The Locus for Human Adenine Phosphoribosyltransferase on Chromosome No. 16

Evidence for assigning the locus determining the structure of adenine phosphoribosyltransferase (APRT) to human chromosome No. 16 is presented. Hybrids of APRT-deficient mouse cells and of human fibroblasts having normal APRT were isolated by fusing the parental cells with Sendai virus, blocking de novo purine nucleotide synthesis with azaserine and selecting for hybrids that could use exogenous adenine. The hybrid clones that were studied had only APRT activity that was indistinguishable from human APRT with regard to electrophoretic migration and reaction with antibodies against the partially purified human enzyme. No. 16 was the only human chromosome consistently present in all of the clones, and in one clone, it was the only human chromosome detected. Selection against hybrid cells with 2,6-diaminopurine (DAP) yielded DAP-resistant survivors that lacked chromosome No. 16. One hybrid that originally had an intact No. 16 yielded adenine-utilizing subclones that lacked No. 16 but had a new submetacentric chromosome. The distribution of centromere-associated heterochromatin and the fluorescence pattern indicated that this chromosome consisted of a mouse telocentric chromosome and the long arm of No. 16. Cells having the submetacentric chromosome had human APRT. Both the enzyme and the chromosome were absent in DAP-resistant derivatives. These results suggest that the structure of APRT is defined by a locus on the long arm of human chromosome No. 16.     

Multidrug-resistant phenotype cosegregates with an amplified gene in somatic cell hybrids of drug-resistant Chinese hamster ovary cells and drug-sensitive murine cells.

Gene amplification has been associated with multidrug resistance (MDR) in several drug-resistant Chinese hamster ovary (CHO) cell lines which exhibit cross-resistance to other unrelated, cytotoxic drugs. In situ hybridization studies (Teeter et al., J. Cell Biol., in press) suggested the presence of an amplified gene associated with the MDR phenotype on the long arm of either of the largest CHO chromosomes (1 or Z1) in vincristine-resistant cells. In this study, somatic cell hybrids were constructed between these vincristine-resistant CHO cells and drug-sensitive murine cells to determine the functional relationship between the chromosome bearing the amplified sequences and the MDR phenotype. Hybrids exhibited primary drug resistance and MDR in an incomplete dominant fashion. Hybrid clones and subclones segregated CHO chromosomes. Concordant segregation between vincristine resistance, the MDR phenotype, the presence of the MDR-associated amplified sequences, overexpression of the gene located in those sequences, and CHO chromosome Z1 was consistent with the hypothesis that there is an amplified gene on chromosome Z1 of the vincristine-resistant CHO cells which is responsible for the MDR in these cells. A low level of discordance between CHO chromosomes Z8 and 2 and the drug resistance phenotype suggests that these chromosomes may contain genes involved with the MDR phenotype.     

A highly polymorphic locus in human DNA revealed by probes from cosmid 1-5 maps to chromosome 2q35----37.

The highly polymorphic locus D2S3 is revealed by three single-copy probes from cosmid C1-5. These probes, 1-30, 1-32, and 2-96, collectively reveal seven restriction fragment length polymorphisms. Fifty-three of 56 unrelated individuals (93%) were heterozygous at one or more of the seven loci, making the compound locus a very useful marker for gene mapping. Chromosomal assignment of D2S3 was obtained using a panel of human X hamster and human X mouse somatic cell hybrids. Molecular hybridization of EcoRI-digested DNA from these cell lines with the DNA inserts from subclones 1-30, 1-32, and 2-96 showed that all three probes mapped to the long arm of chromosome 2. Additionally, in situ hybridization of [3H]-labeled probe 2-96 to metaphase chromosome preparations allowed more precise assignment of the locus to the region 2q35----37.     

Chromosomal assignment of the genes for human aldehyde dehydrogenase-1 and aldehyde dehydrogenase-2.

Chromosomal assignment of the genes for two major human aldehyde dehydrogenase isozymes, that is, cytosolic aldehyde dehydrogenase-1 (ALDH1) and mitochondrial aldehyde dehydrogenase-2 (ALDH2) were determined. Genomic DNA, isolated from a panel of mouse-human and Chinese hamster-human hybrid cell lines, was digested by restriction endonucleases and subjected to Southern blot hybridization using cDNA probes for ALDH1 and for ALDH2. Based on the distribution pattern of ALDH1 and ALDH2 in cell hybrids, ALDH1 was assigned to the long arm of human chromosome 9 and ALDH2 to chromosome 12.     

