Antiproliferative effect of bcl-2 gene does not concern the control of mitotic events

E1A + c-Ha-ras-transformants overexpressing bcl-2 oncogene are able to be arrested at the G1/S boundary of the cell cycle after DNA damage and upon serum starvation, this cell cycle blockage being accompanied by a decrease in the activity of cyclin E--Cdk2 complexes. Roscovitine-induced inhibition of cyclin-dependent kinases (Cdks) activity does not result in the G1/S arrest of E1A + c-Ha-ras + bcl-2-transformants. Roscovitine treatment causes an accumulation of G2/M cells, mainly at the expense of mitotic cells. However, the expression of Bcl-2 oncoproducts does not re-establish the regulation of mitotic events broken by introduction of E1A and c-Ha-ras oncogenes in normal cells, as revealed by the treatment of E1A + c-Ha-ras + bcl-2-transformants with nocodazole inducing mitotic arrest in normal cells. In spite of the elevated expression of antiapoptotic bcl-2 gene in transformants, nocodazole treatment results in mass apoptotic death preceded by polyploidy. Roscovitine also induces apoptosis with no polyploid cell accumulation being observed. Inhibition of Cdks activity with Roscovitine, as well as violation of microtubule depolymerization with nocodazole result in the apoptotic death in the tested cell lines sensitive (E1A + c-Ha-ras) and resistant (E1A + c-Ha-ras + bcl-2) to damaging agents. Thus, the application of Roscovitine, a specific inhibitor of Cdks, suggests that the decrease in Cdks activity in E1A + c-Ha-ras + bcl-2-transformants is not likely to be responsible for G1/S cell cycle arrest realization after damaging influences. Moreover, an antiproliferative effect of Bcl-2 in E1A + c-Ha-ras-transformants is restricted by restoration of cell cycle events at G1/S and G2/M boundaries, and does not concern the program of mitotic events regulation.     

Autoradiographic determination of the parameters of the mitotic cycle of tumors of human testis in tissue culture]

By means of autoradiography with thymidine-H3 the authors studied the mitotic cycle of a primary culture of the human testicle tumours on the 16th day of growth. Prolonged incubation with the isotope was employed. The following parameters of the mitotic cycle for the whole cellular population were established: T-83.6 hours, G + M = 60.25 hours, S = 5.35 hours, G2 = 18.0 hours. A conclusion was drawn that it was possible to use the primary culture to determine the mitotic cycle of human tumours.     

与细胞周期G2/M期进程相关的H2AX磷酸化

γH2AX焦点(foci)被普遍当做DNA双链断裂（DSB）损伤的分子标志物.为探 讨细胞周期进程相关的H2AX磷酸化规律特征,采用胸腺嘧啶双阻滞结合噻氨酯哒唑(nocodazole)的后续处理,将HeLa细胞同步于有丝分裂的前中期．然后,用流式细胞仪检测细胞周期、Western印迹和免疫荧光法,观察γH2AX表达和γH2AX焦点的形成．结果显示,细胞进入G2/M期和有丝分裂过程中,γH2AX水平显著增加 ;在无DNA DSB发生的情况下,部分M期细胞中也存在大量的γH2AX焦点．随着细 胞完成有丝分裂从M期退出再进入G1期,γH2AX的表达水平逐渐降低．这种 γH2AX表达变化特征与G2/M期密切关联的PLK1和Cyclin B1的表达规律相类似． 在4 Gy大剂量照射下,HeLa细胞于照后8 到12 h出现明显的G2/M期阻滞．γH2AX 焦点数在照后1 h达高峰,随后降低,照后8 h又上升,出现了第2个峰值．与之不同的是,在1 Gy低剂量照射下,细胞的G2/M期阻滞微弱,γH2AX焦点数在照后 0.5 h最高,随后下降,且无反弹,符合DNA DSB的修复动力学特征．因此,将γ H2AX当做DNA DSB分子标志物时,还需要考虑细胞周期变化的影响．γH2AX适合 作为1 Gy以下照射的DNA双链断裂损伤的分子标志．     

Cell cycle diversity involves differential regulation of Cyclin E activity in the Drosophila bristle cell lineage

