Initiation of DNA replication in chromosomes of Chinese hamster ovary cells

The initiation of DNA replication and the subsequent chain elongation were studied using Chinese hamster ovary cells synchronized at the beginning of S phase. The cells were synchronized by a combination of mitotic selection and treatment with 5-fluorodeoxyuridine (FdU). The use of this drug at a concentration of 10^–5 M was found to effectively prevent the leakage of cells into S phase. Reversal of the FdU block by supplying thymidine resulted in the synchronous onset of initiation at multiple sites in each cell. The length of the nascent chains, as determined by autoradiography and velocity sedimentation in alkaline gradients, increased linearly with time during the first twenty minutes of S phase after release. — We applied these procedures to study the effects of the length of an FdU block on the number of functional origins per cell, the rate of chain growth, and the rate of DNA synthesis per cell following reversal of the block. Although no change was noted in the rate of DNA synthesis in cells held at the beginning of S phase from 10.5 to 24 h after division, the rate of chain growth decreased from 0.94 to 0.28 microns per min. This decrease indicated that the number of functional origins increased markedly with length of FdU block. The calculated number of utilized origins per cell increased from 1,900 to 5,700. We also presented arguments that 1,900 origins per cell represents the approximate number of origins utilized by any cell held at the beginning of S phase for less than 10.5 h after division.     

Effect of UV light on DNA replication and chain elongation in Chinese hamster UV61 cells

Exposure of eukaryotic cells to ultraviolet light results in a temporary inhibition of DNA replication as well as a temporary blockage of DNA fork progression. Recently there has been considerable debate as to whether the (5-6)cyclobutane pyrimidine dimer, the pyrimidine(6-4)pyrimidone lesion or both are responsible for these effects. Using cell lines that repair both of these lesions (CHO AA8), only (6-4) lesions (CHO UV61) or neither (CHO UV5), we have shown that in rodent cells both lesions appear to play a role in both the inhibition of thymidine incorporation and the blockage of DNA fork progression. Specifically, after exposure to 2.5 J/m2, AA8 cells recover normal rates of DNA replication within 5 h after exposure, while UV5 cells exhibit a greater depression in thymidine incorporation for at least 10 h. UV61 cells, on the other hand, show an intermediate response, both with respect to the extent of the initial depression and the rate of recovery of thymidine incorporation. UV61 cells also exhibit an intermediate response with respect to blockage of DNA fork progression. In previous publications we have shown that UV5 cells exhibit extensive blockage of DNA fork progression and only limited recovery of this effect within the first 5 h after exposure to UV. In this report we show that UV61 cells exhibit a more extensive blockage of fork progression than is observed in AA8 cells. These blocks also appear to be removed (or overcome) more slowly than in the AA8 cells, but more rapidly than in UV5 cells. Taken together we conclude that both lesions appear to be involved in the initial depression in thymidine incorporation and the initial blockage of DNA fork progression in rodent cells. These data also indicate that (6-4) lesions may be responsible for the prolonged depression in thymidine incorporation and the prolonged blockage of DNA fork progression observed in UV5 cells.     

The recovery of normal DNA replication kinetics in ultraviolet-irradiated Chinese hamster cells

The kinetics of DNA replication were analyzed in the second S phase following UV irradiation of Chinese hamster ovary cells synchronized at the beginning of S phase. The cells were synchronized by treating cells selected in mitosis with hydroxyurea for 9 h. Following UV irradiation, the cells were allowed to progress until the next mitosis; at which time they were resynchronized at the beginning of the second S phase by the same procedure. The kinetics of DNA replication were determined by measuring the proportion of DNA which achieved hybrid buoyant density on CsCl density gradients as a function of the time of incubation in the presence of 5-bromodeoxyuridine.The results of these experiments showed that even though the rate of DNA replication is substantially depressed during the first S phase following UV irradiation with a fluence of 5 J/m², the rate has recovered to the extent that it is indistinguishable from the unirradiated control by the time the cells have entered their second S phase. It was concluded from these observations that the lesions in DNA which caused the rate of DNA replication to be initially depressed during the first S phase have been either removed or modified such that they no longer are able to cause a reduction in the rate of DNA replication in the second S phase following UV irradiation.     

Immunofluorescent visualization of DNA replication sites within nuclei of Chinese hamster ovary cells

The spatial distribution of replication sites was studied by a sensitive method in cells cultured in vitro. Exponentially growing Chinese hamster ovary cells were permeabilized and pulse labeled in the presence of deoxyribonucleoside triphosphates, dTTP being replaced by biotin-11-dUTP as a substrate for DNA replication. The distribution of replication sites was visualized in isolated nuclei by fluorescent microscopy of samples taken periodically after short-term (2 min) in vitro labeling and pulse-chase experiments. Propidium iodide and 4,6-diamino-2-phenylindole served as fluorescent probes for total cellular DNA. Avidin-fluorescein isothiocyanate and biotinylated goat antiavidin antibody were used in an amplification procedure to fluorescently label the incorporated biotin-11-dUTP. Similar experiments using synchronized cells showed the distribution of replicons at different stages of S phase.     

