Chromosome mapping of the rod photoreceptor cGMP phosphodiesterase β-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 β-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.     

Localization of the gene for interphotoreceptor retinoid-binding protein to mouse chromosome 14 near Np-1

Interphotoreceptor retinoid-binding protein (IRBP) is a large glycoprotein known to bind retinoids and found primarily in the interphotoreceptor matrix of the retina between the retinal pigment epithelium and the photoreceptor cells. It is thought to transport retinoids between the retinal pigment epithelium and the photoreceptors, a critical role in the visual process. We have used a 900-bp bovine IRBP cDNA fragment to map the corresponding gene, Rbp-3, to mouse chromosome 14 with somatic cell hybrids and have positioned the gene near Np-1 (nucleoside phosphorylase-1) by analysis of the progeny of an intersubspecific backcross. In the human genome, NP maps to human chromosome 14 and RBP3 to human chromosome 10. Thus, these two genes span the putative site of a chromosomal translocation which contributed to divergent karyotype evolution of man and mouse.     

Provisional assignment of the gene for uridine monophosphatase-2 (Umph-2) to mouse chromosome 11

The segregation of the mouse gene for uridine monophosphatase-2 (Umph-2) was examined in 14 independent mouse-Syrian hamster hybrids and 10 hybrid subclones. Umph-2 cosegregated with the mouse galactokinase (Glk) gene in 23 of the 24 hybrids and showed at least four discordances with all other mouse marker isozymes examined. The observed synteny of Umph-2 and Glk, which has also been observed in humans, indicates that the mouse Umph-2 gene is on chromosome 11.     

Tctex3, related to Drosophila Polycomblike, is expressed in male germ cells and mapped to the mouse t-complex

Tctex3 showing restricted expression in male germ cells has been isolated during the process of chromosome walking in the mouse t-complex region. The total sequence of Tctex3 cDNA predicts a protein of 580 amino acids with two C4HC3 type PHD fingers. The region containing this conserved motif is shared among members of the Polycomblike proteins that include the mouse M96 and Drosophila Polycomblike. A partial cDNA for a human homolog of Tctex3, HUTEX3, has also been isolated. Mouse Tctex3 gene was mapped adjacent to Tsc2 gene on mouse Chromosome (Chr) 17, and HUTEX3 was located closely to HSET gene in the HLA class II region of chromosome 6. Received: 10 April 1998 / Accepted: 22 June 1998     

Molecular cloning of the human gene STK10 encoding lymphocyte-oriented kinase, and comparative chromosomal mapping of the human, mouse, and rat homologues

 LOK is a new and unique member of the STE20 family with serine/threonine kinase activity, and its expression is restricted mostly to lymphoid cells in mice. We cloned the cDNA encoding the human homologue of LOK. The amino acid sequence deduced from the cDNA shows a high similarity to that of mouse LOK, with 88% identity as a whole. The kinase domains at the N-terminus and the coiled-coil regions at the C-terminus are particularly conserved, showing 98% and 93% identity, respectively. Western blot analysis with mouse LOK-specific antibody detected 130 000 M _r LOK proteins in human and rat lymphoid cell lines and tissues. The gene encoding the LOK (STK10/Stk10) gene was mapped by fluorescence in situ hybridization to chromosome 5q35.1 in human, chromosome 11A4 in mouse, and chromosome 10q12.3 in rat. By virtue of polymorphic CA repeats found in the 3' untranslated region of the mouse Stk10 gene, the Stk10 locus was further pinpointed to chromosome 11 between D11Mit53 and D11Mit84, using the intersubspecific backcross mapping panel. These results established STK10 as a new marker of human chromosome 5 to define the syntenic boundary of human chromosomes 5 and 16 on mouse chromosome 11. Received: 28 September 1998 / Revised: 2 November 1998     

Assignment of the Y4Receptor Gene (PPYR1) to Human Chromosome 10q11.2 and Mouse Chromosome 14

The human and mouse genes for the neuropeptide Y₄receptor have been isolated, sequenced, and shown to contain no introns within the coding region of the gene. Nonisotopicin situhybridization and interspecific mouse backcross mapping have localized the genes to human chromosome 10q11.2 and mouse chromosome 14. Five nucleotide variants, which do not alter the protein sequence, have been identified within the coding region of the human receptor gene. The human Y₄subtype is most closely related to the Y₁-receptor subtype (42%), suggesting that it evolved from an ancestral Y₁-like receptor via an RNA-mediated transpositional event.     

