Tandem integration of complete and defective SV40 genomes in mouse-human somatic cell hybrids.

We have analyzed the arrangement of SV40 DNA sequences integrated in human chromosome 7 in two lines of mouse-human somatic cell hybrids: one containing only one human chromosome 7 per cell and the other containing an average of about three. We found that the integration site differs in both the viral and host sequences in the two clones. However, the sites of integration into the several copies of human chromosome 7 of one clone are identical. Each chromosome 7 in both clones carries approximately six viral genomes tandemly linked. Some of these genomes lack about 20% of the DNA from the late region, including the Eco RI site.     

Galactocerebrosidase activity in somatic cell hybrids derived from twitcher mouse/control human fibroblasts is associated with human chromosome 17.

Somatic cell hybrids derived from twitcher mouse cells and from control human fibroblasts were selected by two different methods. One method utilized 6-thioguanine-resistant twitcher cells as a parental line and the other used neomycin-resistant control human fibroblasts as a parental line so that hybrid lines could be selected in either HAT or in G-418 medium, respectively. The hybrid lines were analyzed for galactocerebrosidase activity. Since the twitcher cell lines are deficient in galactocerebrosidase activity, the presence of this activity in these hybrid lines depends upon the presence of human chromosome contents. Both galactocerebrosidase-positive and -deficient hybrid lines were analyzed for their human chromosome contents by the use of isozyme markers. In hybrids derived from both selection methods the expression of galactocerebrosidase activity was associated with the presence of human chromosome 17 marker isozymes. This was confirmed cytogenetically by means of trypsin-banded Giemsa staining of intact human chromosome 17 in three galactocerebrosidase-positive hybrid lines.     

Linkage relationship between the genes for thymidine kinase and galactokinase in different primates.

In this study we investigated the expression of primate galactokinase in somatic cell hybrids between a thymidine kinase-deficient mouse cell line and two different primate cell lines, one of which was derived from African green monkey kidney cells and the other from chimpanzee fibroblasts. All the African green monkey-mouse hybrid clones, selected in HAT medium, expressed monkey galactokinase activity and contained a monkey chromosome similar to a human E-group chromosome. When these clones were backselected in medium containing 5-bromodeoxyuridine, both this chromosome and the monkey galactokinase activity were lost. All the hybrid clones between mouse and chimpanzee cells, which were selected in HAT medium, contained the chimpanzee chromosome 17 and expressed chimpanzee galactokinase activity. These results indicate that the linkage relationship between galactokinase and thymidine kinase has been maintained in 3 divergent primate species--man, chimpanzee, and Old World monkey.     

Integration of Ecogpt and SV40 early region sequences into human chromosome 17: a dominant selection system in whole cell and microcell human-mouse hybrids

The dominant selectable gene, Ecogpt, has been introduced, by the calcium phosphate precipitation technique, into normal human fibroblasts, along with the SV40 early region genes. In one transfectant clone, integration of these sequences into human chromosome 17 was demonstrated by the construction of human-mouse somatic cell hybrids, selected for by growth in medium containing mycophenolic acid and xanthine. A whole cell hybrid, made between the human transfectant and a mouse L cell, was used as donor of the Ecogpt-carrying human chromosome 17 to 'tribrids' growing in suspension, made by whole cell fusion between a mouse thymoma cell line, and to microcell hybrids made with a mouse teratocarcinoma cell line. Two tribrids contained karyotypically normal human chromosomes 17 and a small number of other human chromosomes, while a third tribrid had a portion of the long arm of chromosome 17 translocated to mouse as its only human genetic material. Two independent microcell hybrids contained a normal chromosome 17 and no other human chromosome on a mouse teratocarcinoma background. These experiments demonstrate the ability to construct human-mouse somatic cell hybrids using a dominant selection system. By applying this approach it should be possible to select for a wide range of different human chromosomes in whole cell and microcell hybrids. In particular, transfer of single human chromosomes to mouse teratocarcinoma cells will allow examination of developmentally regulated human gene sequences after differentiation of such hybrids.     

Alu-PCR: characterization of a chromosome 6-specific hybrid mapping panel and cloning of chromosome-specific markers.

