THE SYNTHESIS OF PHOSPHOLIPIDS IN THE NUCLEUS AND NUCLEAR MEMBRANE OF SYNCHRONIZED HeLa CELLS

HeLa cells were synchronized by a double thymidine block and pulse labeled at different stages of the cell cycle with ³H-choline. The specific activity of phospholipids extracted from the cell, the nucleus and the nuclear membrane showed a progressive increase from S to G₁; the incorporation of choline into phospholipids of asynchronous cells showed a specific activity intermediate between the values of S and G₁ cells. Similar results were obtained when ³²phosphorus was used as a precursor instead of choline. Thin layer chromatographic analysis of phospholipids extracted from cells in S and from cells in G₁ failed to show any difference in the distribution of radioactivity among the various phospholipid classes. Choline uptake by HeLa cells in different phases of the cell cycle did not show significant variations. However, during the synchronization process, shortly after the addition of excess thymidine, an increased uptake of choline by cells and an increased incorporation of choline into phospholipids were found. The results indicate that some of the changes occurring in phospholipids synthesis may not be cell cycle dependent, but may be the effect of the synchronizing process.     

The use of zonal centrifugation to study membrane formation during the life cycle of mammalian cells. Synthesis of `marker' enzymes and other components of cellular organelles

1. The activity of enzymes characteristic of microsomes (NADPH-cytochrome c reductase and uridine diphosphatase) and of inner mitochondrial membranes (cytochrome c oxidase and succinate-cytochrome c reductase) increases during the cell cycle of P815Y neoplastic mast cells in concert with total protein. The activity of glutamate dehydrogenase, an enzyme of the mitochondrial matrix, increases in a somewhat different manner. 2. The specific activity of mitochondrial structures involved in energy-coupling measured with a fluorescent probe remains constant during the cell cycle. 3. Mitochondrial and microsomal protein increases during the cycle at the same time as total protein; nuclear protein increases rather more sharply. 4. The rate of incorporation of labelled choline or inositol into nuclear, mitochondrial or microsomal phospholipid during the cell cycle follows the rate of incorporation into total phospholipid. 5. It is concluded that the major components of cellular membranes are synthesized, like total protein or phospholipid, throughout most of the intermitotic period.     

Cell cycle and growth stage-dependent changes in the transport of nucleosides, hypoxanthine, choline, and deoxyglucose in cultured Novikoff rat hepatoma cells

Populations of Novikoff rat hepatoma cells (subline N1S1-67) were monitored for the rates of transport of various substrates and for their incorporation into acid-insoluble material as a function of the age of cultures of randomly growing cells in suspension as well as during traverse of the cells through the cell cycle. Populations of cells were synchronized by a double hydroxyurea block or by successive treatment with hydroxyurea and Colcemid. Kinetic analyses showed that changes in transport rates related to the age of cultures or the cell cycle stage reflecte alterations in the V max of the transport processes, whereas the Km remained constant, indicating that changes in transport rates reflect alterations in the number of functional transport sites. The transport sites for uridine and 2-deoxy-D-glucose increased continuously during traverse of the cells through the cell cycle, whereas those for choline and hypoxanthine were formed early in the cell cycle. Increases in thymidine transport sites were confined to the S phase. Synchronized cells deprived of serum failed to exhibit normal increases in transport sites, although the cells divided normally at the end of the cell cycle. Arrest of the cells in mitosis by treatment with Colcemid prevented any further increases in transport rates. The formation of functional transport sites was also dependent on de novo synthesis of RNA and protein. Inhibition of DNA synthesis in early S phase inhibited the increase in thymidine transport rates which normally occurs during the S phase, but had no effect on the formation of the other transport systems. Transport rates also fluctuated markedly with the age of the cultures of randomly growing cells, reaching maximum levels in the mid-exponential phase of growth. The transport systems for thymidine and uridine were rapidly lost upon inhibition of protein and RNA synthesis, and thus seem to be metabolically unstable, whereas the transport systems for choline and 2-deoxy-D-glucose were stable under the same conditions.     

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.     

Interaction of caffeine with the DNA of Chinese hamster cells.

