Requirement for phosphatidylinositol-3 kinase activity during progression through S-phase and entry into mitosis

Phosphatidylinositol-3 kinase (PI3K) proteins are important regulators of cell survival and proliferation. PI3K-dependent signalling regulates cell proliferation by promoting G1- to S-phase progression during the cell cycle. However, a definitive role for PI3K at other times during the cell cycle is less clear. In these studies, we provide evidence that PI3K activity is required during DNA synthesis (S-phase) and G2-phase of the cell cycle. Inhibition of PI3K with LY294002 at the onset of S-phase caused a 4- to 5-h delay in progression through G2/M. LY294002 treatment at the end of S-phase caused an approximate 2-h delay in progression through G2/M, indicating that PI3K activity functions for both S- and G2-phase progression. The expression of constitutively activated Akt partially reversed the inhibitory effects of LY294002 on mitotic entry, which demonstrated that Akt was one PI3K target that was required during G2/M transitions. Inhibition of PI3K resulted in enhanced susceptibility of G2/M synchronized cells to undergo apoptosis in response to DNA damage as compared to asynchronous cells. Thus, similar to its role in promoting cell survival and cell cycle transitions from G1 to S phase, PI3K activity appears to promote entry into mitosis and protect against cell death during S- and G2-phase progression.     

An association between the radiation-induced arrest of G2-phase cells and low-dose hyper-radiosensitivity: a plausible underlying mechanism?

The survival of asynchronous and highly enriched G1-, S- and G2-phase populations of Chinese hamster V79 cells was measured after irradiation with 60Co gamma rays (0.1-10 Gy) using a precise flow cytometry-based clonogenic survival assay. The high-dose survival responses demonstrated a conventional relationship, with G2-phase cells being the most radiosensitive and S-phase cells the most radioresistant. Below 1 Gy, distinct low-dose hyper-radiosensitivity (HRS) responses were observed for the asynchronous and G2-phase enriched cell populations, with no evidence of HRS in the G1- and S-phase populations. Modeling supports the conclusion that HRS in asynchronous V79 populations is explained entirely by the HRS response of G2-phase cells. An association was discovered between the occurrence of HRS and the induction of a novel G2-phase arrest checkpoint that is specific for cells that are in the G2 phase of the cell cycle at the time of irradiation. Human T98G cells and hamster V79 cells, which both exhibit HRS in asynchronous cultures, failed to arrest the entry into mitosis of damaged G2-phase cells at doses less than 30 cGy, as determined by the flow cytometric assessment of the phosphorylation of histone H3, an established indicator of mitosis. In contrast, human U373 cells that do not show HRS induced this G2-phase checkpoint in a dose-independent manner. These data suggest that HRS may be a consequence of radiation-damaged G2-phase cells prematurely entering mitosis.     

The cell cycle dependence of thermotolerance. I. CHO cells heated at 42 degrees C

We examined the dependence of heat killing and thermotolerance on the position and progression of Chinese hamster ovary (CHO) cells in the cell cycle. We measured cell cycle perturbations and survival of asynchronous and synchronized G1-, S-, and G2-phase cells resulting from continuous heating at 42.0 degrees C for up to 80 hr. Thermotolerance under these conditions was transient in nature, was dependent on the position of cells in the cell cycle, and occurred concurrently with a heat-induced delay of progression of G1- and G2-phase cells. When G1 cells were heated, survival decreased to 25% after 4 hr, at which time the thermotolerance was expressed. For G2 cells survival decreased initially at the same rate (T0 congruent to 3 hr) but thermotolerance was not expressed until approximately 12 hr, at which time the survival was 4%. The rate of decrease in survival was much more rapid for cells heated in mid-S phase (T0 congruent to 0.5 hr), and these cells did not express thermotolerance at a measurable level. Concurrent with the expression of thermotolerance, the progression of cells heated in G1 and G2 was delayed. Following the expression of tolerance, progression resumed at a rate approximately equal to the rate of decrease in survival of the G1 population. Cells heated in mid-S phase continued to progress through the cell cycle until they reached G2, where they were also delayed.     