The Alu-polymerase chain reaction (Alu-PCR) was applied to selectively amplify DNA sequences from human chromosome 6 using a single primer (A1) directed to the human Alu consensus sequence. A specific amplification pattern was demonstrated for a panel of eight somatic cell hybrids containing different portions of chromosome 6. This PCR pattern permits the identification of submicroscopic DNA alterations and can be utilized as a reference for additional chromosome 6-specific hybrids. To obtain new chromosome 6-specific markers we established two libraries from PCR-amplified sequences using two somatic cell hybrids (MCH381.2D and 640-5A). Out of a total of 109 clones that were found to be chromosome 6 specific, 13 clones were regionally assigned. We also included a procedure that allows the isolation of chromosome 6-specific markers from hybrids that contain human chromosomes other than 6. Our results will contribute to the molecular characterization of chromosome 6 by fostering characterization of somatic cell hybrids and by the generation of new regionally assigned DNA markers.     

A method for generating hybrids containing nonselected fragments of human chromosomes

We have used an irradiation and fusion technique to generate somatic cell hybrids that contain human chromosomal fragments. As a model system, a human-hamster hybrid containing a single human X chromosome was gamma-irradiated and fused with a rodent line. Hybrids were obtained without imposing direct selection for human material. Analysis of 29 clones by in situ hybridization and Southern blotting revealed that human fragments were incorporated into the hybrid cell genomes in most lines. Like chromosome-mediated gene transfer (CMGT)-generated hybrids, these hybrids contained multiple human fragments and retained alphoid centromeric sequences with a high frequency. However, unlike the CMGT, human fragments (apart from alphoid sequences) of less than 10(7) bp showed no evidence for rearrangements. This technique provides a method for constructing hybrids that contain a limited number of small human fragments derived exclusively from any chromosome of choice without the need to impose selection. Such hybrids provide a valuable resource for high-resolution mapping over short distances and for the isolation of disease and other loci mapped genetically.     

Isolation and regional localisation of DNA sequences from a human chromosome 11-specific cosmid library

Summary A cosmid library has been prepared in the lorist-B vector from a mouse/human somatic cell hybrid containing region 11q23-11pter as the only human component. This chromosome region is stably maintained in the hybrid as a result of translocation onto one copy of mouse chromosome 13. Individual cosmids containing human DNA were isolated by their ability to hybridise with total human DNA, digested with either HindIII or EcoRI, and 33 individual unique sequences were identified. These fragments were then isolated and subcloned into the bluescribe plasmid vector. Regional localisation of these unique sequences was achieved using a panel of somatic cell hybrids containing different overlapping deletions of chromosome 11. The majority of the 33 mapped sequences derived from the long arm of chromosome 11. Two clones were located within the 11p13–p14 region, which is associated with a predisposition to Wilms' tumour. These probes supplement those already mapped to this chromosome and will assist in the generation of a detailed chromosome 11 linkage map.     

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.     

Localization of the human alpha-globin structural gene to chromosome 16 in somatic cell hybrids by molecular hybridization assay

We have used 16 human × mouse somatic cell hybrids containing a variable number of human chromosomes to demonstrate that the human α-globin gene is on chromosome 16. Globin gene sequences were detected by annealing purified human α-globin complementary DNA to DNA extracted from hybrid cells. Human and mouse chromosomes were distinguished by Hoechst fluorescent centromeric banding, and the individual human chromosomes were identified in the same spreads by Giemsa trypsin banding. Isozyme markers for 17 different human chromosomes were also tested in the 16 clones which have been characterized. The absence of chromosomal translocation in all hybrid clones strongly positive for the α-globin gene was established by differential staining of mouse and human chromosomes with Giemsa 11 staining. The presence of human chromosomes in hybrid cell clones which were devoid of human α-globin genes served to exclude all human chromosomes except 6, 9, 14 and 16. Among the clones negative for human α-globin sequences, one contained chromosome 2 (JFA 14a 5), three contained chromosome 4 (AHA 16E, AHA 3D and WAV R4D) and two contained chromosome 5 (AHA 16E and JFA14a 13 5) in >10% of metaphase spreads. These data excluded human chromosomes 2, 4 and 5 which had been suggested by other investigators to contain human globin genes. Only chromosome 16 was present in each one of the three hybrid cell clones found to be strongly positive for the human α-globin gene. Two clones (WAIV A and WAV) positive for the human α-globin gene and chromosome 16 were counter-selected in medium which kills cells retaining chromosome 16. In each case, the resulting hybrid populations lacked both human chromosome 16 and the α-globin gene. These studies establish the localization of the human α-globin gene to chromosome 16 and represent the first assignment of a nonexpressed unique gene by direct detection of its DNA sequences in somatic cell hybrids.     