Incubation of Chinese hamster cells with labelled caffeine leads to transfer of radioactivity to DNA. This association occurs during the S phase of the cell cycle and involves parental as well as newly synthesised strands. The replacement of thymidine by BrdUrd prevents the incorporation radioactivity from caffeine into the DNA strands containing BrdUrd. Thymine is the only base which becomes labelled and data suggesting the participation of methyl groups of caffeine in the biosynthesis of thymine are presented. Ultraviolet irradiation increases the incorporation of radioactivity from caffeine to DNA.     

Glucose-stimulated DNA synthesis through mammalian target of rapamycin (mTOR) is regulated by KATP channels: effects on cell cycle progression in rodent islets

The aim of this study was to define metabolic signaling pathways that mediate DNA synthesis and cell cycle progression in adult rodent islets to devise strategies to enhance survival, growth, and proliferation. Since previous studies indicated that glucose-stimulated activation of mammalian target of rapamycin (mTOR) leads to [3H]thymidine incorporation and that mTOR activation is mediated, in part, through the K(ATP) channel and changes in cytosolic Ca2+, we determined whether glyburide, an inhibitor of K(ATP) channels that stimulates Ca2+ influx, modulates [3H]thymidine incorporation. Glyburide (10-100 nm) at basal glucose stimulated [3H]thymidine incorporation to the same magnitude as elevated glucose and further enhanced the ability of elevated glucose to increase [3H]thymidine incorporation. Diazoxide (250 microm), an activator of KATP channels, paradoxically potentiated glucose-stimulated [3H]thymidine incorporation 2-4-fold above elevated glucose alone. Cell cycle analysis demonstrated that chronic exposure of islets to basal glucose resulted in a typical cell cycle progression pattern that is consistent with a low level of proliferation. In contrast, chronic exposure to elevated glucose or glyburide resulted in progression from G0/G1 to an accumulation in S phase and a reduction in G2/M phase. Rapamycin (100 nm) resulted in an approximately 62% reduction of S phase accumulation. The enhanced [3H]thymidine incorporation with chronic elevated glucose or glyburide therefore appears to be associated with S phase accumulation. Since diazoxide significantly enhanced [3H]thymidine incorporation without altering S phase accumulation under chronic elevated glucose, this increase in DNA synthesis also appears to be primarily related to an arrest in S phase and not cell proliferation.     

Uptake of amino acids and thymidine during the first cell cycle of synchronized hamster cells

Summary The net total uptake of four amino acids (valine, leucine, lysine and methionine) used at concentrations required for growth, and of thymidine at tracer concentrations, has been studied during the first cell cycle of an asparagine-dependent strain of transformed BHK cells synchronized by asparagine starvation. The rate of the total uptake of the amino acids, the free pool of the amino acids taken up, and the rate of their incorporation into protein at the cell cycle. The increase in these parameters during the cell cycle was not linear. The uptake of thymidine started before the onset of DNA synthesis and proceeded linearly beyond the peak of the S phase. The rate of accumulation of thymidine into the acid-soluble fraction also increased during the S phase, apart from a tendency to plateau off at the peak of this phase. It reached a second plateau towards the end of the cell cycle, and then declined slightly. Evidence is presented which suggests that the total quantity of protein synthesized during the cell cycle is more than the newly synthesized protein present in the cells at the end of the cell cycle; this indicates degradation and/or secretion of a substantial proportion of the newly synthesized protein. The total protein synthesized at different time points in the cell cycle appeared to contain different proportions of the amino acids used.     

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.     

Thymidine transport by Novikoff rat hepatoma cells synchronized by double hydroxyurea treatment

Suspension cultures of Novikoff rat hepatoma cells were synchronized by a double hydroxyurea block. About 80% of the cells of the population doubled 5 to 8 h after the reversal of the second hydroxyurea block. At all stages of the cell cycle, thymidine was rapidly incorporated into the acid-soluble pool of the cells (mainly dTTP) and the rate of incorporation was limited by the rate of thymidine transport. The rate of thymidine transport per cell roughly doubled during the S or late S phase and decreased again to the base level during cell division. This was reflected by corresponding changes in V_max for thymidine transport, whereas the apparent K_m remained constant throughout the cell cycle.     

