Assignment of the human ST2 gene to chromosome 2 at q11.2

The humanSt2 locus has been assigned to chromosome 2, using a human ST2 cDNA clone, by a human/rodent somatic cell hybrid mapping panel. TheSt2 locus has also been mapped to chromosome 2811.2, using a human ST2 genomic DNA clone, by in situ hybridization. The locus is very tightly linked to theIl-1r1 locus. Together with the structural similarity of ST2 to IL-1RI, these data suggest functional relationships between these two genes.     

Comparative mapping of mouse chromosome 2 and human chromosome 9q: the genes for gelsolin and dopamine beta-hydroxylase map to mouse chromosome 2.

The mapping of human chromosome 9 (HSA9) and mouse chromosome 2 (MMU2) has revealed a conserved syntenic region between the distal end of the long arm of chromosome 9 and proximal mouse chromosome 2. Two genes that map to human chromosome 9q34, gelsolin (GSN) and dopamine beta-hydroxylase (DBH), have not previously been located in the mouse. We have used an interspecific backcross to map each of these genes, by Southern blot analysis, to mouse chromosome 2. Gelsolin (Gsn) is tightly linked to the gene for complement component C5 (Hc), and dopamine beta-hydroxylase (Dbh) is just proximal to the Abelson leukemia virus oncogene (Abl) and alpha-spectrin 2 (Spna-2). The loci for gelsolin and dopamine beta-hydroxylase therefore form part of the conserved synteny between HSA9q and MMU2.     

Regional localization of the LCA oncogene to human chromosome region 2q14----q21

A novel human oncogene, LCA, was assigned to region 2q14----q21 by in situ molecular hybridization. The present regional mapping substantiates the previous assignment that was performed by Southern blot analyses of DNAs from flow-sorted human chromosomes and human-mouse somatic cell hybrids.     

Localization of the acetylcholine receptor gamma subunit gene to human chromosome 2q32----qter

The nicotinic acetylcholine receptor of skeletal muscle (CHRN in man, Acr in mouse) is a transmembrane protein composed of four different subunits (alpha, beta, gamma, and delta) assembled into the pentamer alpha 2 beta gamma delta. These subunits are encoded by separate genes which derive from a common ancestral gene by duplication. We have used a murine full-length 1,900-bp-long cDNA encoding the gamma subunit subcloned into M 13 (clone gamma 18) to prepare single-stranded probes for hybridization to EcoRI-digested DNA from a panel of human x rodent somatic cell hybrids. Using conditions of low stringency to favor cross-species hybridization, and prehybridization with rodent DNA to prevent rodent background, we detected a single major human band of 30-40 kb. The pattern of segregation of this 30-40 kb band correlated with the segregation of human chromosome 2 within the panel and the presence of a chromosomal translocation in the distal part of the long arm of this t(X;2)(p22;q32.1) chromosome allowing the localization of the gamma subunit gene (CHRNG) to 2q32----qter. The human genes encoding the gamma and delta subunits have been shown to be contained in an EcoRI restriction fragment of approximately 20 kb (Shibahara et al., 1985). Consequently, this study also maps the delta subunit gene (CHRND) to human chromosome 2q32.1----qter. In the mouse, the Acrd and Acrg genes have been shown to be linked to Idh-1, Mylf (IDH1 and MYL1 in humans, respectively) and to the gene encoding villin on chromosome 1. Interestingly, we have recently localized the human MYL1 gene to the same chromosomal fragment of human chromosome 2. These results clearly demonstrate a region of chromosomal homoeology between mouse chromosome 1 and human chromosome 2.     

Assignment of the S-antigen gene (SAG) to human chromosome 2q24-q37

We report the mapping of the gene coding for the S-antigen (48-kDa protein) to human chromosome 2 using somatic cell hybrids. In situ hybridization further confirms this assignment and regionally maps the gene to 2q24-q37.     

