Distribution of endogenous murine leukemia virus DNA sequences among mouse chromosomes.

We used mouse-Chinese hamster somatic cell hybrids which lose mouse chromosomes to examine the distribution of murine leukemia virus DNA sequences in the genome of A/HeJ mice. We analyzed total cellular DNA from various hybrid clones for the presence of viral sequences by molecular hybridization and used the Southern blot hybridization procedure to identify viral DNA in cellular restriction endonuclease fragments. Our results show that murine leukemia virus DNA sequences are distributed among many mouse chromosomes in this strain. Chromosome 4 was shown to contain murine leukemia virus DNA sequences.     

The Mos proto-oncogene maps near the centromere on mouse chromosome 4

The Mos proto-oncogene, the cellular homolog of the transforming gene of Moloney murine sarcoma virus, was originally assigned to mouse chromosome 4 using independent panels of mouse/hamster somatic cell hybrids. By in situ hybridization to metaphase chromosomes and standard genetic backcrosses, we have confirmed this assignment and determined that Mos maps near the centromere in a region devoid of other markers. We have also identified a restriction fragment length polymorphism (RFLP) that defines two alleles of the Mos locus in selected inbred strains of laboratory mice. Using the RFLP, we determined the strain distribution pattern for the Mos gene in three sets of recombinant inbred strains and in five strains congenic for histocompatibility antigen genes localized on chromosome 4. These results establish Mos as a useful marker in a poorly characterized region of the mouse genome. In addition, these results will facilitate the genetic analysis of the Mos locus.     

Efficient procedure for transferring specific human genes into Chinese hamster cell mutants: interspecific transfer of the human genes encoding leucyl- and asparaginyl-tRNA synthetases.

We have developed a simple and efficient procedure for transferring specific human genes into mutant Chinese hamster ovary cell recipients that does not rely on using calcium phosphate-precipitated high-molecular-weight DNA. Interspecific cell hybrids between human leukocytes and temperature-sensitive Chinese hamster cell mutants with either a thermolabile leucyl-tRNA synthetase or a thermolabile asparaginyl-tRNA synthetase were used as the starting material in these experiments. These hybrids contain only one or a few human chromosomes and require expression of the appropriate human aminoacyl-tRNA synthetase gene to grow at 39 degrees C. Hybrids were exposed to very high doses of gamma-irradiation to extensively fragment the chromosomes and re-fused immediately to the original temperature-sensitive Chinese hamster mutant, and secondary hybrids were isolated at 39 degrees C. Secondary hybrids, which had retained small fragments of the human genome containing the selected gene, were subjected to another round of irradiation, refusion, and selection at 39 degrees C to reduce the amount of human DNA even further. Using this procedure, we have constructed Chinese hamster cell lines that express the human genes encoding either asparaginyl- or leucyl-tRNA synthetase, yet less than 0.1% of their DNA is derived from the human genome, as quantitated by a sensitive dot-blot nucleic acid hybridization procedure. Analysis of these cell lines with Southern blots confirmed the presence of a small number of restriction endonuclease fragments containing human DNA specifically. These cell lines represent a convenient and simple means to clone the human genomic sequences of interest.     

Assignment of genes encoding metallothioneins I and II to Chinese hamster chromosome 3: evidence for the role of chromosome rearrangement in gene amplification.

Cadmium resistant (Cdr) variants with coordinately amplified metallothionein I and II (MTI and MTII) genes have been derived from both Chinese hamster ovary and near-euploid Chinese hamster cell lines. Cytogenetic analyses of Cdr variants consistently revealed breakage and rearrangement involving chromosome 3p. In situ hybridization with a Chinese hamster MT-encoding cDNA probe localized amplified MT gene sequences near the translocation breakpoint involving chromosome 3p. These observations suggested that both functionally related, isometallothionein loci are linked on Chinese hamster chromosome 3. Southern blot analyses of DNAs isolated from a panel of Chinese hamster X mouse somatic cell hybrids which segregate hamster chromosomes confirmed that both MTI and MTII are located on chromosome 3. We speculate that rearrangement of chromosome 3p could be causally involved with the amplification of MT genes in Cdr hamster cell lines.     

