Cell cycle progression in serum-free cultures of Sf9 insect cells: modulation by conditioned medium factors and implications for proliferation and productivity

Cell cycle progression was studied in serum-free batch cultures of Spodoptera frugiperda (Sf9) insect cells, and the implications for proliferation and productivity were investigated. Cell cycle dynamics in KBM10 serum-free medium was characterized by an accumulation of 50-70% of the cells in the G(2)/M phase of the cell cycle during the first 24 h after inoculation. Following the cell cycle arrest, the cell population was redistributed into G(1) and in particular into the S phase. Maximum rate of proliferation (micro(N, max)) was reached 24-48 h after the release from cell cycle arrest, coinciding with a minimum distribution of cells in the G(2)/M phase. The following declining micro(N) could be explained by a slow increase in the G(2)/M cell population. However, at approximately 100 h, an abrupt increase in the amount of G(2)/M cells occurred. This switch occurred at about the same time point and cell density, irrespective of medium composition and maximum cell density. An octaploid population evolved from G(2)/M arrested cells, showing the occurrence of endoreplication in this cell line. In addition, conditioned medium factor(s) were found to increase micro(N,max), decrease the time to reach micro(N,max), and decrease the synchronization of cells in G(2)/M during the lag and growth phase. A conditioned medium factor appears to be a small peptide. On basis of these results we suggest that the observed cell cycle dynamics is the result of autoregulatory events occurring at key points during the course of a culture, and that entry into mitosis is the target for regulation. Infecting the Sf9 cells with recombinant baculovirus resulted in a linear increase in volumetric productivity of beta-galactosidase up to 68-75 h of culture. Beyond this point almost no product was formed. Medium renewal at the time of infection could only partly restore the lost hypertrophy and product yield of cultures infected after the transition point. The critical time of infection correlated to the time when the mean population cell volume had attained a minimum, and this occurred 24 h before the switch into the G(2)/M phase. We suggest that the cell density dependent decrease in productivity ultimately depends on the autoregulatory events leading to G(2)/M cell cycle arrest.     

Infection of cells with human cytomegalovirus during S phase results in a blockade to immediate-early gene expression that can be overcome by inhibition of the proteasome

Cells infected with human cytomegalovirus (HCMV) after commencing DNA replication do not initiate viral immediate-early (IE) gene expression and divide before arresting. To determine the nature of this blockade, we examined cells that were infected 24 h after release from G(0) using immunofluorescence, laser scanning cytometry, and fluorescence-activated cell sorting (FACS) analysis. Approximately 40 to 50% of the cells had 2N DNA content, became IE(+) in the first 12 h, and arrested. Most but not all of the cells with >2N DNA content did not express IE antigens until after mitosis. To define the small population of IE(+) cells that gradually accumulated within the S and G(2)/M compartments, cells were pulsed with bromodeoxyuridine (BrdU) just prior to S-phase infection and analyzed at 12 h postinfection for IE gene expression, BrdU positivity, and cell cycle position. Most of the BrdU(+) cells were IE(-) and had progressed into G(2)/M or back to G(1). The majority of the IE(+) cells in S and G(2)/M were BrdU(-). Only a few cells were IE(+) BrdU(+), and they resided in G(2)/M. Multipoint BrdU pulse-labeling revealed that, compared to cells actively synthesizing DNA at the beginning of the infection, a greater percentage of the cells that initiated DNA replication 4 h later could express IE antigens and proceed into S. Synchronization of the cells with aphidicolin also indicated that the blockade to the activation of IE gene expression was established in cells soon after initiation of DNA replication. It appears that a short-lived protein in S-phase cells may be required for IE gene expression, as it is partially restored by treatment with the proteasome inhibitor MG132.     

