Oxygen dependence of nuclear DNA replication in Ehrlich ascites cells

Oxygen was excluded from cultured Ehrlich ascites cells for 5-7 h and then readmitted. During the anaerobic period and for about 1 h following reoxygenation the DNA synthesis of the cells was studied by determining the DNA synthesis rate from [3H] thymidine incorporation data, by evaluation of the thymidine (pulse labelling) index, by DNA fibre autoradiography, and by alkaline sucrose gradients in order to follow the maturation of the daughter chains. The DNA synthesis rate was found to decay to a few percent of the initial value within 5-7 h after deoxygenation. Immediately after reoxygenation it increased to exceed the control level within 0.5-1 h. The only partial process of the genome replication definitely responding to deoxygenation/reoxygenation was the initiation of new replicon units, while progress of the replication forks and maturation of the new daughter chains were not significantly affected. The coordination of replicon initiation within groups or clusters was maintained throughout. The interruption of replication at the level of initiation of clusters upon deoxygenation was interpreted as a regulatory response of the cells to ensure basic viability under unfavourable conditions.     

Selective and synchronous activation of early-S-phase replicons of Ehrlich ascites cells.

Twelve-hour exposure of G1 Ehrlich ascites cells to controlled hypoxia (200 ppm of O2 at 1 bar) suppressed replicon initiation. Synchronous cycling, beginning with a normal S phase, was released by reoxygenation immediately. The addition of cycloheximide at reoxygenation largely resuppressed, after a short initial burst, succeeding replicon initiations. Alkaline sedimentation analysis of growing daughter strand DNA, DNA fiber autoradiography, and analysis of the newly formed DNA demonstrated that normal chain growth and DNA maturation (replicon termination) in the initially activated replicons continued in the presence of cycloheximide. After 2 to 3 h, a low level of cycloheximide-insensitive background replication emerged out of the then-ebbing single surge of activity of the initially released replicons.     

Application of hypoxia-induced shut down of replicon initiation to the analysis of replication intermediates in Ehrlich ascites cells

Cultured Ehrlich ascites cells were subjected to hypoxic conditions for about 2 h, then reaerated or allowed to remain hypoxic. The newly formed DNA of hypoxic or reaerated cells was labeled with [3H]thymidine using different pulse and pulse/pulse-chase protocols. The chain length distribution of the labeled DNA molecules was analysed by sedimentation after lysing the cells on the top of alkaline sucrose gradients. The results indicated that the hypoxia effectively and reversibly suppressed the initiation of new replication units. Initiation, growth and integration of Okazaki pieces into active replicons was not noticeably affected. In marked contrast to aerobic cells, the use of hypoxic cells allows the separation of Okazaki pieces as a distinct class of pulse labeled short DNA chains. Short daughter DNA of very recently initiated replicons did not interfere at pulse times shorter than 4 min. For examination of the newly initiated replicons it seems favourable to trigger a burst of initiations by reaeration.     

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.     

Further characterization of the growth inhibitory effect of rotenone on in vitro cultured Ehrlich ascites tumour cells

Summary As an approach for a better understanding of the mode of action of rotenone on mammalian cells we have studied the proliferation properties, metabolism and basic cell composition of Ehrlich ascites tumour cells cultured in vitro in the presence of 2,5 µM rotenone and after removal of the inhibitor.Experiments on asynchronous cells showed a rapid cessation of cell division accompanied by increased glycolytic rate, reduced oxygen consumption, moderate increase in DNA content and a fair increase in protein and RNA content of the cultures. DNA histograms obtained by flow-cytometry revealed an accumulation of cells in the G2 and M phase of the cell cycle. Electron micrographs taken after a 24 h treatment of cells illustrated the formation of giant mitochondria and fragmented nuclei.In order to elucidate the dual effect of rotenone — inhibition of mitochondrial energy metabolism and of mitotic processes — the influence on cells of rotenone at different stages of the cell cycle was tested using Ehrlich ascites tumour cells enriched in G1, S and G2 by centrifugal elutriation. DNA histograms and [³H]thymidine labelling index curves of cells from the different fractions cultured in the presence of 2,5 AM rotenone indicated that in addition to the observed accumulation in G2 and mitotic arrest of cells, the cell cycle progression is delayed in G1 phase. This may be explained by an effect of the inhibitor on the respiratory chain. S phase cells seemed to continue the cycle for several hours at a rate comparable to that of controls.Recultivation experiments on rotenone-treated asynchronous cells in inhibitor-free medium confirmed that some cells reinitiate DNA synthesis without preceeding cell division.Thus it must be concluded that cells at all stages of the cycle are affected by rotenone, but the impairment of cellular metabolism becomes manifest and lethal as soon as the acute block at mitosis is abolished and cells reenter the cycle.Abbreviations EAT cells Ehrlich ascites tumour cells - Hanks' solution Hanks' balanced salt solution - Hepes 4-(2-hydroxyethyl)-1-piperazineethane sulfonic acid     

