Cytokinetic studies on the switch from glucose to uridine metabolism, and vice versa, of Ehrlich ascites tumour cells in vitro

Abstract. Glucose is normally required as the energy source and for the proliferation of neoplastic cells. For Ehrlich ascites tumour cells, kept under glucose-free culture conditions, this requirement was alleviated by uridine, indicating that the supply of ribose is obligatory for sustaining growth capacity.
In a 96-hr culture experiment with mouse-derived cells, the increase in cell number from cultures supplemented with 5 mM uridine was 50–70%, whilst lactate production was 5% that of controls. An increase in the number of multinucleate cells was observed from cell-smears; DNA histograms indicated the presence of cells with a DNA content higher than 4c and an increased portion of cells in G₂ phase. For precise determination of changes in cell cycle distribution on transfer of cells from glucose-supplemented to glucose-free conditions, the progression of phase-accumulated cells (by centrifugal elutriation) was monitored by DNA distribution analysis; G₂ cells continued the cycle at a rate comparable to controls but were delayed, in the following cycle, predominantly in S and G₂ phases. This was also observed with G₁ cells from a G₁-accumulated fraction in the first cycle.
The addition of glucose to cells kept for some hours in glucose-free, uridine-supplemented medium resulted in an immediate increase in mitotic index (amplification by the colcemid method).
The results are interpreted and support our concept that the delivery of compounds, necessary for normal growth, i.e. hexoses for glycoproteins and glycolipids, are limited as a consequence of the 'metabolic channelling' of pentose from uridine in Ehrlich ascites tumour cells. Therefore, the constantly lowered growth-rate in uridine-supplemented cells observed with long-term culture experiments could reflect an adaption of growth-cycle to these limitations.     

Uridine, but not cytidine can sustain growth of Ehrlich ascites tumor cells in glucose-deprived medium with altered proliferation kinetics

Cell cycle kinetics and energy metabolism of Ehrlich ascites tumor cells grown in glucose-deprived medium supplemented with uridine, were investigated in order to extend our knowledge about the significance of the metabolic conversion of glucose for cell cycle progression of these cells. Viability (dye exclusion test) of uridine supplemented cells was not affected, although growth was reduced to 50 to 60% of the controls. Uridine did not significantly impair growth of controls in standard medium up to 20 mM. Studies on cell cycle progression using flow cytometry (BrdU-H33258 technique) revealed an accumulation of cells in G2M phase, which can be explained by a delay in the passage of G2M-compartment of about 12 +/- 2 h. After a 24 h culture period, 60% of the cell populations were found in G2M (30% in control cultures). This fraction increased to about 70% in the following passage. Protein and DNA synthesis corresponded to the proliferation rate. Oxygen uptake was increased by about 50%, glutamine consumption by 30%, lactate production was reduced to below 10% of the controls. The ATP/ADP concentration ratio was found in a physiological range of 4 to 6. It was calculated that cells grown in standard medium produced 60% of ATP via oxidative pathways and 40% via glycolysis; however, in glucose-free, uridine-supplemented medium the values are more than 90% and less than 10%. No significant differences in total ATP production were observed. Growth of the cells in glucose-deprived medium could not be sustained by cytidine. All our data substantiate the present concept that glycolytic ATP-production is not essential for maintenance of viability and growth of these 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     

Anaerobiosis and oxygen recovery: changes in cell cycle distribution of Ehrlich ascites tumor cells grown in vitro.

The cell cycle distribution of in vitro cultured Ehrlich ascites tumor (EAT) cells was analysed by pulse-cytophotometry to characterize the growth cessation observed under anaerobic conditions. DNA histograms provided evidence that in the absence of oxygen EAT cells accumulate in the G1 and early S phase of the cell cycle while in the presence of oxygen an increase in G2 was observed during 24h culture period. Cellular recovery from anaerobiosis was observed soon after transfer of the cells into fresh aerobic culture medium but occurred slowly if the cells were only resupplied with air. Cell cycle analyses as well as (14C)-thymidine incorporation suggest considerable synchronization results from the introduction of anaerobiosis.     

