Inhibition of Chinese hamster ovary cell DNA synthesis by hydrogen peroxide

The DNA synthesis inhibitory effect of hydrogen peroxide has been examined under a number of experimental conditions. Results have indicated that the effect of the oxidant is more pronounced when the treatment is performed at 37 degrees C than at 4 degrees C and in low density as compared to high density cultures. In addition, similar levels of inhibition were achieved by measuring the incorporation of radiolabelled thymidine in the presence of, or following treatment with, the oxidant. Although early events seem to be responsible for the decreased rate of DNA synthesis, it would appear that hydrogen peroxide does not alter thymidine extracellularly and/or decrease the transport of the nucleoside across the plasma membrane, which may actually be slightly augmented. Thus, the previously illustrated results may represent an underestimate of the actual capacity of the oxidant to reduce DNA synthesis. This inference is further supported by the fact that the effect of hydrogen peroxide appears markedly enhanced in cells preloaded with the radiolabelled precursor. A temporal relationship seems to exist between the steady state level of DNA single strand breaks and the extent of DNA synthesis inhibition by hydrogen peroxide. The oxidant has no effect on DNA chain elongation. In conclusion, data presented in this paper suggest that early events, involving selective effects on replicon initiation, mediate the DNA synthesis inhibitory effect of hydrogen peroxide.     

Effects of 3-aminobenzamide on DNA synthesis and cell cycle progression in Chinese hamster ovary cells

3-Aminobenzamide (3AB), an inhibitor of poly(ADP-ribose) polymerase, is a potent inducer of sister chromatid exchanges (SCEs). Because of the possible relation between SCEs and DNA synthesis, the effects of 3AB on DNA synthesis and cell cycle progression in Chinese hamster ovary (CHO) cells were examined. Unlike all other SCE-inducing agents whose effects on DNA synthesis have been studied, short term exposures (30–120 min) of 3AB did not inhibit the overall rate of DNA synthesis and this result was independent of the amount of bromodeoxyuridine (BrdU) in the DNA. Longer exposure times (>24 h) did result in an extended S phase, but this was not due to an effect on the rate of DNA chain elongation. 3AB also delayed the entry of cells into S phase. The overall cell cycle delay was dose dependent, approaching 9 h after a 54 h exposure to 10 mM 3AB. Earlier reports that 3AB is neither mutagenic nor cytotoxic were confirmed. Thus 3AB acts to increase SCE frequency by a mechanism distinct from that which causes cytotoxicity and mutagenicity, and does not involve any inhibition in the rate of DNA chain growth.     

Isolation and characterization of amphotericin B-resistant cell lines in Chinese hamster cells

Amphotericin B is a polyene macrolide antibiotic which interacts specifically with steroids in mammalian cell membranes. Amphotericin B-resistant (AMB^r) lines of stable phenotype have been isolated from cultured Chinese hamster (V79) cells. Three AMB^r clones (AMB^r-1, -2 and -3) isolated independently after treatment with nitrosoguanidine were resistant to ≥150 μg/ml of the antibiotic, while DNA synthesis as well as the colony-forming ability of the parental V79 cells was blocked by >80% of control in the presence of 20–50 μg/ml amphotericin B. The AMB^r cell line also exhibited increased resistance to other polyene macrolide antibiotics such as nystatin and pentamycin. Other agents, however, such as cytosine arabinoside or ricin, blocked DNA synthesis in AMB^r cells to the same extent as in V79 cells. The amphotericin B resistance phenotype was stably retained even after AMB^r cells were cultured in the absence of the drug for over 200 generations. The content of free cholesterol or its esters was significantly decreased in all three resistant clones. Furthermore, cholesterol synthesis from acetate as well as mevalonate was partly defective in AMB^r cells, compared with that in V79 cells.     

Inhibition of DNA synthesis in adrenocortical cells by cytochalasin B

ACTH inhibits DNA synthesis in normal rat and mouse tumor Y-1 adrenocortical cells within the same concentration range that it stimulates steroidogenesis. These processes can be independently regulated as demonstrated by the divergent actions of cytochalasin B on these cells. In the normal cells, cytochalasin B does not increase steroidogenesis in serum-free or serum-containing media, and it decreases the stimulation produced by ACTH. In the absence of serum, the Y-1 cells respond in a similar way. However, in serum-containing media, cytochalasin B increases steroidogenesis in these cells and does not inhibit the response to ACTH. In both cell types, cytochalasin B inhibits [3H]thymidine incorporation into DNA by a mechanism different than that of ACTH. In the Y-1 cells, this inhibition is caused by a decreased uptake of [3H]thymidine into the cell, which probably reflects a decreased transport across the cell membrane. In the normal cells, cytochalasin B, like ACTH, does not affect [3H]thymidine transport, but it decreases DNA synthesis much more rapidly than does ACTH. This inhibition may be the result of the disruption of microfilaments by cytochalasinB, because our evidence indicates that it is not caused by a decrease in glucose uptake by the cells.     

