Precise localization of NF1 to 17q11.2 by balanced translocation.

A female patient is described with von Recklinghausen neurofibromatosis (NF1) in association with a balanced translocation between chromosome 17 and 22 [46,XX,t(17;22)(q11.2;q11.2)]. The breakpoint in chromosome 17 is cytogenetically identical to a previously reported case of NF1 associated with a 1;17 balanced translocation and suggests that the translocation events disrupt the NF1 gene. This precisely maps the NF1 gene to 17q11.2 and provides a physical reference point for strategies to clone the breakpoint and therefore the NF1 gene. A human-mouse somatic cell hybrid was constructed from patient lymphoblasts which retained the derivative chromosome 22 (22pter----22q11.2::17q11.2----17qter) but not the derivative 17q or normal 17. Southern blot analysis with genes and anonymous probes known to be in proximal 17q showed ErbA1, ErbB2, and granulocyte colony-stimulating factor (CSF3) to be present in the hybrid and therefore distal to the breakpoint, while pHHH202 (D17S33) and beta crystallin (CRYB1) were absent in the hybrid and therefore proximal to the breakpoint. The gene cluster including ErbA1 is known to be flanked by the constitutional 15;17 translocation breakpoint in hybrid SP3 and by the acute promyelocytic leukemia (APL) breakpoint, which provides the following gene and breakpoint order: cen-SP3-(D17S33,CRYB1)-NF1-(CSF3,ERBA1, ERBB2)-APL-tel. The flanking breakpoints of SP3 and API are therefore useful for rapidly localizing new markers to the neurofibromatosis critical region, while the breakpoints of the two translocation patients provide unique opportunities for reverse genetic strategies to clone the NF1 gene.     

Regional chromosome mapping of the human skin type I procollagen gene using adenovirus 12-fragmentation of human-mouse somatic cell hybrids

Prevous work, using human-mouse somatic cell hybrids, has localized the structural gene for human skin type I procollagen (COL 1) to chromosome 17. One of these hybrids contained only the long arm of human chromosome 17, translocated onto a mouse chromosome, as human chromosomal material. This hybrid was treated with adenovirus 12, and various clones were picked which contained different-sized fragments of human chromosome 17 that were still translocated onto a mouse chromosome. Measurements of these fragments, combined with assays for human COL 1 production and galactose kinase (GAK) activity (also localized on the long arm of human chromosome 17), has allowed us to regionally map the structural gene for human COL 1 to an area just distal to the thymidine kinase (TK) and GAK genes within bands q21 and q22 on human chromosome 17.     

Chromosomal localization of the human interleukin 1 alpha (IL-1 alpha) gene

The human interleukin 1 alpha gene was assigned to chromosome 2 using Southern transfer analysis of human-rodent somatic cell hybrid DNAs. The gene was regionally localized to 2q12-21 using in situ hybridization to metaphase chromosomes. These results indicate that the IL-1 alpha gene maps to the same general region on the long arm of chromosome 2 as the IL-1 beta gene, which has been previously assigned.     

Progress towards identifying the neurofibromatosis (NF1) gene

Von Recklinghausen neurofibromatosis (NF1) is a common autosomal dominant disorder of humans. Linkage analysis has recently mapped the NF1 gene to the proximal long arm of chromosome 17. The identification of two NF1 patients with balanced translocations has now allowed the location of the gene to be narrowed to a few hundred kilobases of chromosome band 17q11.2, using a combination of somatic cell hybrid technology, linking clones and pulsed field gel electrophoresis.     

Localization of HeLa cell tumor-suppressor gene to the long arm of chromosome II.