In the Drosophila bristle lineage, five differentiated cells arise from a precursor cell after a rapid sequence of asymmetric cell divisions (one every 2 hours). We show that, in mitotic cells, this rapid cadence of cell divisions is associated with cell cycles essentially devoid of the G1-phase. This feature is due to the expression of Cyclin E that precedes each cell division, and the differential expression of the S-transition negative regulator, Dacapo. Thus, apart from endocycles (G/S), which occurred in two out of five terminal cells, two other cell cycles coexist in this lineage: (1) an atypical cell cycle (S/G2/M), in which the S-phase is initiated during the preceding telophase; and (2) a canonical cell cycle (G1/S/G2/M) with a brief G1 phase. These two types of cell cycle result from either the absence or very transient expression of Dap, respectively. Finally, we show that the fate determinant factor, Tramtrack, downregulates Cyclin E expression and is probably involved in the exit of the cells from the cell cycle.     

Effect of thyroxine on the duration of the phases of the hepatocyte mitotic cycle at different times of day]

The lengths of the synthetic phase (S) and postsynthetic gap plus a half of the mitotic time (G2+1/2 M) has been investigated in hepatocytes of control and thyroxine-treated male white rats using percent labeled mitosis curves after injection of isotope at 10, 16, 22 and 4 o'clock. In the control, the minimum lengths of G2 lasted 3.0 hours without being changed during 24 hours. On the contrary, G2+1/2 M and S varied from 3.2 to 4.4 and from 8.0 to 9.5 hours, accordingly. A prolonged administration or hormone induced changes in duration of all the above phases whose alterations in thyroxine-treated group of animals showed 2.0--3.0, 2.9--3.4 and 6.4--11.3 hours, respectively. During 24 hours, there was observed a characteristic pattern of changes in the labeling index (LI) of both groups of animals. It has been established for both the groups that the increased in LI coincides with the shortening of S-phase. The data allow to conclude that some intracycle mechanisms may exist controlling the cell division and exerting their effects on the cells at the end of G1-phase and during G2-phase. Thyroxine is a regulator of cell proliferation, and its effect was found to occur due to the intracycle mechanisms of cell cycle kinetics.     

Cell kinetics in the mouse esophageal epithelium in relation to the time of day

The kinetics of mouse esophageal epithelial cells was investigated throughout 90 h after a single injection of 3H-thymidine at 01 or at 13 h--the times of the peak and minimal magnitudes of the radioisotope index in the circadian rhythm of proliferation. The mitotic cycle parameters in the cells varied but insignificantly. For cells treated with 3H-thymidine at 01 h, T = 24.3 h, ts = 6 h, tG2 min = 1.5 h, tG2+ 1/2 M = 2.9 h and tG1+/2 M = 15.4 h; for those treated with 3H-thymidine at 13 h, T = 25.6 h, ts = 8.4 h, tG2 min = 1 h, tG2+ 1/2 M = 2.2 h, tG1+ 1/2 M = 15 h. Cells labeled at 01 h proliferated more actively for a long period of time as compared to those labeled at 13 h. The synchronism in undergoing several successive mitotic cycles was greater for cells labeled at the peak radioisotope index. The data obtained also suggest that the majority of cells enter the G0 phase after the completion of the first cycle. The duration of the G0 phase varies in different cell populations.     

Membrane transport in synchronized Ehrlich ascites tumor cells: uptake of amino acids by the A and L system during the cell cycle.

