Effect of thiopyrimidine ribonucleosides on DNA and RNA synthesis in synchronized mammalian cell cultures

The uptake of ³H-uridine into RNA and of ³H-thymidine into DNA was investigated in synchronized Chinese hamster cells which had been exposed to thiopyrimidine ribonucleosides. The cells were synchronized at metaphase by reversal of colcemid inhibition; these cells were then labeled with either ³H-thymidine or ³H-uridine at selected times, and analyzed in autoradiographs. Incorporation of ³H-thymidine into DNA was not inhibited by administration to the cells of 2-thiouridine or 4-thiouridine (4 × 10⁻³ M). Exposure of the cells to the anti-metabolites for over 15 h significantly reduced the incorporation of ³H-uridine into nuclear RNA and completely blocked the labeling of cytoplasmic RNA. This finding is interpreted as an indication that RNA synthesis was inhibited in cells which continued to synthesize DNA. The inhibition of RNA synthesis hindered cell division and decreased cell viability. This lethal effect is similar to the “unbalanced growth” induced by inhibitors of DNA synthesis. The thiopyrimidine ribonucleosides, however, killed mammalian cells without inhibiting DNA synthesis.     

Lack of effect of butyrate on S phase DNA synthesis despite presence of histone hyperacetylation

The effects of sodium butyrate on [³H]thymidine incorporation and cell growth characteristics in randomly growing and synchronized HeLa S₃ cells have been examined in an attempt to determine what effects, if any, butyrate has on S phase cells. Whereas 5 mM sodium butyrate rapidly inhibits [⁵H]thymidine incorporation in a randomly growing cell populations, it has no effect on incorporation during the S phase in cells synchronized by double thymidine block techniques. This lack of effect does not result from an impaired ability of the S phase cells to take up butyrate, since butyrate administration during this period leads to histone hyperacetylation that is identical with that seen with butyrate treatment of randomly growing cells. Furthermore, the ability to induce such hyperacetylation with butyrate during an apparently normal progression through S phase indicates that histone hyperacetylation probably has no effect on the overall process of DNA replication. Temporal patterns of [³H]thymidine incorporation and cell growth following release from a 24-h exposure to butyrate confirm blockage of cell growth in the G1 phase of the cell cycle. Thus, the inhibition by butyrate of [³H]thymidine incorporation in randomly growing HeLa S₃ cell populations can be accounted for solely on the basis of a G1 phase block, with no inhibitory effects on cells already engaged in DNA synthesis or cells beyond the G1 phase block at the time of butyrate administration.     

DNA synthesis in Hela cells at low temperature

It has been proved that ³H-thymidine is incorporated into DNA of HeLa cells cultured at 4 °C and its labelling distribution in DNA is homogeneous. This incorporation of ³H-thymidine increased with the duration of incubation and only 30% of the cell population was labelled after 12 h. When synchronous cell populations were used, the rate and extent of DNA synthesis at 4 °C was proportional to the relative number of cells in S phase at that temperature. Thus, cellular labelling at 4 °C does not result from a non-specific absorption phenomenon, but indicates a DNA synthesis process.     

Replication of chromosomal DNA in diploid Drosophila melanogaster cells cultured in vitro

Replication rate and replicon sizes in chromosomal DNA of in vitro cultured diploid D. melanogaster cells were determined using autoradiography of ³H-thymidine labeled DNA. Synthesis of DNA in euchromatic and heterochromatic regions of Drosophila diploid cells occurs at different periods of the S phase which lasts 10 h. During the first 4 h the synthesis is observed only in euchromatic regions. The heterochromatic synthesis starts shortly before the synthesis in euchromatic regions is completed and lasts for 6 h until the end of the S phase. The cells were synchronized by 5fluorodeoxyuridine which blocked the diploid cell DNA synthesis. Synthesis was found to start simultaneously in most euchromatic replicons. In the majority of the replicons the synthesis started at a single point and proceeded bidirectionally. The average rate of DNA synthesis per fork was 12.5 m/h (38 kb). The mean distance between the middle points of adjacent labeled regions was 70 m (210 kb). The size of most replicons ranged from 40 to 120 m. — These estimates do not apply to the heterochromatic portions of the D. melanogaster genome since the measurements have been carried out on DNA preparations obtained during the first 2 h of the S phase. — On the average, a replicon can consist of 7 chromomeres since the size of a replicon in diploid cell chromosomal DNA and DNA length of a polytene chromomere average 210 and 30 kb, respectively.     