Molecular cloning of the c-fms locus and its assignment to human chromosome 5

Molecular clones of the retroviral oncogene v-fms were used to isolate recombinant bacteriophages containing c-fms proto-oncogene sequences from a human placental DNA library. Viral and cellular fms sequences were used in Southern blotting experiments with a panel of 32 human X mouse somatic cell hybrids to assign the human c-fms proto-oncogene to human chromosome 5.     

Identification of 57 conventional RFLP and 6 VNTR systems with 32 DNA clones on chromosome 11p15

Fifty-four clones containing human inserts were selected from a cosmid library constructed from a somatic cell hybrid containing chromosome 11p15.3-p15.5 as its only human complement. In 32 of these clones, 63 polymorphic systems were identified with a panel of restriction enzymes: 57 conventional RFLP systems and 6 highly polymorphic VNTR systems. Although we examined the cosmid with only seven enzymes, 18 clones (including 6 VNTRs) were polymorphic with three or more enzymes. The results suggested that DNA sequences on the peritelomeric region of chromosome 11p tend to be highly variable. Because these markers are highly informative, they will be excellent resources for investigations of hereditary diseases and tumor suppressor genes in this region of chromosome 11.     

Molecular analysis of overlapping chromosomal deletions in patients with Langer-Giedion syndrome.

We have obtained lymphoblastoid cell lines from three patients with Langer-Giedion syndrome who have overlapping deletions in 8q24.1. To isolate the deletion chromosomes from their normal homologs, patient cell lines were fused with hamster cells and hybrid cells were selected for retention of human chromosome 8. These hybrid cell lines were screened for the presence of chromosome 8 by fluorescence in situ hybridization and by Southern blot hybridization. We have hybridized 31 recombinant DNA clones derived from the 8q22-qter region to Southern blots of the hybrid cell lines; 8 were found to lie within the deletion of at least one patient. One clone identified sequences that were missing from one copy of chromosome 8 in all three patients. These clones help to further define the deletions in these patients and will serve as starting points for detailed characterization of the region.     

Development and utilization of a somatic cell hybrid mapping panel to assign NotI linking probes to the long arm of human chromosome 6.

A somatic cell hybrid mapping panel that defines seven regions of the long arm and one region of the short arm of human chromosome 6 has been developed. Utilizing this panel, 17 NotI boundary clones from a NotI linking library were regionally assigned to the long arm of chromosome 6. The majority of these clones (11) were found to localize within band regions 6q24-q27. The nonuniform distribution of NotI sites may indicate a cluster of HTF islands and likely represents a coincidence of coding sequences in this region of chromosome 6. Cross-hybridization of these linking clones to DNA from other species (zoo blots) provides further evidence for transcribed sequences in 7 of the NotI clones. These NotI clones were also used to identify corresponding NotI fragments using pulsed-field gel electrophoresis, facilitating further physical mapping of this region. Finally, regional assignment of five polymorphic probes to the long arm of chromosome 6 is also presented. These hybrids and probes should facilitate the construction of a physical and genetic linkage map to assist in the identification of disease loci along chromosome 6.     

Transfer of the human X chromosome to human--Chinese hamster cell hybrids via isolated HeLa metaphase chromosomes.

Evidence is presented for the uptake of the human X chromosome by human-Chinese hamster cell hybrids which lack H P R T activity, following incubation with isolated human HeLa S3 chromosomes. Sixteen independent clonal cell lines were isolated in H A T medium, all of which contained a human X chromosome as determined by trypsin-Giemsa staining. The frequency of H A T-resistant clones was 32 x 10(-6) when 10(7) cells were incubated with 10(8) HeLa chromosomes. Potential reversion of the hybrid cells in H A T medium was less than 5 x 10(-7). The 16 isolated cell lines all contained activity of the human X-linked marker enzymes H P R T, P G K,alpha-Gal A, and G6PD, as determined by electrophoresis. The phenotype of G6PD was G6PD A, corresponding to G6PD A in HeLa cells. The human parental cells used in the fusion to form the hybrids had the G6PD B phenotype. The recipient cells gave no evidence of containing human X chromosomes. These results indicate that incorporation and expression of HeLa X chromosomes is accomplished in human-Chinese hamster hybrids which lack a human X chromosome.     