Localization of the rat immunoglobulin heavy chain locus to chromosome 6

We have previously used rat/mouse somatic cell hybrids to localize the rat c-myc gene to chromosome 7 (Sümegi et al. 1983) and the rat immunoglobulin kappa locus to chromosome 4 (Perlmann et al. 1985). We now report that by utilizing rat/mouse somatic cell hybrids, we have localized the rat immunoglobulin heavy chain locus to chromosome 6.     

Embryonic stem cells can be used to construct hybrid cell lines containing a single, selectable murine chromosome

Microcell-mediated chromosome transfer is a useful technique for the study of gene function, gene regulation, gene mapping, and functional cloning in mammalian cells. Complete panels of donor cell lines, each containing a different human chromosome, have been developed. These donor cell lines contain a single human chromosome marked with a dominant selectable gene in a rodent cell background. However, a similar panel does not exist for murine chromosomes. To produce mouse monochromosomal donor hybrids, we have utilized embryonic stem (ES) cells with targeted gene disruptions of known chromosomal location as starting material. ES cells with mutations in aprt, fyn, and myc were utilized to generate monochromosomal hybrids with neomycin phosphotransferase-marked murine Chr 8, 10, or 15 respectively in a hamster or rat background. This same methodology can be used to generate a complete panel of marked mouse chromosomes for somatic cell genetic experimentaion. Received: 28 July 1998 / Accepted: 15 December 1998     

The Mouse Glutathione PeroxidaseGpx2Gene Maps to Chromosome 12; Its PseudogeneGpx2-psMaps to Chromosome 7

TheGPX2gene codes for GSHPx-GI, a glutathione peroxidase whose mRNA is readily detectable in the gastrointestinal tract. AlthoughGPX2is a single gene in humans, there are two genes in the mouse genome with homology toGPX2.By analyzing a panel of mouse interspecies DNA from the Jackson Laboratory's backcross resource, we have chromosomally mapped these two genes. One was mapped to the central region of mouse chromosome 12 betweenD12Mit4andD12Mit5,nearfosandTgfb3.This region is homologous to human 14q24.1, where humanGPX2has been mapped, and most likely represents the functional mouseGpx2gene. The otherGpx2-like gene was mapped to mouse chromosome 7 betweenPcsk3andHbb.We have isolated the latter gene from a P1 phage library. Its pseudogene nature is revealed by the sequence analysis: (a) it is intronless; (b) it has a single nucleotide deletion in the coding region; and (c) it has a poly(A) tail at its 3′-untranslated region.     

The murine homolog of the human breast and ovarian cancer susceptibility geneBrca1 maps to mouse chromosome 11D

The recently cloned human breast and ovarian cancer suseptibility gene,BRCA1, is located on human chromosome 17q21. We have isolated murine genomic clones containingBrca1 as a first step in generating a mouse model for the loss ofBRCA1 function. A mouse genomic library was screened using probes corresponding to exon 11 of the humanBRCA1 gene. Two overlapping mouse clones were identified that hybridized to humanBRCA1 exons 9–12. Sequence analysis of 1.4 kb of the region of these clones corresponding to part of human exon 11 revealed 72% nucleic acid identity but only 50% amino acid identity with the human gene. The longest of the mouseBrca1 genomic clones maps to chromosome 11D, as determined by two-color fluorescence in situ hybridization. The synteny to human chromosome 17 was confirmed by cohybridization with the mouse probe for the NF1-gene. This comparative study confirms that the relative location of theBRCA1 gene has been conserved between mice and humans.     