Alterations in the cell cycle and in the protein level of cyclin D1, p21CIP1, and p16INK4a after exposure to 50 Hz MF in human cells

The effect of exposure to 50 Hz, 1 mT magnetic fields (MF) on the cell cycle in general, on the DNA synthesis in S-phase, and on the G1-phase regulating proteins Cdk4, cyclin D1, p16INK4a, and p21CIP1 was investigated in human amniotic fluid cells. The BrdU-incorporation assay revealed a significant diminution of S-phase cells in MF-exposed cultures. The protein level of Cdk4 did not change, but MF induced a decreased expression of cyclin D1 after 24 h and 30 h exposures. The level of p16INK4a increased at 1 h and 12 h after exposure, whereas the expression of p21CIP1 was enhanced at 6 h and 12 h after exposure. Reduced levels of both Cdk inhibitors were observed at longer exposure times (24 h, 30 h). Our results suggest an inhibitory effect of MF on the G1-phase induced by altered expression of p16INK4a and p21CIP1.     

DNA content and expression of genes related to cell cycling in developing Gossypium hirsutum (Malvaceae) fibers

The cell cycle in cotton (Gossypium hirsutum) fibers is poorly understood. The objective of this study was to evaluate the cell cycle status and DNA content in developing cotton fibers. The DNA content and cell cycle distribution in fiber and hypocotyl cells were determined by flow cytometry. Expression levels of minichrosomal maintenance protein (mcm), cyclin B, and a retinoblastoma-like protein (rb) genes were determined with real-time PCR in fibers and dividing and nondividing tissues. No endoreduplication occurred, nor did genome size or percentage of G1-phase nuclei differ between hypocotyls and fibers. Approximately 13 and 17% of fiber nuclei were in the S phase in 14 days after anthesis (d) fibers and 25 d fibers, respectively. The mcm and cyclin B were expressed at higher levels in fibers than in mature leaves, but expression levels in fibers were less than 15% of meristematic tissues. Rb was expressed in fibers at levels less than 50% of mature leaves or meristematic tissues. Based on an apparent increase in S-phase cells as fibers mature and the low level of expression of genes associated with cell cycle progression, we conclude that S-phase arrest occurs in developing cotton fiber.     

Mechanisms of 2''-deoxyguanosine toxicity in mouse T-lymphoma cells with purine nucleoside phosphorylase deficiency and resistance to inhibition of ribonucleotide reductase by dGTP.

Purine nucleoside phosphorylase (PNP; EC 2.4.2.1) deficiency is thought to cause T-lymphocyte depletion by accumulation of dG and dGTP, resulting in feedback inhibition of ribonucleotide reductase (RR; EC 1.17.4.1) and hence DNA synthesis. To test for additional toxic mechanisms of dG, we selected a double mutant of the mouse T-lymphoma S-49 cell line, dGuo-L, which is deficient in PNP and partially resistant to dGTP feedback inhibition of RR. The effects of dG on dGuo-L cells (concn. causing 50% inhibition, IC50 = 150 microM) were compared with those on the wild-type cells (IC50 = 30 microM) and the NSU-1 mutant with PNP deficiency only (IC50 = 15 microM). Fluorescence flow cytometry showed that equitoxic dG concentrations arrested wild-type and NSU-1 cells at the G1-S interface while allowing continued DNA synthesis in the S-phase, whereas the double mutant dGuo-L cells progressed through the cell cycle normally. dGuo-L cells accumulated high levels of dGTP in G1-phase, but not in S-phase cells, because of the utilization of dGTP for DNA synthesis and limited capacity to synthesize dGTP from dG. These results support the hypothesis that dG/dGTP toxicity occurs in the G1-phase or at the G1-S interface. Failure of dG to arrest the double mutant dGuo-L cells at the G1-S interface allows these cells to escape into S-phase, with an accompanying drop in dGTP levels. Thus the partial resistance of dGuo-L cells to dG toxicity may result from their shorter residence time in G1, allowing them to sustain higher dGTP levels. Hence RR inhibition by dGuo may not be the primary toxic mechanism in S-49 cells; rather, it may serve as an accessory event in dG toxicity by keeping the cells in the sensitive phase of the cell cycle. Among the possible targets of dG toxicity is RNA synthesis, which was inhibited at an early stage in dGuo-L cells.     