DNA replication in mammalian cells. Altered patterns of initiation during inhibition of protein synthesis

The effects of inhibition of protein synthesis by the antibiotics cycloheximide and puromycin on the initiation of DNA replication in mouse L cells were studied. Cellular DNA was pulse labeled with [3H]thymidine of high, then of low specific activity and prepared for fiber autoradiography. Autoradiograms containing multiple (up to four) replication units were analyzed. In control cells, the proportion of replication units that initiated during a 10-min, high specific activity pulse was approximately equal to the proportion initiating immediately before the pulse. The addition of cycloheximide or puromycin at the start of the pulse inhibited the frequency of initiation in that there was a decrease by up to one-third of units initiating during the pulse relative to controls. Replication direction was also altered. Addition of the antibiotics 2 h before the pulse reduced the proportion of bidirectional units observed from 0.98 to 0.70. Antibiotic treatment for 2 h also decreased initiation synchrony in that the proportion of multiunit autoradiograms on which neighboring units showed similar replication patterns (indicating temporally coordinated initiation) was reduced by one-half. These observations indicate that inhibition of protein synthesis alters the normal pattern of DNA initiation.     

Restimulation of cell cycle progression by hypoxic tumour cells with deoxynucleosides requires ppm oxygen tension

Continuous exposure of Ehrlich ascites tumour cells to argon-CO2 under in vitro conditions caused rapid cessation of cell proliferation. On fixing the O2 level at 10 ppm in the protective atmosphere (0.001% in comparison with about 20% in normoxic atmosphere), G1 and early S cells remained stationary while G2 cells continued to pass from G2 into mitosis, to remain in a non-growing state in G1 of the subsequent cycle. Re-aeration of cells following 12 h hypoxia induced up to 25% of the population to continue DNA synthesis without a preceding cell division, as revealed by flow-cytometric analysis. Supplementation of cells cultured under hypoxia with a combination of deoxynucleosides (100 microM deoxycytidine, 10 microM deoxyadenosine, 10 microM deoxyguanosine) was found to stimulate reprogression through the cycle, provided the residual oxygen tension in the protective atmosphere exceeded 40 ppm. The increase in the number of cells with a DNA content of more than 4 C and in the number of binucleate cells observed after re-aeration of hypoxic cells was not prevented by deoxynucleosides or by uridine, which were present in the medium either during hypoxia of from the beginning of reoxygenation. These results indicate that the development of polyploidy as a result of oxygen deficiency cannot be influenced by improvement of RNA and DNA synthetic precursors.     

Fast control of DNA replication in response to hypoxia and to inhibited protein synthesis in CCRF-CEM and HeLa cells

In order to elucidate whether data about the fast regulation of DNA replication in dependence on oxygen supply and on a functioning protein synthesis, previously elaborated with Ehrlich ascites cells, are valid for human cells too, we repeated key experiments with CCRF-CEM and HeLa cells. The most important techniques employed were DNA fibre autoradiography and alkaline sedimentation analyses of growing (pulse-labeled) daughter strand DNA. It was found that CCRF-CEM and HeLa cells responded to transient hypoxia and to transient inhibition of protein synthesis in an almost identical fashion. Scheduled replicon initiations were reversibly suppressed and the progress rates of replication forks, which were already active before the respective inhibitory conditions were established, were reversibly slowed down. The inclusion of the fork progress rate in the response differs from Ehrlich ascites cells, which respond only by suppressing initiation. Further circumstances of the fast oxygen dependent response, concerning the behaviour of ribonucleotide reductase and of the dNTP pools, revealed no significant differences among the three cell lines. The striking identity of the response of each of the cell lines to hypoxia and to inhibited protein synthesis prompts the suspicion that converging fast regulatory pathways act on the cellular replication machinery. The phenomena as such seem to be rather widespread among mammalian cells.     