Additive effects of radiation and docetaxel on murine SCCVII tumors in vivo: special reference to changes in the cell cycle

The purpose of the present study was to investigate the effects of a combination of docetaxel and irradiation in vivo with special reference to docetaxel-arrested G(2)/M-phase cells. At 24 and 48 h after intraperitoneal administration of docetaxel (90 mg/kg), tumor-bearing mice were irradiated with (60)Co gamma rays. Cell cycle distribution was analyzed by a DNA-Ki-67 double staining method using flow cytometry. An accumulation of cells in the G(2)/M phase of up to approximately 40% was observed 24 h after administration of docetaxel. Between 24 and 72 h, the percentage of cells arrested in G(2)/M phase that expressed Ki-67 decreased from 37.2% to 13.8%, in accordance with the increase in the Ki-67-negative G(2)/M-phase fraction. More than half of the cells arrested in G(2)/M phase lost their expression of Ki-67 protein between 24 and 72 h. The G(1)-phase fraction decreased from 28.4% to 8.6% at 24 h after docetaxel treatment; this remained unchanged at 72 h. These flow cytometry data suggested that docetaxel-arrested G(2)/M-phase cells did not enter the next cell cycle and were killed by docetaxel alone. Our data showed that arrest of cells in G(2)/M phase does not contribute to the synergism that has been reported for combinations of docetaxel and radiation in in vivo tumor models.     

Effect of cell cycle on the regulation of the cell surface and secreted forms of type I and type II human tumor necrosis factor receptors

The cell cycle has been shown to regulate the biological effects of human tumor necrosis factor (TNF), but to what extent that regulation is due to the modulation of TNF receptors is not clear. In the present report we investigated the effect of the cell cycle on the expression of surface and soluble TNF receptors in human histiocytic lymphoma U-937. Exposure to hydroxyurea, thymidine, etoposide, bisbensimide, and democolcine lead to accumulation of cells primarily in G₁/S, S, S/G₂/M, G₂/M, and M stages of the cell cycle, respectively. Whilie no significant change in TNF receptors occurred in cells arrested in G₁/S or S/G₂ stages, about a 50% decrease was observed in cells at M phase of the cycle. Scatchard analysis showed a reduction in receptor number rather than affinity. In contrast, cells arrested at S phase (thymidine) showed an 80% increase in receptor number. The decrease in the TNF receptors was not due to changes in cell size or protein synthesis. The increase in receptors, however, correlated with an increase in total protein synthesis (to 3.8-fold of the control levels). A proportional change was observed in the p60 and p80 forms of the TNF receptors. A decrease in the surface receptors in cells arrested in M phase correlated with an increase in the amount of soluble receptors. The cellular response to TNF increased to 8- and 2-fold in cells arrested in G₁ and S phase, respectively; but cells at G2/M phase showed about 6-fold decrease in response. In conclusion, our results demonstrate that the cell cycle plays an important role in regulation of cell-surface and soluble TNF receptors and also in the modulation of cellular response. © 1995 Wiley-Liss, Inc.     

Differential expression of protein phosphatase type 1 isotypes and nucleolin during cell cycle arrest

In the present study, we examined the expression and cytolocalization of protein phosphatase type 1 (PP1) isoforms and nucleolin in human osteoblastic cell line MG63 cells at two boundaries in the cell cycle. We treated MG63 cells with hydroxyurea and nocodazole to arrest the cells at the G(1)/S and G(2)/M boundaries, respectively. As judged from the results of Western blot analysis, PP1 isoforms were expressed differently at each boundary of the cell cycle. Nucleolin was also shown to have a different expression pattern at each boundary. In the hydroxyurea-treated cells, nucleolus-like bodies were bigger in size and decreased in number compared with those in asynchronized cells. However, the subcellular localization of PP1s and nucleolin was not changed. Anti-nucleolin antibody interacted with 110-kDa and 95-kDa proteins present in asynchronized cells and in the cells treated with hydroxyurea. Treatment of the cells with nocodazole decreased the level of the 95-kDa form of nucleolin. In the nocodazole-treated cells, it was impossible to distinguish the distribution of each protein. The phosphorylation status of nucleolin in the cell cycle arrested samples was examined by 2D-IEF-PAGE followed by Western blot analysis. In the case of asynchronized cells or hydroxyurea-treated ones, nucleolin was located at a basic isoelectric point (dephosphorylated status); whereas in the G(2)/M arrest cells, the isoelectric point of nucleolin shifted to an acidic status, indicating that nucleolin was phosphorylated. The present results indicate that PP1 and nucleolin were differently expressed at G(1)/S and G(2)/M boundaries of the cell cycle and acted in a different fashion during cell-cycle progression.     