A polymorphic locus on the long arm of chromosome 20 defined by two probes from a single cosmid

Summary Two probes from the random human cosmid c1-37 detect restriction fragment length polymorphisms in humans. The loci revealed by these probes are in linkage equilibrium and constitute a compound polymorphic locus with a polymorphism information content of 0.54. A somatic cell hybrid panel has been used to map the probes to chromosome 20; in situ hybridization studies confirm this localization and indicate that the locus is on 20q13. This is the first polymorphic locus to be assigned to the long arm of chromosome 20.     

A refined physical map of the long arm of human chromosome 16

Mapping of 33 anonymous DNA probes and 12 genes to the long arm of chromosome 16 was achieved by the use of 14 mouse/human hybrid cell lines and the fragile site FRA16B. Two of the hybrid cell lines contained overlapping interstitial deletions in bands q21 and q22.1. The localization of the 12 genes has been refined. The breakpoints present in the hybrids, in conjunction with the fragile site, can potentially divide the long arm of chromosome 16 into 16 regions. However, this was reduced to 14 regions because in two instances there were no probes or genes that mapped between pairs of breakpoints.     

Assignment of a human DNA-repair gene associated with sister-chromatid exchange to chromosome 19

The Chinese hamster ovary (CHO) cell mutant, EM9, is defective in rejoining strand breaks, hypersensitive to chlorodeoxyuridine (CldUrd), and has a high frequency of sister-chromatid exchange (SCE). Somatic cell hybrids constructed from fusion of EM9 cells with normal human lymphocytes and fibroblasts, and selected in CldUrd, extensively segregate human chromosomes but preferentially retain markers of human chromosome 19. The SCE frequency in the hybrid clones is low as in normal CHO cells, but in CldUrd-sensitive subclones, which lose the human chromosome 19 markers, SCE frequencies return to mutant levels. We therefore assign a human gene designated repair complementing defective repair in Chinese-hamster (RCC) to chromosome 19. Since this is the second (of two) human genes complementing repair-deficiency mutations in CHO cells assigned to the 19, the assignment and organization of DNA-repair genes is discussed in the light of hemizygosity in CHO cells and the evolutionary conservation of mammalian linkage groups.     

Complementation of repair gene mutations on the hemizygous chromosome 9 in CHO: a third repair gene on human chromosome 19

A human DNA repair gene, ERCC2 (Excision Repair Cross Complementing 2), was assigned to human chromosome 19 using hybrid clone panels in two different procedures. One set of cell hybrids was constructed by selecting for functional complementation of the DNA repair defect in mutant CHO UV5 after fusion with human lymphocytes. In the second analysis, DNAs from an independent hybrid panel were digested with restriction enzymes and analyzed by Southern blot hybridization using DNA probes for the three DNA repair genes that are located on human chromosome 19: ERCC1, ERCC2, and X-Ray Repair Cross Complementing 1 (XRCC1). The results from hybrids retaining different portions of this chromosome showed that ERCC2 is distal to XRCC1 and in the same region of the chromosome 19 long arm (q13.2-q13.3) as ERCC1, but on different MluI macrorestriction fragments. Similar experiments using a hybrid clone panel containing segregating Chinese hamster chromosomes revealed the hamster homologs of the three repair genes to be part of a highly conserved linkage group on Chinese hamster chromosome number 9. The known hemizygosity of hamster chromosome 9 in CHO cells can account for the high frequency at which genetically recessive mutations are recovered in these three genes in CHO cells. Thus, the conservation of linkage of the repair genes explains the seemingly disproportionate number of repair genes identified on human chromosome 19.     

X-Linkage of a Human Genetic Locus That Corrects the DNA Synthesis Lesion in tsC1AGOH Mouse Cells

GM 126 diploid fibroblasts were fused with a heat-sensitive mouse cell mutant defective in DNA synthesis, and primary hybrids were selected at permissive and nonpermissive temperatures in HAT medium. Primary hybrids, primary hybrid clones back-selected in 8-azaguanine at the permissive temperature, and subclones of heat-resistant primary hybrids isolated under nonselective conditions or after 8-azaguanine treatment were tested for heat sensitivity, the expression of 26 human enzymes assigned to 19 different human chromosomes, and the presence of human chromosomes. Only the human X chromosome and X-linked marker enzymes exhibited a clear pattern of concordant segregation with the heat-resistant phenotype. On the basis of these observations, we have defined the human genetic locus that corrects the heat-sensitive lesion in tsC1AGOH as hrC1AGOH and have assigned this locus to the X chromosome. This observation provides the first instance where two selectable markers (heat resistance and 8-azaguanine sensitivity) are found on a single human chromosome and suggests that these markers may prove to be a valuable push-pull selective system of use in determining the linear arrangement of genes on human chromosomes by somatic cell genetics.     

