Enhance anchorage independence and tumorigenicity of aneuploid Chinese hamster cells with nearly doubled chromosome complements.

The role of a cell's chromosome complement in its tumorigenic and anchorage-independent growth properties in vitro was investigated by injecting a Chinese hamster cell line and its subclones into immunodeficient nude mice and by plating the cells in a semisolid medium containing methylcellulose. The parental WOR-6 cell clone originally consisted of 89% 1s cells and 11% cells with a nearly double (2s) complement. Tumors that developed from WOR-6 were found to consis entirely or primarily of cells with near 2s chromosome complements. Subclones of WOR-6 that contained only 1s cells rarely produced tumors in nude mice, even at high inoculum doses, whereas clones containing a high fraction of 2s cells were consistently tumorigenition, serial passage of WOR-6 cells in semisolid medium resulted in selective enrichment for near 2s cells and, concomitantly, greatly enhanced tumorigenicity. Analyses of G-banded chromosomes revealed that the 1s cells of the WOR-6 parental clone, which has a modal chromosome number of 21 and a range of 18 to 23, is completely or partially monosomic for some chromosomes and trisomic for others. The 2s cells, selected both in vivo through growth as tumors in nude mice and in vitro in semisolid medium, appeared to have resulted from preferential duplication of certain chromosomes of the 1s cells. Our results therefore suggest that cells which develop multiple copies of selected genes, while remaining functionally hemizygous for other loci, acquire an enhanced anchorage-independent growth potential in vitro and increased tumorigenicity. This conclusion is consistent with the observation that cellular tumorigenicity is correlated with anchorage independence (Rreedman and Shin, 1974) and leads support to OHNO'S (1974) suggesting that aneuploidy is a possible means employed by cells to express recessive phenotypes and increase their tumorigenicity.     

A cloned gene encoding phosphatidylserine decarboxylase complements the phosphatidylserine biosynthetic defect of a Chinese hamster ovary cell mutant

A phosphatidylserine-auxotrophic mutant of cultured Chinese hamster ovary cells, PSA-3, manifests a defect in phosphatidylserine synthase I activity (Kuge, O., Nishijima, M., and Akamatsu, Y. (1986) J. Biol. Chem. 261, 5790-5794). We cloned a Chinese hamster gene, designated pssC, which was able to transform the PSA-3 cell line to a phosphatidylserine prototroph. The resultant transformant contained phosphatidylserine in normal amounts but remained defective in phosphatidylserine synthase I activity, indicating that pssC is a suppressor gene. Using the genomic fragment of pssC as a probe, a cDNA clone of pssC was isolated, and its nucleotide sequence was determined. A computer search through a protein data bank revealed that pssC had homology with the Escherichia coli psd gene encoding the proenzyme of phosphatidylserine decarboxylase at the amino acid level. Introduction of the cloned pssC gene into PSA-3 resulted in a 2-fold increase in phosphatidylserine decarboxylase activity. When the pssC cDNA was placed downstream of the yeast GAL1 promoter and introduced into yeast Saccharomyces cerevisiae cells, the phosphatidylserine decarboxylase activity increased in a galactose-dependent manner. These results indicate that pssC encodes phosphatidylserine decarboxylase. The mechanism by which pssC complements the defect of PSA-3 in phosphatidylserine biosynthesis is discussed.     

Radiation-induced chromosome damage in X-ray-sensitive mutants (xrs) of the Chinese hamster ovary cell line

