Radiation-induced progression delay in HeLa cells blocked in S phase by aphidicolin

The duration of the cell cycle in synchronous cultures of HeLa S3 cells that were either irradiated with 3.5 Gy of 220-kV X rays in mid-S phase or treated in early G1 or mid-S phase for several hours with 1 or 3 microM aphidicolin, or were subjected to both treatments, was measured by time-lapse cinemicrography. When compared with the generation time of untreated cells, the delay in cell progression with the combined treatment was found to be less than the sum of the delays with the individual treatments, but longer than the imposed delay caused by treatment with aphidicolin alone. Because recovery from potentially lethal radiation damage proceeds in the presence of aphidicolin, this finding suggests that a portion of the radiation-induced delay in cell progression may be associated with processes other than those that directly affect cell viability. It was also observed that the incidence of both spontaneous and radiation-induced sister-cell fusion is decreased in cultures incubated in the presence of aphidicolin.     

Lethal response of HeLa cells to x-irradiation in the latter part of the generation cycle.

The age-response for the killing of HeLa S3 cells by X-rays during the latter part of the generation cycle has been examined in detail. As synchronous cells move from the G1/S boundary through S phase, the relatively high sensitivity of late G1 cells gradually decreases; minimum sensitivity is reached in mid-S and maintained during the remainder of that phase. The response of cells as they progress from S to the point in G2 at which they are temporarily arrested by radiation (or by inhibitors of protein synthesis) was measured in populations free of both S phase cells and late G2 cells that had passed the arrest point: cells retain their high resistance from early G2 up to the arrest point. The response of G2 cells that have passed the arrest point before being irradiated was examined by exposing randomly growing cultures to X-rays and collecting cells periodically thereafter, as they entered mitosis. Survival values very close to those of sensitive mitotic cells were found in the 2 h period after irradiation during which unarrested cells continued to reach mitosis. Values typical of lateS/early G2 were found only after cells that had been arrested began arriving at mitosis. Thus, HeLa S3 cell undergo an abrupt increase in sensitivity at or near the arrest point. The sensitivity to a second irradiation of cells arrested in G2 by a conditioning X-ray dose increases rapidly in the early part of the arrest period.     

Cell progression after selective irradiation of DNA during the cell cycle

Chinese hamster ovary cells were labeled with [125I]iododeoxyuridine (125IUdR, 0.1184 MBq/ml for 20 min) and the labeled mitotic cells were collected by selective detachment ("mitotic shake off"). The cells were pooled, plated into replicate flasks, and allowed to progress through the cell cycle. At several times after plating, corresponding to G1, S, late S, and G2 plus M, cells were cooled to stop cell cycle progression and to facilitate accumulation of 125I decays. Evaluation of cell progression into the subsequent mitosis indicated that accumulation of additional 125I decays during G1 or S phase was eight to nine times less effective in inducing progression delay than decays accumulated during G2. The results support our previous hypothesis that DNA damage per se is not responsible for radiation-induced progression delay. Instead, 125I-labeled DNA appears to act as a source of radiation that associates during the G2 phase of the cell cycle with another radiosensitive structure in the cell nucleus, and damage to the latter structure by overlap irradiation is responsible for progression delay (M. H. Schneiderman and K. G. Hofer, Radiat. Res. 84, 462-476 (1980].     

Evidence for a role of heat-shock proteins in proliferation after heat treatment of synchronized mouse neuroblastoma cells

