H3-THYMIDINE DERIVATIVE POOLS IN RELATION TO MACRONUCLEAR DNA SYNTHESIS IN TETRAHYMENA PYRIFORMIS

The formation of a soluble H³-thymidine derivative pool has been examined in Tetrahymena pyriformis as a function of macronuclear DNA synthesis during the cell life cycle. An autoradiographic technique which allows the detection of water-soluble materials within a cell has shown that these cells do not take up and retain exogenous H³-thymidine during G1 or G2. Uptake of H³-thymidine is restricted to the S period of the cell cycle. Additional autoradiographic experiments show, however, that a soluble pool of H³-thymidine derivatives persists from the end of one DNA synthesis period to the beginning of the next synthesis period in the subsequent cell cycle. Since this persisting pool cannot be labeled with H³-thymidine, the pool does not turn over during non-S periods.     

Cell cycle parameters inAedes albopictus mosquito cells

Summary We have analyzed cell cycle parameters for theAedes albopictus C7-10 mosquito cell line, which has been systematically developed for somatic cell genetics, expression of transfected genes, and synthesis of hormone-inducible proteins. In rapidly cycling cells, we measured a generation time of 10–12 h. The duration of mitosis (M) was ≤1 h, and the DNA synthesis phase (S) required 6 h. UnlikeDrosophila melanogaster Kc cells, in which the G2 gap is substantially longer than G1, in C7-10 cells G1 and G2 each lasted approximately 2h. In these cells, the duration of both S and G2 was independent of the population doubling time, and the increase in population doubling time as cells approached confluency was due to prolongation of G1. When treated with the insect steroid hormone, 20-hydroxyecdysone, C7-10 mosquito cells complete the cycle in progress before undergoing a reversible arrest.     

The probability of G1 cells to enter into S increases with their size while S length decreases with cell enlargement in Allium cepa

The distribution of cell surface area projection (cell size) has been measured at birth and at initiation of DNA synthesis in steady-state populations of Allium cepa root meristems. The conditional probability, P(I/G1), that initiation occurs given that the event of being in G1 also occurs has been estimated from these data. P(I/G1) was found to increase when cells became larger. The distribution of G1 duration has been constructed from indicated cell size distributions. The absolute frequencies of G1 times showed a maximum in the zone of cells with short G1 periods; about 14% of cells appear to enter into S with G1 congruent to 1 h. These results suggest that the increase of P(I/G1) was due to cell enlargement and not to cell aging. By comparing the cell size distribution at initiation of S and at the end of this period, a drastic reduction of cell size variability during DNA replication was observed and both curves were seen as rather similar in shape although they obviously had different modal points. These observations support that there is a negative correlation between the initiation size and the duration of genome duplication, and that cells which initiate DNA synthesis with the same size have a similar replication time. From this hypothesis, a plot of S duration versus cell size at initiation of this period was constructed by comparing the distributions of cell size at start and end of replication; this plot was also consistent with the existence of a negative correlation between cell initiation size and S length.     

Mode of estrogen action on cell proliferation in CAMA-1 cells: II. Sensitivity of G1 phase population

The mammary cancer cell line CAMA-1 synchronized at the G1/S boundary by thymidine block or at the G1/M boundary by nocodazole was used to evaluate 1) the sensitivity of a specific cell cycle phase or phases to 17 beta-estradiol (E2), 2) the effect of E2 on cell cycle kinetics, and 3) the resultant E2 effect on cell proliferation. In synchronized G1/S cells, E2-induced 3H-thymidine uptake, which indicated a newly formed S population, was observed only when E2 was added during, but not after, thymidine synchronization. Synchronized G2/M cells, enriched by Percoll gradient centrifugation to approximately 90% mitotic cells, responded to E2 added immediately following selection; the total E2-treated population traversed the cycle faster and reached S phase approximately 4 hr earlier than cells not exposed to E2. When E2 was added during the last hour of synchronization (ie, at late G2 or G2/M), or for 1 hr during mitotic cell enrichment, a mixed response occurred: a small portion had an accelerated G1 exit, while the majority of cells behaved the same as controls not incubated with E2. When E2 addition was delayed until 2 hr, 7 hr, or 12 hr following cell selection, to allow many early G1 phase cells to miss E2 exposure, the response to E2 was again mixed. When E2 was added during the 16 hr of nocodazole synchronization, when cells were largely at S or possibly at early G2, it inhibited entry into S phase. The E2-induced increase or decrease of S phase cells in the nocodazole experiments also showed corresponding changes in mitotic index and cell number. These results showed that the early G1 phase and possibly the G2/M phase are sensitive to E2 stimulation, late G1, G1/S, or G2 are refractory; the E2 stimualtion of cell proliferation is due primarily to an increased proportion of G1 cells that traverse the cell cycle and a shortened G1 period, E2 does not facilitate faster cell division; and estrogen-induced cell proliferation or G1/S transition occurs only when very early G1 phase cells are exposed to estrogen. These results are consistent with the constant transition probability hypothesis, that is, E2 alters the probability of cells entering into DNA synthesis without significantly affecting the duration of other cell cycle phases. Results from this study provide new information for further studies aimed at elucidating E2-modulated G1 events related to tumor growth.     