The frequency of both spontaneous and X-ray- (95 rad) induced cytogenetical aberrations has been determined for 2 X-ray-sensitive strains (xrs-6 and xrs-7) of the Chinese hamster ovary cell line, and their wild-type parent (CHO-K1). Increased levels of spontaneous aberrations were not a general feature of the xrs strains, although xrs-7 did show a 2-fold increase in chromatid gaps. Unsynchronied populations of xrs cells, estimated to have been irradiated in late S and G2, showed a 3-5-fold increase in chromatid gaps, breaks and exchanges compared to CHO-K1. The irradiation of synchronised populations of xrs-7 and CHO-K1 in G1 demonstrated a 3-5-fold increase in chromosome breaks, gaps and exchanges in xrs-7. In addition xrs-7 displayed a large increase in chromatid-type aberrations, particularly triradials. These X-ray-sensitive strains have previously been shown to have a defect in double-strand break rejoining (Kemp et al., 1984), and an increased number of double-strand breaks (DBSs) remain in their DNA after irradiation compared to wild-type cells. The increased number of DSBs remaining in these strains 20 min after irradiation, correlates well with the increase in chromosome breaks.     

Overexpression of cyclin E does not influence homologous recombination in Chinese hamster cells

Overexpressed cyclin E in tumours is a prognosticator for poor patient outcome. Cells that overexpress cyclin E have been shown to be impaired in S-phase progression and exhibit genetic instability that may drive this subset of cancers. However, the origin for genetic instability caused by cyclin E overexpression is unknown. Homologous recombination plays an important role in S-phase progression and is also regulated by the same proteins that regulate cyclin E-associated kinase activity, i.e., p53 and p21. To test the hypothesis that overexpressed cyclin E causes genetic instability through homologous recombination, we investigated the effect of cyclin E overexpression on homologous recombination in the hprt gene in a Chinese hamster cell line. Although cyclin E overexpression shortened the G1 phase in the cell cycle as expected, we could see no change in neither spontaneous nor etoposide-induced recombination. Also, overexpression of cyclin E did not affect the repair of DNA double-strand breaks and failed to potentiate the cytotoxic effects of etoposide. Our data suggest that genetic instability caused by overexpression of cyclin E is not mediated by aberrant homologous recombination.     

Somatic cell chromosome interconnections in trypan preparations of Chinese hamster testicular cells

Chromosome interconnections joining all chromosomes of a cell are present in somatic and meiotic cells of mammals. They originate at the ends of the chromosomes as extensions of the central axis of the chromosome or chromosome pair and they join the ends of other chromosomes sometimes passing through anastomoses. They are highly elastic single strands with differentiation of light and dark, thick and thin areas. Mouse pachytene interconnections are unusual in that strands arising from the short arms are not elastic.     

Altered cell surface glycoproteins in phytohemagglutinin-resistant mutants of Chinese hamster ovary cells.

Purified membranes from surface-labelled phytohemagglutinin-resistant (Pha(R) and wild-type chinese hamster ovary cells have been analysed by sodium dodecyl sulphate gel electrophoresis. Gel patterns were compared for cells labelled via galactose oxidase and B-3H4 or lactoperoxidase and radioactive iodide. The results suggest that Pha-R cells are altered in the carbohydrate portion of a number of their membrane glycoproteins.     

Chinese hamster ovary cell mutants defective in myo-inositol transport

By means of an in situ colony autoradiographic assay for the incorporation of [14C]inositol into the trichloroacetic acid-insoluble fraction, we have isolated a mutant of cultured Chinese hamster ovary cells defective in inositol transport, named mutant 648. Through comparison of the inositol uptake activity of 648 cells with that of the parental cells with various concentrations of inositol and sodium, it has been demonstrated that Chinese hamster ovary cells possess a sodium-dependent transport system for inositol, and that 648 cells lack this system. The sodium-dependent uptake is inhibited by 2,4-dinitrophenol and ouabain, and the intracellular concentration of inositol exceeds the extracellular concentration during the uptake period, indicating that it is active transport, at least partially driven by the sodium gradient generated by Na+,K(+)-ATPase. The apparent Km for inositol has been estimated to be 12.0 microM. It is inhibited by hyperglycemic concentration of D-glucose in a competitive fashion.     