Using the double thymidine block technique. Ehrlich ascites tumor cells (ELD) carried in continuous spinner culture have been synchronized. Simultaneous monitoring of 3H-thymidine incorporation, cell number and mitotic index yielded a cell cycle time of approximately 13.5 hours. This is composed of an S period of 3-4 hours. G2 of 6-8 hours and M of 1-2 hours. No appreciable G1 is present. Ehrlich cells synchronized in this manner were used to investigate the characteristics of two neutral amino acid transport systems during progression through the cell cycle. Unidirectional influx via the Na-dependent system A was studied using C14-alpha-aminoisobutyrate (AIB) as substrate. The Na-independent system L was monitored using 3H-leucine and 14C-cycloleucine as substrates. Transport by the A system was minimal in M and early S. It underwent a three-fold increase during late S and early G2. In mid G2 the transport via this system rapidly dropped and remained low again through M and early S. The intracellular/extracellular ratios of AIB indicate that the system is actively transporting AIB thoughout the cell cycle. The minimum ratios of approximately 3 were achieved during early M and the maximum ratios of approximately 9 were achieved in late S, early G2. The uptake of leucine and cycloleucine by the L system was quite different during the cell cycle. Maximal unidirectional influx by this system occurred during early and mid S period. Upon progression into G2 the transport rate dropped and remained reduced throughout M. Intracellular/extracellular ratios of leucine or cycloleucine were near unity at the peak of the transport activity (early S) and dropped to values of 0.5 to 0.6 throughout the remainder of the cycle. This result indicates that inward transport by the L system is, for the most part, non-active in growing cells.     

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.     

A new method to discriminate G1, S, G2, M, and G1 postmitotic cells

A new flow cytometric method combining light scattering measurements, detection of bromodeoxyuridine (BrdU) incorporation via fluorescent antibody, and quantitation of cellular DNA content by propidium iodide (PI) allows identification of additional compartments in the cell cycle. Thus, while cell staining with BrdU-antibodies and PI reveals the G1, S, and G2 + M phases of the cell cycle, differences in light scattering allow separation of G2 phase cells from M phase cells and subdivision of G1 phase into two compartments, i.e., G1A representing postmitotic cells which mature to G1B cells ready to initiate DNA synthesis. The method involves fixation of cells in 70% ethanol, extraction of histones with HC1, and thermal denaturation of DNA. This treatment appears to enhance the differences in chromatin structure of cells in the various phases of the cell cycle to the extent that cells could be separated on the basis of the 90 degrees scatter. Mitotic cells show much lower scatter than G2 phase cells, and G1 postmitotic cells (G1A) show lower scatter than G1 cells about to enter the S phase (G1B). Light scattering is correlated with chromatin condensation, as judged by microscopic evaluation of cells sorted on the basis of light scatter. The method has the advantage over the parental BrdU/DNA bivariate analysis in allowing the G2 and M phases of the cell cycle to be separated and the G1 phase to be analyzed in more detail. The method may also allow separation of unlabeled S phase cells from mitotic cells and distinguish between labeled and unlabeled mitotic cells.     

Effect of 2-mercaptoethanol on the individual periods of the mitotic cycle

Dynamics of the mitotic cycle of the KEPV cells being on different interphase stages at the start of a 20 hour 2-mercaptoethanol (0.001 M) treatment has been studied during the treatment and for 11 hours after washing out the agent. The KEPV cells affected by mercaptoethanol during the interphase (G1, S, G2) were shown to continue their passage through the cycle to enter mitosis, but part of the cells of the S period and of the first half of the G2 period were arrested in the interphase. In the presence of mercaptoethanol, mitotic cells reach the metaphase stage, and their further behaviour depends on the duration of the treatment. For the first 8 hours of treatment, a phase of "unstable block" exists for cells that were in S and G2 periods at the beginning of treatment, while other cells are transformed into K-metaphases. 8 hours later a phase of "stable block" occurs and all the normal metaphases are transformed into K-metaphases. After washing out the culture from mercaptoethanol the cells are ejected from the block in K-metaphase. The transformation from K-metaphase into the normal metaphase is realised in the course of this process. The cells which were in S and G2 periods at the beginning of the treatment are ejected from the block simultaneously after washing, while the cells of the G1 period--with a small delay. After washing out mercaptoethanol the cells that were in the interphase (G1, S, G2) at the beginning of the treatment are capable of producing both multipolar mitoses and mitoses without cytotomy.     