Alteration of cell cycle progression in human leukemia cell line (KOPM-28) induced by 12-o-tetradecanoylphorbol-13-acetate

Terminal cell differentiation usually results in an irreversible arrest in the G1 phase of the cell cycle and loss of cell renewal ability. Human promyelocytic leukemia HL-60 cells induced with 12-o-tetradecanoylphorbol-13-acetate (TPA) differentiate into monocytes/macrophages and accumulate in G1. We determined the effect of TPA on the growth kinetics of a human leukemia cell line (KOPM-28), which developed several of the characteristics of megakaryocytes in response to TPA, such as the surface antigen complex IIb/IIIa, platelet peroxidase and polyploidy. Cell growth was immediately and completely inhibited by TPA. Flow cytometric analysis of cellular DNA content revealed a gradual decrease in cells in G1 and an accumulation of cells in G2. These data suggest that TPA prolonged G1 and rapidly arrested the cells in G2. Synchronized cells were utilized to further analyze the rapid G2 arrest. Cells arrested with aphidicolin at the G1/S interphase were released, and the effects of TPA (added at different intervals) on cell cycle progression were examined 14 h after release. The results showed that TPA added at the end of the S phase, as well as at the G1/S interphase incompletely but distinctly arrested cells in G2. Moreover, G2 arrest was observed when TPA was added to cells released from a colcemid-induced G2/M block, suggesting that cells already in G2 were inhibited by TPA from moving through M to G1. Since some cells became multi-nucleated in the course of incubation with TPA, this G2 accumulation may have resulted at least in part from a prolongation of the phase or a transient G2 block. These changes in cell cycle progression induced by TPA may be characteristic of and/or related to megakaryocytic differentiation of hemopoietic precursor cells.     

Differential effect of heme oxygenase-1 in endothelial and smooth muscle cell cycle progression

Arterial remodeling in response to pathological insult is a complex process that depends in part on the balance between vascular cell apoptosis and proliferation. Studies in experimental models suggest that HO-1 mediates neointimal formation while limiting lumen stenosing, indicating a differential effect on vascular endothelial (EC) and smooth muscle cells (SMC). We investigated the effect of HO-1 expression on cell cycle progression in EC and SMC. The addition of SnMP (10 microM), an inhibitor of HO activity, to EC or SMC for 24h, resulted in significant abnormalities in DNA distribution and cell cycle progression compared to cells treated with the HO-1 inducers, heme (10 microM) or SnCl(2) (10 microM). SnMP increased G(1) phase and decreased S and G(2)/M phases in EC while heme or SnCl(2) decreased G(1) phase, but increased S and G(2)/M phases (p<0.05). Opposite effects were obtained in SMC. SnMP decreased G(1) phase and increased S and G(2)/M phases while heme or SnCl(2) increased G(1) phase but decreased S and G(2)/M phases (p<0.05). Our data demonstrate that HO-1 regulates the cell cycle in a cell-specific manner; it increases EC but decreases SMC cycle progression. The mechanisms underlying the HO-1 cell-specific effect on cell cycle progression within the vascular wall are yet to be explored. Nevertheless, these findings suggest that cell-specific targeting of HO-1 expression may provide a novel therapeutic strategy for the treatment of cardiovascular diseases.     