Induction of deoxyribonucleic Acid synthesis in potato tuber tissue by cutting

Incorporation of ³²P-orthophosphate was found in the DNA fraction of aerobically incubated potato discs when examined by methylated albumin kieselguhr column chromatography. The estimation of DNA content of the discs was by a method developed for starchy tissues and showed that the incorporation of ³²P was due to net synthesis of DNA. The DNA content of a disc rapidly increased after a lag period of about 12 hours. The increase continued during the entire test period although at a lower rate during the later period of aging. DNA synthesis was further examined by measuring the rate of incorporation of ³H-thymidine. The striking similarity which was found between changes in the rate of DNA accumulation and in the rate of ³H-thymidine incorporation indicates that the incorporation of ³H-thymidine actually represents the net synthesis of DNA. Although the experiments with microautoradiography revealed that DNA synthesis occurred exclusively in nuclei, no signs of cell division were detected by microscopic observation. DNA synthesis in potato discs was further examined by using inhibitors of protein and RNA synthesis and was sensitive to those inhibitors. The significance of the present results is discussed in relation to the role of wounding in the induction of DNA synthesis.     

DNA SYNTHESIS,CELL DIVISION,AND CELL DIFFERENTIATION DURING LEAF DEVELOPMENT OF XANTHIUM PENNSYLVANICUM

Leaf growth consists of two basic processes, cell division and cell enlargement. DNA synthesis is an integral part of cell division and can be studied with autoradiographic techniques and incorporation of some labeled precursor. Studies were made on the synthesis of nuclear DNA through incorporation of ³H-thymidine in various parts of the lamina during the entire course of leaf development of Xanthium pennsylvanicum. The time course analysis of DNA synthesis was correlated with cell division and rates of cell enlargement. Significant differences in ³H-thymidine incorporation were found in various parts of the lamina. Cell division and DNA synthesis were highest in the early stages of development. Since no ³H-thymidine was incorporated after cessation of cell division (LPI 2.8) in the leaf lamina, it appears that DNA synthesis is not needed for enlargement and differentiation of Xanthium cells. Rates of cell enlargement were negligible in the early development and reached their maximum after cessation of mitoses, between plastochron ages (LPI) 3 and 4. Cells matured between LPI's 5 and 6. Enzymatic activity was correlated with cell division and cell differentiation at various stages of leaf development.     

MICRONUCLEAR RNA SYNTHESIS IN PARAMECIUM CAUDATUM

In a generation time of 8 hr in Paramecium caudatum, the bulk of DNA synthesis detected by thymidine-³H incorporation takes place in the latter part of the cell cycle. The micronuclear cycle includes a G₁ of 3 hr followed by an S period of 3–3½ hr. G₂ and division occupies the remaining period of the cycle. Macronuclear RNA synthesis detected by 5'-uridine-³H incorporation is continuous throughout the cell cycle. Micronuclear RNA synthesis is restricted to the S period. Ribonuclease removes 80–90% of the incorporated label. Pulse-chase experiments showed that part of the RNA is conserved and released to the cytoplasm during the succeeding G₁ period.     

Changes in polyamine metabolism in WI38 cells stimulated to proliferate.

Quiescent confluent monolayers of WI38 human diploid fibroblasts were stimulated to proliferate by replacement of the exhausted medium with fresh medium containing 10% fetal calf serum. The cellular content of the polyamines, putrescine, spermidine, and spermine was studied at various intervals after the nutritional change. The putrescine content increased during the pre-replicative phase of the cell cycle, whereas the content of spermidine and spermine did not increase until after the initiation of DNA synthesis. By varying the composition of the stimulating medium it was possible to alter the percentage of cells that were stimulated to proliferate. Measurement of the cellular polyamine content and ³H-thymidine (³H-TdR) incorporation into DNA at the time of the maximal rate of DNA synthesis showed that the magnitude of putrescine accumulation depended on the percentage of cells that were stimulated to proliferate. These results indicate that there may be a connection between polyamine synthesis and subsequent DNA replication.     

Selective inhibition of thymidine transport at low doses of the alkylating agents triethyleneiminobenzoquinone (Trenimon)

The alkylating antitumor agent triethyleneiminobenzoquinone (Trenimon) causes a rapid decrease in the incorporation of labeled thymidine into the DNA of Yoshida or Ehrlich ascites tumor cells. The effect is expressed 4 h after administration of 6 × 10⁻⁸ moles/kg of the drug to mice bearing Yoshida ascites tumors or of 6 × 10⁻⁷ moles/kg to Ehrlich ascites tumor-bearing animals, respectively. The reduced incorporation of labeled thymidine which is observed under these conditions is not due to an inhibition of DNA synthesis. DNA synthesis was measured by an isotope dilution assay after pulse-labeling with ³H-thymidine and by monitoring the increase in the total amount of DNA of the cell populations. The data demonstrate that DNA synthesis is not affected during the first 8 h after exposure to the drug. This conclusion is supported by cell kinetic measurements which indicate that the alkylating agent does not interfere with the progression of cells into the S phase, but exerts a block at the G 2 stage of the cell cycle. The reduced incorporation of thymidine into DNA is explained by a decreased transport of the nucleoside into the cells.     