Metabolism and non-random occurrence of nonnascent short chains in the DNA of Ehrlich ascites cells

The DNA of Ehrlich ascites cells was labeled with radioactive thymidine using different labeling schedules: Incubation periods between 15 s and 4 h; pulse/pulse-chase experiments with pulses in the range of a few minutes; longtime incubation followed by a longtime chase (both in the range of 1 cell generation). From the purified DNA of the labeled cells a fraction (0.3-0.4%) of short chains was separated and partially fractionated by means of a hydroxyapatite thermochromatography procedure. The evaluation of the labelling patterns of the short chains indicated that less than 5% of them can be regarded as replication intermediates ('Okazaki pieces'). The rest, termed nonnascent pieces, exhibited a slow turnover. The life span of the nonnascent pieces was estimated to be about 1 cell generation. On helical DNA, nonnascent pieces were distributed in a non-random manner. Their preferential localisation was nearby sites which caused binding of the DNA, after purification, to nitrocellulose and which occurred about every 60-80 microns on the nuclear DNA of the cells.     

Nucleosome segregation in chromatin replicated in the presence of cycloheximide

Ehrlich ascites tumour cells and L cells were grown in the presence of [¹⁴C]thymidine to label DNA replicated under normal conditions and were then cultured in the presence of cycloheximide and [³H]thymidine to label DNA replicated in the absence of histone synthesis, Chromatin from these cells was digested with micrococcal nuclease and with restriction endonuclease BspRI (an isoschizomer of HaeIII). The rates of digestion of the ¹⁴C-labelled and of the ³H-labelled DNA, and the size and buoyant density of the BspRI-generated chromatin fragments showed that: (1) chromatin replicated in the presence of cycloheximide contained half the normal amount of histones; (2) it did not contain long stretches of naked DNA; and (3) it was organized in nucleosomes distributed along DNA in groups of several particles separated by relatively short stretches of histone-free DNA. Control experiments showed that this could not be the result of a long-distance sliding of nucleosomes.These data suggest a bilateral mode of nucleosome segregation during DNA replication.     

Effects of temperature changes on thymidine kinase in heat- and cold-sensitive cell-cycle mutants and ‘wild-type’ murine P-815 cells

Two heat-sensitive (arrested in G1 at 39.5°C) and two cold-sensitive (arrested in G1 at 33°C) clonal cell-cycle mutants that had been isolated from the same clone (K 21), of the murine mastocytoma P-815 cell line, were tested for thymidine kinase (EC 2.7.1.21) activity. After shift of mutant cells to the nonpermissive temperature, thymidine kinase activity decreased, and minimal levels (i.e., less than 3% of those observed for ‘wild-type’ K 21 cells at the respective temperature) were attained within 16 h in heat-sensitive and after 3–4 days in cold-sensitive mutants, which is in good agreement with kinetics of accumulation of heat-sensitive and cold-sensitive cells in G1 phase. After return of arrested mutant cells to the permissive temperature, thymidine kinase of heat-sensitive cells increased rapidly and in parallel with entry of cells into the S phase. In cultures of cold-sensitive cells, however, initiation of DNA synthesis preceded the increase of thymidine kinase activity by approx. one cell-cycle time. Thymidine kinase activities in revertants of the heat-sensitive and cold-sensitive mutants were similar to those of ‘wild-type’ cells. In ‘wild-type’ K 21 cells incubated at 39.5°C, thymidine kinase activity was approx. 30% of that at 33°C. This difference is attributable, at least in part, to a higher rate of inactivation of the enzyme at 39.5°C, as determined in cultures incubated with cycloheximide. The rapid increase of thymidine kinase activity that occurred after shift of K 21 cells and of arrested heat-sensitive mutant cells from 39.5°C to 33°C was inhibited by actinomycin D and cycloheximide.     

Osmotic properties of ehrlich ascites tumor cells during the cell cycle

Ehrlich ascites tumor cells were grown and maintained in continuous spinner culture. The population of dividing cells was synchronized by a double thymidine block technique. Cell cycle phases were determined graphically by plotting mitotic index, cell number, and DNA synthesis against time. Changes in the osmotic properties of Ehrlich ascites tumor cells during the cell cycle are described. Permeability to water is highest at the initiation of S and progressively decreases to its lowest value just after mitosis. Heats of activation for water permeability vary during the cell cycle, ranging from 9–14 kcal/mole. Results may imply changes in the state of water in the membrane during the cycle. The volume of osmotically active cell water is highest during S and early G2 and decreases during the mitotic phase, as cells undergo division. Total water content remains stable at 82% (w/w) during the cycle. Total concentration of the three major ions (Na, K, Cl), expressed as mEq/liter total cell volume, does not change. The fraction of total cell water which is osmotically active (Ponder's R) decreased gradually from 0.75 at S to about 0.56 following mitosis. Findings suggest that a fraction of the total water within the cell exists in a “bound” form and is, therefore, incapable of being shifted under the driving force of osmotic pressure. This fraction of bound water increases during the cell cycle. Possible alterations in membrane fluidity and the state of water in the cell are discussed.     

