The polymorphic Fc gamma receptor II gene maps to human chromosome 1q

Human receptors for IgG (Fc gamma R) play important roles in the immune response. Expression of the human Fc gamma RII gene may be relevant in immune complex related disorders such as systemic lupus erythematosus and Sjogren's syndrome. We have used spot blot analysis of dual laser-sorted human chromosomes to localize the Fc gamma RII gene to human chromosome 1. Spot blot analysis of sorted derivative chromosomes sublocalized the gene to the chromosome 1 long arm (1q12----q25.1). This subchromosomal localization involved reassigning a reciprocal chromosome translocation breakpoint. We also identified Xmn I and Taq I Fc gamma RII polymorphic restriction sites that arose before the races diverged. These common Xmn I and Taq I polymorphisms are predicted to be informative for segregation analysis with human diseases in 85% of all matings.     

Localization of the catalytic subunit C gamma of the cAMP-dependent protein kinase gene (PRKACG) to human chromosome region 9q13.

A cDNA for a new catalytic subunit (C gamma) of the cAMP-dependent protein kinase (PKA) was recently isolated from a human testis cDNA library. This subunit was shown to be expressed only in testis, and has so far not been demonstrated in other species. In the present study, we have determined the chromosomal localization of this gene employing a cDNA for C gamma as a probe. Southern blot analysis of genomic DNA from human x mouse somatic cell hybrids allowed us to assign this gene (PRKACG) to human chromosome 9. In situ hybridization to metaphase chromosomes confirmed the somatic cell hybrid data and regionally mapped the C gamma gene of PKA to human chromosome 9q13.     

Regional localization of the human transferrin receptor gene to 3q26.2----qter.

Transport of iron across the cell membrane is mediated by the iron-binding serum protein, transferrin, and its cell-surface receptor. Transferrin receptor is required for cell proliferation and may play a functional role in the pathogenesis of iron-storage disorders and some neoplasias. To better understand the possible involvement of transferrin receptor in such disorders, we have determined the chromosomal locus of the receptor gene by in situ hybridization. The human transferrin receptor gene was thus mapped to 3q26.2----qter, a region of chromosome 3 that appears to be involved in metal transport and that is subject to nonrandom structural rearrangements associated with neoplasia.     

The gene for clotting factor 10 is mapped to 13q32----qter

The structural gene for the human clotting factor 10 (F10) has been mapped to chromosome 13 with a cDNA probe hybridized to DNAs from a panel of human X hamster hybrids. In situ hybridization was used to assign F10 to region 13q32----qter of chromosomes from normal human lymphocytes.     

Localization of the insulin receptor-related receptor gene to human chromosome 1

DNA encoding the insulin receptor-related receptor (IRR), a novel receptor whose predicted primary structure is similar to those of the insulin and insulin-like growth factor I receptors, has been used in Southern blot analysis of DNA from human x mouse somatic cell hybrids to assign the IRR gene (INSRR) to human chromosome 1.     

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 coproporphyrinogen oxidase gene to chromosome band 3q12

The human gene encoding coproporphyrinogen oxidase is the defective gene in hereditary coproporphyria. This gene was mapped to chromosome band 3q12 using fluorescent in situ hybridization. The chromosomal localization was confirmed by cosegregation of the human gene with chromosome 3 in a panel of human/rodent somatic hybrids.     

Localization of the human oestrogen receptor gene to chromosome 6q24----q27 by in situ hybridization

The oestrogen receptor gene (ER) was mapped by in situ hybridization. Using a human cDNA probe containing the coding sequence for the oestrogen receptor, the gene was localized to 6q24----q27.     

Assignment of the functional gene for human adrenodoxin to chromosome 11q13----qter and of adrenodoxin pseudogenes to chromosome 20cen----q13.1.

Adrenodoxin is a small iron/sulfur protein serving as an electron-transport intermediate for all mitochondrial forms of cytochrome P450. Southern blots of normal genomic DNA cleaved with six restriction endonucleases probed with full-length human adrenodoxin cDNA revealed complex patterns indicating the presence of multiple adrenodoxin genes. Southern blots of DNA from a panel of mouse/human somatic cell hybrids identified cross-hybridizing adrenodoxin DNA in two loci, chromosome 11q13----qter and chromosome 20cen----q13.1. Examination of adrenodoxin clones from a genomic DNA library in phage lambda revealed some clones bearing gene fragments interrupted by introns and other clones bearing processed pseudogenes. By probing the mouse/human hybrids with unique intronic DNA and by correlating restriction maps of the phage clones with that of uncloned genomic DNA, we show that the authentic transcribed adrenodoxin gene lies on chromosome 11, while pseudogenes lie on chromosome 20.     