The distribution of 4 genes (alpha GAL, PGK-1, HPRT and G6PD) on the X chromosome of the American mink (Mustela vison)

The segregation of X-linked markers (alpha GAL, PGK-1, HPRT and G6PD) was analysed in hybrids between gamma ray-irradiated mink fibroblasts and Chinese hamster cells, or between mink cells and mouse hepatoma cells. Based on the segregation data and the data of cytogenetics analysis of a few hybrids, the order of the mink genes was deduced as alpha GAL--PGK-1--HPRT--G6PD--qter. This order differs from that reported for human and murine genes, in spite of the very obvious similarity between G-banding of the mink and human X chromosomes. Therefore, at least one reversion is responsible for the differences observed for the human and mink X chromosomes.     

Characterization of Gazdar murine sarcoma virus by nucleic acid hybridization and analysis of viral expression in cells.

Gazdar murine sarcoma virus (Gz-MSV) and Moloney murine sarcoma virus (M-MSV) are closely related. The complete M-MSV-specific nucleic acid sequences constituted a major portion of Gz-MSV-specific sequences. The MSV-specific sequences in both Gz-MSV and M-MSV genomes shared homology with hamster leukemia virus nucleic acid sequences. Both rat cells (S+L+) and hamster (S+L-) cells expressed two viral proteins of 68,000 and 70,000 daltons. These proteins were immunologically related to p60 purified from m1 virions of M-MSV.     

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 herpes simplex virus 1 integration site in the mouse genome defined by somatic cell genetic analysis.

Transfection experiments with HSV 1 in which one uses herpes simplex virus (HSV) thymidine kinase (TK) as a selectable prototrophic marker yield two classes of transformed cells: stable and unstable. In this report, we test the hypothesis that the stability phenotype can be explained by virus genome integration into a recipient cell chromosome. The method of analysis is by means of somatic cell genetics. We have isolated a series of microcell hybrids between a TK- Chinese hamster cell line and a transformed mouse cell line expressing the TK encoded by HSV 1. Several of the hybrid lines contain a single murine chromosome and express only the viral TK. Karyotypic analysis of these hybrids and of TK- derivatives generated by BrdUrd counterselection reveals that the TK+ phenotype is correlated with the presence of the terminal portion of the long arm of a specific murine chromosome. Results of extensive isozyme analyses of the hybrids and their TK- segregants fully corroborate the karyologic data. The results are consistent with the hypothesis that the viral tk gene is covalently integrated into this chromosomal region which itself does not appear to carry the endogenous murine tk locus. Other more complicated models are discussed. Our findings also show that somatic cell genetics can be used to localize viral integration sites in host chromosomes with high resolution.     

Identification of a mouse gene required for binding of Rauscher MuLV envelope gp70.

Mouse chromosome segregating somatic cell hybrids were established between a mouse thymic leukemai cell line (GRSL) and Chinese hamster E36 cells. The GRSL cells specifically bound purified Rauscher leukemia virus gp70 while the E36 cells exhibited no binding. The hybrids selectively bound Ruascher gp70 depending on the presence of a mouse cellular gene for the ecotropic murine luekemia gp70 receptor. A syntenic relationship was observed between the DIP-3 chromosome marker (on chromosome 5) and the gp70 receptor in primary clones and subclones of these hybrids; this was confirmed by chromosome analysis. The involvement of H-2 in the binding of Rauscher MuLV gp70 could be ruled out, because discordancies of the receptor presence and H-2 absence as well as of the receptor absence and H-2 presence type could be observed. Our results indicate that the Rec-1 (replication ecotropic MuLV) gene of Gazdar et al. (4) may well be the receptor gene for the ecotropic murine leukemia virus.     

Gene mapping in the Chinese hamster and conservation of syntenic groups and Q-band homologies between Chinese hamster and mouse chromosomes

Using Chinese hamster/mouse somatic cell hybrids segregating hamster chromosomes, we assigned 15 enzyme genes to six different Chinese hamster autosomes. Of the 15 loci, three genes, HK1, PEPC, and SORD, were newly assigned to chromosomes 1, 5, and 6, respectively, while ENO1, PGD, and PGM1 were assigned to the long arm of chromosome 2, in the segment 2q113----qter. The locations of the following loci were confirmed: ESD, NP, and PEPB on chromosome 1, ME1 and MPI on chromosome 4, AK1 on chromosome 6, and GPI and PEPD on chromosome 9. Comparative mapping of Chinese hamster and laboratory mouse chromosomes revealed conservation of syntenic groups and extensive banding homology between the Chinese hamster and mouse chromosomes on which homologous enzyme markers have been mapped.     