苜蓿银纹夜蛾核型多角体病毒的感染对Sf9细胞周期的影响

病毒的感染导致细胞内部发生一系列变化。应用流式细胞仪FACS的荧光检测 ,测出Sf9细胞完成整个周期循环大约需要 18h ,G1、S、G2 /M各时相的时间间隔约为 6h ;AcNPV感染Sf9细胞 12 18h ,细胞被抑制于G2 /M期 ;Sf9细胞同步于G1/S期后释放细胞并用AcNPV感染 ,12h后 ,2 / 3的细胞处于G2 /M期 ,1/ 3的细胞处于S期     

Cdc4, a Protein Required for the Onset of S Phase, Serves an Essential Function during G2/M Transition in Saccharomyces cerevisiae

Saccharomyces cerevisiae proteins Cdc4 and Cdc20 contain WD40 repeats and participate in proteolytic processes. However, they are thought to act at two different stages of the cell cycle: Cdc4 is involved in the proteolysis of the Cdk inhibitor, Sic1, necessary for G(1)/S transition, while Cdc20 mediates anaphase-promoting complex-dependent degradation of anaphase inhibitor Pds1, a process necessary for the onset of chromosome segregation. We have isolated three mutant alleles of CDC4 (cdc4-10, cdc4-11, and cdc4-16) which suppress the nuclear division defect of cdc20-1 cells. However, the previously characterized mutation cdc4-1 and a new allele, cdc4-12, do not alleviate the defect of cdc20-1 cells. This genetic interaction suggests an additional role for Cdc4 in G(2)/M. Reexamination of the cdc4-1 mutant revealed that, in addition to being defective in the onset of S phase, it is also defective in G(2)/M transition when released from hydroxyurea-induced S-phase arrest. A second function for CDC4 in late S or G(2) phase was further confirmed by the observation that cells lacking the CDC4 gene are arrested both at G(1)/S and at G(2)/M. We subsequently isolated additional temperature-sensitive mutations in the CDC4 gene (such as cdc4-12) that render the mutant defective in both G(1)/S and G(2)/M transitions at the restrictive temperature. While the G(1)/S block in both cdc4-12 and cdc4Delta mutants is abolished by the deletion of the SIC1 gene (causing the mutants to be arrested predominantly in G(2)/M), the preanaphase arrest in the cdc4-12 mutant is relieved by the deletion of PDS1. Collectively, these observations suggest that, in addition to its involvement in the initiation of S phase, Cdc4 may also be required for the onset of anaphase.     

Deoxyribonucleotide metabolism and cyclic AMP resistance in hydroxyurea-resistant S49 T-lymphoma cells

We investigated the cell cycle regulation of deoxyribonucleoside triphosphate (dNTP) metabolism in hydroxyurea-resistant (HYUR) murine S49 T-lymphoma cell lines. Cell lines 10- to 40-fold more hydroxyurea-resistant were selected in a stepwise manner. These HYUR cells exhibited increased CDP reductase activity (5- to 8-fold) and increased dNTP pools (up to 5-fold) that appeared to result from increased activity of the M2 subunit (binding site of hydroxyurea) of ribonucleotide reductase. These characteristics remained stable when the cells were grown in the absence of hydroxyurea for up to 2 years. In both wild type and hydroxyurea-resistant cell populations synchronized by elutriation, dCTP and dTTP pools increased in S phase, whereas dATP and dGTP pools generally remained the same or decreased, suggesting that allosteric effector mechanisms were operating to regulate pool sizes. Additionally, CDP reductase activity measured in permeabilized cells increased in S phase in both wild type and hydroxyurea-resistant cells, suggesting a nonallosteric mechanism of increased ribonucleotide reductase activity during periods of active DNA synthesis. While wild type S49 cells could be arrested in the G1 phase of the cell cycle by dibutyryl cyclic AMP, hydroxyurea-resistant cell lines could not be arrested in the G1 phase by exogenous cyclic AMP or agents that elevate the concentration of endogenous cyclic AMP. These data suggest that cyclic AMP-generated G1 arrest in S49 cells might be mediated by the M2 subunit of ribonucleotide reductase.     