Cytogenetic and molecular genetic analyses of human intraspecific HeLa x fibroblast hybrids have provided evidence for the presence of a tumor-suppressor gene(s) on chromosome 11 of normal cells. In the present study, we have carried out extensive RFLP analysis of various nontumorigenic and tumorigenic hybrids with at least 50 different chromosome 11-specific probes to determine the precise location of this tumor-suppressor gene(s). Two different hybrid systems, (1) microcell hybrids derived by the transfer of a normal chromosome 11 into a tumorigenic HeLa-derived hybrid cell and (2) somatic cell hybrids derived by the fusion of the HeLa (D98OR) cells to a retinoblastoma (Y79) cell line, were particularly informative. The analysis showed that all but one of the nontumorigenic hybrid cell lines contained a complete copy of the normal chromosome 11. This variant hybrid contained a segment of the long arm but had lost the entire short arm of the chromosome. The tumorigenic microcell and somatic cell hybrids had retained the short arm of the chromosome but had lost at least the q13-23 region of the chromosome. Thus, these results showed a perfect correlation between the presence of the long arm of chromosome 11 and the suppression of the tumorigenic phenotype. We conclude therefore that the gene(s) involved in the suppression of the HeLa cell tumors is localized to the long arm (q arm) of chromosome 11.     

Chromosomal localization of the human interleukin 1α (IL-1α) gene

The human interleukin 1α gene was assigned to chromosome 2 using Southern transfer analysis of human-rodent somatic cell hybrid DNAs. The gene was regionally localized to 2q12–21 using in situ hybridization to metaphase chromosomes. These results indicate that the IL-1α gene maps to the same general region on the long arm of chromosome 2 as the IL-1β gene, which has been previously assigned.     

A human SHC-related sequence maps to chromosome 17, the SHC gene maps to chromosome 1

The SHC gene encodes a protein that is thought to act as an adapter in many signal transduction pathways; the SHC protein probably facilitates the activation of RAS proteins in response to a variety of factors. We have mapped the human SHC gene and have identified a new SHC-related sequence. We have sequenced the region corresponding to the SHC 3 UTR from both loci and have mapped cosmids by fluorescence in situ hybridization. The human SHC gene maps to the proximal long arm of chromosome 1 and the SHC-related sequence maps to the proximal long arm of chromosome 17. A number of cancers have been positioned in the proximal long arm of chromosome 1; this is of interest given the oncogenic potential of the SHC protein.     

Chromosomal localization and structure of the human P1 protamine gene

The human P1 protamine gene and mRNA were amplified with the use of the polymerase chain reaction and cloned into PTZ19R. The sequences were determined which revealed the presence of an intron. Southern and Northern hybridization analyses showed that the gene was single copy and that the mRNA was approximately 450 bases long. The gene was mapped to chromosome 16 with the use of a somatic cell hybrid panel and localized to the 21 region of the q arm by in situ hybridization of the human P1 protamine probe to human metaphase chromosomes.     

The pronatriodilatin gene is located on the distal short arm of human chromosome 1 and on mouse chromosome 4.

Atrial natriuretic factors (ANF) are polypeptides having natriuretic, diuretic, and smooth muscle-relaxing activities that are synthesized from a single larger precursor: pronatriodilatin. Chromosomal assignment of the gene coding for human pronatriodilatin was accomplished by in situ hybridization of a [3H]-labeled pronatriodilatin probe to human chromosome preparations and by Southern blot analysis of somatic cell hybrid DNAs with normal and rearranged chromosomes 1. The human pronatriodilatin gene was mapped to the distal short arm of chromosome 1, in band 1p36. Southern blot analysis of mouse X Chinese hamster somatic cell hybrids was used to assign the mouse pronatriodilatin gene to chromosome 4. This assignment adds another locus to the conserved syntenic group of homologous genes located on the distal half of the short arm of human chromosome 1 and on mouse chromosome 4.     