Localization of the xeroderma pigmentosum group B-correcting gene ERCC3 to human chromosome 2q21

The human excision-repair gene ERCC3 was cloned after DNA-mediated gene transfer to the uv-sensitive Chinese hamster ovary mutant cell line 27-1, a member of complementation group 3 of the excision-defective rodent cell lines. The ERCC3 gene specifically corrects the DNA repair defect of xeroderma pigmentosum (XP) complementation group B, which displays the clinical symptoms of XP as well as of another rare excision-repair disorder, Cockayne syndrome. The gene encodes a presumed DNA and chromatin binding helicase, involved in early steps of the excision-repair pathway. ERCC3 was previously assigned to human chromosome 2 (L.H. Thompson, A.V. Carrano, K. Sato, E.P. Salazar, B.F. White, S.A. Stewart, J.L. Minkler, and M.J. Siciliano (1987) Somat. Cell Genet. 13: 539-551). Here we report its subchromosomal localization in the q21 region of chromosome 2 via somatic cell hybrids containing a translocated chromosome 2 and in situ hybridization with fluorescently labeled ERCC3 probes.     

Localization of the human gene allowing infection by gibbon ape leukemia virus to human chromosome region 2q11-q14 and to the homologous region on mouse chromosome 2.

Retrovirus receptors remain a largely unexplored group of proteins. Of the receptors which allow infection of human and murine cells by various retroviruses, only three have been identified at the molecular level. These receptors include CD4 for human immunodeficiency virus, Rec-1 for murine ecotropic virus, and GLVR1 for gibbon ape leukemia virus. These three proteins show no homology to one another at the DNA or protein level. Therefore, work to date has not shown any general relationship or structural theme shared by retroviral receptors. Genes for two of these receptors (CD4 and Rec-1) and several others which have not yet been cloned have been localized to specific chromosomes. In order to assess the relationship between GLVR1 and other retroviral receptors, we mapped the chromosome location of GLVR1 in human and mouse. GLVR1 was found to map to human chromosome 2q11-q14 by in situ hybridization and somatic-cell hybrid analysis. This location is distinct from those known for receptors for retroviruses infecting human cells. Glvr-1 was then mapped in the mouse by interspecies backcrosses and found to map to chromosome 2 in a region of linkage conservation with human chromosome 2. This mouse chromosome carries Rec-2, the likely receptor for M813, a retrovirus derived from a feral Asian mouse. These data raise the interesting possibility that Rec-2 and Glvr-1 are structurally related.     

Localization of the villin gene on human chromosome 2q35-q36 and on mouse chromosome 1

Summary A partial cDNA clone coding for the 110 carboxyterminal amino acids of human villin was used for mapping the human villin gene. In situ hybridization experiments on human chromosomes with tritiated probe allowed the regional localization of the villin locus to chromosome 2 at q35-36. Data obtained from restriction fragment length polymorphism analysis of two mouse species demonstrated the assignment of the villin gene to mouse chromosome 1 by assessment of linkage with the fast skeletal isoform of the myosin light-chain gene. These villin gene localizations add a fourth locus to the conserved gene cluster encoding the fast skeletal muscle isoform of the myosin light chain, isocitrate dehydrogenase, and the crystallins and confirm the partial homology of the human chromosome 2 long arm and mouse chromosome 1.     

Mapping of the kinesin-related gene ATSV to chromosome 2q37

The human ATSV (axonal transporter of synaptic vesicles) gene encodes an anterograde axonal motor transport protein and demonstrates homology to the kinesin gene family in several species. The human ATSV gene was mapped to chromosome 2q37 by screening of a human/rodent somatic cell hybrid panel by the polymerase chain reaction and by fluorescent in situ hybridization analysis using genomic and cDNA clones. Received: 12 November 1998 / Accepted: 18 December 1998     

Localization of the human glucagon gene (GCG) to chromosome segment 2q36----37

Hybridization of a 3H-labeled bovine glucagon cDNA plasmid to human metaphase chromosomes revealed significant labeling of the distal portion of the long arm of chromosome 2. A large portion (37%) of the cells analyzed exhibited labeling of the 2. A significant percentage (40%) of the labeled sites on the 2 were in segment 2q36----37. Therefore, the human glucagon gene (GCG), was assigned to this segment. Localization of the glucagon gene, whose chromosomal assignment was previously not known, demonstrates the general applicability of in situ hybridization as a powerful gene mapping technique.     

Linkage of early-onset osteoarthritis and chondrocalcinosis to human chromosome 8q.