Patterns of protein synthesis during the cell cycle of Chinese hamster ovary cells

The protein synthesis patterns at various stages of the cell cycle of Chinese hamster ovary cells were examined by labelling cells with [35S]methionine and then separating the proteins by isoelectric focussing and two-dimensional, nonequilibrium pH gradient gel electrophoresis. We have observed a number of proteins which display quantitative differences in synthesis at specific cell cycle stages and of these the alpha- and beta-tubulins have been identified. A few proteins appear to be uniquely synthesized at specific times during the cell cycle. These include the histones and a modified version of them, which are synthesized only in S phase, and a pair of 21 kilodalton (kDa), pI 5.5 proteins, which appear only in late G2 and mitosis. We have also identified a 58-kDa, pI 7.5 protein which is present at all cell cycle stages except during late G2. This protein appears to have the same temporal properties as a 57-kDa protein called "cyclin" originally described in sea urchin embryos.     

Glycoprotein synthesis in a temperature-sensitive Chinese hamster cell cycle mutant

A temperature-sensitive mutant of Chinese hamster cells is described which has two interesting properties: (1) it is a cell cycle mutant and (2) glycoprotein synthesis appears to be affected at the at the non-permissive temerature (40degreesC). Synchronized cells shifed to 40degreesC in the beginning of their G1 phase do not incorporate [3H]-thymidine into DNA during the expected S-phase, but once DNA synthesis has been initiated ( approximately 10 hours after termination of serum starvation) a shift to 40 degrees C no longer leads to an arrest of DNA synthesis. Flow microfluorimetric analysis of DNA content/cell supports this conclusion and indicates that a majority of cells become arrested in the G1 phase of the cell cycle when a non-synchronized population of cells is transferred to 40degreesC. Apparently at all times in the cell cycle there is a drastic reduction if incorporation of labeled sugars (particularly fucose) into glycoproteins. The uptake of fucose and its conversion to GDP-fucose appears to be normal at 40degreesC. Chromatographic analysis indicates that all classes of glycoproteins are affected, and we do not find any evidence for partially completed oligosaccharides at 40 degrees C. Overall protein synthesis is not reduced at he nonpermissive temperature during the time interval under consideration and the number of polysomes attached to membranes (RER) is also normal at 40degreesC. This suggests that the defect is at an early step in the synthesis or regulation of synthesis of glycoproteins. The mutation is a recessive mutation in hybrid cells and mutagen induced revertants can be obtained which grow normally at 40degreesC and in which glycoprotein synthesis at 40 degrees C is restored to normal, wild type levels.     

Inhibition of repair of UV-damaged DNA by caffeine and mutation induction in Chinese hamster cells

The effect of caffeine on UV-irradiated Chinese hamster cells in vitro was studied on the cellular and molecular levels. Caffeine (1 mM) was shown to decrease the colony-forming ability and the frequencies of spontaneous and UV-induced mutations in Chinese hamster cells. The effect of caffeine in reducing the frequency of UV-induced mutations was demonstrated only if caffeine was present in the culture medium during the first post-irradiation cell division. Using alkaline sucrose gradient centrifugation, both parental and newly synthesized DNA in UV-irradiated and unirradiated cells were studied in the presence and absence of caffeine. Caffeine affected the sedimentation profile of DNA synthesized in UV-irradiated cells but not in unirradiated cells. Caffeine had no apparent effect on the incorporation of [³H]-thymidine into DNA of control or UV-irradiated cells, nor on the small amount of excision of UV-induced pyrimidine dimers. These results may be interpreted by a hypothesis that caffeine inhibits a certain S-phase specific, post-replication, dark-repair mechanism. The hamster and perhaps other rodent cells exposed to low doses of UV are capable of DNA replication, by-passing the non-excised pyrimidine dimers. This postulated repair process probably involves de novo DNA synthesis to seal the gaps in the nascent strand. This repair may be also responsible for the enzymatic production of mutations.     