In vitro studies of the effect of intermittent compressive forces on cartilage cell proliferation.

Intermittent compressive (IC) forces (96 mm Hg, 0.3 Hz) inhibit by 35–60% the serum stimulated increase in ornithine decarboxylase activity (ODC) in chick embryo epiphyseal cartilage cells and rat chondrosarcoma cells. IC had no effect on mouse fibroblast L-cells ODC. The dose-response pattern of the IC effect indicated an all-or-none response with a threshold at 80 mm Hg, a pressure roughly equivalent to the in vivo weight bearing force. The k_m of the cartilage cell ODC, measured at four hours, was about 0.1 mM and was not affected by IC. The V_max, on the other hand, was significantly reduced by IC which is consistent with less enzyme or non-competitive inhibition. IC also produced a significant increase in cAMP levels in both cartilage explants and isolated cells in the presence and absence of serum and a significant reduction in ³H-thymidine incorporation into DNA. The findings show that cellular cAMP, on one hand, and ODC and DNA synthesis, on the other hand, change in opposite directions following exposure to serum and/or IC. Investigation of the IC effect on DNA synthesis in serum-deprived synchronized cartilage cells revealed that IC reduced the number of cells going into S but did not lengthen the G₁ phase. Exposure to IC early in G₁ (0–13 hours) produced the full effect, whereas IC application between 13 to 24 hours (pre S) had no effect. IC had no effect on ³H-thymidine incorporation in L-cells.     

Temporally different poly(adenosine diphosphate-ribosylation) signals are required for DNA replication and cell division in early embryos of sea urchins

To analyze the temporal relationship of poly(adenosine diphosphate [ADP]-ribosylation) signal with DNA replication and cell divisions, the effect of 3 aminobenzamide (3ABA), an inhibitor of the poly(ADP-ribose)synthetase, was determined in vivo during the first cleavage division of sea urchins. The incorporation of ³H-thymidine into DNA was monitored and cleavage division was examined by light microscopy. The poly(ADP-ribose) neosynthesized on CS histone variants was measured by labeling with ³H-adenosine during the two initial embryonic cell cycles and the inhibitory effect of 3ABA on this poly(ADP-ribosylation) was determined. The results obtained indicate that the CS histone variants are poly(ADP-ribosylated) de novo during the initial cell cycles of embryonic development. The synthesis of poly(ADP-ribose) is decreased but not abolished by 20 mM of 3ABA. The incubation of zygotes in 3ABA at the entrance into S1 phase decreased ³H-thymidine incorporation into DNA in phase S2, while S1 was unaltered. Alternatively, when the same treatment was applied to zygotes at the exit of S1 phase, a block of the first cleavage division and a retardation of S2 phase were observed. The inhibitory effect of 3ABA on both DNA replication and cell division was totally reversible by a release of the zygotes from this inhibition. Taking together these observations it may be concluded that the poly(ADP-ribosylation) signals related to embryonic DNA replication are not contemporaneous with S phase progression but are a requirement before its initiation. These results also indicate that a poly(ADP-ribosylation) signal is required for cell division; such signal is temporally different from that related to S phase initiation and occurs at the exit of S phase. © 1993 Wiley-Liss, Inc.     

Expression of the mitochondrial genome in HeLa cells. XXI. Mitochondrial protein synthesis during the cell cycle

Chloramphenicol sensitive [³H]leucine incorporation into protein (due to mitochondrial protein synthesis) in synchronized HeLa cells has been found to continue throughout interphase, its rate per cell approximately doubling from the G₁ to the G₂ phase. This increase in the rate of [³H]leucine incorporation during the cycle does not seem to parallel closely the increase in cell mass. In fact, the observations made on cultures incubated at 34.5 °C, where the G₁ and S phases are better resolved than at 37 °C, indicate that the rate remains constant during the G₁ phase, and starts to accelerate with the onset of nuclear DNA synthesis. Correspondingly, on a per unit mass basis, there appears to be a slight decline in the rate of [³H]leucine incorporation into protein during the G₁ phase, which is compensated by an increase in the early S phase. No significant variations were observed in the mitochondrial leucine pool labeling during the cell cycle; therefore, the observed pattern of [³H]leucine incorporation into protein should reflect fairly accurately the behavior of mitochondrial protein synthesis. Evidence has been obtained indicating a depression in the rate of incorporation of [³H]leucine into protein in mitochondria of mitotic cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the products of mitochondrial protein synthesis has not revealed any differences in the size distribution of the proteins synthesized in the various portions of the cell cycle.     