Flow cytometric analysis of cell cycle kinetics of anagen scalp hair correlated with plasma androgens in hirsutism

Cell kinetics of anagen scalp hair bulbs obtained from hirsute (n = 13) as well as healthy (n = 10) females were analysed by DNA-flow cytometry. The cell cycle kinetics in hirsutism revealed a significant increase of S-phase cells (10.2%) and a significant decrease of G0/1-phase cells (80.7%) compared with healthy females (S-phase 7.5%, G0/1 phase 86%). Moreover, dehydroepiandrosterone sulfate (DHEA-S) levels and cell cycle kinetics obtained from the hirsute females yielded a strong correlation between the height of S-phase percentages and DHEA-S values, whereas no correlation could be proved between testosterone levels and DNA-FCM data. Therefore, the weak androgen DHEA-S is assumed to be one hormonal factor influencing the cellular growth kinetics of hair bulbs in androgen-sensitive scalp areas.     

Cell cycle dependent distribution of proliferating cell nuclear antigen/cyclin and cdc2-kinase in mouse T-lymphoma cells

The aim of the present study was to investigate bromodeoxyuridine (BrdU) uptake and coordinated distribution of proliferating cell nuclear antigen (PCNA) and p34-cdc2-kinase, two important proteins involved in cell cycle regulation and progression. Flow cytometric analysis of marker proteins in freshly plated mouse T-lymphoma cells (Yac-1 cells), using fluorescein isothiocyanate (FITC)-labeled specific antibodies, showed PCNA distributed throughout the cell cycle with increased intensity in S-phase. PCNA is essential for cells to cycle through S-phase and its synthesis is initiated during late G1-phase before incorporation of BrdU and remains high during active DNA replication. The intensity of PCNA fluorescence increases with the duration of incubation after plating. The cdc2-kinase was detectable in all phases of the cell cycle and the G2-M-phase appears to have the maximum concentrations. The cell cycle analysis of high dose colcemid (2 μg/ml) treated Yac-1 cells showed an aneuploid or hypodiploid population. Although the G2-M-phase seems to be the dominating population in aneuploid cells, the concentrations of cdc2-kinase were variable in this phase of cell cycle. The colcemid treatment at 25 ng/ml arrested 96% of cells in S-phase and G2-M-phase, but PCNA expression was evident in a portion of the cell population in G2-M-phase. Although cells blocked in M-phase seem to have high levels of cdc2-kinase, colcemid renders them inactive. From these data, it appears that the down regulation and/or inactivation of cdc2-kinase could be responsible for the colcemid arrest of cells in M-phase.     

Cell cycle-dependent expression of phosphorylated histone H2AX: reduced expression in unirradiated but not X-irradiated G1-phase cells

Exposure of cells to ionizing radiation causes phosphorylation of histone H2AX at sites flanking DNA double-strand breaks. Detection of phosphorylated H2AX (gammaH2AX) by antibody binding has been used as a method to identify double-strand breaks. Although generally performed by observing microscopic foci within cells, flow cytometry offers the advantage of measuring changes in gammaH2AX intensity in relation to cell cycle position. The importance of cell cycle position on the levels of endogenous and radiation-induced gammaH2AX was examined in cell lines that varied in DNA content, cell cycle distribution, and kinase activity. Bivariate analysis of gammaH2AX expression relative to DNA content and synchronization by centrifugal elutriation were used to measure cell cycle-specific expression of gammaH2AX. With the exception of xrs5 cells, gammaH2AX level was approximately 3 times lower in unirradiated G(1)-phase cells than S- and G(2)-phase cells, and the slope of the G(1)-phase dose-response curve was 2.8 times larger than the slope for S-phase cells. Cell cycle differences were confirmed using immunoblotting, indicating that reduced antibody accessibility in intact cells was not responsible for the reduced antibody binding in G(1)-phase cells. Early apoptotic cells could be easily identified on flow histograms as a population with 5-10-fold higher levels of gammaH2AX, although high expression was not maintained in apoptotic cells by 24 h. We conclude that expression of gammaH2AX is associated with DNA replication in unirradiated cells and that this reduces the sensitivity for detecting radiation-induced double-strand breaks in S- and G(2)-phase cells.     

