UV-B辐射对拟南芥细胞周期G1/S期转变的影响

以同步化的拟南芥(Arabidopsis thaliana)根尖细胞为材料, 研究了UV-B辐射对拟南芥细胞周期G1/S期转变的影响。细胞周期荧光显微图像分析表明, UV-B辐射延缓了拟南芥根尖细胞G1/S期的转变。基因表达的RT-PCR检测表明, 在UV-B辐射下G1/S期转变的标志基因Histone H4和E2Fa的表达受抑制, 而G1/S期转变的抑制因子KRP2基因表达则受诱导上调。单细胞凝胶电泳检测结果表明, UV-B辐射引起拟南芥根尖细胞内积累大量的环丁烷嘧啶二聚体。以上结果表明, UV-B辐射抑制植物的生长可能受细胞周期和DNA损伤调控。     

Regulation of late G1/S phase transition and APC Cdh1 by reactive oxygen species

Proliferating cells have a higher metabolic rate than quiescent cells. To investigate the role of metabolism in cell cycle progression, we examined cell size, mitochondrial mass, and reactive oxygen species (ROS) levels in highly synchronized cell populations progressing from early G1 to S phase. We found that ROS steadily increased, compared to cell size and mitochondrial mass, through the cell cycle. Since ROS has been shown to influence cell proliferation and transformation, we hypothesized that ROS could contribute to cell cycle progression. Antioxidant treatment of cells induced a late-G1-phase cell cycle arrest characterized by continued cellular growth, active cyclin D-Cdk4/6 and active cyclin E-Cdk2 kinases, and inactive hyperphosphorylated pRb. However, antioxidant-treated cells failed to accumulate cyclin A protein, a requisite step for initiation of DNA synthesis. Further examination revealed that cyclin A continued to be ubiquitinated by the anaphase promoting complex (APC) and to be degraded by the proteasome. This antioxidant arrest could be rescued by overexpression of Emi1, an APC inhibitor. These observations reveal an intrinsic late-G1-phase checkpoint, after transition across the growth factor-dependent G1 restriction point, that links increased steady-state levels of endogenous ROS and cell cycle progression through continued activity of APC in association with Cdh1.     

Cytotoxic effects of dexamethasone restricted to noncycling,early G1-phase cells of L1210 leukemia

The cytostatic and cytolytic effects of dexamethasone were studied as functions of cell cycle position in mouse L1210 leukemia cells. To this end, the cells were separated according to size by sedimentation at unit gravity in a specially designed sedimentation chamber. The fractions were analyzed by radioautography and flow cytophotometry. The size-distributions obtained by 1g sedimentation coincided with cell-cycle age distribution. With increasing fraction number, samples highly enriched in G1, S, and G2/M cells, respectively were obtained: the smallest cells being in early G1 and the largest in mitosis. In the presence of dexamethasone (10^?6-10^?5 M), growth slowed down after a few cell cycles and the cells accumulated in early G1 phase. Lytic cell kill by continued exposure to the drug was confined to the fractions containing the small, early G1-phase cells. These fractions were also enriched in noncycling cells that were not labeled by prolonged exposure to ³H-thymidine. After removal of dexamethasone, the cells in S and G2/M phase completed cell cycle traverse but were retarded again in the G1 and early S phase of the next division cycle. The data suggest a memory effect for previous drug exposure. It is concluded that the cytostatic and cytolytic effects of dexamethasone are separate, though not unrelated events. Cytolysis is confined to the noncycling cells that in untreated populations can exit from the dividing compartment during a transitional phase of about 60 minutes subsequent to mitotic division. The cytostatic effects potentiate cytolysis by accumulating the cells in the early G1 phase and thus increasing the probability of their transit to the G0 compartment, sensitive for drug-mediated cytolysis.     

12-O-tetradecanoylphorbol-13-acetate induces transient cell cycle arrest in G1 and G2 in metastatic melanoma cells: inhibition of phosphorylation of p34cdc2.