Effects of the dilution rate on cell cycle distribution and PEI-mediated transient gene expression by CHO cells in continuous culture

In this study, a continuous culture system was applied to mammalian cells on large scale, and polyethyleneimine (PEI) mediated transient gene expression (TGE). PEI MAX 40,000 was chosen as a superior reagent from three types of PEI. The cell cycle distribution of cells in batch and continuous cultures was determined, in which the effects of cell cycle distribution on transfection efficiency, post-transfection proliferation and recombinant prothrombin expression were evaluated. Compared with cells from end-log and plateau phase in batch culture, cells from mid-log phase possessed a larger fraction of S and G2/M phase cells and a smaller fraction of G1 phase cells. In the continuous culture, the fraction of cells in the S and G2/M phases increased and the fraction of cells in the G1/G0 phase decreased with increasing dilution rates. Cells from the continuous culture run at highest dilution rate had excellent proliferation, transfection efficiency and protein expression. These results were confirmed by transfecting cells synchronized to different phases. The G2/M arrested cells exhibited a nearly 10-fold increase in recombinant human prothrombin production relative to that of non-dividing cells. The use of continuous culture for large scale transfection demonstrated a better cell physiological state for TGE process.     

Cell cycle status affects coxsackievirus replication, persistence, and reactivation in vitro

Enteroviral persistence has been implicated in the pathogenesis of several chronic human diseases, including dilated cardiomyopathy, insulin-dependent diabetes mellitus, and chronic inflammatory myopathy. However, these viruses are considered highly cytolytic, and it is unclear what mechanisms might permit their long-term survival. Here, we describe the generation of a recombinant coxsackievirus B3 (CVB3) expressing the enhanced green fluorescent protein (eGFP), which we used to mark and track infected cells in vitro. Following exposure of quiescent tissue culture cells to either wild-type CVB3 or eGFP-CVB3, virus production was very limited but increased dramatically after cells were permitted to divide. Studies with cell cycle inhibitors revealed that cells arrested at the G(1) or G(1)/S phase could express high levels of viral polyprotein and produced abundant infectious virus. In contrast, both protein expression and virus yield were markedly reduced in quiescent cells (i.e., cells in G(0)) and in cells blocked at the G(2)/M phase. Following infection with eGFP-CVB3, quiescent cells retained viral RNA for several days in the absence of infectious virus production. Furthermore, RNA extracted from nonproductive quiescent cells was infectious when transfected into dividing cells, indicating that CVB3 appears to be capable of establishing a latent infection in G(0) cells, at least in tissue culture. Finally, wounding of infected quiescent cells resulted in viral protein expression limited to cells in and adjacent to the lesion. We suggest that (i) cell cycle status determines the distribution of CVB3 during acute infection and (ii) the persistence of CVB3 in vivo may rely on infection of quiescent (G(0)) cells incapable of supporting viral replication; a subsequent change in the cell cycle status may lead to virus reactivation, triggering chronic viral and/or immune-mediated pathology in the host.     

Different expression profiles of human cyclin B1 in normal PHA-stimulated T lymphocytes and leukemic T cells