Cyclic AMP and theophylline enhance DNA synthesis in L cells stimulated with anti-actin IgG and [(IgG)2protein A]2 complex by recruiting cells into S-phase

Surface binding of anti-actin IgG alone or in a M_r = 716 000 [(IgG)₂Protein A]₂ complex results in a stimulation of DNA synthesis and cell growth in L cells. Cyclic-AMP (0.01–1.0 mM) added to such cell cultures augmented DNA synthesis as measured by incorporation of [³H]thymidine into DNA. Theophylline (0.1–1.0 mM), a phosphodiesterase inhibitor which prevents enzymatic breakdown of cAMP, had similar effects, but cGMP (0.01–1.0 μM) reversed the effects of cAMP and theophylline upon DNA synthesis. Analysis of the cell cycle by flow cytometry revealed that antibody produced a shift (7%) of cells from the G₁-phase to the S-phase (DNA-synthetic) of the cell cycle at 72 hr of incubation. Addition of cAMP (0.5 mM) to cell cultures, however, produced significant shifts of antibody stimulated cells from G₁-phase to S-phase at all time points measured, i.e., 24 (12%),48 (22%),72 hr (23%). Thus, antibody recruited cells into S-phase of the cell cycle and cAMP greatly augmented the effect. These observations suggest that the mechanism of activation of L cell growth by antibody to surface antigens involves a recruitment of cells into the DNA-synthetic phase and that the effect may be mediated by cAMP.     

The effect of bleomycin on rapidly proliferating epidermis. A comparative investigation using micro-flow fluorometry, H3Tdr incorporation and a stathmokinetic method (colcemid).

At different time intervals after injection of Bleomycin (BLM) th effect on several kinetic parameters of the hairless mouse epidermis stimulated to proliferate by previous adhesive tape stripping was measured. Micro-flow fluorometry was used to determine the relative number of cells in the various phases of the cell cycle (G1, S and G2). Tritiated thymidine was used to determine labelling indices and grain counts. Colcemid was used to observe the mitotic rate. An initial decrease followed by a subsequent significant increase compared to the non-BLM-treated controls was observed in all parameters studied except the mitotic rate, which remained lower than in the control animals during all 48 hours. The transit time of the cells through the S-phase was initially slightly prolonged, but thereafter it seemed to be shorter than that of the controls. BLM seems to provoke a partial blocking of cells in the G1 phase. When the block is released, a greater number of cells pass through the S phase in partial synchrony at a higher than normal speed. BLM induced a low mitotic rate which remained below the level of that of the normal animals after stripping, even though there obviously was a considerably higher influx of cells from the S phase to the G2 phase. This resulted in a subsequent accumulation of cells in the G2-phase. Thus, BLM has also a blocking effect on the G2-M boundary of the cell cycle. This inhibitory effect of BLM on the mitotic rate was shown to be independent of the effect of BLM on the DNA synthesis. BLM therefore seems to have complex influence on epidermal cell kinetics in vivo. Cells in G1-phase are partially and transiently blocked, but this block is soon released. These cells thereafter pass through the S-phase and pile up in the G2-phase, because BLM also blocks the passage of cells from the G2-phase to mitosis. The overall reduction in cell proliferation seen after BLM in vivo seems mainly to be due to the effect on the G2-M boundray of the cell cycle.     

Calmodulin and the cell cycle: Involvement in regulation of cell-cycle progression

Calmodulin levels are elevated twofold at late G1 and/or early S phases during the growth cycle of CHO-K1 cells. These levels are maintained throughout the remainder of the cell cycle until cytokinesis. The G1 daughter cells then contain half the intracellular calmodulin level found prior to cell division. Elevation of calmodulin at the G1-S boundary is independent of the length of G1, and the increase in calmodulin appears to be related to progression into S phase. The importance of calmodulin for G1-S progression is suggested by the ability of the anticalmodulin drug W13 to elicit specific and reversible progression delays into and through S phase.     