XRCC1 protects cells from chromate-induced chromosome damage, but does not affect cytotoxicity

Hexavalent chromium Cr(VI) is a well known human carcinogen. This genotoxic metal induces DNA strand breaks and chromosome damage. However, the relationship between these lesions is uncertain. Our study focused on examining the role of XRCC1 in sodium chromate-induced cytotoxicity and chromosomal aberrations in Chinese Hamster Ovary (CHO) cells. Three different cell lines were used: AA8 (parental), EM9 (XRCC1 mutant) and H9T3 (EM9 complemented with human XRCC1 gene). Results show that concentration-dependent decreases in relative survival are similar in all three cell lines, indicating that XRCC1 is not crucial for protecting cells from sodium chromate-induced cytotoxicity. Similarly the frequency of damaged metaphase cells was not affected by XRCC1 deficiency. However, the total number of Cr(VI)-induced chromosome aberrations was exacerbated by XRCC1 deficiency and the spectrum of chromosome damage changed dramatically. Specifically, chromatid and isochromatid lesions were the most prominent aberrations induced in the cell lines and XRCC1 was essential to reduce the formation of chromatid lesions. In addition, XRCC1 deficiency caused a dramatic increase in the number of chromatid exchanges indicating that it is involved in protection from Cr(VI)-induced chromosome instability.     

XRCC1 protects cells from chromate-induced chromosome damage, but does not affect cytotoxicity

Hexavalent chromium Cr(VI) is a well known human carcinogen. This genotoxic metal induces DNA strand breaks and chromosome damage. However, the relationship between these lesions is uncertain. Our study focused on examining the role of XRCC1 in sodium chromate-induced cytotoxicity and chromosomal aberrations in Chinese Hamster Ovary (CHO) cells. Three different cell lines were used: AA8 (parental), EM9 (XRCC1 mutant) and H9T3 (EM9 complemented with human XRCC1 gene). Results show that concentration-dependent decreases in relative survival are similar in all three cell lines, indicating that XRCC1 is not crucial for protecting cells from sodium chromate-induced cytotoxicity. Similarly the frequency of damaged metaphase cells was not affected by XRCC1 deficiency. However, the total number of Cr(VI)-induced chromosome aberrations was exacerbated by XRCC1 deficiency and the spectrum of chromosome damage changed dramatically. Specifically, chromatid and isochromatid lesions were the most prominent aberrations induced in the cell lines and XRCC1 was essential to reduce the formation of chromatid lesions. In addition, XRCC1 deficiency caused a dramatic increase in the number of chromatid exchanges indicating that it is involved in protection from Cr(VI)-induced chromosome instability.     

ELF magnetic field affects proliferation of SPD8/V79 Chinese hamster cells but does not interact with intrachromosomal recombination

Extremely low-frequency (ELF) magnetic fields have previously been shown to affect conformation of chromatin, cell proliferation, and calcium metabolism. Possible mutagenic and carcinogenic effects of ELF have also been discussed and tested. In this study, intrachromosomal recombination in the hprt gene after exposure to ELF magnetic field was investigated using the SPD8 recombination assay. SPD8 cells, derived from V79 Chinese hamster cells were exposed to ELF at a specific combination of static and ELF magnetic fields, that has been proven to have effects on chromatin conformation in several cell types. The genotoxic agent camptothecin (CPT) was used either as a positive control or simultaneously with ELF. We also analysed the effect of ELF and CPT on chromatin conformation with the anomalous viscosity time dependence (AVTD) technique, cell growth kinetics, and cell survival with clonogenic assay. DNA fragmentation was analysed by pulsed field gel electrophoresis (PFGE). ELF did not induce recombination alone, neither did ELF modify the recombinogenic effect of CPT. Although, there was no effect on cell survival in response to ELF exposure, inhibition of cell growth was observed. On the other hand, ELF exposure partly counteracted the growth inhibition seen with CPT. The data suggest that ELF exposure may stimulate or inhibit cell growth depending on the state of the cells. Although, ELF did not induce recombination, a weak but statistically significant DNA fragmentation comparable with CPT-induced fragmentation was observed with PFGE 48h after exposure to ELF.     