Immunofluorescent visualization of DNA replication sites within nuclei of Chinese hamster ovary cells

Summary The spatial distribution of replication sites was studied by a sensitive method in cells cultured in vitro. Exponentially growing Chinese hamster ovary cells were permeabilized and pulse labeled in the presence of deoxyribonucleoside triphosphates, dTTP being replaced by biotin-11-dUTP as a substrate for DNA replication. The distribution of replication sites was visualized in isolated nuclei by fluorescent microscopy of samples taken periodically after short-term (2 min) in vitro labeling and pulse-chase experiments. Propidium iodide and 4,6-diamino-2-pheny-lindole served as fluorescent probes for total cellular DNA. Avidin-fluorescein isothiocyanate and biotinylated goat antiavidin antibody were used in an amplification procedure to fluorescently label the incorporated biotin-11-dUTP. Similar experiments using synchronized cells showed the distribution of replicons at different stages of S phase.     

Effects of mercuric chloride on synchronized Chinese hamster ovary cells: survival and DNA replication

Chinese hamster ovary (CHO) cells in vitro were treated with HgCl2 at various stages in the cell cycle and the effects of this chemical on cell survival, DNA replication, and cell division were observed. In terms of survival the early G1 cells were the most sensitive to treatment, followed by late G1 and early S, while mid S and late S-G2 treated cells were the least sensitive. Treatment with HgCl2 also resulted in reduced rates of DNA replication and delays in cell division. The early G1 treated cells showed substantially reduced rates of DNA replication followed by 4--5 h division delay. The early S and late S-G2 treated cells had some reduction in their rates of DNA replication followed by corresponding division delay of 2.5 h in the early S treated cells and 1 h in the late S-G2 treated cells.     

DNA replication in Chinese hamster ovary cells made permeable to nucleotides by tween-80 treatment

We have developed a method for permeabilizing CHO cells to nucleotides under conditions which allow most cells to remain viable. Permeabilized cells can carry out ATP-dependent, semiconservative synthesis of DNA. The data are consistent with the continuation of DNA synthesis in those cells in S phase at the time of treatment, possibly limited to completion of replicon synthesis without new initiations.     

Dependence of mammalian DNA replication on DNA supercoiling. II. Effects of novobiocin on DNA synthesis in Chinese hamster ovary cells.

Novobiocin, an inhibitor of gyrase-induced DNA supercoiling and DNA replication in prokaryotes, inhibited the incorporation of DNA precursors into DNA in both intact and permeable Chinese hamster ovary cells; much higher concentrations were required for permeable cells, in which no new replicons were initiated. Nucleoids were prepared from cells that were incubated for 60 min with 200 micrograms/ml novobiocin, made permeable, and incubated with 0--50 micrograms/ml ethidium bromide. Sedimentation of the nucleoids in neutral sucrose gradients suggested that the number of supercoils in the average nucleoid had been reduced by prior incubation with novobiocin. In intact cells, novobiocin is required inside the cell for continued inhibition of DNA synthesis, suggesting that it does not act directly on the DNA. Alkaline sucrose gradient profiles of DNA synthesized in the presence of novobiocin in intact cells indicated that the drug inhibited replicon initiation while having little if any effect on chain elongation. These data are consistent with the idea that an activity similar to the bacterial gyrase generates supercoils in mammalian DNA and produces the proper conformation for the initiation of DNA replication.     

Early replication signals in nuclei of Chinese hamster ovary cells

Summary DNA replication sites generally known as replicon domains were resolved as individual replication signals in interphase nuclei of permeabilized Chinese hamster ovary cells by immunofluorescent microscopy. Biotin-11-dUTP was utilized as a tool to label newly replicated DNA in permeable cells and to study the distribution of nascent DNA in pulselabel and in pulsechase experiments. Active sites of DNA replication were visualized in exponentially growing cells and in synchronized cultures throughout the S phase. Fluorescent images of replication sites were analyzed by standard fluorescense microscopy and in three dimensions by confocal laser scanning microscopy. The rapid increase in number of discrete foci of newly replicated DNA is an indication that DNA synthesis starts at limited number of sites in mammalian nuclei rather than at thousands of foci at the same time.     

Species-specific differences in the toxicity of puromycin towards cultured human and Chinese hamster cells

The toxicity of the protein synthesis inhibitor puromycin towards a number of human and Chinese hamster cell lines has been examined. In comparison to cells of human origin, Chinese hamster cells exhibited about 25-fold higher resistance towards puromycin. These differences appeared to be species related as all the cell lines from any one species showed similar sensitivity towards puromycin. The incorporation of [3H]leucine in the hamster cell lines was accordingly found to be more resistant to the inhibitory effects of puromycin as compared to human cells. Studies on the cellular uptake of [3H]puromycin showed that in comparison to human cells, the drug uptake/binding in the hamster cell lines was greatly reduced. However, protein synthesis in the extracts of hamster and human cells showed no significant differences in sensitivity towards puromycin. These results show that the observed species related differences in cellular toxicity to puromycin are due to differences in the cellular uptake/binding of the drug.     