A role for heat-shock proteins (HSPs) in proliferation after heat treatment was considered in synchronized mouse neuroblastoma cells. For this purpose enhancement of HSP synthesis after heat treatment was inhibited by actinomycin D and the effect of this on cell cycle progression into mitosis and on cell survival was studied both in thermoresistant G1- and in thermosensitive late S/G2-phase cells. In G1-phase cells expression of basal and heat-induced HSP synthesis was the same as that in late S/G2-phase cells, which suggests that regulation of thermoresistance throughout the cell cycle is not directly linked with HSP synthesis. The synthesis of HSP36, HSP68, and HSP70 was enhanced after a 30-min treatment at 41-43 degrees C. Increase of HSP synthesis after heat shock was partly suppressed by the presence of 0.1 microgram/ml actinomycin D during heat treatment, while 0.2 micrograms/ml prevented enhancement of HSP synthesis completely. Suppression of heat-induced HSP synthesis by actinomycin D had the same concentration dependency in G1- and late S/G2-phase cells. Actinomycin D potentiated induction of mitotic delay by heat treatment (30 min, 42.5 degrees C) but only under conditions where it actually inhibited heat-induced enhancement of HSP synthesis. Heat-induced cell killing was also potentiated by actinomycin D. The potentiating effect of actinomycin D on heat-induced mitotic delay and on heat-induced cell killing was more pronounced in G1-phase cells than in late S/G2-phase cells. These results give evidence for a role of HSPs in the resumption of proliferation after heat treatment and suggest that heated G1-phase cells are more dependent on HSP synthesis for recovery of proliferation after heat treatment than heated late S/G2-phase cells.     

Inhibition of S/G2 phase CDK4 reduces mitotic fidelity

Cyclin-dependent kinase 4 (CDK4)/cyclin D has a key role in regulating progression through late G(1) into S phase of the cell cycle. CDK4-cyclin D complexes then persist through the latter phases of the cell cycle, although little is known about their potential roles. We have developed small molecule inhibitors that are highly selective for CDK4 and have used these to define a role for CDK4-cyclin D in G(2) phase. The addition of the CDK4 inhibitor or small interfering RNA knockdown of cyclin D3, the cyclin D partner, delayed progression through G(2) phase and mitosis. The G(2) phase delay was independent of ATM/ATR and p38 MAPK but associated with elevated Wee1. The mitotic delay was because of failure of chromosomes to migrate to the metaphase plate. However, cells eventually exited mitosis, with a resultant increase in cells with multiple or micronuclei. Inhibiting CDK4 delayed the expression of the chromosomal passenger proteins survivin and borealin, although this was unlikely to account for the mitotic phenotype. These data provide evidence for a novel function for CDK4-cyclin D3 activity in S and G(2) phase that is critical for G(2)/M progression and the fidelity of mitosis.     

Modulation of functional and optimal (Na+-K+)ATPase activity during the cell cycle of neuroblastoma cells

Functional and optimal activities of the (Na+-K+)ATPase, as determined by ouabain-sensitive K+ influx in intact cells and ATP hydrolysis in cell homogenates respectively, have been measured during the cell cycle of neuroblastoma (clone Neuro-2A) cells. The cells were synchronized by selective detachment of mitotic cells. The ouabain-sensitive K+ influx decreased more than fourfold from 1.62 +/- 0.11 nmoles/min/10(6) cells to 0.36 +/- 0.25 nmoles/min/10(6) cells on passing from mitosis to early G1 phase. On entry into S phase a transient sixfold increase to 2.07 +/- 0.30 nmoles/min/10(6) cells was observed, followed by a rapid decline, after which the active K+ influx rose again steadily from 1.03 +/- 0.25 nmoles/min/10(6) cells in early S phase to 2.10 +/- 0.92 nmoles/min/10(6) cells just prior to the next mitosis. The ouabain-insensitive component rose linearly through the cycle in the same manner as the protein content/cell. Combining total K+ influx values with efflux data obtained previously showed that net loss of K+ occurred with transition from mitosis to G1 phase while net accumulation occurred with entry into S. Throughout mid-S phase net K+ flux was virtually zero, but a large net influx occurred again just before the next mitosis. The (Na+-K+)ATPase activity measured in cell homogenates decreased rapidly from mitosis to G1 phase and increased steadily throughout S phase, but the transient activation on entry into S phase was not observed. Complete inhibition of the (Na+-K+)ATPase mediated K+ influx by ouabain (5 mM) prevents the cells from entering S phase, while partial inhibition by lower concentrations of ouabain (0.2 and 0.5 mM; km = 0.17 mM) causes partial blockage in G1 and, to a lesser extent, a reduced rate of progression through the rest of the cell cycle. We conclude that the transient increase in (Na+-K+)ATPase mediated K+ influx at the G1/S transition is a prerequisite for entry into S phase, while maintenance of adequate levels of K+ influx is necessary for normal rate of progression through the rest of the cell cycle.     