Inhibition of DNA synthesis and cytotoxic effects of some DNA topoisomerase II and gyrase inhibitors in Chinese hamster V79 cells

In this study, some DNA topoisomerase II and gyrase inhibitors have been identified as inhibitors of polymerization of deoxyribonucleotides [novobiocin (NVB), nalidixic acid (NDA), oxolinic acid (OXA)], or inhibitors of replicon initiation and DNA-chain elongation [etoposide (VP-16), teniposide (VM-26), 4'-(9-acridinylamino)methansulfon-m-anisidine (m-AMSA), ellipticine (ELT)]. The inhibitors of deoxyribonucleotide polymerization produced a significant (greater than 85%) suppression of [3H]thymidine incorporation into V79 cells within 20 min of treatment, followed by a rapid recovery of DNA synthesis, and reduced cell killing. In contrast, the inhibitors of replicon initiation and DNA-chain elongation needed about 60 min to induce a partial, but irreversible inhibition of DNA replication, associated with extensive cell killing.     

Inhibition of repair of radiation-induced DNA damage by thermal shock in Chinese hamster ovary cells

The effect of exposure to elevated temperatures (41-45 degrees C) on the repair of radiation-induced DNA strand breaks was measured in monolayer cultured Chinese hamster ovary (CHO) cells. Prior exposure of cells to temperatures between 43 and 45 degrees C resulted in significant decreases in the rate of repair of DNA damage. Exposure to 45 degrees C for 15 min slowed the rate of DNA repair to 0.17 of the control repair rate. The To for inactivation of DNA repair was observed to be 34, 13 and 6 min at 43, 44 and 45 degrees C, respectively. Stepdown-heating (45 degrees C for 15 min followed by repair at 41 degrees C) resulted in greater inhibition of DNA repair (0.11 of the control rate) than was observed after acute heating alone. Repair at 41 degrees C was observed to proceed in unheated cells at a faster rate than at 37 degrees C. An Arrhenius analysis of the inactivation kinetics of DNA repair between 43 and 45 degrees C indicated an activation energy of 140 kcal mol-1 of protein for the inhibition of DNA repair. In general, the results were inconsistent with either a retardation of the DNA repair rate or an increase in unrepaired DNA lesions being responsible for heat-induced radiosensitization.     

Inhibition by actinomycin D of ribosomal RNA synthesis in the presynthesis period of the mitotic cycle of Chinese hamster cell cultures]

Using radioautographic technique actinomycin D at a concentration of 0.08 mug/ml was shown to inhibit selectively ribosomal RNA (rRNA) synthesis in monolayer cultures of Chinese hamster cells. The treatment with actinomycin D of cells synchronized by mitotic selection in the beginning of the G1 period causes a delay in the onset of DNA synthesis. However, a similar treatment in the late G1 period does not prevent cells from entering the S-period. The same effect has been produced by 9 mug/ml lucanthone, another inhibitor of rRNA synthesis. The experiments demonstrate a pronounced difference in cell reaction to the depression of rRNA synthesis in early and late G1 period. The data imply that the formation of rRNA, essential for the initiation of DNA synthesis, is accomplished in the first half of the G1 period, while part of rRNA has been already formed in the previous cycle.     

Continued initiation of DNA synthesis in arginine-deprived Chinese hamster ovary cells

When exponentially growing CHO cells were deprived of arginine (Arg), cell multiplication ceased after 12 h, but initiation of DNA synthesis continued: after 48 h of starvation with continuous [3H]thymidine exposure, 85% of the population had incorporated label, as detected autoradiographically. Consideration of the distribution of exponential cells in the various cell cycle phases leads to a calculation that most cells in G1 at the time that Arg was removed, as well as those in S, engaged in some DNA synthesis during starvation. In contrast, isoleucine (Ile)-starved cells did not initiate DNA synthesis, as has been reported by others. Experiments with cells synchronized by mitotic selection confirmed this difference in Arg- and Ile- deprived behavior, but also showed that cells which underwent the mitosis leads to G1 transition during Arg starvation remained arrested in G1 (G0?). The results suggest that Arg-deprived cells continue to maintain some proliferative function(s) while Ile-deprived cells do not.     

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.     

DNA synthesis and mitosis in a temperature sensitive Chinese hamster cell line

Viability, DNA synthesis and mitosis have been followed in the temperature sensitive Chinese hamster cell mutant K12 under permissive and non-permissive conditions. On incubation at 40°C cells retained their ability to form colonies at 33°C for 15 to 20 hours, but viability was lost gradually during the following 20 hours. When random cultures of K12 were shifted to 40°C the rate of DNA synthesis was normal for three to four hours but then decreased markedly, reaching 95% inhibition after 24 hours. Under the same conditions mitosis was inhibited after 15 hours. If cultures which had been incubated at 40°C for 16 hours were placed at 33°C the rate of DNA synthesis increased five hours after the shift down and mitosis 18 hours after. These results can be interpreted on the assumption that K12 at 40°C is unable to complete a step in the cell cycle which is essential for DNA synthesis and which occurs three to four hours before the start of S at 33°C.     