The activities of thymidine metabolising enzymes during the cell cycle of a human lymphocyte cell line LAZ-007 synchronised by centrifugal elutriation

The activities throughout the cell cycle of thymidine kinase (EC 2.7.1.21), dihydrothymine dehydrogenase (EC 1.3.1.2), thymidine phosphorylase (EC 2.4.2.4) and dTMP phosphatase (EC 3.1.3.35) were measured in the Epstein-Barr virally transformed human B lymphocyte line LAZ-007. Cells were synchronised at different stages of the cell cycle using the technique of centrifugal elutriation. The degree of synchrony in each cycle-stage cell population was determined by flow microfluorimetric analysis of DNA content and by measurement of thymidine incorporation into DNA. The activity of the anabolic enzyme thymidine kinase was low in the G₁ phase cells, but increased many-fold during the S and G₂ phases, reaching a maximum after the peak of DNA synthesis, then decreasing in late G₂ + M phase. By contrast, the specific activities of the enzymes involved in thymidine and thymidylate catabolism, dihydrothymine dehydrogenase, thymidine phosphorylase and dTMP phosphatase remained essentially constant throughout the cell cycle, indicating that the fate of thymidine at different stages of the cell cycle is governed primarily by regulation of the level of the anabolic enzyme thymidine kinase and not by regulation of the levels of thymidine catabolising enzymes.     

Uptake of amino acids and thymidine during the first cell cycle of synchronized hamster cells.

The net total uptake of four amino acids (valine, leucine, lysine and methionine) used at concentrations required for growth, and of thymidine at tracer concentrations, has been studied during the first cell cycle of an asparagine-dependent strain of transformed BHK cells synchronized by asparagine starvation. The rate of the total uptake of the amino acids, the free pool of the amino acids taken up, and the rate of their incorporation into protein at the end of the first cell cycle were, on the average, 12-fold that at the beginning of the cell cycle. The increase in these parameters during the cell cycle was not linear. The uptake of thymidine started before the onset of DNA synthesis and proceeded linearly beyond the peak of the S phase. The rate of accumulation of thymidine into the acid-soluble fraction also increased during the S phase, apart from a tendency to plateau off at the peak of this phase. It reached a second plateau towards the end of the cell cycle, and then declined slightly. Evidence is presented which suggests that the total quantity of protein synthesized during the cell cycle is more than the newly synthesized protein present in the cells at the end of the cell cycle; this indicated degradation and/or secretion of a substantial proportion of the newly synthesized protein. The total protein synthesized at different time points in the cell cycle appeared to contain different proportions of the amino acids used.     

Phospholipids are synthesized in the G2/M phase of the cell cycle

Very little is known about the metabolism of phospholipids in the G2 and M phases of the cell cycle, but limited studies have led to the postulation that phospholipid synthesis ceases during this period. To investigate whether phospholipids are synthesized in the G2/M phase of the cell cycle, protocols were developed to produce synchronized MCF-7 cell populations with greater than 80% of the cells in G1/S or G2/M phases that moved in synchrony following removal of the blocking agent. Analysis of the activities of key phosphatidylcholine and phosphatidylethanolamine biosynthetic enzymes in subcellular fractions obtained from MCF-7 cells at different cell cycle phases revealed that there was robust activity of key enzymes in the fractions prepared from MCF-7 cells in G2/M phase. Radiolabeled choline and ethanolamine were rapidly incorporated into cells maintained at G2/M phase with nocodazole, and the rates of incorporation were similar to those obtained in cells allowed to progress into the G1 phase. Furthermore, radiolabeled glycerol was incorporated into phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol, phosphatidylserine and phosphatidic acid in MCF-7 cells maintained at G2/M phase with nocodazole. Similar results were obtained in CHO cells. These results demonstrate that glycerophospholipid synthesis is very active in the G2/M phase of these cells. Therefore, the postulated cessation of phospholipid synthesis in G2/M phases is not applicable to all cell types.     