Computerized video time-lapse (CVTL) analysis of cell death kinetics in human bladder carcinoma cells (EJ30) X-irradiated in different phases of the cell cycle

The purpose of this study was to quantify the modes and kinetics of cell death for EJ30 human bladder carcinoma cells irradiated in different phases of the cell cycle. Asynchronous human bladder carcinoma cells were observed in multiple fields by computerized video time-lapse (CVTL) microscopy for one to two cell divisions before irradiation (6 Gy) and for 6-11 days afterward. By analyzing time-lapse movies collected from these fields, pedigrees were constructed showing the behaviors of 231 cells irradiated in different phases of the cell cycle (i.e. at different times after mitosis). A total of 219 irradiated cells were determined to be non-colony-forming over the time spans of the experiments. In these nonclonogenic pedigrees, cells died primarily by necrosis either without entering mitosis or over 1 to 10 postirradiation generations. A total of 105 giant cells developed from the irradiated cells or their progeny, and 30% (31/105) divided successfully. Most nonclonogenic cells irradiated in mid-S phase (9-12 h after mitosis) died by the second generation, while those irradiated either before or after this short period in mid-S phase had cell deaths occurring over one to nine postirradiation generations. The nonclonogenic cells irradiated in mid-S phase also experienced the longest average delay before their first division. Clonogenic cells (11/12 cells) divided sooner after irradiation than the average nonclonogenic cells derived from the same phase of the cell cycle. The early death and long division delay observed for nonclonogenic cells irradiated in mid-S phase could possibly result from an increase in damage induced during the transition from the replication of euchromatin to the replication of heterochromatin.     

Effects of exogenous cyclic AMP on growth characteristics and radiation response of Reuber H35 hepatoma cells

Reuber H35 rat hepatoma cells, clone KRC, were used to study the effect of cyclic AMP on radiation-induced cell death. Treatment of logarithmically growing cultures with 0.5 mM cAMP for 17 hr prior to irradiation resulted in a decreased cell survival. Similar results were obtained with cultures irradiated after treatment with Bt2cAMP. Treatment of H35 cells with cAMP or Bt2cAMP caused inhibition of their proliferation and resulted in an accumulation of cells in early S phase and a depletion of G2-phase cells. In synchronized cultures cells were relatively radioresistant during their S phase. In addition to single-dose treatment with X rays, the effect of Bt2cAMP on radiation-induced cell death was studied during fractionated irradiation with 2.5 Gy per day. This fractionated irradiation resulted in a dose-reduction factor of 1.6 at the 10% survival level and a 10-fold decrease in the surviving cell population due to the cooperative effects of Bt2cAMP on growth rate and radiation survival. The effect of cAMP on radiation-induced mitotic delay was also studied. It appeared that whereas cAMP had no effect on the progression of G2 cells into mitosis, it prevented cells from recovery from the X-ray mitotic delay in G2.     

Staurosporine overrides checkpoints for mitotic onset in BHK cells.