Kinetics of the nuclear division cycle of Aspergillus nidulans.

We have analyzed the cell cycle kinetics of Aspergillus nidulans by using the DNA synthesis inhibitor hydroxyurea (HU) and a temperature-sensitive cell cycle mutant nimT that blocks in G2. HU rapidly inhibits DNA synthesis (S), and as a consequence progression beyond S to mitosis (M) is blocked. Upon removal of HU the inhibition is rapidly reversible. Conidia (asexual spores) of nimT were germinated at restrictive temperature to synchronize germlings in G2 and then downshifted to permissive temperature in the presence of HU. This procedure synchronizes the germlings at the beginning of S in the second cell cycle after spore germination. We have measured the total duration of S, G2, and M as the time required for these cells to recover from the HU block and undergo the next nuclear division. The duration of S was defined by the time course of sensitivity to reintroduction of HU during recovery from the initial HU block. The cell cycle time was measured as the nuclear doubling time, and the duration of mitosis was determined from the mitotic index. The duration of G1 was calculated by subtracting the combined durations of S, G2, and M from the nuclear doubling time, and the length of G2 was calculated by subtracting S and M from the aggregate length of S, G2, and M. We have also determined the duration of the phases of the cell cycle during the first cycle after spore germination. In these experiments spores were germinated directly in HU without first being blocked in G2. Because the durations of G1, S, G2, and M for the first cell cycle after spore germination were identical with those previously determined for spores presynchronized at the beginning of S in the second cell cycle, we conclude that dormant conidia of A. nidulans are arrested at, or before, the start of S.     

Cell cycle regulation of the mixotrophic dinoflagellate Dinophysis acuminata: Growth,photosynthetic efficiency and toxin production

The mixotrophic dinoflagellate Dinophysis acuminata is a widely distributed diarrhetic shellfish poisoning (DSP) producer. Toxin variability of Dinophysis spp. has been well studied, but little is known of the manner in which toxin production is regulated throughout the cell cycle in these species, in part due to their mixotrophic characteristics. Therefore, an experiment was conducted to investigate cell cycle regulation of growth, photosynthetic efficiency, and toxin production in D. acuminata. First, a three-step synchronization approach, termed “starvation-feeding-dark”, was used to achieve a high degree of synchrony of Dinophysis cells by starving the cells for 2 weeks, feeding them once, and then placing them in darkness for 58 h. The synchronized cells started DNA synthesis (S phase) 10 h after being released into the light, initiated G2 growth stage eight hours later, and completed mitosis (M phase) 2 h before lights were turned on. The toxin content of three dominant toxins, okadaic acid (OA), dinophysistoxin-1 (DTX1) and pectenotoxin-2 (PTX2), followed a common pattern of increasing in G1 phase, decreasing on entry into the S phase, then increasing again in S phase and decreasing in M phase during the diel cell cycle. Specific toxin production rates were positive throughout the G1 and S phases, but negative during the transition from G1 to S phase and late in M phase, the latter reflecting cell division. All toxins were initially induced by the light and positively correlated with the percentage of cells in S phase, indicating that biosynthesis of Dinophysis toxins might be under circadian regulation and be most active during DNA synthesis.     

A UV-responsive G2 checkpoint in rodent cells.

We have studied the effect of UV irradiation on the cell cycle progression of synchronized Chinese hamster ovary cells. Synchronization of cells in S or G2 phase was accomplished by the development of a novel protocol using mimosine, which blocks cell cycle progression at the G1/S boundary. After removal of mimosine, cells proceed synchronously through the S and G2 phases, allowing manipulation of cells at specific points in either phase. Synchronization of cells in G1 was achieved by release of cells after a period of serum starvation. Cells synchronized by these methods were UV irradiated at defined points in G1, S, and G2, and their subsequent progression through the cell cycle was monitored. UV irradiation of G1-synchronized cells caused a dose-dependent delay in entry into S phase. Irradiation of S-phase-synchronized cells inhibited progression through S phase and then resulted in accumulation of cells for a prolonged interval in G2. Apoptosis of a subpopulation of cells during this extended period was noted. UV irradiation of G2-synchronized cells caused a shorter G2 arrest. The arrest itself and its duration were dependent upon the timing (within G2 phase) of the irradiation and the UV dose, respectively. We have thus defined a previously undescribed (in mammalian cells) UV-responsive checkpoint in G2 phase. The implications of these findings with respect to DNA metabolism are discussed.     