Cell cycle changes and cytotoxicity in irradiated cultures of bovine aortic endothelial cells

The purpose of this experiment was to determine the effect of ionizing radiation on cell number, lactate dehydrogenase (LDH) release, cell cycle distribution, [3H]thymidine incorporation, and autoradiographic labeling index in bovine aortic endothelial cells in vitro. Confluent endothelial monolayers were exposed to single doses of 0.5-10 Gy of 60Co gamma rays and were analyzed from 2 to 24 h postirradiation. Irradiated monolayers exhibited a time- and dose-dependent decrease in cell number, increase in LDH release, and redistribution of cells in the cell cycle. Cell cycle redistribution included an increase in the proportion of cells in S phase at 4 h after irradiation and a decrease in S phase at 24 h. The cells also exhibited a decrease in [3H]thymidine incorporation as early as 2 h after 5 Gy. This represented the most rapid radiation response observed in the present study. These data demonstrate that radiation cytotoxicity in confluent, plateau-phase endothelial monolayers is accompanied by changes in the cell cycle distribution of adherent cells, and that reduced [3H]thymidine incorporation is an early marker of radiation injury in this clinically important cell type.     

Chromatin phospholipids and DNA synthesis in hepatic cells

The synthesis of phospholipids found in microsomes, in the nuclei and in chromatin has been studied in rat liver after partial hepatectomy. [32P]O4(2-)incorporation in phospholipids has been compared with that of (3H) thymidine over a period of 48 h after operation. The presence of two peaks of DNA synthesis has been observed at 18 and 36 h; nuclear phospholipids show a continuous synthesis starting from 12 h, whereas the microsomes show two peaks at 12 and 24-30 h. The specific activity of the chromatin phospholipid fraction increases at 12h, doubles its initial value at 18 h, shows a peak at 30 h and comes back to the initial value at 48 h. It is concluded that chromatin phospholipids increase their synthesis in relation to the S phase of the cell cycle, whereas those of the nuclear membranes do not change the rate of synthesis throughout the cell cycle. The possibility is suggested that chromatin phospholipids are synthesized in the microsomes and transferred to the nucleus.     

NUCLEIC ACID CONTENT OF HeLa S3 CELLS DURING THE CELL CYCLE: VARIATIONS BETWEEN CYCLES

The process of continuous resynchronization with excess thymidine provides sufficient cell material for accurate chemical determination of DNA and RNA in HeLa S3 cells at hourly intervals during the cell cycle. Total DNA is constant during the non-S phase portion of the cell cycle but varies widely among cycles of synchronous growth. Total cellular RNA content increases linearly in the G₁ phase and accelerates to a higher linear rate of accumulation, which remains constant during most of the S and G₂ phases. The ratios of early and late cycle rates of RNA accumulation are not constant among cycles.     

Synthesis of glycolipids and phospholipids in hamster cells: dependence on cell density and the cell cycle.

Sakiyama et al. ('72) reported the isolation of a line of hamster cells (NIL 1c1) which contains only three glycolipids, hematoside, ceramide monohexoside and ceramide dihexoside. The incorporation of radiolabeled palmitate into hematoside during 24 hours was three fold higher in normal confluent, non growing cells than sparse, growing ones. Polyoma transformed cells did not exhibit this effect. We have continued studies with the untransformed cell line and have found that the higher incorporation of radiolabeled palmitate into hematoside by normal confluent cells is not due to a higher rate of turnover of hematoside at confluence but represents a true chemical increase. We have also found that this increase is not a gradual process during cell growth but instead occurs only when the cells become confluent and stop growing. The increase of hematoside at confluence is not due to a higher rate of synthesis of hematoside during G1, relative to the other phases of the cell cycle. We found the rate of synthesis of hematoside to be constant throughout the cell cycle. The rate of synthesis of phosphatidyl choline, phosphatidyl ethanolamine, phosphatidyl serine, phosphatidyl inositol and sphingomyelin was also studied as a function of the cell cycle. We found no large differences in the synthetic rate of any given phospholipid species throughout the cell cycle although the rate of synthesis of the glycerophospholipids was somewhat higher during late G1 and S. We did, however, find major differences in the rates of synthesis of the different phospholipid species.     

