucleotide-binding site (NBS)-encoding resistance (NBS-R) genes have evolved in the genomic context and to understand mechanisms for the genome evolution. We show that, in grapevine, i) helitrons have significantly contributed to transposition of NBS-R genes, and ii) NBS-R gene cluster similarity indicates the existence of two groups of chromosomes (named as Va and Vc) that may have evolved independently. Chromosome triplets consist of two Va and one Vc chromosomes, as expected from the tetraploid and diploid conditions of the two component genomes. The hexaploid state could have been derived from either allopolyploidy or the separation of the Va and Vc component genomes in the same nucleus before fusion, as known for Rosaceae species. Time estimation indicates that grapevine component genomes may have fused about 60 mya, having had at least 40-60 mya to evolve independently. Chromosome number variation in the Vitaceae and related families, and the gap between the time of eudicot radiation and the age of Vitaceae fossils, are accounted for by our hypothesis.     

A murine locus on chromosome 18 controls NKT cell homeostasis and Th cell differentiation

Th cell differentiation is a critical event in the adaptive immune response. C57BL strains develop predominant Th1 responses while BALB/c develops a predominant Th2 response. To identify quantitative trait loci controlling this variation, we performed Th1/Th2 differentiation assays of F(1) x BALB/c progeny. A single strong quantitative trait locus was identified on chromosome 18, with weaker effects detectable on chromosomes 5, 12, and 14. By preparing a congenic BALB.B10.D2c18 strain, we were able to demonstrate that this single locus was sufficient to "repolarize" spleen cell cultures. This difference was not due to intrinsic differences in CD4(+) T cells. Rather, introgression of the chromosome 18 locus into BALB/c disrupted Va14Ja18 NKT cell homeostasis resulting in the almost complete absence of this T cell subset. Taken together, these data indicate that genes within chromosome 18 control strain-dependent development of Va14Ja18 NKT cells.     

FISH mapping of the IGF2 gene in horse and donkey—detection of homoeology with HSA11

Three genomic subclones derived from a phage clone containing the equine IGF2 gene were used to FISH map the gene on horse (ECA) and donkey (EAS) metaphase chromosomes. The gene mapped on ECA 12q13 band and is the first locus mapped to this horse chromosome. In donkey the gene mapped very terminal on the long arm of one small submetacentric chromosome that shows almost identical DAPI-banding pattern with ECA12. This is the first locus mapped in donkey genome. Cross species chromosome painting of equine metaphase chromosomes with human Chromosome (Chr) 11-specific probe showed homoeology of this human chromosome with ECA12 and ECA7. The novel ECA12 comparative painting results are thus in accordance with the localization of the equine IGF2 gene. Comparison of the hitherto known physical locations of IGF2 in different species, viz. human, cattle, sheep, horse, and donkey, shows that this gene tends to maintain a terminal location on the chromosome arm. Received: 12 January 1997 / Accepted: 17 March 1997     

The identification, characterization, and mapping of a gene for flocculation in Saccharomyces sp.

Genetic studies of a flocculent haploid strain of Saccharomyces have revealed the flocculation to be dominant and controlled at a single gene locus. The flocculation character of both hybrids and haploids derived from such hybrids appears to be influenced by the repression or derepression status of the culture. Mapping studies of this flocculation gene have revealed that it is linked to ade 1 and therefore located on Chromosome I. Consequently, this is a different gene to the three flocculation genes studied by other laboratories because they have found such genes to be unlinked to ade 1. The flocculation gene being discussed in this paper has been designated FLO4. FLO4 has been located 32-33 cM from the Chromosome I centromere and 37 cM from ade 1 (i.e., FLO4 is on the opposite side of the centromere to ade 1).     

Chromosomal localization of three vacuolar-H+ -ATPase 16 kDa subunit (ATP6V0C) genes in the murine genome

Vacuolar-H(+)-ATPase (V-H-ATPase) is a large multimeric protein composed of at least 12 distinct subunits. The 16-kDa hydrophobic proteolipid subunit (ATP6V0C; ATPase, H(+ )transporting, lysosomal 16 kDa, V0 subunit C) plays a central role in H(+) transport across cellular membranes. We have mapped three ATP6V0C genes (Atp6v0c, Atp6v0c-ps1 and Atp6voc-ps2) in the murine genome. Atp6v0c-ps1 and Atp6v0c-ps2 map to Chromosomes 7 and 6, respectively. Atp6v0c maps to Chromosome 17, closely linked to the Tsc2 locus and D17Mit55. This region of Chromosome 17 in mouse is homologous with chromosome 16 in human where the ATP6V0C gene is localized.     