Normal X chromosome induced reversion in the direction of chromosome segregation in mouse-Chinese hamster somatic cell hybrids

The effect of a normal mouse X chromosome on the chromosome segregation of mouse-Chinese hamster somatic cell hybrids was determined by (i) producing hybrids between the mouse sarcoma line CMS4 and a microcell hybrid (mfe4) of the hamster line E36, containing a mouse X chromosome from a normal cell; (ii) isolating hybrids between CMS4 and a 6-thioguanine selected (X minus) mfe4 subpopulation; (iii) comparing the direction of segregation in the two sets of hybrids. It was found that the normal X chromosome, like the X chromosomes from two MCA-transformed sarcoma lines reported previously [9], has the ability to switch the chromosome segregation of mouse-Chinese hamster somatic cell hybrids. We conclude that the reversal in chromosome segregation is mediated by factors located on the X chromosome. We designate these genetic elements as segregation reversal genes or sr genes.     

Chromosome segregation from cell hybrids. VII. Reverse segregation from karyoplast hybrids suggests control by cytoplasmic factors.

Using human and Chinese hamster established lines as cell parents, we constructed hamster-human cell hybrids and human cell - hamster karyoplast hybrids. The cell hybrids retained one or two sets of hamster chromosomes and lost most of the human chromosomes. The karyoplast hybrids, however, retained a full set of human chromosomes and lost most of the Chinese hamster chromosomes. This reverse segregation pattern implies that cytoplasmic factors are major determinants of the direction of chromosome segregation.     

Identification of a cellular receptor for mouse mammary tumor virus and mapping of its gene to chromosome 16

Pseudotypes of vesicular stomatitis virus (VSV) containing envelope glycoproteins provided by C3H mammary tumor virus (MTV) instead of the normal VSV G-proteins were prepared and used to assay the presence of an MTV receptor on cells. The assay was specific as demonstrated by competition studies with excess MTV particles and neutralization of the pseudotypes with anti-MTV serum or monoclonal antibodies directed against MTV gp52. The MTV receptor was abundantly present on mouse cells but hardly detectable on nonmurine cells, including the Chinese hamster cell line E36. Somatic cell hybrids between E36 cells and GRS/A spontaneous leukemia cells (GRSL cells) and between E36 and GRS/A primary mammary tumor cells were made. The hybrids retained all Chinese hamster chromosomes but segregated mouse chromosomes. From the analysis of the isoenzymes and chromosomes of the hybrid cell lines we conclude that the gene for the receptor (MTVR-1) is located on mouse chromosome 16.     

RAS gene hot-spot mutations in canine neoplasias

Point mutations in the cellular homologues HRAS, KRAS2, and NRAS of the viral Harvey and Kirsten rat sarcoma virus oncogenes are commonly involved in the onset of malignancies in humans and other species such as dog, mouse, and rat. Most often, three particular hot-spot codons are affected, with one amino acid exchange being sufficient for the induction of tumor growth. While RAS genes have been shown to play an important role in canine tumors such as non-small lung cell carcinomas, data about RAS mutations in canine fibrosarcomas as well as KRAS2 mutations in canine melanomas is sparse. To increase the number of tumors examined, we recently screened 13 canine fibrosarcomas and 11 canine melanomas for point mutations, particularly within the mutational hot spots. The results were compared to the already existing data from other studies about these tumors in dogs.     

Requirement of human chromosomes 19, 6 and possibly 3 for infection of hamster x human hybrid cells with baboon M7 type C virus.