Human homologs of two testes-expressed loci on mouse chromosome 17 map to opposite arms of chromosome 6

Our laboratory has recently cloned and characterized two testes-expressed loci--the Tcp-10 gene family cluster and the D17Si11 gene--that map to the proximal portion of mouse chromosome 17. Human homologs of both loci have been identified and cloned. Somatic cell hybrid lines have been used to map the human homolog of D17Si11 to the short arm of chromosome 6 (p11-p21.1) along with homologs of other genes from the (Pim-1)-(Pgk-2) region of the mouse chromosome. The human TCP 10 locus maps to the long arm of chromosome 6 (q21-qter) along with homologs of other genes from the mouse chromosome 17 region between the centromere and Pim-1. The mapping of large portions of the mouse t haplotype to unlinked regions on human chromosome 6 rules out the possibility that a t-haplotype-like chromosome could exist in humans.     

Linkage Mapping in Sheep and Deer Identifies a Conserved Pecora Ruminant Linkage Group Orthologous to Two Regions of HSA16 and a Portion of HSA7Q

Two orthologous linkage groups have been mapped in sheep and deer. Seven loci have been mapped in deer, and 12 in sheep. The sheep linkage group is assigned to ovine chromosome 24. The linkage groups consist of loci from the short arm of human chromosome 16, spanning the region containing the human Batten disease locus, and from human chromosome 7. One locus from the long arm of human chromosome 16 is also present, demonstrating a previously unknown rearrangement between human and ruminant chromosomes. There is no significant difference in marker order and distances between the two linkage groups, implying that this linkage pattern was present in the genome of the common ancestor of the pecora ruminants.     

The human QARS locus: assignment of the human gene for glutaminyl-tRNA synthetase to chromosome 1q32–42

Summary We have used a cDNA encoding the core region of the human glutaminyl-tRNA synthetase to determine the chromosomal localization of the corresponding gene. Southern blots of restricted DNA from a panel of rodent-human cell lines and in situ chromosome hybridization gave identical results showing that the human gene locus for glutaminyl-tRNA synthetase resides on the distal long arm of chromosome 1. There are now nine mapped aminoacyl-tRNA synthetase genes in the human genome.     

The cystic fibrosis locus

The identification of the cystic fibrosis locus (CF) provides a model for the study of single gene defects where the biochemical lesion is not known. Using families each of which has several affected siblings, it was possible to exclude a number of 'candidate genes' which had previously been proposed as possible sites of the CF mutation. Exclusion mapping of the genome using polymorphic protein and DNA markers showed that CF is on the long arm of human chromosome 7. The most closely linked flanking markers were identified, and human chromosome fragments containing them (and therefore the CF locus) were isolated in rodent cell lines by chromosome-mediated gene transfer. The transgenome was then analysed using cosmid contig mapping, pulse-field gel electrophoresis, HTF island identification and linkage disequilibrium. In this way, a candidate coding sequence has been identified which always segregates with CF.     

Characterization, physical location and expression of the genes encoding calcium/calmodulin-dependent protein kinases in maize (Zea mays L.)

The maize genomic sequence and cDNA encoding a calcium/calmodulin-dependent protein kinase homolog were isolated and identified. The deduced peptide (MCK2) from this cDNA shared high amino acid identity (91.2%) with maize MCK1. These two genes were physically mapped onto chromosomes by fluorescence in situ hybridization using the first introns of the genes as gene-specific probes. While the MCK1 gene was assigned to a locus on the long arm of chromosome 9, the MCK2 gene was localized to a locus on the long arm of chromosome 1. Both of these genes were expressed in roots, leaves, stems and flowers, and the expression patterns of MCK were verified by RNA in situ hybridization. These results indicated that MCK expression is temporally and spatially regulated during maize growth and development.     

The structural gene for the M1 subunit of ribonucleotide reductase maps to chromosome 11, band p15, in human and to chromosome 7 in mouse

The genes for the M1 subunit of the enzyme ribonucleotide reductase have been mapped in the human and the murine species by use of two independently derived mouse cDNA clones. Southern blot analysis of rodent x human somatic cell hybrid DNAs confirmed the assignment of RRM1 to the short arm of human chromosome 11. In situ hybridization to human metaphase chromosomes revealed a peak of silver grains over the distal third of band 11p15, a region corresponding to subbands p15.4----p15.5. The mouse Rrml locus was assigned to chromosome 7, where it forms part of a conserved syntenic group of at least seven other genes assigned to human chromosome band 11p15.     