Sea urchin egg fertilization studied with a fluorescent probe (ANS)

The rates of intracellular DNA synthesis at various temperatures between 39 ° and 31 °C were determined in hamster fibroblasts and HeLa cells by measuring average amounts of ³H-thymidine incorporated per cell in S phase per unit of time. The energy of activation and Q₁₀ for intracellular DNA synthesis were calculated from the slopes of the relative rates of DNA synthesis in HeLa cells and hamster fibroblasts vs. time, plotted on Arrhenius coordinates. In both cell types the incorporation of thymidine into DNA is characterized by an energy of activation of 21 000 calories/mole and a Q₁₀ of 2.94. The absolute rates of DNA synthesis were determined in hamster cells at various temperatures, with values ranging from 1.44 to 0.60 × 10^?14 g DNA/ min/cell at 39 ° to 31 °C, respectively. The length of the S phase of the hamster cell was calculated over a 39 ° to 31 °C range, and found to be 5.0 to 11.9 h, respectively. It is concluded that the S phase length is partly determined by the rate of temperature-dependent DNA synthesis.     

Putrescine biosynthesis in mammalial cells: Essential for DNA synthesis but not for mitosis

The object of this study was to examine the role of putrescine in the regulation of DNA synthesis and mitosis in synchronized Chinese hamster ovary cells using 1,3-diaminopropane (DAP) which is a potent inhibitor of ornithine decarboxylase (EC 4.1.17). Inhibition of putrescine biosynthesis significantly reduced the incorporation of [${}^3\text{H}$]-TdR into DNA but had no effect on the progression of cells from G1 to S phase. However, inhibition of putrescine synthesis in synchronized S phase cells did not affect their progression to mitosis. In these experiments, the DAP treatment had little or no effect on the levels of spermidine and spermine. These results indicate that putrescine biosynthesis is essential for the completion of DNA synthesis but not required for mitosis and cell division.     

Separate effect of hydroxyurea on the initiation and elongation of DNA synthesis in BHK cells

Summary BHK21/C₁ cells, starved for 30 h in serum deficient medium and treated for 15 h with 1 mm hydroxyurea (HU) in order to obtain a synchronous cell population in the G₁/S-boundary, incorporate a residual proportion of ³H-thymidine (dThd). This residual incorporation is due to semiconservative synthesis and may not be reduced by increasing the drug concentration without affecting the reversion capacity of the cells proportionally. As shown by autoradiographic analysis, the residual DNA synthesis does not correspond to ³H-dThd incorporation within a small number of resistant cells, but is located in the nuclei of a high proportion of cells with reduced density of silver grains. After treatment with 0.05 mm HU, however, the incorporation of ³H-dThd increases considerably over the control values. The determination of the radioactivity incorporated by µg DNA corresponding to nuclei in S phase indicates that this concentration of HU is also able to reduce the rate of DNA polymerization. Kinetic data on the appearance of this increased ³H-dThd incorporation and on the accumulation of labelled nuclei in cells growing at random and labelled continuously with the radioactive DNA precursor indicate that HU stimulates the cells to enter the S phase. The reported results are consistent with a mechanism of action of HU which affects initiation and elongation of DNA chains separately.     

Nucleic acids methylation of synchronized BHK 21 HS 5 fibroblasts during the mitotic phase

The methylation of nucleic acids has been investigated during the cell cycle of an asparagine dependent strain of transformed fibroblasts (BHK 21 HS 5). The synchrony was carried out by a partial asparagine starvation of cells for 24 hours. The amino acid supply induced all cells to enter synchronously the G₁ phase. Methylation and DNA synthesis were respectively measured by pulsed [methyl-¹⁴C] methionine and [methyl-³H] thymidine incorporation. DNA methylation followed a biphasic pattern with maximal methyl incorporations during both S phase and mitosis. A partial desynchronisation induced the S phase of the second cycle to proceed before all the cells have achieved their division. Hydroxyurea was used in order to inhibit the DNA synthesis of cells entering the second cell cycle, which might interfer with the mitosis of the first one. The inhibitor was added either at the first beginning of cell division or during all the G₁ phase. In both conditions it suppressed ³H thymidine incorporation of the second cycle. However, mitosis took place and methylations occurred as in previous experiments. The DNA methylation of the mitotic phase in the first cell cycle could thus be dissociated from the classical post-synthetic DNA maturation and did not correspond to any DNA methylation appearing in the course of the second cell cycle.     