Integration site(s) of herpes simplex virus type 1 thymidine kinase gene and regional assignment of the gene for aminoacylase-1 in human chromosomes

To investigate the chromosomal sites of integration of the herpes simplex virus type 1 (HSV-1) thymidine kinase (TK) gene in HSV-1-transformed human HeLa(BU25)/KOS 8-1 cells, the biochemically transformed cells were fused with TK-negative mouse LM(TK-) cells, and human-mouse somatic cell hybrid lines (LH81) were isolated using a HATG-ouabain selection system. The presence of HSV-1 TK activity in the hybrid lines was verified by disc polyacrylamide gel electrophoresis (PAGE) and by enzyme neutralization with type-specific rabbit anti-HSV-1 TK immunoglobulin. Karyotype analyses of several somatic cell hybrid clones using G-banding, Hoechst 33258 staining, and combined G-banding and Hoechst staining demonstrated that they retained only a few human chromosomes. A marker chromosome, M7, consisting of a chromosome 17 translocated to the short arm of 3, occurred in 25 of the 28 metaphases examined. Also chromosomes 8 and X were found in a minority of metaphases. Isozyme analyses showed that all 19 hybrid clones analyzed expressed human aminoacylase-1 (ACY1) and esterase D (ESD), markers for 3 and 13, respectively. Back-selection of somatic cell hybrid clones with 5-bromodeoxyuridine resulted in the isolation of several subclones lacking HSV-1 TK activity, human ACY1, human ESD, and the human chromosomes. These experiments suggest that the HSV-1 TK gene is associated with either M7 or a segment of 13, or both, in biochemically transformed HeLa(BU25)/KOS 8-1 cells. These experiments also permit localization of the ACY1 structural gene to the pter leads to p12 region of 3.     

Assignment of the gene coding for the alpha-subunit of prolyl 4-hydroxylase to human chromosome region 10q21.3-23.1.

Prolyl 4-hydroxylase, an alpha 2 beta 2 tetramer, catalyzes the formation of 4-hydroxyproline in collagens by the hydroxylation of proline residues in peptide linkages and plays a crucial role in the synthesis of these proteins. The gene for the beta-subunit of prolyl 4-hydroxylase has recently been mapped to the long arm of human chromosome 17, at band 17q25. We report here chromosomal localization of the gene for the catalytically and regulatorily important alpha-subunit of human prolyl 4-hydroxylase. Analysis of 24 rodent x human cell hybrids by Southern blotting with cDNA probes for the human alpha-subunit indicated complete cosegregation of the gene for the alpha-subunit with human chromosome 10. A cell hybrid containing only part of chromosome 10 mapped the gene to 10q11----qter. In situ hybridization mapped the gene to 10q21.3-23.1. The gene for the alpha-subunit is thus not physically linked to that for the beta-subunit of the enzyme.     

Assignment of the human homologue of the mouse t-complex gene TCTE3 to human chromosome 6q27.

The gene TCTE3 from the mouse t-complex region is expressed specifically in testicular germ cells. It maps in the central subregion of the t-complex on mouse chromosome 17 containing loci involved in transmission ratio distortion and male sterility. In this study, somatic cell hybrid lines have been used to map the human homologue, TCTE3, to the long arm of chromosome 6. CISS hybridization with the human lambda clone h117 refined this chromosome assignment to the very distal position of chromosome 6q27, thus providing further evidence that loci from the t-complex of mouse chromosome 17 can map to opposite arms of human chromosome 6.     

Fine structure DNA mapping studies of the chromosomal region harboring the genetic defect in neurofibromatosis type 1

To better map the location of the von Recklinghausen neurofibromatosis (NF1) gene, we have characterized a somatic cell hybrid designated 7AE-11. This microcell-mediated, chromosome-transfer construct harbors a centromeric segment and a neo-marked segment from the distal long arm of human chromosome 17. We have identified 269 cosmid clones with human sequences from a 7AE-11 library and, using a panel of somatic cell hybrids with a total of six chromosome 17q breakpoints, have mapped 240 of these clones on chromosome 17q. The panel included a hybrid (NF13) carrying a der(22) chromosome that was isolated from an NF1 patient with a balanced translocation, t(17;22) (q11.2;q11.2). Fifty-three of the cosmids map into a region spanning the NF13 breakpoint, as defined by the two closest flanking breakpoints (17q11.2 and 17q11.2-q12). RFLP clones from a subset of these cosmids have been mapped by linkage analysis in normal reference families, to localize the NF1 gene more precisely and to enhance the potential for genetic diagnosis of this disorder. The cosmids in the NF1 region will be an important resource for testing DNA blots of large-fragment restriction-enzyme digests from NF1 patient cell lines, to detect rearrangements in patients' DNA and to identify the 17;22 NF1 translocation breakpoint.     