Sialic acid, galactose and fucose on the surface of Ehrlich ascites tumor cells grown in glucose-free medium in the presence of uridine

1) The content and accessibility of terminal sialic acid and galactose residues as well as the incorporation of [3H]fucose into glycoconjugates were determined in 48-h cultures of Ehrlich ascites tumor cells in a glucose-free medium supplemented with uridine, a compound which can fulfil the necessary functions of glucose. 2) Sialic-acid residues accessible to sialidase cleavage were reduced from 695 +/- 80 nmol/10(9) cells (controls) to 284 +/- 22 nmol/10(9) cells (43% of controls). In situ labeling using periodate oxidation followed by sodium borotritiide reduction revealed a tritium incorporation of 47 +/- 11% that of controls (= 4.1 x 10(5) cpm/mg protein). 3) Labeling of galactose residues of 80-90% of that of controls was achieved after treatment of the cells with galactose oxidase/sodium borotritiide. A nearly six-fold enhancement of tritium incorporation into galactose of control cells was observed after sialidase/galactose oxidase treatment and sodium borotritiide reduction (1.5----8.8 x 10(5) cpm/mg protein); only a 3.6-fold increase (1.2 x 10(5)----4.3 x 10(5) cpm/mg protein) was found with glucose-free cultured cells. It is concluded that the galactose content of the cell surface is reduced to about 50% of controls. 4) The incorporation of tritium into acid-insoluble precipitate after 24 h incubation with [3H]fucose and the activity of the acid-soluble fraction were enhanced by about 85% as compared to controls. The pattern of inhibition by tunicamycin of [3H]fucose uptake and incorporation was the same in glucose-containing standard medium and in glucose-free uridine medium.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

The biosynthetic pathway of pyrimidine (deoxy)nucleotides: A sensor of oxygen tension necessary for maintaining cell proliferation?

Culture experiments on Ehrlich ascites tumor cells revealed that a low oxygen tension (about 20% in normoxic atmosphere) induced an increase in the length of the growth cycle. The relative growth of aerobic control cells after transfer to the second in vitro passage was 145% within 24 h, and reduced to 50% at 1% O2 and about 30% at 0.1% O2. The increase in protein and DNA content of these hypoxic cultures was equally impaired. Also, the cell cycle traverse as analyzed by flow cytometry was affected predominantly at the G1/early S stage. Uptake of labeled thymidine into acid-insoluble material of hypoxic cells was below that of controls whereas incorporation of uridine exceeded that of normoxic controls. Supplementation of cells cultured under 0.1 and 1% O2 with 0.1 mM uridine or 0.1 mM deoxycytidine + 0.01 mM deoxyadenosine and deoxyguanosine improved all growth parameters; deoxynucleosides were more effective than uridine in cells under 0.1% O2 whereas in cells cultured under 1% O2 similar effects of both were observed. This points to an insufficient supply of nucleic acid precursors even under moderate limitations of oxygen tension and not only under strict hypoxia. Whereas a 12-h cultivation time at 0.1% O2 hardly impaired cell growth after reoxygenation, a cultivation time of 24 h considerably reduced the cellular capability to recover. This was alleviated by addition of (deoxy)nucleosides from the beginning of hypoxic culture. The results are interpreted as supporting the concept that the biosynthetic pathway of pyrimidine (deoxy)nucleotides--because of two oxygen-dependent enzymes, dihydroorotate dehydrogenase and ribonucleotide reductase--is a potential transducer of environmental limitations in oxygen tension to the proliferative capacity of cells.     

Uridine kinase: altered subunit size or enzyme expression as a function of cell type, growth stimulation, or mutagenesis

Using antibody prepared against pure uridine kinase from Ehrlich ascites cells, we have measured the expression of enzyme protein by the Western blot technique. Variations were observed in the Mr of the enzyme subunit for uridine kinase from different species: 32,000 (mouse Ehrlich ascites cells), 30,000 (normal human lymphocytes), 28,000 (mouse tissues), 27,500 (rat tissues). For different normal tissues from the same species, there was no significant variation in the subunit size. Transformed human and mouse cell lines, selected for a deficiency of uridine kinase activity in the presence of inhibitors activated by this enzyme, expressed two cross-reacting proteins, one with a normal (30,000) and one with a smaller (21,000) subunit molecular weight than was found in the parental cell line (human lymphoma), or only a smaller protein of Mr 25,000 (mouse lymphoma). Our results show that selection protocols using metabolite inhibitors do not always repress the expression of the enzyme but instead may lead to selection of those cells that have a mutation in the uridine kinase gene, resulting in the expression of an inactive enzyme. The expression of uridine kinase protein changes when cells are stimulated to divide. For both mouse fibroblasts and human lymphocytes, expression of uridine kinase protein as well as activity clearly increased after cells were stimulated to grow. In fibroblasts, increases are seen by 3 hr after stimulation, and plateau after 9 hr at a sevenfold increase. In lymphocytes, no change is seen until 12 hr after stimulation, and a plateau is not reached until 72 hr, with a total increase of approximately 50-fold. There has been considerable interest in the possibility of uridine kinase isozymes. Except for cells that have been mutagenized, the present results show that, as judged by subunit molecular weight, there appears to be only one enzyme form in normal and neoplastic cells or in cells in which uridine kinase activity is induced.     