Inhibition of post-replication repair of alkylated DNA by caffeine in Chinese hamster cells but not HeLa cells

Caffeine has been found to potentiate the lethal effects of sulphur mustard (SM) and N-methyl-N-nitrosourea (MNU) in a line of Chinese hamster cells but not in a line of HeLa cells. The sensitization of SM-treated cells by caffeine was S phase specific, and persisted for up to 24 h after alkylation of asynchronous cell cultures. The sensitization of MNU-treated cells, however, was not S phase specific but persisted for up to 50 h after the initial alkylation. Possible explanations for this difference between these two types of alkylating agent were discussed. Previously, evidence was presented which suggested that the alkylation-induced delay in the time of the peak rate of DNA synthesis in Chinese hamster cells was associated with the operation of post-DNA replication repair mechanism in these cells. Caffeine has now been found to reverse this alkylation-induced delay of DNA synthesis in both SM- and MNU-alkylated Chinese hamster cells. It is therefore proposed that caffeine sensitizes alkylated cells by inhibition of a post-replication DNA repair mechanism. No support was obtained for the alternative possibility that caffeine inhibits alkylation-induced excision repair of damaged DNA. The role of DNA repair in the production of the lethal mutagenic and cytological effects of alkylating agents is discussed.     

Chinese hamster ovary cell mutants defective in the internalization of ricin.

Chinese hamster ovary mutants simultaneously resistant to ricin and Pseudomonas toxin have been isolated. Two mutant cell lines (4-10 and 11-2) were found to retain normal levels of binding of both ricin and Pseudomonas toxin. They were defective in the internalization of [125I]ricin into the mutant cells, as measured by both a biochemical assay for ricin internalization and electron microscopic autoradiographic studies. Although pretreatment of Chinese hamster ovary cells with a Na+/K+ ionophore, nigericin, resulted in an enhancement of the cytotoxicities of ricin and Pseudomonas toxin in the wild-type Chinese hamster ovary cells, preculture of the mutant cells did not alter the susceptibility of the mutant cells to either toxin. These results provide further evidence that there is a common step in the internalization process for ricin and Pseudomonas toxin.     

Chromium picolinate does not produce chromosome damage in CHO cells

Chromium picolinate (CrPic, Chromax) is a dietary supplement that has been commercially available for the past two decades. CrPic has potential benefits for reducing insulin dependence in diabetics by increasing sensitivity of insulin receptors and in stimulating insulin binding. In this study, CrPic was tested for its ability to produce chromosomal aberrations in vitro using Chinese hamster ovary K1 (CHO) cells. CHO cells were exposed to a range of cytotoxic to non-cytotoxic concentrations of CrPic for 4 or 20h in the absence of metabolic (S9) activation or for 4h in the presence of S9 activation. CrPic was solubilized with dimethyl sulfoxide (DMSO) to attain the highest possible solubility for maximizing the test doses. Cells were treated with 96.25, 192.5, 385 or 770 microg/mL of CrPic for 4 h in the presence of S9 activation, and for 4 or 20 h in the absence of S9 activation. A distinct precipitate of CrPic was evident in the cell culture medium at 770 microg/mL, which was the highest dose tested. Results showed no statistically significant increases in structural or numerical chromosome aberrations were produced at any test dose level with CrPic in 4-h treatments up to a precipitating dose of 770 microg/mL in either the presence or absence of S9 activation. Additionally no aberrations were observed up to 385 microg/mL (the maximum analyzable dose) following treatment for 20 h in the absence of S9 activation. The percentage of cells with structural or numerical aberrations in CrPic treated cultures was not statistically different (p>0.05) from that quantified in controls at any dose level. The absence of significant differences from control levels demonstrates that CrPic did not induce structural or numerical chromosome aberrations up to doses that were insoluble in the culture medium.     

Human chromosome 5 complements the DNA double-strand break-repair deficiency and gamma-ray sensitivity of the XR-1 hamster variant.