Organization of the newly replicated chromatin in the vicinity of the replication fork

Ehrlich ascites tumour cells were pulse-labelled with [³H]thymidine for 1 min or were treated with cycloheximide and labelled with [³H]thymidine for 45 min. The kinetics of digestion with micrococcal nuclease of both pulse-labelled and cycloheximide chromatins showed that they exhibited increased susceptibility towards the enzyme. At the same time their release from the nucleus was retarted and this was interpreted to mean that, unlike the bulk of chromatin, they were tightly bound to a fixed nuclear structure. When subjected to an equilibrium metrizamide-triethanolamine density gradient centrifugation both pulse-labelled and cycloheximide chromatins banded at higher density than control chromatin, which was an indication of their higher protein to DNA ratio. After a mild trypsinization, eliminating H1 and the nonhistone proteins, the pulse-labelled chromatin sedimented to the same density as control chromatin, and the cycloheximide chromatin sedimented to a density which was intermediate between those of control chromatin and free DNA. This result showed that the newly replicated chromatin had the same, and the cycloheximide chromatin half the amount of core histones present in control chromatin.     

Increased level of histone H1(0) messenger RNA in hypoxic Ehrlich ascites tumor cells

We have investigated the expression of the H1 histone subtype H1(0) gene in Ehrlich ascites tumor cells (EAT) under varied conditions of oxygen supply. Our results show that proliferating EAT cells express H1(0) mRNA at a basal level under normoxic conditions. Severe hypoxia leads to a cessation of cell growth and causes an accumulation of cells in G1. Here, we show that the level of H1(0) histone mRNA increases within a few hours after the onset of hypoxia.     

Initiation of DNA synthesis in the liver and other tissues of adult mice by a growth factor (EACF) isolated from acellular fluid of the Ehrlich ascites carcinoma

The mitogenic effect of a new growth factor that we recently isolated from the acellular ascitic fluid of the Ehrlich ascites carcinoma grown in vivo was examined. We have called this factor EACF (Ehrlich ascites carcinoma factor). EACF caused initiation of DNA synthesis in the liver, submandibular gland, exorbital lacrimal gland and epithelium of the tongue of adult mice after i.p. injection at a protein concentration of 3 micrograms per 25 g of body weight. For all tissues examined, except the tongue, EACF initiated DNA synthesis at about 48 to 60 h after injection, with the maximum effect at approx. 85 h, and the stimulatory effect lasting approx. 60 h. The initiation of DNA synthesis in liver, which is normally characterized by only an occasional cell passing through the S phase, by EACF is of particular interest. The initiation of DNA synthesis in the liver was not prevented by hypophysectomy. Evidence also indicates that a similar heat-labile growth promoting factor(s) is present in calf serum.     

Lack of correlation between thymidine kinase activity and changes of DNA synthesis with tumour age: an in vivo study in Ehrlich ascites tumour

Thymidine kinase (TK) and its isoenzymes were studied in relation to age of Ehrlich ascites tumour cells growing in vivo. Various steps of the pathway of thymidine through deoxynucleotide metabolism were studied: [3H]-thymidine cellular uptake and incorporation into DNA; the cellular nucleotide pools; and the concentration of thymidine in ascites. In addition, the proportion of cells in the various parts of the cell cycle and the bromodeoxyuridine labelling index were determined. Four isoenzymes at pI 4.1, 5.3, 6.9 and 8.3 were identified using isoelectric focusing. The TK activity declined with age of the tumour by about 90%, mostly due to a decrease of the isoenzyme at pI 8.3. However, this decline was neither related to the changes in DNA synthesis rate of the cells with tumour age, nor to the proportion of cells in S-phase or the bromodeoxyuridine (BrdU) labelling index. In contrast, the contribution of DNA synthesis via the thymidine salvage pathway relative to the total DNA synthesis increased from less than 1% at exponential growth to about 15% at plateau phase of growth. Blocking of DNA synthesis by aphidicolin did not change the TK activity. We therefore conclude that changes in TK activity and changes in cell growth are epiphenomena rather than causally related to each other. All nucleotide pools decreased with tumour age. The inhibition of TK by an increase in the deoxythymidine triphosphate pool could therefore be excluded. With a decrease of the TK activity during tumour growth, increasing amounts of TdR were excreted by the cells and accumulated in the ascites fluid. To explain our results on TK activity we propose a substrate cycle in which thymidine monophosphate supplied by de novo synthesis is dephosphorylated and is then either phosphorylated by TK to thymidine monophosphate or excreted by the cell.     