The growth of Demel human metastatic melanoma cells was inhibited by 12-O-tetradecanoylphorbol-13-acetate (TPA) and other nonphorbol tumor promoters including palytoxin and okadaic acid. Using flow cytometry, we have demonstrated that the cells arrested growth in G1 and G2 phases of the cell cycle. Detailed analysis of the kinetics of the growth arrest in unsynchronized cells showed that (a) the growth arrest was transient and peaked 16-20 h following addition of TPA; (b) effects of TPA on cell growth began within 1-2 h after the addition; and (c) cells completed S phase and arrested in G2. In addition, TPA induced a pronounced morphological change, which peaked by 1 h and gradually subsided over 24 h. In populations of cells synchronized in G1 using lovastatin, (a) addition of TPA blocked the onset of DNA synthesis up to the end of G1; (b) the lag between addition of the drug and onset of DNA synthesis was less than 30 min; and (c) addition of TPA at the end of G1 prevented the increased phosphorylation of p34cdc2, as determined by immunoprecipitation. The experiments reported here show that TPA transiently blocked the proliferation of Demel melanoma cells at the G1-S border and in G2, thus preventing cells from progressing through the cell cycle. These experiments suggest that pathways involving protein kinase C interact with and rapidly alter the molecular pathways involving p34cdc2 which regulate the onset of DNA synthesis and the G2-M transition.     

Bcl-2 over-expression reduces growth rate and prolongs G1 phase in continuous chemostat cultures of hybridoma cells.

Recent studies have suggested that Bcl-2 can affect cell cycle re-entry by inhibiting the transition from G0/G1 to S phase. In this study, we have taken a novel route to the study of the relationship between Bcl-2 expression and cell cycle progression. Continuous cultures of pEF (control) and Bcl-2 transfected murine hybridoma cells were operated at a range of dilution rates from 0.8 day-1 down to 0.2 day-1. The specific growth rate of the pEF cell line was the same as the dilution rate down to a value of 0.6 day-1. However, as the dilution rate was reduced stepwise to 0.2 day-1, the growth rate levelled-off at approximately 0.55 day-1 and this coincided with a fall in culture viability. By contrast, the specific growth rate of the Bcl-2 transfected cell line followed the dilution rate down to a value of 0.3 day-1 with high levels of cell survival. At high dilution rates, the cell cycle distributions were very similar for both cell lines. However, the distributions diverged as the dilution rate was reduced and, at a rate of 0.2 day-1, the percentage of G1 cells in the Bcl-2 culture was 80%, compared to only 56% in the pEF cell population. This corresponded with a greater extension in the duration of the G1 phase in the Bcl-2 cells, which was 1.7 days at the lowest dilution rate tested, compared to only 0.6 day for the pEF cell line. The durations of the G2/M and S phases remained constant throughout the culture. The maximum doubling time was 1.2 days in the pEF culture compared to 2.3 days in the Bcl-2 culture. Analysis of amino acids, ammonia and lactate concentrations indicated that the observed effects on cell cycle dynamics were probably not due to differences in the culture environment. It is suggested that the expression of Bcl-2 can effect G1 to S phase transition in continuously cycling cells, but this is only apparent at suboptimal growth rates.     

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.     

G1/S control of anchorage-independent growth in the fibroblast cell cycle

We have developed methodology to identify the block to anchorage-independent growth and position it within the fibroblast cell cycle. Results with NRK fibroblasts show that mitogen stimulation of the G0/G1 transition and G1-associated increases in cell size are minimally affected by loss of cell anchorage. In contrast, the induction of G1/S cell cycle genes and DNA synthesis is markedly inhibited when anchorage is blocked. Moreover, we demonstrate that the anchorage-dependent transition maps to late G1 and shortly before activation of the G1/S p34cdc2-like kinase. The G1/S block was also detectable in NIH-3T3 cells. Our results: (a) distinguish control of cell cycle progression by growth factors and anchorage; (b) indicate that anchorage mediates G1/S control in fibroblasts; and (c) identify a physiologic circumstance in which the phenotype of mammalian cell cycle arrest would closely resemble Saccharomyces cerevisiae START. The close correlation between anchorage independence in vitro and tumorigenicity in vivo emphasizes the key regulatory role for G1/S control in mammalian cells.     

Human cytomegalovirus infection inhibits G1/S transition.