XR-1 is a Chinese hamster ovary (CHO) cell mutant which is unusually sensitive to killing by gamma rays in the G1 portion of the cell cycle but has nearly normal resistance to gamma-ray damage in late S phase. The cell-cycle sensitivity correlates with the mutant's inability to repair DNA double-strand breaks (DSBs) produced by ionizing radiation and restriction enzymes. We have previously shown in somatic cell hybrids of XR-1 cells and human fibroblasts that the XR-1 mutation is a recessive mutation. In this study, using somatic cell hybrids formed between XR-1 and human fibroblasts, we map the human complementing gene to chromosome 5 by chromosome-segregation analysis. This gene biochemically restores the hamster defect to wild-type levels of gamma-ray and bleomycin resistance as well as restoring its proficiency to repair DNA DSBs, suggesting that a single gene is responsible for the XR-1 phenotype. We have tentatively assigned the name XRCC4 (X-ray-complementing Chinese hamster gene 4) to this human gene until its biochemical function in repair is discovered.     

On the selection for the modal chromosome number in Chinese hamster cells

Chinese hamster cell lines have a strong tendency to maintain as modal chromosome number the euploid one characteristic of the species. By following the evolution of karyotypes in cloned subpopulation it has been possible to show that these pseudodiploid constitutions are not simply established due to a selective advantage but they are actually generated in populations where pseudodiploid classes had been absent. The possible role of the mitotic apparatus in keeping and restoring the euploid number is discussed.     

Replication timing in a single human chromosome 11 transferred into the Chinese hamster ovary (CHO) cell line

DNA replication in eukaryotes initiates from discrete genomic regions, termed origins, according to a strict and often tissue-specific temporal program. However, the genetic program that controls activation of replication origins has still not been fully elucidated in mammalian cells. Previously, we measured replication timing at the sequence level along human chromosomes 11q and 21q. In the present study, we sought to obtain a greater understanding of the relationship between replication timing programs and human chromosomes by analysis of the timing of replication of a single human chromosome 11 that had been transferred into the Chinese hamster ovary (CHO) cell line by chromosome engineering. Timing of replication was compared for three 11q chromosomal regions in the transformed CHO cell line (CHO(h11)) and the original human fibroblast cell line, namely, the R/G-band boundary at 11q13.5/q14.1, the centromere and the distal telomere. We found that the pattern of replication timing in and around the R/G band boundary at 11q13.5/q14.1 was similar in CHO(h11) cells and fibroblasts. The 11q centromeric region, which replicates late in human fibroblasts, replicated in the second half of S phase in CHO(h11) cells. By contrast, however, the telomeric region at 11q25, which is late replicating in fibroblasts (and in several other human cell lines), replicated in the first half of S phase or in very early S phase in CHO(h11) cells. Our observations suggest that the replication timing programs of the R/G-band boundary and the centromeric region of human chromosome 11q are maintained in CHO(h11) cells, whereas that for the telomeric region is altered. The replication timing program of telomeric regions on human chromosomes might be regulated by specific mechanisms that differ from those for other chromosomal regions.     

Association of human chromosome 14 with a ts defect in G1 of Chinese hamster K12 cells.

Somatic cell hybrids between human lymphoblastoid cells (Raji) and temperature-sensitive Chinese hamster cells (K12) were selected from monolayer cultures in MEM at 40 degrees C. A total of 21 hybrid clones were isolated and karyotyped. All clones contained a near complete set of Chinese hamster chromosomes and 1 to 5 human chromosomes. Human chromosome 14 present in the hybrid cells of all clones; and was the only human chromosome retained in 10 clones. The presence of human chromosome 14 in hybrids was further confirmed by the demonstration of human nucleoside phosphorylase activity in the hybrid cells. Only one hybrid clone was positive for EBNA, the Epstein-Barr virus antigen present in Raji cells. These findings indicate that human chromosome 14 contains the necessary information for the K12 cells to overcome their G1 defect in the cell cycle and grow at non-permissive temperature. The present study lends strong support to the possibility that different steps in the G1 phase of the cell cycle are controlled by genes located on different chromosomes.