Under normal conditions, mammalian cells will not initiate mitosis in the presence of either unreplicated or damaged DNA. We report here that staurosporine, a tumor promoter and potent protein kinase inhibitor, can uncouple mitosis from the completion of DNA replication and override DNA damage-induced G2 delay. Syrian hamster (BHK) fibroblasts that were arrested in S phase underwent premature mitosis at concentrations as low as 1 ng/ml, with maximum activity seen at 50 ng/ml. Histone H1 kinase activity was increased to approximately one-half the level found in normal mitotic cells. Inhibition of protein synthesis during staurosporine treatment blocked premature mitosis and suppressed the increase in histone H1 kinase activity. In asynchronously growing cells, staurosporine transiently increased the mitotic index and histone H1 kinase activity but did not induce S phase cells to undergo premature mitosis, indicating a requirement for S phase arrest. Staurosporine also bypassed the cell cycle checkpoint that prevents the onset of mitosis in the presence of damaged DNA. The delay in mitotic onset resulting from gamma radiation was reduced when irradiation was followed immediately by exposure to 50 ng/ml of staurosporine. These findings indicate that inhibition of protein phosphorylation by staurosporine can override two important checkpoints for the initiation of mitosis in BHK cells.     

Haspin inhibition delays cell cycle progression through interphase in cancer cells

Haspin (Haploid Germ Cell-Specific Nuclear Protein Kinase) is a serine/threonine kinase pertinent to normal mitosis progression and mitotic phosphorylation of histone H3 at threonine 3 in mammalian cells. Different classes of small molecule inhibitors of haspin have been developed and utilized to investigate its mitotic functions. We report herein that applying haspin inhibitor CHR-6494 or 5-ITu at the G1/S boundary could delay mitotic entry in synchronized HeLa and U2OS cells, respectively, following an extended G2 or the S phase. Moreover, late application of haspin inhibitors at S/G2 boundary is sufficient to delay mitotic onset in both cell lines, thereby, indicating a direct effect of haspin on G2/M transition. A prolonged interphase duration is also observed with knockdown of haspin expression in synchronized and asynchronous cells. These results suggest that haspin can regulate cell cycle progression at multiple stages at both interphase and mitosis.     

Effect of caffeine on radiation-induced mitotic delay: delayed expression of G2 arrest

In the presence of 5 mM caffeine, irradiated (1.5 Gy) S and G2 cells progressed to mitosis in register and without arrest in G2. Caffeine (5 mM) markedly reduced mitotic delay even after radiation doses up to 20 Gy. When caffeine was removed from irradiated (1.5 Gy) and caffeine-treated cells, a period of G2 arrest followed, similar in length to that produced by radiation alone. The arrest expressed was independent of the duration of the caffeine treatment for exposures up to 3 hr. The similarity of the response to the cited effects of caffeine on S-phase delay suggests a common basis for delay induction in S and G2 phases.     

Chinese hamster ovary cell mitosis and its response to ionizing radiation: a morphological analysis of the living cell

Repeated microscopic observations of exponentially growing Chinese hamster ovary cells were made and the times and mitotic stages were recorded in control and irradiated cultures at 37 degrees C. As determined by autoradiography, the time from the end of S phase to early prophase (the G2 phase) was 46 min, to breakdown of the nuclear envelope was 91 min, and to restoration of the nuclear envelope was 116 min. The time spent in morphologically distinguishable phases of mitosis and the effects of 0.5, 1.0, 1.5, 2.0, and 4.0 Gy of gamma or X radiation on cells at each phase were determined. Affected cells were found to be delayed without or with reversion to an earlier mitotic stage before recovering and advancing through mitosis. Cells were timed in the five steps comprising delay with reversion: inertia, cessation I, regression, cessation II, and reprogression. No cells treated in late prophase, i.e., within 8-10 min of nuclear envelope breakdown, were delayed by the doses used; therefore the critical or transition point must be situated in middle prophase. Cells irradiated in this stage were not delayed by 0.5 or 1.0 Gy, but suffered a dose-dependent delay with or without reversion after 1.5, 2.0, and 4.0 Gy. Cells irradiated in early prophase and very late interphase responded similarly, but a greater percentage of the latter reverted.     