Two Molecularly Distinct G2/M Checkpoints Are Induced by Ionizing Irradiation

Cell cycle checkpoints are among the multiple mechanisms that eukaryotic cells possess to maintain genomic integrity and minimize tumorigenesis. Ionizing irradiation (IR) induces measurable arrests in the G(1), S, and G(2) phases of the mammalian cell cycle, and the ATM (ataxia telangiectasia mutated) protein plays a role in initiating checkpoint pathways in all three of these cell cycle phases. However, cells lacking ATM function exhibit both a defective G(2) checkpoint and a prolonged G(2) arrest after IR, suggesting the existence of different types of G(2) arrest. Two molecularly distinct G(2)/M checkpoints were identified, and the critical importance of the choice of G(2)/M checkpoint assay was demonstrated. The first of these G(2)/M checkpoints occurs early after IR, is very transient, is ATM dependent and dose independent (between 1 and 10 Gy), and represents the failure of cells which had been in G(2) at the time of irradiation to progress into mitosis. Cell cycle assays that can distinguish mitotic cells from G(2) cells must be used to assess this arrest. In contrast, G(2)/M accumulation, typically assessed by propidium iodide staining, begins to be measurable only several hours after IR, is ATM independent, is dose dependent, and represents the accumulation of cells that had been in earlier phases of the cell cycle at the time of exposure to radiation. G(2)/M accumulation after IR is not affected by the early G(2)/M checkpoint and is enhanced in cells lacking the IR-induced S-phase checkpoint, such as those lacking Nbs1 or Brca1 function, because of a prolonged G(2) arrest of cells that had been in S phase at the time of irradiation. Finally, neither the S-phase checkpoint nor the G(2) checkpoints appear to affect survival following irradiation. Thus, two different G(2) arrest mechanisms are present in mammalian cells, and the type of cell cycle checkpoint assay to be used in experimental investigation must be thoughtfully selected.     

Variation through the cell cycle in the dose-response of DNA neutral filter elution in X-irradiated synchronous CHO-cells

Dose-response curves for DNA neutral (pH 9.6) filter elution were obtained with synchronized CHO cells exposed to X-rays at various phases of the cell cycle. The dose response was similar in synchronized and plateau-phase G1 cells, as well as in cells that were arrested at the G1/S border using aphidicolin; it flattened as cells progressed into S phase and reached a minimum in the middle of this phase. An increase in DNA elution dose response, to values only slightly lower than those obtained with G1 cells, was observed as cells entered G2 phase. Significant alterations in the sedimentation properties of the DNA during S phase were also observed in Ehrlich ascites tumor cells using the neutral sucrose gradient centrifugation technique. A significant proportion of the DNA from S cells irradiated with 10 Gy sedimented at speeds (350S-700S) well above the maximum sedimentation speed expected for free sedimenting DNA molecules (Smax = 350S), indicating the formation of a DNA complex. DNA from G1, G1/S, or G2 + M cells sedimented as expected for free sedimenting molecules. These results indicate significant alterations in the physicochemical properties of the DNA--probably caused by DNA replication-associated alterations in DNA structure and chromatin conformation--as cells enter S phase, and are invoked to explain the observed variation in DNA elution dose response throughout the cycle. It is proposed that the formation of a complex DNA structure, resistant to the proteolytic enzymes and detergents used, affected the elution characteristics of the DNA and gave rise to the observed curvilinear DNA elution dose-response curves, as well as to the fluctuations in elution characteristics observed throughout the cell cycle.     

Alterations in the cell cycle characteristics of granulosa cells during the periovulatory period: evidence of ovarian and oviductal influences

Granulosa cells at different stages of differentiation were collected from ovarian follicles and oviducts during the periovulatory period, and their nuclear DNA content was monitored by flow cytometry to establish their cell cycle characteristics (G0 + G1, S, G2 + M). The proportion of cells in the three phases of the cell cycle varied in characteristics patterns depending upon the time they were collected, before or following ovulation. Granulosa (cumulus) cells recovered from ovulated oocytes were mitotically inactive as shown by the large proportion of cells with a 2C amount of DNA and the absence of cells in S phase. The proportion of granulosa cells in G2 + M decreased when recovery from the oviducts was delayed. In contrast, granulosa (cumulus and/or mural) cells recovered from preovulatory follicles prior to luteinizing hormone (LH) exposure contained a considerable population of cells undergoing DNA synthesis, and a decreased proportion of cells with a 2C DNA content. Our findings indicate that granulosa cells undergo dynamic and characteristics changes in all cell cycle phases during the periovulatory period, within follicular and oviductal environments. Intrafollicular events appear to play a major role in controlling DNA synthesis, proliferation, and related cell cycle events in the granulosa cells. Flow cytometric techniques provide objective and detailed information on the cell cycle characteristics of granulosa cell populations at different stages of differentiation. Elucidation of the mechanisms regulating cell cycle parameters of granulosa cells and their physiological significance thus seems feasible.     