Subject index for volume 1

The mutant gene causing von Recklinghausen neurofibromatosis (NF1) was recently shown to map to chromosome 17. We have used additional markers for chromosome 17 to narrow further the location of the gene defect. A preliminary multipoint linkage analysis suggests that the NF1 gene is located on the long arm of chroomsome 17, flanked by D17Z1 and NGFR. Linkage analysis with the human oncogene homolog erbA1, which maps to this region, suggests that this cancer-related gene is not the primary cause of NF1.     

A cell hybrid and recombinant DNA library that facilitate identification of polymorphic loci in the vicinity of the Huntington disease gene.

Somatic cell hybrids were selected that retain a derivative chromosome 5 from an individual in which the p15.1-pter segment of chromosome 5 is replaced with the p15.1-pter segment of chromosome 4. Hybrids that retain this derivative chromosome exclusively were found to be positive for G8, a DNA marker closely linked to the Huntington disease gene on chromosome 4p. From one such hybrid, a segregant was isolated that had deleted the entire q arm of the derivative chromosome but retained the p arm intact as its only detectable human DNA. A complete recombinant DNA library was prepared from this cell line, and the inserts in approximately 1/3 of the recombinant phage with human DNA were shown to be derived from 4pter-4p15.1, which represents only approximately 1% of the total human genome. The cell hybrid and DNA library represent a rapid and efficient means to identify and isolate many polymorphic DNA markers close to and flanking the Huntington disease gene.     

Flanking markers for the gene causing von Recklinghausen neurofibromatosis (NF1)

The defective gene causing von Recklinghausen neurofibromatosis (NF1), one of the most common inherited disorders affecting the human nervous system, was recently mapped to chromosome 17. We have used additional DNA markers to further narrow and bracket the NF1 defect. A multipoint linkage analysis suggests that the NF1 gene is flanked by D17Z1 on the centromeric side and by EW 207 on the telomeric side of the long arm of chromosome 17. The identification of closely linked flanking markers should allow us to develop a reliable prenatal and presymptomatic diagnostic test for this serious neurological disorder and provides the basis for applying chromosome-specific cloning techniques for the isolation and characterization of the mutant gene.     

Human creatine kinase genes on chromosomes 15 and 19, and proximity of the gene for the muscle form to the genes for apolipoprotein C2 and excision repair.

The human chromosomal assignments of genes of the creatine kinase (CK) family--loci for brain (CKBB), muscle (CKMM), and mitochondrial (CKMT) forms--were studied by Southern filter hybridization analysis of DNAs isolated from a human x rodent somatic cell hybrid clone panel. Probes for the 3'-noncoding sequences of human CKBB and CKMM hybridized concordantly only to DNAs from somatic cell hybrids containing chromosomes 14 and 19, respectively. Thus the earlier assignment of the gene coding for the CKBB isozyme to chromosome 14 was confirmed by molecular means, as was the provisional assignment of CKMM to the long arm of chromosome 19. A probe containing canine sequences for CKMM cross-hybridized with human sequences on chromosomes 14 and 19, a result consistent with the assignments of CKBB and CKMM. A probe containing human sequences for CKMT enabled the provisional assignment of CKMT to human chromosome 15. Independent hybrids with portions of the long arm of chromosome 19 missing indicated the order of genes on the long arm of chromosome 19 as being cen-GPI-(TGFB, CYP1)-[CKMM, (APOC2-ERCC1)]-(CGB, FTL). The unexpectedly more distal location of APOC2 among the genes on the long arm--and APOC2's close association with CKMM--is discussed with respect to the close linkage relationship of APOC2 to myotonic muscular dystrophy.     

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.     

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.