Cell cycle progression during cytomegalovirus infection was investigated by fluorescence-activated cell sorter (FACS) analysis of the DNA content in growth-arrested as well as serum-stimulated human fibroblasts. Virus-infected cells maintained in either low (0.2%) or high (10%) serum failed to progress into S phase and failed to divide. DNA content analysis in the presence of G1/S (hydroxyurea and mimosine) and G2/M (nocodazole and colcemid) inhibitors demonstrated that upon virus infection of quiescent (G0) cells, the cell cycle did not progress beyond the G1/S border even after serum stimulation. Proteins which normally indicate G1/S transition (proliferating cell nuclear antigen [PCNA]) or G2/M transition (cyclin B1) were elevated by virus infection. PCNA levels were induced in infected cells and exhibited a punctate pattern of nuclear staining instead of the diffuse pattern observed in mock-infected cells. Cyclin B1 was induced in infected cells which exhibited a G1/S DNA content by FACS analysis, suggesting that expression of this key cell cycle function was dramatically altered by viral functions. These data demonstrate that contrary to expectations, cytomegalovirus inhibits normal cell cycle progression. The host cell is blocked prior to S phase to provide a favorable environment for viral replication.     

Low and High Concentrations of the Topo II Inhibitor Daunorubicin in NIH3T3 Cells: Reversible G2/M Versus Irreversible G1 and S Arrest

Daunorubicin (DNR) blocks the cell cycle by interfering with synthesis and repair of DNA. In both drug-sensitive 3T3 cells, and drug-resistant 3T3 cells, NIH-MDR-6815, (created by transfection with a human MDR1 cDNA), low concentrations of DNR (up to 80 ng/ml in sensitive cells, 1600 ng/ml in resistant cells), cells initially slowed S-phase progression for 2 to 3 hours, but the treated cells then continued in progression at a steady rate, close to that of untreated cells and accumulated in G2/M. The 2 to 3 h lag period represents the time taken for fully establishing the G2/M block. The time required to bring about cessation of proliferation is the sum of this lag period and the time taken to travel through the cell cycle. This low concentration effect is cytostatic, and fully reversible on washing out the daunorubicin. At higher drug concentrations (above 160 ng/ml in sensitive cells, 3200 ng/ml in resistant cells) the cells became blocked in both G1 and S, and did not reach G2/M. The high concentration effect was cytotoxic and irreversible, and was followed by cell death. Only cells that were in S phase were subject to this block in S, since cells that had accumulated in G2/M by using a low concentration (60 ng/ml DNR for 20 h) were not blocked in S, and did not die, when subsequently treated with high drug concentrations (320 ng/ml, 30 h). The low concentration effect occurred at the same maximal rate (4 %/h) in sensitive or resistant cells, but the external drug concentration required to produce half the maximal rate was, appropriately, twenty-fold higher in the resistant cells (20 ng/ml and 400 ng/ml, respectively).     

卡铂通过抑制ERK1/2通路诱导人卵巢癌细胞S和G0/G1期阻滞

卡铂(carboplatin, CBP)是一种抗肿瘤活性较强的化疗药物, 通过诱导细胞周期阻滞抑制肿瘤细胞生长, 但其诱导细胞周期阻滞的报告不甚一致. 本研究探索卡铂对卵巢癌HO-8910细胞生长及细胞周期进程的影响. MTS结果显示, 卡铂以浓度和时间依赖方式抑制卵巢癌HO-8910细胞生长, 联合使用ERK1/2通路抑制剂PD98059可使卡铂抗卵巢癌细胞增殖作用增强. 采用Giemsa染色法观察到, 卡铂与PD98059单用或联用均能致卵巢癌细胞发生明显的形态学变化. 流式细胞术检测细胞周期发现, 随卡铂浓度的增高, S期阻滞作用增强; 抑制ERK1/2通路可拮抗卡铂对HO-8910细胞S期阻滞作用, 增加G1期阻滞作用, 而对G2/M期细胞影响不明显. Western印迹结果显示, 随卡铂浓度的增高, p-ERK1/2、Cdc2(Y15)和p Cdc2(T161)的表达逐渐升高, Cyclin E1和Cyclin B1的表达逐渐降低; 抑制ERK1/2通路可将卡铂上调,p-ERK1/2和p-Cdc2(T161)的作用反转为下调作用, 上调Cdc2(Y15)的表达受阻, 抑制Cyclin B1的下调作用, 促进Cyclin E1的下调作用. 本研究结果提示, 卡铂通过抑制ERK1/2激活, 诱导人卵巢癌HO-8910细胞S和G1期阻滞, 抑制卵巢癌细胞生长.     