The AKT1 proto-oncogene maps to human chromosome 14, band q32

The human AKT1 gene is the proto-oncogene of the viral oncogene v-akt. The AKT1 gene has been localized to human chromosome 14, band q32, proximal to the heavy-chain immunoglobulin locus (IGHM), by analysis of human-hamster somatic cell hybrids and by in situ hybridization. Chromosome rearrangements of this band which occur in T-lymphoid malignancies and Hodgkin's disease may affect the AKT1 gene.     

水稻抗白叶枯病基因Xa4位点跨叠BAC克隆群的构建

水稻白叶枯病抗性基因Xa4已被定位于第11染色体长臂末端的分子标记VG181和L1044之间,并与抗性基因同源序列片段RS13共分离。利用这3个标记筛选IRBB56的BAC文库,共得到128个阳性BAC克隆,其中RS13获得18个阳性克隆,这18个克隆中有4个和6个我隆分别同时为G181和L1044的阳性克隆,选其中的12克隆进行分析,构建了一个从G181到L1044区间的BAC跨叠克隆,全长420kb,并且56M22、106P13和104B153个BAC克隆可覆盖整个跨叠克隆群。这一研究结果为进一步分离Xa4基因打下基础。     

Location of histocompatibility and interferon loci on chromosome 3 of the mouse

Two histocompatibility loci, H-23 and H-28, and an interferon locus, If-1, are shown linked to matted, ma, and varitint-waddler, Va, on chromosome 3 of the mouse. The gene order (from centromere) with intervening percent recombination is: ma-19.1(+/- 4.9)-H-23-12.0(+/- 4.0)-VaJ-7.7(+/- 2.2)-H-28-5.9(+/- 2.2)-If-1.     

A locus for eosinophilia in the MES rat is on Chromosome 19

Matsumoto Eosinophilia Shinshu (MES) is a rat strain that spontaneously develops eosinophilia and eosinophil-related inflammatory lesions in many organs. We performed chromosomal mapping of the gene for eosinophilia by breeding backcross progeny. The onset of eosinophilia appeared to be delayed in the progeny compared with that in MES, with the prevalence of eosinophilia in the backcross progeny at 12 weeks of age being 22.5%. Genetic linkage analysis with marker loci indicated the major locus for eosinophilia was located at the end of the q arm region of Chromosome 19 (between D19Rat8 and telomere). The locus was denoted eosinophilia 1 (eos1). These data will form the basis for identification of the eos1 gene using a reverse genetic approach, which will hopefully lead to elucidation of the mechanisms involved in eosinophilia and eosinophilopoiesis.     

The defensin-related murine CRS1C gene: expression in Paneth cells and linkage to Defcr, the cryptdin locus.

The site of defensin-related CRS1C gene expression in mouse small bowel and the chromosomal location of the CRS1C locus, Defcr-rs1, have been determined. CRS1C (cryptdin-related sequence 1C) mRNA is an abundant small intestinal sequence that exhibits extensive similarity to the prepro-coding regions of defensin mRNAs yet does not encode a defensin (A. J. Ouellette and J. C. Lualdi, 1990, J. Biol. Chem. 265: 9831-9837). Using sequence-specific probes, CRS1C mRNA was detected in Paneth cells at the base of intestinal crypts by in situ hybridization. Southern blot analysis of genomic DNAs from inbred and recombinant inbred (RI) mouse strains, also conducted with probes specific for CRS1C, showed that the CRS1C locus maps to the proximal region of Chromosome 8. In 62 RI strains, no discordancies were found between Defcr-rs1 and Defcr, the cryptdin gene. Thus, both the Defcr-rs1 and the Defcr genes are expressed in Paneth cells and both are genetically inseparable within 1.58 cM on Chromosome 8. These studies identify a second defensin-related Paneth cell gene in mice.     

The bovine lactoferrin gene (LTF) maps to Chromosome 22 and syntenic group U12

Five overlapping lambda EMBL-clones, containing the complete bovine lactoferrin gene (LTF), have been used to map this gene by fluorescence in situ hybridization to bovine Chromosome (Chr) band 22q24. Primers derived from promoter and exon I sequences were applied in polymerase chain reactions (PCRs) to DNA samples of a previously characterized panel of somatic cell hybrid lines, allowing the assignment of the bovine lactoferrin locus to syntenic group U12. These results permit the assignment of syntenic group U12 to bovine Chr 22.     