细胞松弛素B对多头绒泡菌有丝分裂的影响

将细胞松弛素Ｂ（Ｃｙｔｏｃｈａｌａｓｉｎ Ｂ,ＣＢ）注入同步化的多头绒泡菌原质团,在光镜和电镜下跟踪观察有有丝分裂进程,发现多头绒泡菌进入有丝分裂的时间推迟,与未经ＣＢ处理的样品相比,在Ｓ期注入ＣＢ的样品进入有丝分裂的时间推迟３５ｍｉｎ,在Ｇ２早期注入ＣＢ的样品则推迟２０ｍｉｎ;在Ｇ２中期注入的推迟４５ｍｉｎ;在Ｇ２晚期注入的推迟６０ｍｉｎ,说明抑制肌动蛋白的功能则使有丝分裂受到明显影响。ＣＢ处理     

Method for probing cells in radiation-induced G2 arrest: demonstration of potentially lethal damage repair

Chinese hamster ovary cells were arrested in the G2 phase of the cell cycle by X-irradiation. When subsequently treated with 5 mM caffeine the arrested population progressed into mitosis as a synchronous cohort where it was harvested by mitotic cell selection. This procedure provides a means to isolate cell populations treated in G2, for the investigation of G2 arrest. Comparisons were made of the number of cells retrieved from G2 arrest with the number suffering arrest, as determined by flow cytometry and by matrix algebraic simulations of irradiated cell progression. The retrieved population was not significantly less than expected for doses up to 3.5 Gy, indicating that the retrieval process does not favour the isolation of any population subset below this dose. Cell populations retrieved from arrest at varying intervals (0-3 h) after irradiation (0-3.5 Gy) showed an increase in survival with increase in interval, consistent with repair of potentially lethal damage. The repair curves (surviving fraction vs time) were each described by a single exponential. G2 cells that were brought to mitosis without a period of arrest exhibited the same radiation response as cells irradiated in mitosis.     

A change in the oxygen effect throughout the cell-cycle of human cells of the line NHIK 3025 cultivated in vitro.

NHIK 3025 cells were synchronized by repeated mitotic selection. The S-phase was determined by 3H-thymidine incorporation and scintillation counting. By comparing the age-response surves of aerobic cells irradiated with 500 rad with those of extremely hypoxic (less than4 p.p.m. O2) cells irradiatedwith 1500 rad, it was found that the sensitizing effect of oxygen was not constant throuhgout the cycle. It was significantly higher in S, G2 and mitosis than in G1. No significant sensitizing effect of 120 p.p.m. O2 (compared with less than4 p.p.m.O2) was found on cells in G1 when the cells were irradiated with 1500 rad. In S, G2 and mitosis, however, the sensitizing effect of oxygen at 120 p.p.m. is considered to be significant. Experiments performed with cells irradiated with 2000 rad incontact with either less than4 p.p.m. O2 or 80 p.p.m. O2 showed the same trend, little sensitizing effect in G1 and higher in S, G2 andmitosis. Dose-response curves for cells in mid-G1 and mid-S under aerobic and extremely hypoxic conditions were well fitted by the formula S=exp (-alphaD-betaD2). From the dose-response curves it was conculded that the change in the sensitizing effect of oxygen throughout the cell-cycle only appeared for low doses (in the dose region where alpha dominates). The sensitizing effect of oxygen on cells in mid-G1 was found to be increasing with increasing dose.     

Role of inhibitory CDC2 phosphorylation in radiation-induced G2 arrest in human cells

The activity of the mitosis-promoting kinase CDC2-cyclin B is normally suppressed in S phase and G2 by inhibitory phosphorylation at Thr14 and Tyr15. This work explores the possibility that these phosphorylations are responsible for the G2 arrest that occurs in human cells after DNA damage. HeLa cell lines were established in which CDC2AF, a mutant that cannot be phosphorylated at Thr14 and Tyr15, was expressed from a tetracycline-repressible promoter. Expression of CDC2AF did not induce mitotic events in cells arrested at the beginning of S phase with DNA synthesis inhibitors, but induced low levels of premature chromatin condensation in cells progressing through S phase and G2. Expression of CDC2AF greatly reduced the G2 delay that resulted when cells were X- irradiated in S phase. However, a significant G2 delay was still observed and was accompanied by high CDC2-associated kinase activity. Expression of wild-type CDC2, or the related kinase CDK2AF, had no effect on the radiation-induced delay. Thus, inhibitory phosphorylation of CDC2, as well as additional undefined mechanisms, delay mitosis after DNA damage.     