Cyclic x-ray responses in Mammalian cells in vitro

Various radiation responses in mammalian cells depend on the position of the cell within its generation cycle (that is, its age) at the time of irradiation. Studies have most often been made by irradiating synchronized populations of cells in vitro. Results in different cell lines are not easy to compare, but an attempt has been made here to point out similarities and differences with regard to cell killing and division delay. In general, survival data obtained so far show that, in cells with a short G(1), cells are most sensitive in mitosis and in G(2), less sensitive in G(1), and least sensitive during the latter part of the S period. In cells with a long G(1), in addition to the above, there is usually a resistant phase early in G(1) followed by a sensitive stage near its end. (The latter may be as sensitive as mitosis.) Exceptions to the above, especially in some L cell sublines, have been noted, and a possible explanation is given. In Chinese hamster cells, maximum survival after irradiation occurs during S, but it does not coincide with the time of the maximum rate of DNA synthesis or with the time of the maximum number of cells in DNA synthesis, and changes in survival also occur in cells inhibited from synthesizing DNA. Rather, survival depends on the position the cell has reached in the cycle at that time, which involves not only DNA synthesis but other processes as well. Survival is not completely correlated with DNA synthesis, since halting DNA synthesis just before or just after irradiation only slightly affects survival at its maximum. Division delay exhibits a pattern of response which is similar in most cell lines. Delay is considerable for cells irradiated in mitosis, is small for cells in G(1), increases to a maximum for cells during S, and declines for cells in G(2). L cells or human kidney cells may have a longer delay for cells irradiated in G(2) than for those irradiated in S. The results can be explained in terms of a two-component model of division delay. One component results from the prolongation of the S period due to the reduced rate of DNA synthesis, and the other, a block in G(2), is independent of DNA synthesis. The proportion of the two components may vary in different cell lines.     

Partial elimination of G1 and G2 periods in higher plant cells by increasing the S period

Meristematic cells from Allium cepa L roots can attain a steady-state of growth at both 15 and 25 °C in the presence of drugs, hydroxyurea and 5-amino-uracil, which reduce the rate of DNA synthesis. These drugs, at used concentrations, significantly lengthen the S period without altering the cell growth rate, as indicated by the maintenance of the generation time. It has been observed that steady-state populations respond to a gradual increase in S by a reduction of G2 until a minimum value; with larger lengthening of S, both G1 and G2 are reduced. Natural synchronous populations have been used to study cell cycle parameters during transition from the physiological steady-state to the new one created by the presence of the drug. G2 (but not G1) is reduced during transition even in the presence of maximum drug concentrations that do not alter the cell growth rate. Both the S period and the division time are lengthened during transition. These observations support the concept that certain fractions of G1 and G2 are expendable, because they have no role in the DNA-division sequence of cell cycle events. We conclude that cell size regulates the length of these fractions by means of a negative correlation.     

The role of protein accumulation in the cell cycle control of human NHIK 3025 cells

The cell cycle kinetics of NHIK 3025 cells, synchronized by mitotic selection, was studied in the presence of cycloheximide at concentrations (0.125-1.25 μM) which inhibited protein synthesis partially and slowed down the rate of cell cycle traverse. The median cell cycle duration was equal to the protein doubling time in both the control cells and in the cycloheximide-treated cultures at all drug concentrations. This conclusion was valid whether protein synthesis was continuously depressed by cycloheximide throughout the entire cell cycle, or temporarily inhibited during shorter periods at various stages of the cell cycle. These results may indicate that cell division does not take place before the cell has reached a critical size, or has completed a protein accumulation-dependent sequence of events. When present throughout the cell cycle, cycloheximide increased the median G1 duration proportionally to the total cell cycle prolongation. However, the entry of cells into S, once initiated, proceeded at an almost unaffected rate even at cycloheximide concentrations which reduced the rate of protein synthesis 50%. The onset of DNA synthesis seemed to take place in the cycloheximide-treated cells at a time when the protein content was lower than in the control cells. This might suggest that DNA synthesis in NHIK 3025 cells is not initiated at a critical cell mass.     

A new analytical method for determining duration of phases, rate of DNA synthesis and degree of synchronization from flow-cytometric data on synchronized cell populations.