BACKGROUND: In a previous work, we demonstrated with flow cytometry (FCM) methods that accumulation of human cyclin B1 in leukemic cell lines begins during the G(1) phase of the cell cycle (Viallard et al. , Exp Cell Res 247:208-219, 1999). In the present study, FCM was used to compare the localization and the kinetic patterns of cyclin B1 expression in Jurkat leukemia cell line and phytohemagglutinin (PHA)-stimulated normal T lymphocytes. METHODS: Cell synchronization was performed in G(1) with sodium n-butyrate, at the G(1)/S transition with thymidine and at mitosis with colchicine. Cells (leukemic cell line Jurkat or PHA-stimulated human T-lymphocytes) were stained for DNA and cyclin B1 and analyzed by FCM. Western blotting was used to confirm certain results. RESULTS: Under asynchronous growing conditions and for both cell populations, cyclin B1 expression was essentially restricted to the G(2)/M transition, reaching its maximal level at mitosis. When the cells were synchronized at the G(1)/S boundary by thymidine or inside the G(1) phase by sodium n-butyrate, Jurkat cells accumulated cyclin B1 in both situations, whereas T lymphocytes expressed cyclin B1 only during the thymidine block. The cyclin B1 fluorescence kinetics of PHA-stimulated T lymphocytes was strictly similar when considering T lymphocytes blocked at the G(1)/S phase transition by thymidine and in exponentially growing conditions. These FCM results were confirmed by Western blotting. The detection of cyclin B1 by Western blot in cells sorted in the G(1) phase of the cell cycle showed that cyclin B1 was present in the G(1) phase in leukemic T cells but not in normal T lymphocytes. Cyclin B1 degradation was effective at mitosis, thus ruling out a defective cyclin B1 proteolysis. CONCLUSIONS: We found that the leukemic T cells behaved quite differently from the untransformed T lymphocytes. Our data support the notion that human cyclin B1 is present in the G(1) phase of the cell cycle in leukemic T cells but not in normal T lymphocytes. Therefore, the restriction point from which cyclin B1 can be detected is different in the two models studied. We hypothesize that after passage through a restriction point differing in T lymphocytes and in leukemic cells, the rate of cyclin B1 synthesis becomes constant in the S and G(2)/M phases and independent from the DNA replication cycle.     

Oncogenic RAS induces accelerated transition through G2/M and promotes defects in the G2 DNA damage and mitotic spindle checkpoints

Activating mutations of RAS are prevalent in thyroid follicular neoplasms, which commonly have chromosomal losses and gains. In thyroid cells, acute expression of HRAS(V12) increases the frequency of chromosomal abnormalities within one or two cell cycles, suggesting that RAS oncoproteins may interfere with cell cycle checkpoints required for maintenance of a stable genome. To explore this, PCCL3 thyroid cells with conditional expression of HRAS(V12) or HRAS(V12) effector mutants were presynchronized at the G(1)/S boundary, followed by activation of expression of RAS mutants and release from the cell cycle block. Expression of HRAS(V12) accelerated the G(2)/M phase by approximately 4 h and promoted bypass of the G(2) DNA damage and mitotic spindle checkpoints. Accelerated passage through G(2)/M and bypass of the G(2) DNA damage checkpoint, but not bypass of the mitotic spindle checkpoint, required activation of mitogen-activated protein kinase (MAPK). However, selective activation of the MAPK pathway was not sufficient to disrupt the G(2) DNA damage checkpoint, because cells arrested appropriately in G(2) despite conditional expression of HRAS(V12,S35) or BRAF(V600E). By contrast to the MAPK requirement for radiation-induced G(2) arrest, RAS-induced bypass of the mitotic spindle checkpoint was not prevented by pretreatment with MEK inhibitors. These data support a direct role for the MAPK pathway in control of G(2) progression and regulation of the G(2) DNA damage checkpoint. We propose that oncogenic RAS activation may predispose cells to genomic instability through both MAPK-dependent and independent pathways that affect critical checkpoints in G(2)/M.     