The replication pattern of the endogenous baboon type C virus M7 was studied in 29 primary Chinese hamster × human hybrid clones generated with leukemic cells from two different patients with acute lymphoblastic or myeloblastic leukemia. There was no evidence of viral particulate RDDP or M7 antigen before viral infection. M7 virus replicated in human and some hybrid cells but not in Chinese hamster cells, indicating that M7 requires dominantly expressed human gene(s) for replication. Enzyme and cytogenetic analyses show that a gene(s) coded for by human chromosome 19 is necessary for M7 infection of these hybrids. Detailed cytogenetic correlations revealed, however, that the chromosome 19+/M7 + hybrid clones with intact chromosomes also had copies of chromosomes 3 and 6. Previously, Bevi, the putative integration site for M7 virus, has been assigned to human chromosome 6. Many clones with various combinations of chromosomes 3 and 6 lacked chromosome 19, however, and failed to replicate exogenously applied M7 virus, while tests of 27 secondary clones showed that M7 markers co-segregated with chromosome 19 markers. These findings all confirm the need for a chromosome 19-coded function in Chinese hamster × human hybrids. In addition, the yield of viral particulate RDDP produced into the culture fluid was 50–100 fold less per viral antigen-positive cell in the hybrids compared with human cells. Thus some form of regulation of viral components exists in the hybrid cells. When the virus replicating in hybrid cells was transferred back to human cells, this regulation was relaxed and the yield of RDDP per FA(+) cell greatly increased. We conclude that human chromosomes 6 and 19 code for functions involved in M7 virus metabolism, and we cannot exclude a function coded for by chromosome 3.     

Fibroblast interferon in man is coded by two loci on separate chromosomes.

We have examined viral and poly(rl):poly(rC) induction of interferon synthesis in several human, mouse and Chinese hamster cell lines, and in hybrids derived from the fusion of such cells. We observed species and cell-type differences in inducer effectiveness and in the kinetics of interferon production. In some cases, parental characteristics are preserved in somatic cell hybrids, and in other cases, the expression of the donor phenotype is modulated by the epigenetic state of the recipient cell. Mapping studies in human/mouse and human/Chinese hamster hybrids indicate that there are at least two structural genes for human fibroblast interferon. Chromosomes 2 and 5 each contain genetic information for the synthesis of fibroblast interferon. Gene dosage experiments indicate that one gene is on the long arm of chromosome 2 and another is on the short arm of chromosome 5. Leukocyte interferon genes could not be mapped to these chromosomes, but this negative result could be influenced by the epigenetic state of the hybrid cells.     

Esterase gene expression in Chinese hamster and mouse lymphoma hybrids isolated under nonselective pressure

Hybrids between a fibroblastic Chinese hamster cell line (CH23) and a mouse lymphoma cell line (P388F36) were produced and isolated by a simple new method without using selective media and avoiding contact with the parental cells. The chromosomal situation in the two hybrid types (PCM and PCS) isolated suggested that growth on glass surface (PCM) or in suspension (PCS) depended on the number of hamster and mouse chromosomes which existed in the hybrids. Chromosomal stability in hybrids grown as monolayers (PCM) was reached at a stage in which two to four mouse chromosomes coexisted with no fewer than 19 hamster chromosomes. In a study of gene linkage utilizing clones of this hybrid population, five out of nine genes regulating the synthesis of different esterases in the mouse cells used were found to be unlinked.     

The genes coding for the muscle contractile proteins, myosin heavy chain, myosin light chain 2, and skeletal muscle actin are located on three different mouse chromosomes.

The chromosomal distribution of murine genes expressed during differentiation of skeletal muscle cells was determined by Southern blot analysis of DNA from mouse-Chinese hamster hybrid cell lines containing incomplete subsets of mouse chromosomes. All detectable myosin heavy chain genes are located on chromosome 11. The gene for the myosin light chain 2 is located on chromosome 7. The skeletal muscle alpha-actin gene and several other actin genes, or pseudogenes, are located on chromosome 3. Additional actin DNA sequences are distributed on other mouse chromosomes.     

Conservation of the syntenic group enol - pgd - pgm in mammals: its assignment to chromosome 2 in the Chinese hamster

Hybrids between cells from mouse permanent lines and Chinese hamster thymus cells explanted from animals maintained mouse chromosomes and lost most hamster chromosomes. In twenty-seven hybrids examined for expression of enolase 1. phosphogluconate dehydrogenase, and phosphoglucomutase, the Chinese hamster forms of the three enzymes were either expressed together, or not expressed at all. Thus, the three genes eno1, pgd, and pgm appear syntenic in Chinese hamster as they are in man (chromosome 1p), and in mouse (chromosome 4). The three markers map on the Chinese hamster chromosome 2.