Low and high concentrations of the topo II inhibitor daunorubicin in NIH3T3 cells: reversible G2/M versus irreversible G1 and S arrest

Daunorubicin (DNR) blocks the cell cycle by interfering with synthesis and repair of DMA. In both drug-sensitive 3T3 cells and drug-resistant 3T3 cells (NIH-MDR-6185, created by transfection with a human MDR1 cDNA), low concentrations of DNR (up to 80 ng/ml in sensitive cells, 1600 ng/ml in resistant cells) initially slowed S-phase progression for 2 to 3 hours, but the treated cells then continued in progression at a steady rate, close to that of untreated cells, and accumulated in G(2)/M. The 2 to 3 h lag period represents the time taken for fully establishing the G(2)/M block. The time required to bring about cessation of proliferation is the sum of this lag period and the time taken to travel through the cell cycle. This low concentration effect is cytostatic, and fully reversible on washing out the daunorubicin. At higher drug concentrations (above 160 ng/ml in sensitive cells, 3200 ng/ml in resistant cells) the cells became blocked in both G] and S, and did not reach G(2)/M. The high concentration effect was cytotoxic and irreversible, and was followed by cell death. Only cells that were in S phase were subject to this block in S, since cells that had accumulated in G(2)/M by using a low concentration (60 ng/ml DNR for 20 h) were not blocked in S, and did not die, when subsequently treated with high drug concentrations (320 ng/ml, 30 h). The low concentration effect occurred at the same maximal rate (4 %/h) in sensitive or resistant cells, but the external drug concentration required to produce half the maximal rate was, appropriately, twenty-fold higher in the resistant cells (20 ng/ml and 400 ng/ml, respectively).     

Inhibition of cdk1 by alsterpaullone and thioflavopiridol correlates with increased transit time from mid G2 through prophase

Current models suggest that cyclin B1/cdk1 regulates the G2 to M transition and that its activity is maximal during the period from prophase to metaphase in mammalian cells. Although data are lacking, the idea that cyclin B1/cdk1 regulates the transit time from prophase to metaphase is reasonable. Development of small molecule inhibitors of cyclin dependent kinases (cdk's) as cancer therapeutics presents an opportunity to evaluate the effects of inhibiting cdk's in asynchronous cell populations. Analysis of cdk1 inhibitors is complicated by their ability to inhibit other cdk's in vitro at higher concentrations. In this study we measured the effects of two cdk1 inhibitors on S, G2, and M transit for Hela cells and correlated these effects on cyclin B1/cdk1 and cyclin A/cdk2 activities. Dose responses demonstrate that low concentrations of both compounds inhibited the activity of cdk1 but not cdk2 in HeLa cells. The partial loss of cdk1 activity at low doses induced a prophase accumulation during a 3 h period and an increased transit time through mitosis. In addition, both inhibitors lengthened the G2 transit time with progressively greater effect on mid and late G2. High doses of both inhibitors increased the S phase time, which correlated with the inhibition of cdk2 activity. These results suggest that cdk1-cyclin activity is rate limiting for cell cycle progression during a period from mid G2 through prophase.     

Inhibition of Cdk1 by Alsterpaullone and Thioflavopiridol Correlates with Increased Transit Time from Mid G2 Through Prophase

Current models suggest that cyclin B1/cdk1 regulates the G2 to M transition and that its activity is maximal during the period from prophase to metaphase in mammalian cells. Although data are lacking, the idea that cyclin B1/cdk1 regulates the transit time from prophase to metaphase is reasonable. Development of small molecule inhibitors of cyclin dependent kinases (cdk’s) as cancer therapeutics presents an opportunity to evaluate the effects of inhibiting cdk’s in asynchronous cell populations. Analysis of cdk1 inhibitors is complicated by their ability to inhibit other cdk’s in vitro at higher concentrations. In this study we measured the effects of two cdk1 inhibitors on S, G2, and M transit for Hela cells and correlated these effects on cyclin B1/cdk1 and cyclin A/cdk2 activities. Dose responses demonstrate that low concentrations of both compounds inhibited the activity of cdk1 but not cdk2 in HeLa cells. The partial loss of cdk1 activity at low doses induced a prophase accumulation during a 3 h period and an increased transit time through mitosis. In addition, both inhibitors lengthened the G2 transit time with progressively greater effect on mid and late G2. High doses of both inhibitors increased the S phase time, which correlated with the inhibition of cdk2 activity. These results suggest that cdk1-cyclin activity is rate limiting for cell cycle progression during a period from mid G2 through prophase.     