Heat production of mammalian cells at different cell-cycle phases

1. 1.|Heat production of Reuber H35 rat hepatoma cells and murine C1300 neuroblastoma cells at different stages of the cell cycle were measured microcalorimetrically.

2. 2.|Reuber H35 monolayer cultures of G1-phase cells and cells in S-phase were trypsinized, reincubated in suspension culture and immediately used for microcalorimetric measurements. There was a remrkable difference in the heat evolution of H35-cells in suspension derived from a monolayer culture of G1-phase cells and that of cells in S-phase of the cell cycle. Heat production of G1-cells was relatively continuous during the experiment, in contrast to S-phase cells that showed a decrease in heat production after an initial maximum.

3. 3.|Neuroblastoma cells synchronized by mitotic shake-off and cultured in suspension progressed through their cell cycle. They showed maximal heat production shortly before and durign mitosis.

Alterations of cell cycle kinetics and vimentin expression in TPA-treated, asynchronous MPC-11 mouse plasmacytoma cells

Vimentin expression throughout the cell cycle has been analyzed at the single-cell level in asynchronously growing MPC-11 cells using multiparameter flow cytometry. We have previously shown that these cells normally lack detectable amounts of intermediate filament proteins. In the presence of the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA), cell proliferation ceases and large quantities of the intermediate filament protein vimentin are synthesized and accumulate in most of the cells. In the present study, the short-term effect of TPA on distribution of cells within the cell cycle was a depletion in early S phase followed by a depletion in mid- and late S phase. In parallel, the G1-phase fraction increased significantly. In addition, a delay in progression through G2/M phase was observed. These data strongly suggest an inhibition of progression of cells through the cell cycle in G1 phase as the primary event on cell cycle kinetics elicited by TPA. Vimentin accumulation could be detected by flow cytometry as early as 2 h after TPA addition; at this time, the percentage of vimentin-positive cells was highest in G2/M phase. Prolonged TPA treatment induced vimentin accumulation in cells of all cell cycle phases. However, even at later times, the G1-phase population consisted of two subpopulations with low and high vimentin content, respectively. The fraction of cells which displayed a higher level of vimentin probably represents those G1-phase cells which previously had undergone cell division in the presence of TPA. Our data indicate that TPA-induced vimentin synthesis is regulated in a cell cycle-dependent manner and is maximally induced in cells which have passed a putative cell cycle restriction point in G1 phase.     

Prespore cell fate bias in G1 phase of the cell cycle in Dictyostelium discoideum

By generating a population of Dictyostelium cells that are in the G1 phase of the cell cycle we have examined the influence of cell cycle status on cell fate specification, cell type proportioning and its regulation, and terminal differentiation. The lack of observable mitosis during the development of these cells and the quantification of their cellular DNA content suggests that they remain in G1 throughout development. Furthermore, chromosomal DNA synthesis was not detectable these cells, indicating that no synthesis phase had occurred, although substantial mitochondrial DNA synthesis did occur in prespore cells. The G1-phase cells underwent normal morphological development and sporulation but displayed an elevated prespore/prestalk ratio of 5.7 compared to the 3.0 (or 3:1) ratio normally observed in populations dominated by G2-phase cells. When migrating slugs produced by G1-phase cells were bisected, each half could reestablish the 5.7 (or 5.7:1) prespore/prestalk ratio. These results demonstrate that Dictyostelium cells can carry out the entire developmental cycle in the G1 phase of the cell cycle and that passage from G2 into G1 phase is not required for sporulation. Our results also suggest that the population asymmetry provided by the distribution of cells around the cell cycle at the time of starvation is not strictly required for cell type proportioning. Finally, when developed together with G2-phase cells, G1-phase cells preferentially become prespore cells and exclude G2-phase cells from the prespore-spore cell population, suggesting that G1-phase cells have an advantage over G2-phase cells in executing the spore cell differentiation pathway.     