Thiopyronine-sensitized photodynamic effect on cell growth, RNA and DNA synthesis of Chinese hamster ovary cells

After treatment of Chinese hamster ovary (CHO) cells with very low concentrations of thiopyronine (TP; 1 microgram/ml) and visible light, a delay in growth of cell cultures (prolongation of the lag phase] was observed. The lengthened lag phase, however, was followed by normal growth of the cells. The length of the lag period is dependent on the irradiation dose applied. A similar effect on DNA and RNA synthesis could be seen after photodynamic treatment with TP in CHO cells: the maxima of RNA and DNA synthesis occur later but are not significantly reduced after treatment with low concentrations of TP and irradiation with visible light. This result is further evidence that the photodynamic effect with TP does not involve attack on nuclear DNA in eukaryotic cells.     

Effect of cadmium on cell cycle progression in Chinese hamster ovary cells

Chinese hamster ovary K1 (CHO K1) cells are very sensitive to cadmium (Cd) toxicity. They were used to investigate the effect of Cd on cell cycle progression. Cells were cultured with 0.1, 0.4, 1 or 4 microM Cd for various time intervals. There was no difference in growth rate when less than 0.4 microM Cd was given within 24 h. A dose-dependent reduction of cell proliferation was observed when more than 0.4 microM of Cd was given. The cells were pulse-labeled with 5-bromodeoxyuridine (BrdU), and the labeled cells were cultured in the presence of increasing concentrations of Cd. Cell cycle progression was retarded as a function of Cd concentration. G2/M arrest was observed when the BrdU-labeled cells were treated with 1 microM Cd for 8h, whereas cells receiving 4 microM Cd stopped at the S phase within 4 h. Cell cycle analysis of cells treated with Cd for 24 h showed that G2/M arrest occurred only when cells received 0.8 to 2 microM Cd. Despite the occurrence of G2/M arrest in the Cd treatment, only a limited proportion of the cells were blocked in the M phase. However, the increase in M phase cells coincided with an elevation in the cyclin-dependent kinase 1 activity. To examine whether Cd acts on cells at a specific cell stage, they were synchronized at the G1 or G2/M phase then treated with 1 microM Cd for 12 h. The cells were blocked at the G2/M and G1/S phase, respectively. This finding indicates that Cd toxicity is global and not cell phase specific. We also investigated the involvement of Cd-induced reactive oxygen species (ROS) with the occurrence of G2/M block and found a lack of correlation between cell cycle arrest and ROS production. We measured the Cd content that caused G2/M arrest from a series of Cd treatments and determined the ranges of cumulative Cd concentrations that could result in cell cycle arrest.     

Over-replication of DNA in S phase Chinese hamster ovary cells after DNA synthesis inhibition

Agents that inhibit DNA synthesis increase the frequency of methotrexate resistance and gene amplification in cultured mammalian cells. Chinese hamster ovary cells blocked with hydroxyurea rereplicated dihydrofolate reductase gene sequences within a single cell cycle upon release from the block (Mariani, B.D., and Schimke, R.T. (1984) J. Biol. Chem. 259, 1901-1910). Perturbation of DNA synthesis was postulated to result in misfiring of replicon initiation, subsequent over-replication of DNA sequences, and amplification of specific genes. To test this hypothesis, we have exposed Chinese hamster ovary cells pulsed with bromodeoxyuridine to three agents that inhibit DNA synthesis and enhance gene amplification: UV irradiation, hydroxyurea, and aphidicolin. After release from the block, the progression of cells throughout the cell cycle was analyzed by flow cytometry through simultaneous measurement of total cellular DNA content and bromodeoxyuridine-labeled DNA. Although the cell cycle effects varied depending on the agent used for the block, in all cases a subset of cells that were in S phase at the time of the block exhibited DNA histograms with greater than 4C DNA content at various times after release and prior to cell division. Cells with the excess DNA were approximately 10-fold more resistant to methotrexate compared to treated cells with normal DNA content or untreated cells. Therefore, cells in S phase at the time of the block produce excess DNA per cell prior to division, and this over-replicated DNA may be relevant to gene amplification and drug resistance.