Zinc-, copper- and cadmium-binding protein in Ehrlich ascites tumour cells.

The properties of Ehrlich ascites tumour cells exposed in vivo to cadmium were investigated as a function of the zinc status of the host animals. Tumour-cell growth was inhibited by cadmium in both zinc-sufficient and zinc-deficient animals. However, cells in zinc-sufficient tumours accumulate much less cadmium than those in deficient tumours. The subcellular distributions of cadmium and zinc do not depend on zinc status. Cadmium and zinc are bound to a low-molecular-weight protein with properties similar to metallothionein. Without exposure to cadmium, a zinc- and copper-binding protein is still present that behaves like a metallothionein. This protein can rapidly bind cadmium added to Ehrlich cells in vitro. It is shown that the zinc- and copper-binding protein contains free thiol groups. Ehrlich cells isolated from cadmium-treated animals are viable and show normal incorporation of uridine into RNA, but the cellular uptake of thymidine and its incorporation into DNA are inhibited.     

Studies on Ehrlich ascites tumour cells: DNA synthesis,and template activity of chromatin for DNA polymerase

Summary Chromatin obtained from Ehrlich ascites cells on different days after cell inoculation has been assayed for its template activity with added DNA polymerase 1. We have found that the template activity is 2 times higher in 7–8 day cell chromatin than in 4-day chromatin. Studies with added polylysine indicate that this increase reflects an increase in initiation sites rather than in accessibility to the enzyme. We have measured the growth fraction, mitotic index and rate of DNA chain growth in the intact cells. The results show that there is a large decrease in growth fraction with age of tumour, the number of cells dropping out of cycle approximately doubling over the period studied. The overall rate of chain growth decreases in the later stages of growth but in a small proportion of cells there is an increase in rate with fewer replicons involved in DNA synthesis. We suggest that in the ascites cells there is a decrease in level of repair and replicative enzymes with age of tumour; this would account both for the increase in initiation sites in the chromatin DNA, for the decrease in number of cells in cycle and for the overall decreased rate of chain growth.     

Variation through the cell cycle in the dose-response of DNA neutral filter elution in X-irradiated synchronous CHO-cells

Dose-response curves for DNA neutral (pH 9.6) filter elution were obtained with synchronized CHO cells exposed to X-rays at various phases of the cell cycle. The dose response was similar in synchronized and plateau-phase G1 cells, as well as in cells that were arrested at the G1/S border using aphidicolin; it flattened as cells progressed into S phase and reached a minimum in the middle of this phase. An increase in DNA elution dose response, to values only slightly lower than those obtained with G1 cells, was observed as cells entered G2 phase. Significant alterations in the sedimentation properties of the DNA during S phase were also observed in Ehrlich ascites tumor cells using the neutral sucrose gradient centrifugation technique. A significant proportion of the DNA from S cells irradiated with 10 Gy sedimented at speeds (350S-700S) well above the maximum sedimentation speed expected for free sedimenting DNA molecules (Smax = 350S), indicating the formation of a DNA complex. DNA from G1, G1/S, or G2 + M cells sedimented as expected for free sedimenting molecules. These results indicate significant alterations in the physicochemical properties of the DNA--probably caused by DNA replication-associated alterations in DNA structure and chromatin conformation--as cells enter S phase, and are invoked to explain the observed variation in DNA elution dose response throughout the cycle. It is proposed that the formation of a complex DNA structure, resistant to the proteolytic enzymes and detergents used, affected the elution characteristics of the DNA and gave rise to the observed curvilinear DNA elution dose-response curves, as well as to the fluctuations in elution characteristics observed throughout the cell cycle.     