The Golgi stack reassembles during telophase before arrival of proteins transported from the endoplasmic reticulum

HeLa cells arrested in prometaphase were pulse-labeled with [35S]methionine and chased in the absence of nocodazole to allow passage through mitosis and into G1. Transport of histocompatibility antigen (HLA) molecules to the medial- and trans-Golgi cisternae was measured by monitoring the resistance to endoglycosidase H and the acquisition of sialic acid residues, respectively. Transport to the plasma membrane was measured using neuraminidase to remove sialic acid residues on surface HLA molecules. The half-time for transport to each of these compartments was about 65-min longer in cells progressing out of mitosis than in G1 cells. This delay was only 5-min longer than the half-time for the fall in histone H1 kinase activity suggesting that inactivation of the mitotic kinase triggers the resumption of protein transport. The half-time for reassembly of the Golgi stack, measured using stereological procedures, was also 65 min, suggesting that both transport and reassembly are triggered at the same time. However, since reassembly was complete within 5 min, whereas HLA took 25 min to reach the medial-cisterna, we can conclude that the Golgi stack has reassembled by the time HLA reaches it.     

X-irradiation--induced changes in the progression of type B spermatogonia and preleptotene spermatocytes

In response to induced DNA damage, proliferating cells arrest in their cell cycle or go into apoptosis. Ionizing radiation is known to induce degeneration of mammalian male germ cells. The effects on cell-cycle progression, however, have not been thoroughly studied due to lack of methods for identifying effects on a particular cell-cycle phase of a specific germ cell type. In this study, we have utilized the technique for isolation of defined segments of seminiferous tubules to examine the cell-cycle progression of irradiated rat mitotic (type B spermatogonia) and meiotic (preleptotene spermatocytes) G1/S cells. Cells irradiated as type B spermatogonia in mitotic S phase showed a small delay in progression through meiosis. Thus, it seems that transient arrest in the progression can occur in the otherwise strictly regulated progression of germ cells in the seminiferous epithelium. Contrary to the arrest observed in type B spermatogonia and in previous studies on somatic cells, X-irradiation did not result in a G1 delay in meiotic cells. This lack of arrest occurred despite the presence of unrepaired DNA damage that was measured when the cells had progressed through the two meiotic divisions.     

Effects of monocerin on cell cycle progression in maize root meristems synchronized with aphidicolin

Summary Monocerin is a benzopyran fungal toxin with broad activity on plants, fungi and insects. Its effect upon cell cycle progression has been analyzed in maize roots. Meristematic cells were synchronized by treatment with aphidicolin. Flow cytometric DNA analysis and mitotic indices indicated durations of 1.5 h, 5 h, 2 h and 1 h for respectively G1, S, G2 and M phases of the normal cell cycle at 25°C. Treatment of these synchronized meristems with 0.5 mM monocerin during release after an aphidicolin block produced a short delay in S phase and then a more important delay (about 2.5 h) in entry into mitosis. Treatments for similar durations (3 h) during progression through the cycle revealed two periods of action of monocerin. The first appears to be mid to late S and the second one G2, before the transition point between G2 and M. Action on either one of these target periods could lead to a delay in the G2/M transition, but these two responses did not appear to be additive.Abbreviations APH Aphidicolin - CV Coefficient of variation - DAPI Diamidinophenylindole - DMSO Dimethyl sulfoxide - EDTA Ethylenediaminetetraacetic acid - HPLC High pressure liquid chromatography - MI Mitotic index - SD Standard deviation - UV ultraviolet light