L-cells synchronized by mitotic selection were investigated by flow-cytometry and the fractions of cells in the various cell cycle compartments were determined as a function of time. A new analytical evaluation procedure was developed, by which the mean transit-times of cells through various cell cycle phases can be calculated from these data. Three examples for application of the method are presented: (1) determination of the duration of G1, S, G2 + M and of the whole cell cycle; (2) calculation of the rate of DNA synthesis in several subcompartments of the S-phase; and (3) evaluation of the degree of synchronization at different stages of the cell cycle.     

Regulation of DNA synthesis in cytochalasin B (CB)-induced binucleate HeLa cells

The effects of timing and duration of cytochalasin B (CB) treatment on the kinetics of the initiation of DNA synthesis in mono- and binucleate HeLa cells, synchronized in the G1 phase of the cell cycle by the reversal of a mitotic block (N₂O at 80 PSI), were studied. In the control, bi-, tri- and tetranucleate cells entered S phase slightly earlier than the mononucleate cells at a rate proportional to the number of their nuclei. The difference between any two adjacent sub-populations was less than 0.5 h. However, the binucleate cells produced by a 90 min CB treatment immediately after the reversal of the mitotic block exhibited a considerably shorter G1 period as compared to mononucleate cells (a difference of 1.5 h). This exaggerated difference in the duration of G1 period between mono- and binucleate cells disappeared when the CB treatment was delayed by 75 or 90 min indicating that it was an experimental artifact. From this study, we conclude that there is naturally some degree of nuclear cooperation in the multinucleate systems, particularly with regard to the initiation of DNA synthesis, which is not influenced by CB treatment.     

Synthesis of poly(adenosine diphosphate ribose) in synchronized Chinese hamster cells.

Chinese hamster ovary cells were synchronized by mitotic selection and used to study the relation of poly(adenosine diphosphate ribose) synthesis to DNA synthesis and the different phases of the cell cycle. DNA synthesis was measured in cells rendered permeable to exogenously supplied nucleotides. Poly(ADPR) synthesis was also measured in permeable cells in the presence of both minimum and maximum DNA damage. The maximum DNA damage was produced by treating the cells with saturating concentrations of DNase. As anticipated, the DNA synthesis complex showed its maximum activity during S phase and showed 4–5-fold less activity during the other phases of the cell cycle. The basal level of poly(ADPR) synthesis was elevated during G1, fell to its lowest level during S phase, then increased during G2 and rose to its highest level during G1. The DNase responsive activity of poly(ADPR) synthesis was relatively constant thru the cell cycle but showed a peak at the end of S phase; then the activity decreased during the subsequent G2-M period.     

Synchronization of HeLa cell cultures by inhibition of DNA polymerase alpha with aphidicolin.

Both the inhibitory effect of aphidicolin on the replicative alpha-polymerase and the reversibility of its action in vivo (Pedrali-Noy & Spadari, 1979, Biochem. Biophys. Res. Commun. 88, 1194-2002) allow the synchronization of cells in culture. Aphidicolin prevents G1 cells from entering the DNA synthetic period, blocks cells in "S" phase, allows G2, M and G1 cells to continue the cell cycle and to accumulate at the G1/S border. Aphidicolin is a more useful reagent than hydroxyurea and thymidine because it does not affect cell viability or "S" phase duration and does not interfere with the synthesis of dNTPs or DNA polymerases. In fact cells exposed to the drug continue to synthesize all three DNA polymerases alpha, beta and gamma as well as all dNTPs which, when the block is removed, are present at levels optimal for DNA initiation and replication. The technique is simple and can be applied to cells growing in suspension or monolayers and allows one to harvest large quantities of synchronized cells.     

Lipid biosynthesis and its coordination with cell cycle progression

The activation of cell cycle regulators at the G1/S boundary has been linked to the cellular protein synthesis rate. It is conceivable that regulatory mechanisms are required to allow cells to coordinate the synthesis of other macromolecules with cell cycle progression. The availability of highly synchronized cells and flow cytometric methods facilitates investigation of the dynamics of lipid synthesis in the entire cell cycle of the heterotrophic dinoflagellate Crypthecodinium cohnii. Flow cytograms of Nile red-stained cells revealed a stepwise increase in the polar lipid content and a continuous increase in neutral lipid content in the dinoflagellate cell cycle. A cell cycle delay at early G1, but not G2/M, was observed upon inhibition of lipid synthesis. However, lipid synthesis continued during cell cycle arrest at the G1/S transition. A cell cycle delay was not observed when inhibitors of cellulose synthesis and fatty acid synthesis were added after the late G1 phase of the cell cycle. This implicates a commitment point that monitors the synthesis of fatty acids at the late G1 phase of the dinoflagellate cell cycle. Reduction of the glucose concentration in the medium down-regulated the G1 cell size with a concomitant forward shift of the commitment point. Inhibition of lipid synthesis up-regulated cellulose synthesis and resulted in an increase in cellulosic contents, while an inhibition of cellulose synthesis had no effects on lipid synthesis. Fatty acid synthesis and cellulose synthesis are apparently coupled to the cell cycle via independent pathways.     