Effect of near ultraviolet and visible light on amoeba.

The near ultraviolet and visible light (VL) impinging at an intensity of 2-5 x 10(2) J s-1 m-2 for 2-5 h kills the mitotic and the early S-phase (0- to 15-min-old) amoebae. At the mid- and late S-period only a fraction of cells are killed by VL and G2 phase cells are quite resistant. Amoebae of all cell cycle stages show a delay in the first mitotic division. DNA synthesis, as measured by [3H]thymidine incorporation, is depressed in the VL-exposed early-S amoebae. A concurrent but temporary inhibition in [3H]leucine incorporation also occurs in these cells. However, no significant change in [3H]uridine incorporation has been found. To localize the site of lethal damage, nuclear transplantation studies were undertaken between the control amoebae and the amoebae treated with VL. The nucleus of a VL-exposed early S-phase cell recovers when transplanted immediately after VL exposure into an enucleate G2 cytoplasm but dies if grafted into an enucleat S-phase cytoplasm. The therapeutic effect of the G2 cytoplasm, although at a lower level, is also evident even when the treated early S-phase nucleus is implanted 20 h later, but not after 48 h, into the G2 cytoplasm. The amoeba cytoplasm shows resistance to VL-irradiation, can accept a control nucleus from any cell cycle stage, and function normally. The G2 nucleus also remains apparently unaffected to VL exposure and can survive when it is transfered to the control cytoplasm of any cell-cycle phase. All these findings are discussed in the light of the possible existence of a repair system against VL-induced damage in the G2-phase amoeba.     

Cell cycle-dependent effects of wortmannin on radiation survival and mutation

Wortmannin, a known radiation sensitizer, has been used in experiments with synchronized cells to compare its effect on radiation survival and mutation induction within the cell cycle. PL61 cells (CHO cells with an inactivated HPRT gene containing a single active copy of a bacterial gpt gene) were synchronized by mitotic selection. Wortmannin administered before gamma irradiation caused a greater sensitization in G(1)-phase cells relative to late S/G(2)-phase cells. Preferential radiosensitization of G(1)-phase cells by wortmannin sets a limit to the proposed use of wortmannin in radiation therapy, since, in contrast to normal tissues, tumors usually have high proportions of S-phase cells. Wortmannin increased mutation frequencies in both G(1)- and S/G(2)-phase cells. Interestingly, relative increases in radiation-induced mutations in G(1) and S/G(2) phases were comparable. The results are discussed in terms of the contributions of different repair modes in the production of mutations.     

Flow cytometric detection of mitotic cells using the bromodeoxyuridine/DNA technique in combination with 90 degrees and forward scatter measurements

Mitotic cells could be well discriminated from the cells in the G1-, S- and G2-phases of the cell cycle using pulse labeling of S-phase cells with bromodeoxy-uridine (BrdUrd) and staining of the cells for incorporated BrdUrd and total DNA content. Unlabeled G2- and M-phase cells could be measured as two separate peaks according to propidium iodide fluorescence. M-phase cells showed lower propidium iodide fluorescence emission compared to G2-phase cells. The fluorescence difference of M- and G2-phase cells was caused by the different thermal denaturation of their DNA. Best separation of M- and G2-phase cells was obtained after 30-50 min heat treatment at 95 degrees C. Mitotic index could be measured if no unlabeled S-phase cells were present in the cell culture. With additional measurements of 90 degree scatter and/or forward scatter signals, mitotic cells could be clearly discriminated from both unlabeled G2- and S-phase cells. The correct discrimination (about 99%) of mitotic cells from interphase cells was verified by visual analysis of the nuclear morphology after selective sorting. Unlabeled and labeled mitotic cells could be observed as pulse-labeled cells progressed through the cell cycle. We conclude that this modified BrdUrd/DNA technique using prolonged thermal denaturation and the simultaneous measurement of scatter signals may offer additional information especially in the presence of BrdUrd-unlabeled S-phase cells.