Speedy/Ringo C regulates S and G2 phase progression in human cells

Cyclin-dependent kinases (CDKs) control cell cycle transitions and progression. In addition to their activation via binding to cyclins, CDKs can be activated via binding to an unrelated class of cell cycle regulators termed Speedy/Ringo (S/R) proteins. Although mammals contain at least five distinct Speedy/Ringo homologues, the specific functions of members of this growing family of CDK activators remain largely unknown. We investigated the cell cycle roles of human Speedy/Ringo C in HEK293 cells. Down-regulation of Speedy/Ringo C by RNA interference delayed S and G2 progression whereas ectopic expression had the opposite effect, reducing S and G2/M populations. Double thymidine arrest and release experiments showed that overexpression of Speedy/Ringo C promoted late S phase progression. Using a novel three-color FACS protocol to determine the length of G2 phase, we found that the suppression of Speedy/Ringo C by RNAi prolonged G2 phase by ~30 min whereas ectopic expression of Speedy/Ringo C shortened G2 phase by ~25 min. In addition, overexpression of Speedy/Ringo C disrupted the G2 DNA damage checkpoint, increased cell death and caused a cell cycle delay at the G1-to-S transition. These observations indicate that CDK-Speedy/Ringo C complexes positively regulate cell cycle progression during the late S and G2 phases of the cell cycle.     

Simian virus 40 large T-antigen expression decreases the G1 and increases the G2 + M cell cycle phase durations in exponentially growing cells.

The effect of simian virus 40 large T-antigen (Tag) expression on the cell cycle of exponentially growing, established, mouse NIH 3T3 fibroblasts was examined by using a sensitive flow cytometric assay to analyze nonselected cells immediately after infection with a Tag-encoding recombinant retrovirus. Tag expression resulted in reduced percentages of G1-phase cells and increased percentages of S- and G2 + M-phase cells compared with cell populations infected with a control virus not encoding the Tag gene. Cell cycle-blocking drugs were used to examine the exit rate for each of the cell cycle phases, G1, S, and G2 + M, for Tag-expressing and Tag-nonexpressing cells growing in the same cell culture dish. As a result of Tag expression, the duration of the G1 phase was decreased (average G1-phase exit duration decreased by 18%) and the duration of the G2 + M phase was increased (average G2 + M exit duration increased by 29%). The duration of S phase was unaffected by Tag expression.     

Inhibition of ATP-sensitive potassium channels causes reversible cell-cycle arrest of human breast cancer cells in tissue culture

The purpose of this study was to determine if potassium channel activity is required for the proliferation of MCF-7 human mammary carcinoma cells. We examined the sensitivities of proliferation and progress through the cell cycle to each of nine potassium channel antagonists. Five of the potassium channel antagonists produced a concentration-dependent inhibition of cell proliferation with no evidence of cytotoxicity following a 3-day or 5-day exposure to drug. The IC₅₀ values for these five drugs, quinidine (25 μM), glibenclamide (50 μM), linogliride (770 μM), 4-aminopyridine (1.6 mM), and tetraethylammmonium (5.8 mM) were estimated from their respective concentration-response curves. Four other potassium channel blockers were tested at supra-maximal channel blocking concentrations, including charybdotoxin (200 nM), iberiotoxin (100 nM), margatoxin (10 nM), and apamin (500 nM), and they had no effect on MCF-7 cell proliferation, viability, or cell cycle distribution. Of the five drugs that inhibited proliferation, only quinidine, glibenclamide, and linogliride also affected the cell cycle distribution. Cell populations exposed to each of these drugs for 3 days showed a statistically significant accumulation in GO/G1 phase and a significant proportional reduction in S phase and G2/M phase cells. The inhibition of cell proliferation correlated significantly with the extent of cell accumulation in GO/G1 phase, and the threshold concentrations for inhibition of growth and GO/G1 arrest were similar. The GO/G1 arrest produced by quinidine and glibenclamide was reversed by removing the drug, and cells released from arrest entered S phase synchronously with a lag period of ～24 hours. Based on the differential sensitivity of cell proliferation and cell cycle progression to the nine potassium channel antagonists, we conclude that inhibition of ATP-sensitive potassium channels in these human mammary carcinoma cells reversibly arrests the cells in the GO/G1 phase of the cell cycle, resulting in an inhibition of cell proliferation. © 1995 Wiley-Liss, Inc.