Towards a further understanding of the growth-inhibiting action of oxygen deficiency. Evaluation of the effect of antimycin on proliferating Ehrlich ascites tumour cells

The effect of 1 microM antimycin on the proliferative properties, metabolism and basic cell composition of Ehrlich ascites tumour cells cultured in the second in vitro passage was studied. Continuous drug exposure of asynchronous cells caused rapid cessation of cell growth, characterized by the cell number and DNA, RNA and protein content of cultures. Cells cease to consume oxygen and enhance their glycolytic activity. Uptake of labelled thymidine into acid-insoluble material was far below that of the controls, whereas incorporation of labelled uridine exceeded that of controls, as was also observed with other inhibitors of the respiratory chain (sodium cyanide, 2-thenoyltrifluoroacetone, or anaerobiosis). The influence of antimycin on cells at different stages of the cell cycle was tested using cells enriched in either G1, S or G2 phase by centrifugal elutriation. DNA histograms (flow cytometry) and pulse-labelling index curves gave detailed insight into cell-cycle progression of antimycin-treated cells: G1 and early S cells remained stationary; G2 cells still passed from G2 into mitosis to remain subsequently in a non-growing state in G1; S cells were either slowed or halted. Supplementation of antimycin-containing cultures with exogenous pyrimidine nucleosides stimulated reprogression of G1 cells without changing their ATP content. The results of the current experiments are interpreted as supporting the concept that growth cessation of G1 cells under respiratory insufficiency is not predominantly caused by impairment of respiratory phosphorylation but may be the consequence of a lack of precursors for DNA and RNA synthesis.     

Accumulation of polyploid cells and G2-phase cells during ascites tumor growth

Ehrlich ascites tumor cells from the plateau phase of growth were transplanted into new hosts, pulse-labeled with tritiated thymidine and blocked with repeated injections of vinblastine. When unlabeled cells were analyzed for their cellular DNA content utilizing a cytophotometric technique it was found that in relation to the total number of cells (labeled plus unlabeled), 13% had a 2C DNA content, 36% a 4C DNA content and 5% an 8C DNA content at 0.5 hours after transplantation. By 24 hours the distributions changed dramatically: the initially unlabeled 2C cells were now 4C, the 36% of the cells that were initially 4C partitioned into 24% that were still 4C and 12% that progressed to 8C, and the initial 8C cells remained 8C. These studies indicate that the accumulation of 4C cells during the plateau phase of growth is due to a combination of G2 diploid and G1 tetraploid cells.     

Lack of correlation between thymidine kinase activity and changes of DNA synthesis with tumour age: an in vivo study in Ehrlich ascites tumour

Abstract. Thymidine kinase (TK) and its isoenzymes were studied in relation to age of Ehrlich ascites tumour cells growing in vivo. Various steps of the pathway of thymidine through deoxynucleotide metabolism were studied: [³H]-thymidine cellular uptake and incorporation into DNA; the cellular nucleotide pools; and the concentration of thymidine in ascites. In addition, the proportion of cells in the various parts of the cell cycle and the bromodeoxyuridine labelling index were determined.
Four isoenzymes at pi 41, 5-3, 6–9 and 8-3 were identified using isoelectric focusing. The TK activity declined with age of the tumour by about 90%, mostly due to a decrease of the isoenzyme at pi 8-3. However, this decline was neither related to the changes in DNA synthesis rate of the cells with tumour age, nor to the proportion of cells in S-phase or the bromodeoxyuridine (BrdU) labelling index. In contrast, the contribution of DNA synthesis via the thymidine salvage pathway relative to the total DNA synthesis increased from less than 1% at exponential growth to about 15% at plateau phase of growth. Blocking of DNA synthesis by aphidicolin did not change the TK activity. We therefore conclude that changes in TK activity and changes in cell growth are epiphenomena rather than causally related to each other.
All nucleotide pools decreased with tumour age. The inhibition of TK by an increase in the deoxythymidine triphosphate pool could therefore be excluded. With a decrease of the TK activity during tumour growth, increasing amounts of TdR were excreted by the cells and accumulated in the ascites fluid. To explain our results on TK activity we propose a substrate cycle in which thymidine monophosphate supplied by de novo synthesis is dephosphorylated and is then either phosphorylated by TK to thymidine monophosphate or excreted by the cell.