Control of cell progression through the mitotic cycle by carbohydrate provision. I. Regulation of cell division in excised plant tissue

A stationary phase in the root meristem of excised pea roots was established by prolonged carbohydrate deprivation in sterile culture medium. When the stationary phase had been established, cells that had collected in the G1 period of the mitotic cycle were induced to enter the S stage by subjection to relatively short intervals of carbohydrate provision (sucrose spurts). Progression and cycle location of the G1 cells induced to enter S were measured with tritiated thymidine and radioautography. The results indicated that the number of G1 cells induced to enter S increased directly with the spurt duration and that cells could be positioned and retained in the S and/or G2 periods by varying the duration of the spurt. The data support the hypothesis that S and maybe M stages have a relatively larger dependence on carbohydrate availability, and presumably a greater energy requirement, than G1 and G2.     

Cell cycle analysis of cultured porcine mammary cells

One of the major points of debate in determining the effectiveness of nuclear transfer technology has been the phase of the cell cycle of the donor cell at the time of nuclear transfer. Here, a primary mammary cell line has been isolated and various treatments for synchronization of the cell cycle have been tested. The cells were then simultaneously stained for DNA content and protein content and the percentages of cells in G1, G0, S, and G2 + M were estimated. In the first experiment, cells were either cycling, grown to confluence, or serum-starved for 5 days. Serum starvation increased (p < 0.05) the percentage of cells in G0 compared to confluent or cycling cells from 3% to 8% to 22%. By using forward scatter to determine the size of the cells it was determined that if small cells (7-15 microm) were selected from the serum-starved group 43.9% will be in G(0) as compared to 4.5% of cycling cells and 9.9% of confluent cells. Dimethyl sulfoxide (DMSO) treatment (0%, 0.5%, or 1.0%) for 72 hours (shown to synchronize some cell types in G0) had no effect on the percentage of cells in G0, G1, S, or G2 + M. Treatment with mimosine (0 microM, 0.4 microM, 0.8 microM or 1.2 microM), a compound that should synchronize the cells in G1, increased (p < 0.05) the percentage of cells in G1 from 66.7% (0 microM mimosine) to 79.0% to 82.0%. Finally, treatment with colchicine for 24 hours (shown to synchronize some cell types in G2 + M) increased (p < 0.05) the percentage of cells in G2 + M (0 microM colchicine) from 13.3% to 27.2% to 31.6%. It is concluded that many cell cycle synchronization techniques are effective in porcine mammary cell lines, but none of the techniques are 100% effective. Such results should help elucidate the mechanisms involved in nuclear transfer.     

Cell-cycle studies by multiparametric automatic scanning of topographically preserved cells in culture

The authors have developed a new methodology for characterizing in situ the cell cycle of human mammary epithelial cell lines. Using a SAMBA 200 cell image processor (scanning cytometry), 15 densitometric and textural parameters were computed on each Feulgen-stained nucleus. Parameters computed from the grey level cooccurrence and run-length section matrices allowed assessment of the chromatin pattern. Multiparametric analysis of data defined: 1) the relative position of each cell; 2) the relative positions of groups of cells, each group corresponding to a definite phase of the cell cycle; and 3) the function of these parameters best separating these phases. Files then were constructed for each phase: G0/G1, S, G2/ and M. Using these three files as a reference to classify cells, it was possible to ascertain the phase of the cell cycle for each cell of a population. The MDA AG human cell line synchronized by mitotic selection was used as a model to develop this method. The criteria used to assign cells to G0/G1, S, or G2 was DNA content. Classification in M phase was achieved by visual identification of mitotic cells. This method was checked on unsynchronized MDA AG and then applied to other human cell lines (MDA MB231, MCF-7, T47D C111). Comparison of results obtained by scanning cytometry and flow cytometry showed the proportion of cells assigned to G0/G1, S, and G2/M by the two methods to be similar. This new method removes some of the limitations of flow cytometry by 1) allowing visual verification of each cell analyzed; 2) lowering the number of cells required for study; 3) discriminating between G2 and M; and 4) preserving cell topography.     