A cytokinetic approach to determine the range of O2-dependence of pyrimidine(deoxy)nucleotide biosynthesis relevant for cell proliferation

In vitro cultured Ehrlich ascites tumour (EAT) cells were used because of the ease of their manipulation under different levels of hypoxia. They were used to clarify further the complex mechanism of oxygen-dependent cell proliferation. On reducing the oxygen concentration from 20% to lower levels (1-7%) an increase in the length of the population doubling time with concomitant reductions in protein, RNA and DNA content of cultures were observed. The incorporation of [14C]HCO3- into the RNA fraction of cells by de novo biosynthesis of uridine monophosphate (UMP) was reduced proportionally to the microenvironmental O2 tension. Uptake of this labelled precursor by cells in the presence of N-phosphonoacetyl-L-aspartate was found to be similarly inhibited. To correlate the reduction of cell growth under hypoxia with the functional pyrimidine supply, hypoxic cells were cultured in the presence of a balanced mixture of deoxynucleosides and/or uridine (100 microM deoxycytidine, 10 microM deoxyadenosine, 10 microM deoxyguanosine, 100 microM uridine). Above 3% O2 in the protective atmosphere, no improvement of growth parameters by the exogenous pyrimidinenucleotide precursors was obtained, whereas these compounds had a positive influence below this level. The increase in cell number was raised to about 60% of that of control cultures (20% O2) irrespective of the oxygen tension. In addition, when above 3% O2 the incorporation of HCO3- into RNA was comparable to that of controls, indicating that the pyrimidine de novo pathway is not a limiting factor in RNA biosynthesis. In conclusion, whereas at suboptimal O2 levels (5-7%) no correlation between pyrimidine metabolism and reduction of proliferation rate appears to exist, at low O2 concentrations (less than 3%) the rate of orotate/UMP production seems to be an important factor in the growth cessation of EAT cells; at critical O2 tensions (less than 1%) the lack of pyrimidine-deoxynucleosides substantially reduces cell cycle progression.     

Synthesis of nucleic acids and proteins in synchronized Ehrlich tumour cells

The activation of RNA synthesis in Ehrlich tumour cells occurs during the transition: G1 leads to S simultaneously with the onset of DNA replication and is intermittent. A high rate of synthesis is maintained at a constant level for some period of time and is decreased only by the end of the mitotic cycle. Actinomycin D (0.05 mkg/ml) inhibits the label incorporation into RNA in the S- and G2 phases, but has no inhibiting effect at earlier stages. These findings and the data from polyacrylamide gel electrophoresis suggest that all types of rRNA and tRNA are synthesized in the course of the S- and G2 phases. The rate of protein synthesis is correlated with that of protein synthesis in tumour cells at all stages of the cycle. Electrophoresis in polyacrylamide gel shows that the spectra of nuclear proteins and Ehrlich tumour cell cytoplasm are not significantly changed throughout the mitotic cycle. The amount of histones in the nuclei is increased simultaneously with the increase in the level of DNA, so that the histone/DNA ratio remains constant throughout the cycle and is equal to 0,96 +/- 0,03.     

Synchronization of mammalian cells by selection and additional chemical block studied by DNA distribution analysis and BrdUrd-Hoechst 33258-technique

Abstract. Ehrlich ascites tumour cells growing in vitro in suspension culture were separated according to volume by the technique of velocity sedimentation in a zonal rotor with a reorienting gradient. Using DNA distribution analysis the sedimentation pattern of the cells could be analysed in detail. With appropriate conditions it was possible to separate pure G1 cells. Samples could also be obtained which were enriched in S or G2 + M cells. The main limitation of the selection in this type of rotor was the reorientation of the gradient which caused disturbances during deceleration of the rotor. The synchronous growth of selected G1 cells has been studied in detail to investigate the reasons for the rather poor synchrony of these cells. The poor synchrony was found to be caused mainly by the small volume of the selected G1 cells compared with the normal volume of G1 cells in an asynchronous population. The synchronization of these cells could be essentially improved by a short treatment with excess thymidine causing a metabolic block at the G1/S border. The duration of this treatment could be minimized using DNA distribution analysis of growing cells after releasing of the block. The durations of the cell cycle phases in synchronized cells agreed with the values calculated in asynchronous cells by DNA distribution analysis and the BrdUrd-Hoechst 33258-technique.     