CYTOKINETICS OF RAT TRACHEAL EPITHELIUM STIMULATED BY MECHANICAL TRAUMA

Mild abrasion of rat tracheal epithelium results in irreversible damage to the superficial cells and stimulates the viable basal cells to participate in a nearly synchronous wave of DNA synthesis and mitosis. For the growth population as a whole, DNA synthesis started at 14 hr after injury and persisted for 16 hr. The duration of S in individual cells was determined autoradiographically by identifying the time at which a second pulse of DNA precursor (¹⁴C-TdR) was no longer incorporated by cells labelled with ³H-TdR at the onset of S. S was found to be 8–9 hr long. It was also determined that cells entering S at later times synthesized DNA for the same 8–9 hr period. T_G2 was calculated to be 21/2–31/2 hr by subtraction of T_s and 1/2T_M from the period from onset of DNA synthesis to metaphase. By making a second denuding lesion adjacent to the first injury, the cells were stimulated through at least another period of S. At the peak of the second wave of DNA synthesis (50 hr after injury) ¹⁴C-TdR was present in the same cells which had incorporated ³H-TdR administered at the mid-point of the preceding synthetic phase. The 28-hr interval between these two peaks of synthesis is the measure of cell cycle duration for these regenerating tracheal epithelial cells.     

EGF induces cell cycle arrest of A431 human epidermoid carcinoma cells

The human carcinoma cell line A431 is unusual in that physiologic concentrations of epidermal growth factor (EGF) inhibit proliferation. In the presence of 5-10 nM EGF proliferation of A431 cells is abruptly and markedly decreased compared to the untreated control cultures, with little loss of cell viability over a 4-day period. This study was initiated to examine how EGF affects the progression of A431 cells through the cell cycle. Flow cytometric analysis of DNA in EGF-treated cells reveals a marked change in the cell cycle distribution. The percentage of cells in late S/G2 increases and early S phase is nearly depleted. Since addition of the mitotic inhibitor vinblastine causes accumulation of cells in mitosis and prevents reentry of cells into G1, it is possible to distinguish between slow progression through G1 and G2 and blocks in those phases. When control cells, not treated with EGF, are exposed to vinblastine, the cells accumulate mitotic figures, as expected, and show progression into S, thus diminishing the number of cells in G1. In contrast, no mitotic figures are found among the EGF-treated cells in the presence or absence of vinblastine, and progression from G1 into S is not observed, as the number of cells in G1 remains constant. These results suggest that there are two EGF-induced blocks in cell cycle transversal; one is in late S and/or G2, blocking entry into mitosis, and the other is in G1, blocking entry into S phase. After 24 hours of EGF treatment, DNA synthesis is reduced to less than 10% compared to untreated controls as measured by the incorporation of [3H]thymidine or BrdU. In contrast, protein synthesis is inhibited by about twofold. Although inhibition of protein synthesis is less extensive, it occurs 6 hours prior to an equivalent inhibition of DNA synthesis. The rapid decrease in protein synthesis may result in the subsequent cell cycle arrest which occurs several hours later.     

Cell cycle phase expansion in nitrogen-limited cultures of Saccharomyces cerevisiae

The time and coordination of cell cycle events were examined in the budding yeast Saccharomyces cerevisiae. Whole-cell autoradiographic techniques and time-lapse photography were used to measure the duration of the S, G1, and G2 phases, and the cell cycle positions of "start" and bud emergence, in cells whose growth rates were determined by the source of nitrogen. It was observed that the G1, S, and G2 phases underwent a proportional expansion with increasing cell cycle length, with the S phase occupying the middle half of the cell cycle. In each growth condition, start appeared to correspond to the G1 phase/S phase boundary. Bud emergence did not occur until mid S phase. These results show that the rate of transit through all phases of the cell cycle can vary considerably when cell cycle length changes. When cells growing at different rates were arrested in G1, the following synchronous S phase were of the duration expected from the length of S in each asynchronous population. Cells transferred from a poor nitrogen source to a good one after arrest in G1 went through the subsequent S phase at a rate characteristic of the better medium, indicating that cells are not committed in G1 to an S phase of a particular duration.