Elevation of Survivin Levels by Hematopoietic Growth Factors Occurs in Quiescent CD34+ Hematopoietic Stem and Progenitor Cells Before Cell Cycle Entry

Survivin is a member of the inhibitor of apoptosis protein (IAP) family that is over-expressed during G2/M phase in most cancer cells. In contrast, we previously reported that Survivin is expressed throughout the cell cycle in normal CD34+ hematopoietic stem and progenitor cells stimulated by the combination of Thrombopoietin (Tpo), Stem Cell Factor (SCF) and Flt3 ligand (FL). In order to address whether Survivin expression is specifically up-regulated by hematopoietic growth factors before cell cycle entry, we isolated quiescent CD34+ cells and investigated Survivin expression in response to growth factor stimulation. Survivin is up-regulated in CD34+ cells with 2N DNA content following growth factor addition, suggesting it becomes elevated during G0/G1. Survivin is barely detectable in freshly isolated umbilical cord blood (UCB) Ki-67negative and Cyclin Dnegative CD34+ cells, however incubation with Tpo, SCF and FL for 20 hrs results in up-regulation without entry of cells into cell cycle. Culture of G0 CD34+ cells isolated based on Hoechst 33342/PyroninY staining with Tpo, SCF and FL for 48 hrs, results in significantly elevated Survivin mRNA and protein levels. Moreover, labeling of fresh G0 CD34+ cells with 5-(and 6-) carboxyfluorescein diacetate succinimidyl ester (CFSE) before culture with growth factors for up to 72 hrs, revealed that Survivin expression was elevated in CFSEbright G0 CD34+ cells, indicating that up-regulation occurred before entry into G1. These results suggest that up-regulation of Survivin expression in CD34+ cells is an early event in cell cycle entry that is regulated by hematopoietic growth factors and does not simply reflect cell cycle progression and cell division.

Key Words:

Survivin, Cord blood, CD34+ cells, 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.     

The induction of chromosomal aberrations and SCEs by visible light in combination with dyes. II. Cell cycle dependence, and the effect of hydroxyl radical scavengers during light exposure in cultures of Chinese hamster ovary cells sensitized with acridine orange

Chinese hamster ovary (CHO) cells were synchronized by mitotic shake-off, treated with the fluorochrome acridine orange (AO; 0.5 micrograms/ml), washed free of excess dye and subsequently exposed to visible light (2 X 40 W/8 Wm-2). The light exposure was performed on cells in the G1, G1/S, S or G2 phase of the cell cycle. AO + light induced high frequencies of aberration in the S phase and even higher in the G1 phase. The aberrations observed were all of the chromatid type. The chromosome-type aberrations (dicentrics, rings) obtained when cells in the G1 phase were exposed to X-rays were not found after corresponding treatments with AO + light. With the exception of an increased frequency of gaps, no chromosomal aberrations were induced in G2-phase cells. Sister-chromatid exchanges were efficiently produced by the photodynamic system in the G1, G1/S and S phase of the cell cycle. In other experiments, AO-treated unsynchronized CHO cells were exposed to light in the presence of the hydroxyl radical scavengers mannitol (100 mM) and 5-dimethyl thiourea (100 mM). In parallel experiments these scavengers were found to reduce markedly the chromosome breaking effects by X-rays but had no influence on the photodynamic induction of chromosomal alterations. The results presented show that the visible light-induced chromosomal alterations in CHO cells sensitized with the fluorochrome AO are obtained by an S-dependent mechanism. Furthermore, the results indicate that the hydroxyl free radical does not play a major role in the production of chromosomal alterations by AO + light.     

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.