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.     

Absence of anthracycline-induced degradation of nuclear DNA in Ehrlich ascites tumour cells

The in vivo effects of anthracycline antibiotics on the integrity of Ehrlich ascites tumour cell DNA have been studied by sedimentation analysis of nuclear structures containing superhelical DNA in neutral sucrose gradients. These fast-sedimenting protein-DNA complexes may be released by gently lysing cells in solution containing non-ionic detergents and high NaCl concentrations (1.95 M). The supercoiled structure of DNA in these protein-DNA complexes is suggested by the characteristic sedimentation in the presence of intercalating agents. Apparently, no DNA damage could be detected in Ehrlich cells from 7-day-old tumours within 3 h after various doses of daunomycin (0.5–10 mg/kg of body wt.) were administered i.p. to mice. Sedimentation anomalies could not be observed even 15 or 30 h after administration of therapeutic doses of daunomycin or adriamycin. In contrast, at 30 min after administration to mice, therapeutic doses of bleomycin (2–8 mg/kg) caused extensive fragmentation of tumour cell DNA, which could be monitored as slowly sedimenting DNA structures (compared with the control). Similarly, DNA damage could be induced by procarbazine at therapeutic doses. Exposure to bleomycin or procarbazine abolished the characteristic biphasic response to ethidium bromide. The absence of anthra-cycline-induced degradation of Ehrlich ascites tumour cell DNA is apparently in contrast with the DNA damage observed in L1210 tumour cells. These observations suggest that DNA damage is not a necessary condition for antitumour activity.     

Selection of ehrlich tumor cells in different phases of the cell cycle by ficoll gradient centrifugation

Mouse Ehrlich ascites tumor cells were centrifuged at low speed on a linear Ficoll gradient. Cells from different fractions of the gradient were collected separately and analysed by cytological and cytochemical methods (DNA content, mean volume and number of cells). Nearly pure populations of cells in G1 or S were selected. A heterogeneous population containing 70% G2 and mitotic cells was also isolated. No ultrastructural alterations were detected in the cells after centrifugation. Selected G1 cells were cultured in vitro, their kinetic parameters were measured and compared with those of the original population. No difference was observed as far as the duration of the cycle of these cells is concerned.     

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.     

APOPTOSIS OF EHRLICH MOUSE ASCITES CELLS INDUCED BY LONG-TERM EXPOSURE OF WEAK ELECTROMAGNETIC FIELDS IN VIVO

To study the possibility of apoptosis of tumor cells induced by weak electromagnetic fields (EMFs) in vivo, mice were inoculated with Ehrlich ascites cells and exposed to a long-term electromagnetic field (1 mT, 700 KHz). During the treatment, growth curves of mice were measured and compared between exposed and sham-exposed mice. The results show that the growth curves of healthy controls agree well with the ideal curve of logistic growth, but the growth curves of cancer mice deviate from the ideal curve. There is no difference in growth curves between exposed, and sham-exposed healthy mice, and they both agree with the ideal curve. However, a notable difference in growth curves between exposed and sham-exposed cancer mice was obtained. Moreover, the curves of sham-exposed mice deviate even more than those of the exposed mice; in other words, the growth curves of Ehrlich ascites mice deviate from the ideal curve of healthy mice but are shifted toward it by the EMF treatments. After the treatment, apoptosis of Ehrlich ascites cells from inoculated mice was analyzed by several methods, including flow cytometry, fluorescence microscopy, and DNA gel electrophoresis. Statistical analysis from flow cytometry shows that the apoptotic ratio of cells from exposed Ehrlich ascites mice was significantly higher than that from sham-exposed treated mice. Microscopic observation of Ehrlich ascites cells stained with acridine orange (AO) and propidium iodide (PI) showed typical apoptotic changes in exposed animals whose cell nuclei were highly condensed or fragmented and uniformly stained green by the AO, whereas cell nuclei from sham-exposed mice were stained green and showed a fine reticular pattern. Agarose gel electrophoresis of DNA from exposed mice showed that the chromatin DNA exhibited ladders, a characteristic feature of internucleosomal degradation of DNA by EMF treatments. For interactions between external electromagnetic fields and DNA, the mechanism of apoptosis of tumor cells induced by weak EMFs is discussed.