Calcium pyrophosphate-deposition disease (CPDD), also called "chondrocalcinosis" or "pseudogout," is a disorder characterized by the deposition of calcium-containing crystals in joint tissue, which leads to arthritis-like symptoms. The presence of these crystals in joint tissue is a common finding in the elderly, and, in this population, there is a poor correlation with joint pain. In contrast, early-onset CPDD has been described in several large families in which the disease progresses to severe degenerative osteoarthritis (OA). In these families, an autosomal dominant mode of inheritance is observed, with an age at onset between the 2d and 5th decades of life. In this report, we describe a large New England family with early-onset CPDD and severe degenerative OA. We found genetic linkage between the disease in this family and chromosome 8q, with a multipoint lod score of 4.06. These results suggest that a defective gene at this location causes the disease in this family.     

Order of genes on human chromosome 5q with respect to 5q interstitial deletions

Using (a) somatic cell hybrids retaining partial chromosome 5 and (b) clinical samples from patients with acquired deletions of the long arm of chromosome 5, combined with chromosome 5-linked DNA probes, some of which exhibited RFLPs, we have determined the order of a series of genes on chromosome 5. The order established is 5pter----MLVI-2----cen----HEXB----DHFR----Pi227- --- cp12.6----(IL5,IL4)----IL3----GMCSF---- FGFA---- (CSF1R,PDGFR)----(treC,ADRBR)----(ARH-H9,CSF1 )----qter. The suggested order and orientation for the closely linked IL3/GMCSF gene pair is cen----5' IL3 3'----5' GMCSF 3'----qter, on the basis of analysis of the GMCSF rearrangement in HL60 DNA. The map position of the GRL locus, which was consistent with both somatic cell hybrid and 5q- analyses, was telomeric to GMCSF and centromeric to CSF1R/PDGFR, near FGFA. Long-range restriction-enzyme analysis of 5q- DNAs did not detect rearrangements of 5q-linked probes except in HL60 DNA, but it did reveal putative long-range RFLPs of several loci. RFLPs for GRL, Pi227, cp12.6, IL3, and CSF1R can detect deletions in bone marrow and in leukemia cells from patients with acquired 5q deletions.     

Cloning and expression of human nebulin cDNAs and assignment of the gene to chromosome 2q31-q32

We have isolated two nonoverlapping cDNAs encoding human nebulin, a muscle-specific protein. Northern hybridization analysis shows that nebulin is encoded by a huge message at least 25 kb in length. By hybridizing two nonoverlapping cDNAs to DNA isolated from rodent X human cell hybrids, we assign this presumably single-copy gene to human chromosome 2; sublocalization studies indicate that the nebulin gene is on the long arm of the chromosome, in the region 2q31-q32.     

Localization of histidase to human chromosome region 12q22----q24.1 and mouse chromosome region 10C2----D1

The human gene for histidase (histidine ammonia-lyase; HAL), the enzyme deficient in histidinemia, was assigned to human chromosome 12 by Southern blot analysis of human X mouse somatic cell hybrid DNA. The gene was sublocalized to region 12q22----q24.1 by in situ hybridization, using a human histidase cDNA. The homologous locus in the mouse (Hal) was mapped to region 10C2----D1 by in situ hybridization, using a cell line from a mouse homozygous for a 1.10 Robertsonian translocation. These assignments extend the conserved syntenic region between human chromosome 12 and mouse chromosome 10 that includes the genes for phenylalanine hydroxylase, gamma interferon, peptidase, and citrate synthase. The localization of histidase to mouse chromosome 10 suggests that the histidase regulatory locus (Hsd) and the histidinemia mutation (his), which are both known to be on chromosome 10, may be alleles of the histidase structural gene locus.     

Large-scale mapping and chromosome jumping in the q27 region of the human X chromosome

We have used pulsed field gel electrophoresis for further physical mapping studies in the q27 region of the human X chromosome. We show that the DXS 102 locus and the F9 gene are separated by only 300 kb despite a genetic distance of 1.4 cM; this linkage orients our large-scale map and shows that the mcf.2 transforming sequence is telomeric to F9. A BssHII complete-digest jumping library was used to jump toward the DXS 105 locus; a 130-kb jump was achieved and the corresponding "linking clone" was obtained.