Genes for serum amyloid A proteins map to Chromosome 7 in the mouse

Summary Several restriction fragment length variants have been detected among inbred strains using a mouse serum amyloid A cDNA clone. Five variants were shown to segregate as a single genetic unit and were mapped to Chromosome 7 between the glucose phosphate isomerase locus (Gpi-1) and the pink eye dilution locus (p) using recombinant inbred and congenic strains. The finding that no major MspI or BclI restriction fragments were shared between digests of DNAs from a Chromosome 7 congenic strain and its inbred partner, indicate that most, and probably all, sequences detected with the probe are clustered on Chromosome 7. Aneuploid mapping was used to show that the serum amyloid A gene complex (Saa) is proximal to the Chromosome 7 breakpoint in T(7;X)1Ct, a translocation in which the middle third of Chromosome 7 is inserted into the X-chromosome. A survey of inbred strains revealed a single common Saa haplotype and eight rare haplotypes. The complex distribution of 14 different variants suggests that recombination may have played a role in haplotype evolution.This work was supported by grants GM18684 and CA33093 from the National Institute of General Medical Sciences and the National Cancer Institute, respectively.     

Host defenses in experimental scrub typhus: mapping the gene that controls natural resistance in mice

Natural resistance of mice to lethal ifections of Rickettsia tsutsugamushi, strain Gilliam, is controlled by a single, autosomal, dominant gene, which we have designated Ric, with r and s representing the resistant nd susceptible alleles, respectively. Using three sets of recombinant inbred mouse strains (BXD, BXH, and BXJ), the Ric locus was mapped to Chromosome 5 closely linked to the retinal degeneration (rd) locus. This linkage was confirmed by a backcross analysis. Based on the RI strains and the C57BL/6Ty-le congenic strain (the only proven Ric-rd cross-over), we estimate the recombination frequency between Ric and rd to be 0.015. Three presumptive Ric-rd recombinants detected among 93 backcross mice may represent caes of incomplete penetrance of the resistance allele rather than recombination. Analyis of th C57BL/6JTy-le congenic strain indicates that Ric is proximal to rd on Chromosome 5. If so, the correct gene order is Pgm-1-W-Ric-rd-Gus.     

Localization of the gene encoding myelin basic protein to mouse chromosome 18E3----4 and rat chromosome 1p11----p12.

The location of a gene encoding myelin basic protein in rat (MBP) and mouse (Mbp) was determined by in situ hybridization using the mouse Mbp cDNA labeled with biotin-11-dUTP as a specific probe. The localization of biotin signals in the mouse was found on Chromosome 18E2----3. The result is consistent with the previous report that the Mbp gene is located on the distal half of Chromosome 18. In the rat, the signals localized on chromosome 1p11----p12, suggesting homology between mouse Chromosome 18 and the short arm of rat chromosome 1.     

Distinct QTLs are linked to cardiac left ventricular mass in a sex-specific manner in a normotensive inbred rat intercross

Genetic mapping of the progeny of an F₂ intercross between WKY and WKHA rats had previously allowed us to detect male-specific linkage between locus Cm24 and left ventricular mass index (LVMI). By further expanding that analysis, we detected additional loci that were all linked to LVMI in a sex-specific manner despite their autosomal location. In males, we detected one additional locus (Lvm8) on Chromosome 5 (LOD = 3.4), the two loci Lvm13 (LOD = 4.5) and Lvm9 (LOD = 2.8) on Chromosome 17, and locus Lvm10 (LOD = 4.2) on Chromosome 12. The locus Lvm13 had the same boundaries as locus Cm26 previously reported by others using a different cross. None of these loci showed linkage to LVM in females. In contrast, we identified in females the novel locus Lvm11 on Chromosome 15 (LOD = 2.8) and locus Lvm12 (LOD = 2.7) that had the same boundaries on Chromosome 3 as locus Cm25 detected previously by others using a cross of other normotensive strains. In prepubertal males, there were no differences in the width of cardiomyocytes from WKY and WKHA rats, but cardiomyocytes from WKHA became progressively wider than that of WKY as sexual maturation progressed. Altogether, these results provide evidence that distinct genes may influence LVMI of rats in a sex-dependent manner, maybe by involving sex-specific interactions of sex steroids with particular genes involved in the determination of LVMI and/or cardiomyocyte width.