Chromosomal Localization of the Human and Mouse Hyaluronan Synthase Genes

We have recently identified a new vertebrate gene family encoding putative hyaluronan (HA) synthases. Three highly conserved related genes have been identified, designatedHAS1, HAS2,andHAS3in humans andHas1, Has2,andHas3in the mouse. All three genes encode predicted plasma membrane proteins with multiple transmembrane domains and approximately 25% amino acid sequence identity to theStreptococcus pyogenesHA synthase, HasA. Furthermore, expression of any oneHASgene in transfected mammalian cells leads to high levels of HA biosynthesis. We now report the chromosomal localization of the threeHASgenes in human and in mouse. The genes localized to three different positions within both the human and the mouse genomes.HAS1was localized to the human chromosome 19q13.3–q13.4 boundary andHas1to mouse Chr 17.HAS2was localized to human chromosome 8q24.12 andHas2to mouse Chr 15.HAS3was localized to human chromosome 16q22.1 andHas3to mouse Chr 8. The map position forHAS1reinforces the recently reported relationship between a small region of human chromosome 19q and proximal mouse chromosome 17.HAS2mapped outside the predicted critical region delineated for the Langer–Giedion syndrome and can thus be excluded as a candidate gene for this genetic syndrome.     

The Protein Tyrosine Phosphatase ? Gene Maps to Mouse Chromosome 7 and Human Chromosome 10q26

We have mapped the mouse protein tyrosine phosphatase ? (PTP?, gene symbolPtpre) gene to the distal region of chromosome 7 by linkage analysis using two sets of multilocus genetic crosses. The humanPTP? gene (gene symbolPTPRE) was mapped to chromosome 10q26 by fluorescencein situhybridization. We have previously documented the existence of two isoforms ofPTP?—a transmembranal, receptor-type isoform and a shorter, cytoplasmic one. Both isoforms have been suggested to arise from a single gene through the use of alternative promoters and 5′ exons. The identification of a singlePTP? locus in both organisms is consistent with this suggestion.     

Tissue-Specific Expression and Mapping of theCox7ahGene in Mouse

We have isolated and examined the gene for the heart isoform of cytochromecoxidase subunit VIIa (COX VIIa-H) in mouse, an isoform gene previously thought to be lacking in rodents. Interspecies amino acid comparisons indicate that mouse COX VIIa-H protein displays 82.5 and 70.9% identity with the bovine and human heart isoforms of COX VIIa, but only 53.7% identity with the paralogous mouse liver isoform (COX VIIa-L). Expression in adult mouse tissues is limited to heart and skeletal muscle, as found in other species. In the early mouse embryo,Cox7alwas the exclusive isoform expressed andCox7ahmRNA was not detectable until day 17postcoitum.That the mouseCox7ahgene characterized in this study is orthologous to the humanCOX7AHgene was also suggested by its mapping to mouse chromosome 7, to a conserved region syntenic with the human chromosome location ofCOX7AH,19q13.1. As a result, all three COX heart isoform genes in mouse group to chromosome 7. Interestingly, mapping of the mouseCox7alto chromosome 9 suggests a new syntenic region between the mouse and the human genomes.     

Mapping of the Glycoprotein 330 (Gp330) Gene to Mouse Chromosome 2

Glycoprotein 330 (Gp330) is a member of the low-density lipoprotein receptor gene family that is expressed in the kidney. We have mapped the Gp330 gene to mouse chromosome 2, 4.5 cM proximal to Acra, in an interspecific backcross of (C57BL/6J × Mus spretus) F1 × C57BL/6J.     

A new dispensable genetic locus of the terminus region involved in control of cell division in Escherichia coli

Summary Temperature-sensitive mutants defective in cell division were isolated after localised mutagenesis of the terminus region of the Escherichia coli chromosome. The defective gene in one of these mutants, dicA, was mapped at 34.9 min by linkage with manA and with three physically characterized Tn10 insertions. Temperature-sensitivity conferred by mutation dicA1 in a recA backround was suppressed by the presence of hybrid plasmids carrying the wild-type gene. In addition, the mutation was suppressed either by tranposon inactivation of a nearby gene, dicB, or by deletion of the entire dicA-dicB interval. These results define the dicA-dicB locus as a new dispensable genetic cluster involved in the control of cell division.     