The action of 5-amino uracil on log growth and division-synchronized Tetrahymena

The influence of 5-amino uracil (5-AU) was investigated on the cell cycle of log growth and division-synchronized Tetrahymena pyriformis GL. The division index of log growth phase Tetrahymena was suppressed by 50% after 40 min in 8 mM 5-AU. Cells division-synthronized by one heat shock per generation were also treated with 5-AU. Cells treated either prior to the first synchronous division (80 min EH) or up to 25 min prior to the second synchronous division (after 160 min EH) were not delayed in their progress through the cell cycle. Cells treated during the S phase of the first free running cell cycle, however, were delayed 5-30 min from reaching the second synchronous division. The effect of 5-AU on DNA and RNA synthesis was also examined. Incorporation of [3H]thymidine into acid-precipitable material was reduced in the presence of 5-AU; the rate of DNA synthesis was also reduced. The depression in the rate of DNA synthesis was greater at the beginning of S than at the end of S. The size of the thymidine pool (nucleosides + nucleotides) did not change during 5-AU treatment; however, an accumulation of thymidine tri-phosphate and a decrease in the amount of thymidine nucleoside was observed. A suppression of [14C]uridine incorporation resulting from 5-AU treatment was observed throughout the cell cycle. The rate of RNA synthesis as monitored by [14C]uridine incorporation into acid precipitable material was also reduced during 5-AU treatment. No change in either the size or the composition of the pool of uridine (nucleoside + nucleotide) was detected in 5-AU treated cells as compared to controls.     

Cyclic AMP-dependent and -independent protein phosphokinase activity in subcellular fractions of synchronously growing leydig I-10 cells.

The Leydig I-10 tumor cell line was synchronized by the double thymidine block method using 1.0 mM thymidine. Protein phosphokinase activity of subcellular fractions was determined at various times throughout the cell cycle. Microsomal cAMP-independent kinase activity increased in G2 and decreased during the S and G1 phases. Except for relatively small increases during the G1 and late S phases, microsomal cAMP-dependent kinase activity remained unchanged throughout most of the cycle. In the lysosomal-mitochondrial fraction, cAMP-dependent and cAMP-independent protein kinase activity increased during the S phase. Independent kinase activity peaked again during G1, while the dependent kinase became depressed. Phosphokinase activity increased in the nuclear fraction in late G2 and during mitosis, and was due to increases in both cAMP-independent and cAMP-dependent kinase activity. Cytosol cAMP-dependent kinase activity increased in G2 and during mitosis; cAMP-independent kinase activity showed some increased activity during late G2 and mitosis. These temporal variations in the subcellular kinase activities throughout the cell cycle may act to phosphorylate subcellular protein substrates in a cell cycle-specific fashion.     

Immunological studies of aging. IX. Impaired proliferation of T lymphocytes detected in elderly humans by flow cytometry

Lymphocytes from humans over the age of 65 incorporate approximately 50% less tritiated thymidine than do lymphocytes from young donors when cultured with phytohemagglutinin. Because lymphocytes from elderly humans are more sensitive to cell cycle arrest induced by tritiated thymidine, it was impossible to determine to what extent impaired thymidine incorporation reflected a defect in proliferation or the increased sensitivity to the radioactive isotope. Flow cytometry was used to measure the proliferative response of T cells from young and old donors in culture with PHA. It was found that 25 percent fewer lymphocytes from old as compared to young humans enter the G1 or complete the S phase of the cell cycle. However, the rate of progression through the cell cycle by activated cells from young and old humans is comparable. Thus, flow cytometry suggested that the difference in thymidine incorporation by lymphocytes from old and young donors is attributable equally to a proliferative defect and to cell cycle arrest induced by tritiated thymidine. This conclusion was supported by the fact that the relative impairment of thymidine incorporation by lymphocytes from old donors was only one-half as great when a 20-min instead of a 24-hr pulse of tritiated thymidine was used.