The dependence of DNA synthesis on protein synthesis in HeLa S3 cells

The rate of DNA synthesis in HeLa S3 cells, as measured by incorporation of C¹⁴-labeled thymidine, is strongly dependent on protein synthesis at all times during the S phase. The relation between the rate of DNA synthesis and the rate of protein synthesis is linear when measured two or three hours after reducing the rate of protein synthesis with either puromycin or cycloheximide. The effect is manifested rapidly, is found in both random and synchronized cultures, and is independent of the method of synchronization.     

Rate of DNA synthesis as a function of temperature in cultured hamster fibroblasts (V-79) and HeLa-S3 cells

The rates of intracellular DNA synthesis at various temperatures between 39 ° and 31 °C were determined in hamster fibroblasts and HeLa cells by measuring average amounts of ³H-thymidine incorporated per cell in S phase per unit of time. The energy of activation and Q₁₀ for intracellular DNA synthesis were calculated from the slopes of the relative rates of DNA synthesis in HeLa cells and hamster fibroblasts vs. time, plotted on Arrhenius coordinates. In both cell types the incorporation of thymidine into DNA is characterized by an energy of activation of 21 000 calories/mole and a Q₁₀ of 2.94. The absolute rates of DNA synthesis were determined in hamster cells at various temperatures, with values ranging from 1.44 to 0.60 × 10⁻¹⁴ g DNA/ min/cell at 39 ° to 31 °C, respectively. The length of the S phase of the hamster cell was calculated over a 39 ° to 31 °C range, and found to be 5.0 to 11.9 h, respectively. It is concluded that the S phase length is partly determined by the rate of temperature-dependent DNA synthesis.     

The effect of tritiated thymidine on human chromosomes

Summary The effect of low dosages of³H-thymidine on human chromosomes was investigated. Two established human cell lines, amnion and HeLa cells, were treated for various periods of time 0.125, 0.25, 0.50 or 0.75 μCi/ml of this agent. Chromatid-type aberrations were observed, occurring only if³H-thymidine was incorporated into DNA during the S phase of the cell cycle. The higher the dosage and the longer the³H-thymidine acted on chromatin, the greater the number of aberrations induced. Chromosomes were most sensitive to the effects of³H-thymidine during the early S phase of the cell cycle. This work was supported by the Medical Research Council, Canada Grant MA 1639.     

A pool of peptides extracted from wheat bud chromatin inhibits tumor cell growth by causing defective DNA synthesis

Background

We previously reported that a pool of low molecular weight peptides can be extracted by alkali treatment of DNA preparations obtained from prokaryotic and eukaryotic cells after intensive deproteinization. This class of peptides, isolated from wheat bud chromatin, induces growth inhibition, DNA damage, G2 checkpoint activation and apoptosis in HeLa cells. In this work we studied their mechanism of action by investigating their ability to interfere with DNA synthesis.

Methods

BrdUrd comet assays were used to detect DNA replication defects during S phase. DNA synthesis, cell proliferation, cell cycle progression and DNA damage response pathway activation were assessed using 3H-thymidine incorporation, DNA flow cytometry and Western blotting, respectively.

Results

BrdUrd labelling close to DNA strand discontinuities (comet tails) detects the number of active replicons. This number was significantly higher in treated cells (compared to controls) from entry until mid S phase, but markedly lower in late S phase, indicating the occurrence of defective DNA synthesis. In mid S phase the treated cells showed less 3H-thymidine incorporation with respect to the controls, which supports an early arrest of DNA synthesis. DNA damage response activation was also shown in both p53-defective HeLa cells and p53-proficient U2OS cells by the detection of the phosphorylated form of H2AX after peptide treatment. These events were accompanied in both cell lines by an increase in p21 levels and, in U2OS cells, of phospho-p53 (Ser15) levels. At 24 h of recovery after peptide treatment the cell cycle phase distribution was similar to that seen in controls and CDK1 kinase accumulation was not detected.

Conclusion

The data reported here show that the antiproliferative effect exhibited by these chromatin peptides results from their ability to induce genomic stress during DNA synthesis. This effect seems to be S-phase specific since surviving cells are able to progress through their normal cell cycle when the peptide fraction is removed from the culture medium. It is likely that the subsequent apoptosis is a consequence of the failed attempt of the tumour cells to repair the DNA damage induced by the peptides.