Protection of Chinese hamster ovary cells from hyperthermic killing by cycloheximide or puromycin

Cycloheximide (CHM) and puromycin (PUR) were used at various concentrations up to maxima of 10 micrograms/ml and 100 micrograms/ml, respectively, which inhibited protein synthesis by 95% without any cytotoxicity. The drugs were added to the cells for a maximum period of 7 h, with various combinations for treatment before, during, and after heating. Maximum protection, i.e., a 10,000-fold increase in survival from 5 X 10(-6) to 5 X 10(-2) after 4 h at 43 degrees C, required both 1-2 h of treatment before heating and 1-2 h of treatment during heating. For treatments at 45.5 degrees C, the protection was less, i.e., a 100-fold increase in survival from 10(-5) to 10(-3). Little or no protection was observed if after treatment, the drug was removed before heating, or if the drug was added at the start of heating and left on for 5 min to 3 h after heating. For both drugs, the amount of protection increased as inhibition of protein synthesis increased. However, the amount of protection from the drugs was the same only at about 95% inhibition; at 60-85% inhibition, CHM afforded more protection than PUR. Therefore, the modes of action of the drugs might be common at high drug concentrations, but different when intermediate concentrations are used.     

Effects of ultraviolet irradiation on the rate and sequence of DNA replication in synchronized Chinese hamster cells.

The effects of ultraviolet light (UV) irradiation on the rate of DNA replication in synchronized Chinese hamster ovary (CHO) cells were investigated. A technique for measuring semiconservative DNA replication was employed that involved growing the cells in medium containing 5-bromodeoxyuridine and subsequently determining the amount of DNA that acquired hybrid buoyant density in CsCl density gradients. One of the advantages of this technique was that it allowed a characterization of the extent of DNA replication as well as rate after irradiation. It was found that while there was a dose-dependent reduction in the rate of DNA replication following UV-irradiation, doses of up to 10 J/m2 (which produce many dimers per replication) did not prevent the ultimate replication of the entire genome. Hence, we conclude that dimers cannot be absolute blocks to DNA replication. In order to account for the total genome replication observed, a mechanism must exist that allows genome replication between dimers. The degree of reduction in the rate of replication by UV was the same whether the cells were irradiated at the G1-S boundary or 1 h into S-phase. Previous work had shown that cells in early S-phase are considerably more sensitive to UV than cells at the G1-S boundary. Experiments specifically designed to test for reiterative replication showed that UV does not induce a second round of DNA replication within the same S-phase.     

Antagonistic effect of magnesium chloride on the nickel chloride-induced inhibition of DNA replication in Chinese hamster ovary cells

The degree of inhibition of semiconservative DNA replication induced by nickel chloride (NiCl2) was analyzed by radiolabeled-thymidine incorporation alone or with cesium chloride (CsCl) density gradient centrifugation. The onset and duration of this Ni2+-induced inhibition was time- and concentration-dependent, but the degree of inhibition was not. A maximal reduction in the rate of DNA synthesis was observed within the first hour of treatment with 2.5 mM NiCl2, which was the highest noncytotoxic concentration utilized. After six hours, 500 microM and 1 mM as well as 2.5 mM NiCl2 all produced the same 50% to 60% reduction in [3H]-thymidine incorporation into DNA. The inhibitory effect of nickel ions on DNA synthesis was reversible. The rate of DNA synthesis following a 500 microM or 1 mM NiCl2 treatment began to increase after washout of nickel, but a six-hour exposure of cells to 2.5 mM NiCl2 produced a sustained 50% to 60% suppression of DNA synthetic activity for at least 36 hours. At all concentrations of NiCl2 used in this study, some inhibition of DNA synthesis persisted for at least 48 hours, but by 72 hours after treatment, the rate of [3H]-thymidine incorporation was actually 10% above the control. Examination of autoradiographic slides of cells treated with 2.5 mM NiCl2 for six hours demonstrated a 60% reduction of silver grains, but there was no preferential reduction in the quantity of grains in the nucleolus or any other region. Cesium chloride density gradient analysis of the replication of nucleolar DNA in cells treated with 2.5 mM nickel supported the autoradiographic findings. The inhibitory effect of NiCl2 on DNA replication was prevented by the addition of magnesium chloride (MgCl2) to cells maintained in a simple salts/glucose medium (SGM). This effect did not appear to be due to an antagonism of the cellular uptake of nickel by Mg2+, since the maximally effective dose of Mg2+ reduced 63Ni2+ uptake by no more than 25% while the inhibition of replication was completely reversed.