FXY2/MID2, a Gene Related to the X-Linked Opitz Syndrome Gene FXY/MID1, Maps to Xq22 and Encodes a FNIII Domain-Containing Protein That Associates with Microtubules

Opitz G/BBB syndrome (OS) is a genetically heterogeneous disorder with an X-linked locus and an autosomal locus linked to 22q11.2. OS affects multiple organ systems with often variable severity even between siblings. The clinical features, which include hypertelorism, cleft lip and palate, defects of cardiac septation, hypospadias, and anorectal anomalies, indicate an underlying disturbance of the developing ventral midline of the embryo. The gene responsible for X-linked OS, FXY/MID1, is located on the short arm of the human X chromosome within Xp22.3 and encodes a protein with both an RBCC (RING finger, B-box, coiled coil) and a B30.2 domain. The Fxy gene in mice is also located on the X chromosome but spans the pseudoautosomal boundary in this species. Here we describe a gene closely related to FXY/MID1, called FXY2, which also maps to the X chromosome within Xq22. The mouse Fxy2 gene is located on the distal part of the mouse X chromosome within a region syntenic to Xq22. Analysis of genes flanking both FXY/MID1 and FXY2 (as well as their counterparts in mouse) suggests that these regions may have arisen as a result of an intrachromosomal duplication on an ancestral X chromosome. We have also identified in both FXY2 and FXY/MID1 proteins a conserved fibronectin type III domain located between the RBCC and B30.2 domains that has implications for understanding protein function. The FXY/MID1 protein has previously been shown to colocalize with microtubules, and here we show that the FXY2 protein similarly associates with microtubules in a manner that is dependent on the carboxy-terminal B30.2 domain.     

In situ hybridisation localises the gene for the major intrinsic protein of eye lens fibre cell membranes to human chromosome 12q14.

The gene encoding the major intrinsic protein (MIP) of eye lens fibre cell membranes has been localised to human chromosome 12q14 by in situ hybridisation of a cDNA for rat MIP to G-banded metaphase chromosomes. The human MIP gene maps within a conserved region of synteny with mouse Chromosome 10.     

Assignment of the gene governing cellular ouabain resistance to Mus musculus chromosome 3 using human/mouse microcell hybrids

Human/mouse microcell hybrids were used to establish the assignment of the gene governing resistance to the cardiac glycoside ouabain (Oua-1) to Mus musculus chromosome 3. Microcells were prepared from primary mouse embryo fibroblasts and fused with HeLa S3 cells, and microcell hybrids were isolated and maintained in medium containing 10^–6 m ouabain. Resistance to ouabain was not expressed concordantly with any of 26 murine isozyme markers. Karyotypic analysis of five primary clones showed that one to five murine chromosomes had been transferred from donor to recipient in these experiments. Only mouse chromosome 3 was common to all ouabain-resistant primary clones. Both ouabain-resistant and -sensitive subclones were isolated from hybrids grown in the absence of selective pressure, and karyotyping showed that loss of resistance to ouabain was concordant with the loss of murine chromosome 3.These studies were supported by Grant GM9966 from the National Institutes of Health.     

MappingTNNC1, the Gene That Encodes Cardiac Troponin I in the Human and the Mouse

We have mapped the TNNC1 gene, whose protein product is the cardiac TnI protein. TnI is one of the proteins that makes up the troponin complex, which mediates the response of muscle to calcium ions. The human TNNC1 locus had been assigned to a large region of chromosome 19, and we have refined the mapping position to the distal end of the chromosome by amplification of DNAs from a chromosome 19 mapping panel. We have also mapped the mouse Tnnc1 locus, by following the segregation of an intron sequence through DNAs from the European Interspecific Backcross. Tnnc1 maps close to the centromere on mouse chromosome 7.