A gene involved in control of human cellular senescence on human chromosome 1q.

Normal cells in culture exhibit limited division potential and have been used as a model for cellular senescence. In contrast, tumor-derived or carcinogen- or virus-transformed cells are capable of indefinite division. Fusion of normal human diploid fibroblasts with immortal human cells yielded hybrids having limited life spans, indicating that cellular senescence was dominant. Fusions of various immortal human cell lines with each other led to the identification of four complementation groups for indefinite division. The purpose of this study was to determine whether human chromosome 1 could complement the recessive immortal defect of human cell lines assigned to one of the four complementation groups. Using microcell fusion, we introduced a single normal human chromosome 1 into immortal human cell lines representing the complementation groups and determined that it caused loss of proliferative potential of an osteosarcoma-derived cell line (TE85), a cytomegalovirus-transformed lung fibroblast cell line (CMV-Mj-HEL-1), and a Ki-ras(+)-transformed derivative of TE85 (143B TK-), all of which were assigned to complementation group C. This chromosome 1 caused no change in proliferative potential of cell lines representing the other complementation groups. A derivative of human chromosome 1 that had lost most of the q arm by spontaneous deletion was unable to induce senescence in any of the immortal cell lines. This finding indicates that the q arm of human chromosome 1 carries a gene or set of genes which is altered in the cell lines assigned to complementation group C and is involved in the control of cellular senescence.     

Assignment of the structural gene encoding human aspartylglucosaminidase to the long arm of chromosome 4 (4q21----4qter)

The structural gene for the human lysosomal enzyme aspartylglucosaminidase (AGA) has been assigned to chromosome 4 using somatic cell hybridization techniques. The human monomeric enzyme was detected in Chinese hamster-human cell hybrids by a thermal denaturation assay that selectively inactivated the Chinese hamster isozyme, while the thermostable human enzyme retained activity. Twenty informative hybrid clones, derived from seven independent fusions, were analyzed for the presence of human AGA activity and their human chromosomal constitutions. Without exception, the presence of human AGA in these hybrids was correlated with the presence of human chromosome 4. All other human chromosomes were excluded by discordant segregation of the human enzyme and other chromosomes. Two hybrid clones, with interspecific Chinese hamster-human chromosome translocations involving the long arm of human chromosome 4, permitted the assignment of human AGA to the region 4q21----4qter.     

Isolation and mapping of two porcine skeletal muscle myosin heavy chain isoforms

The present paper describes the isolation and linkage mapping of two isoforms of skeletal muscle myosin heavy chain in pig. Two partial cDNAs (pAZMY4 and pAZMY7), coding for the porcine myosin heavy chain-2B and -β respectively, have been isolated from a pig skeletal muscle cDNA library. Four RFLPs were detected with the putative porcine skeletal myosin heavy chain-2B probe (pAZMY4) and one RFLP was identified with the putative myosin heavy chain-β probe (pAZMY7). Two myosin heavy chain loci were mapped by linkage analysis performed with the five RFLPs against the PiGMaP linkage consortium ResPig database: the MYH1 locus, which identifies the fast skeletal muscle myosin heavy chain gene cluster, was located at the end of the map of porcine chromosome 12, while the MYH7 locus, which identifies the myosin heavy chain-α/-β gene cluster, was assigned to the long arm of porcine chromosome 7.     

The human endonexin II (ENX2) gene is located at 4q28----q32

A relatively recently identified family of structurally similar Ca2(+)-dependent phospholipid binding proteins is called the annexin gene family. At least seven genes are known, although their exact functions are unclear. The endonexin II gene (ENX2), one member of the gene family, is assigned to 4q28----q32 using both Southern transfer analysis of human x rodent somatic cell hybrid DNAs and in situ chromosome hybridization. One of the lipocortin II genes, another annexin, had previously been assigned to the long arm of chromosome 4.     

Assignment of the pepsinogen gene complex (PGA) to human chromosome region 11q13 by in situ hybridization

The genes coding for human pepsinogen (PGA3, PGA4, and PGA5) were assigned to chromosome region 11q13 by in situ hybridization. Previously we localized the PGA gene complex to a centromeric region of chromosome 11 (p11----q13) by Southern blot analysis of mouse-human somatic cell hybrids. Our in situ hybridization results confirm this assignment and further localize the genes to a smaller region on the long arm.