Construction and analysis of linking libraries from the mouse X chromosome

A hybrid cell line containing the mouse X chromosome on a human background has been used to construct linking libraries from the mouse X chromosome, and approximately 250 unique EagI and NotI clones have been identified. Seventy-three clones have been sublocalized onto the X chromosome using interspecific Mus spretus/Mus domesticus crosses and a panel of somatic cell hybrids carrying one-half of reciprocal X-autosome translocations. The average spacing of the linking clones mapped to date is about one every 2 Mb of DNA. Two clones from the central region of the chromosome have been physically linked by pulsed-field gel electrophoresis. A large number of clones contain conserved sequences, indicating the presence of CpG-rich island-associated genes. The clones isolated from these libraries provide a valuable resource for comparative mapping between man and mouse X chromosomes, isolation of X-linked disease loci of interest by reverse genetics, and analysis of the long-range structure and organization of the chromosome.     

A Panel of Radiation Hybrids Defining the 7q31-q32 Region of Human Chromosome 7

Mouse A9 cells containing human chromosome 7 tagged with pSV2neowere irradiated with X-rays and fused to A9 cells to isolateG418-resistant clones. From these clones, we selected radiationhybrids that contained 10–40 Mb of human DNA apparentlyat a single site of their genome by FISH analysis using humanrepetitive sequences as a probe. Then we made a panel of hybridsthat contained various fragments of the 7q31-q32 region andcover its entire region altogether by PCR with STS markers ofhuman chromosome 7. This panel is useful in chromosome transferexperiments since the dominant selective marker neo gene isattached to human DNA.     

Regional assignment of the human acid sphingomyelinase gene (SMPD1) by PCR analysis of somatic cell hybrids and in situ hybridization to 11p15.1----p15.4

Human acid sphingomyelinase (SMPD1) is the lysosomal phosphodiesterase that cleaves sphingomyelin to ceramide and phosphocholine. The deficient activity of SMPD1 is the enzymatic defect in Types A and B Niemann-Pick disease. Previously, the gene encoding human SMPD1 was assigned to chromosome 17 by the differential thermostability of human and hamster SMPD1 in somatic cell hybrids. The recent isolation of the human SMPD1 cDNA (L. E. Quintern, E. H. Schuchman, O. Levran, M. Suchi, K. Ferlinz, H. Reinke, K. Sandhoff, and R. J. Desnick, 1989, EMBO J. 8: 2469-2473) permitted the mapping of this gene by molecular techniques. Oligonucleotide primers were synthesized to PCR amplify the human, but not murine, SMPD1 sequences in man-mouse somatic cell hybrids. In a panel of 15 hybrid cell lines, amplification of the human SMPD1 sequence was 100% concordant with the presence of human chromosome 11. For each of the other human chromosomes there were at least 6 discordant hybrid lines. Further analysis of somatic cell hybrids containing only chromosome 11 or chromosome 11 rearrangements localized the human SMPD1 gene to the region 11p15.1----p15.4. To provide an independent regional gene assignment, in situ hybridization was performed using the radiolabeled human SMPD1 cDNA. In the 58 metaphase cells examined, 34% of the 122 hybridization sites scored were located in the distal end of chromosome 11 with the major peak of hybridization at band 11p15. The absence of any other in situ hybridization site indicated the absence of pseudogenes or homologous sequences elsewhere in the genome. In contrast to the previous provisional localization to chromosome 17, these results assign a single locus for human SMPD1 to 11p15.1----p15.4.     

Molecular clones of the mouse t complex derived from microdissected metaphase chromosomes

Fragments of the proximal half of mouse chromosome 17 including the t-complex region were microdissected from metaphase spreads. DNA was isolated from a pool of such fragments, and was cloned on microscale. Individual clones were used to probe genomic digests of DNA from a pair of Chinese hamster cell lines with or without mouse chromosome 17, and livers of congenic inbred lines of mice carrying wild-type and/or t-haplotype forms of chromosome 17. The data obtained indicate that 95% of the low copy number microclone inserts recognize DNA sequences present on mouse chromosome 17. It has been possible to use one-third of these clones to identify restriction-fragment-length polymorphisms between wild-type and t-haplotype DNA on a congenic background. These results demonstrate that these clones have been derived from the t-complex or regions closely linked to it. Clones of this type should provide starting points for a molecular analysis of this region of the mouse genome.