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.     

Localization of the human GM-CSF receptor beta chain gene (CSF2RB) to chromosome 22q12.2-->q13.1.

The gene for the beta-chain of the human GM-CSF receptor (CSF2RB) has been mapped to chromosome 22 by PCR analysis of a series of human x rodent somatic cell hybrids. In situ hybridization to normal human chromosomes and two translocations involving chromosome 22 and the chromosome expressing the rare fragile site FRA22A place the gene in the region 22q12.2-->q13.1, proximal to the fragile site.     

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 human hexokinase 1 gene to 10q11----qter.

Two partial-length cDNAs encoding the type 1 human hexokinase (ATP:D-hexose 6-phosphotransferase) were isolated from a placenta cDNA library using a 50-bp oligonucleotide synthesized according to the known sequence of human HK1. Using the larger (1.8 kb) cDNA insert as a probe and a panel of human-hamster somatic cell hybrids, we were able to assign the HK1 gene to the long arm of chromosome 10.     

Localization of the humanRGR opsin gene to chromosome 10q23

The humanRGR gene encodes an opsin protein (retinal G protein-coupled receptor), which is expressed in Müller cells and the retinal pigment epithelium and is thought to play a role in the visual process. To investigate a possible linkage of theRGR gene to retinal dystrophies, the locus of the gene was mapped on human metaphase chromosomes. Genomic and cDNA fragments of the humanRGR gene were used as probes for fluorescence in situ hybridization. Analysis of the fluorescence signals on high-resolution banded chromosomes showed that theRGR gene is localized to human chromosome lOq23. This result now provides for the rapid analysis of this gene with respect to inherited diseases of the retina.     

Localization of the human UBC polyubiquitin gene to chromosome band 12q24.3

The localization of specific human ubiquitin genes has not been straightforward because of the conservation of the ubiquitin coding sequence and the number of processed pseudogenes. An congruent to 1.4-kb sequence from the 5'-flanking region of the UBC gene has been shown to be unique to that locus and free from dispersed repeat elements. The cloned 5'-flanking fragment has been used to probe Southern blots of DNA obtained from somatic cell hybrid cell lines. These data indicate that the UBC gene is located on chromosome 12. In situ hybridization with the 5'-flanking probe has refined the assignment to the broad chromosomal subband 12q24.3. These data show that the active ubiquitin genes are not clustered and are located on separate chromosomes. In addition, these studies demonstrate the utility of intron or flanking sequence probes in the specific chromosomal assignment of members of highly conserved gene families.     

Localization of a gene for Duane retraction syndrome to chromosome 2q31

Duane retraction syndrome (DRS) is a congenital eye-movement disorder characterized by a failure of cranial nerve VI (the abducens nerve) to develop normally, resulting in restriction or absence of abduction, restricted adduction, and narrowing of the palpebral fissure and retraction of the globe on attempted adduction. DRS has a prevalence of approximately 0.1% in the general population and accounts for 5% of all strabismus cases. Undiagnosed DRS in children can lead to amblyopia, a permanent uncorrectable loss of vision. A large family with autosomal dominant DRS was examined and tested for genetic linkage. After exclusion of candidate regions previously associated with DRS, a genomewide search with highly polymorphic microsatellite markers was performed, and significant evidence for linkage was obtained at chromosome 2q31 (D2S2314 maximum LOD score 11.73 at maximum recombination fraction. 0). Haplotype analysis places the affected gene in a 17.8-cM region between the markers D2S2330 and D2S364. No recombinants were seen with markers between these two loci. The linked region contains the homeobox D gene cluster. Three of the genes within this cluster, known to participate in hindbrain development, were sequenced in affected and control individuals. Coding sequences for these genes were normal or had genetic alterations unlikely to be responsible for the DRS phenotype. Identifying the gene responsible for DRS may lead to an improved understanding of early cranial-nerve development.