Ribonucleotide reductase activity and deoxyribonucleoside triphosphate metabolism during the cell cycle of S49 wild-type and mutant mouse T-lymphoma cells

We investigated deoxyribonucleoside triphosphate metabolism in S49 mouse T-lymphoma cells synchronized in different phases of the cell cycle. S49 wild-type cultures enriched for G1 phase cells by exposure to dibutyryl cyclic AMP (Bt2cAMP) for 24 h had lower dCTP and dTTP pools but equivalent or increased pools of dATP and dGTP when compared with exponentially growing wild-type cells. Release from Bt2cAMP arrest resulted in a maximum enrichment of S phase occurring 24 h after removal of the Bt2cAMP, and was accompanied by an increase in dCTP and dTTP levels that persisted in colcemid-treated (G2/M phase enriched) cultures. Ribonucleotide reductase activity in permeabilized cells was low in G1 arrested cells, increased in S phase enriched cultures and further increased in G2/M enriched cultures. In cell lines heterozygous for mutations in the allosteric binding sites on the M1 subunit of ribonucleotide reductase, the deoxyribonucleotide pools in S phase enriched cultures were larger than in wild-type S49 cells, suggesting that feedback inhibition of ribonucleotide reductase is an important mechanism limiting the size of deoxyribonucleoside triphosphate pools. The M1 and M2 subunits of ribonucleotide reductase from wild-type S49 cells were identified on two-dimensional polyacrylamide gels, but showed no significant change in intensity during the cell cycle. These data are consistent with allosteric inhibition of ribonucleotide reductase during the G1 phase of the cycle and release of this inhibition during S phase. They suggest that the increase in ribonucleotide reductase activity observed in permeabilized S phase-enriched cultures may not be the result of increased synthesis of either the M1 or M2 subunit of the enzyme.     

High resolution analysis of cell cycle-correlated vimentin expression in asynchronously grown,TPA-treated MPC-11 cells by the novel flow cytometric multiparameter BrdU-hoechst/PI and immunolabeling technique

High resolution, multiparameter analysis using the flow cytometric BrdU/Hoechst quenching technique has been applied to study cell cycle kinetics and vimentin expression in individual cells of asynchronously grown MPC-11 mouse plasmacytoma cell cultures treated with 12-O-tetradecanoylphorbol-13-acetate (TPA) to induce in vitro differentiation. BrdU treatment up to 16 h in the absence or presence of TPA did not affect either cell cycle progression or the kinetics or quantity of vimentin expression. TPA-treated cells became arrested in G1 phase of the second cell cycle; however, this G1 phase arrest was transient only. In addition, G1 phase cells located prior to a putative transition point at the beginning of TPA treatment were completely blocked in cell cycle progression. There is also evidence that cells located in G1 or G2/M phase at the beginning of TPA treatment finally expressed low levels of vimentin. On the contrary, cells located in S phase at TPA exposure showed high vimentin levels after treatment. The results presented here show that, with the flow cytometric BrdU/Hoechst quenching technique, one can correlate time-dependent protein expression at the single cell level in asynchronously grown cultures not only with the actual cell cycle state, but also with the history of cell replication. © 1994 Wiley-Liss, Inc.     

Roles for basal and stimulated p21(Cip-1/WAF1/MDA6) expression and mitogen-activated protein kinase signaling in radiation-induced cell cycle checkpoint control in carcinoma cells

We investigated the role of the cdk inhibitor protein p21(Cip-1/WAF1/MDA6) (p21) in the ability of MAPK pathway inhibition to enhance radiation-induced apoptosis in A431 squamous carcinoma cells. In carcinoma cells, ionizing radiation (2 Gy) caused both primary (0-10 min) and secondary (90-240 min) activations of the MAPK pathway. Radiation induced p21 protein expression in A431 cells within 6 h via secondary activation of the MAPK pathway. Within 6 h, radiation weakly enhanced the proportion of cells in G(1) that were p21 and MAPK dependent, whereas the elevation of cells present in G(2)/M at this time was independent of either p21 expression or MAPK inhibition. Inhibition of the MAPK pathway increased the proportion of irradiated cells in G(2)/M phase 24-48 h after irradiation and enhanced radiation-induced apoptosis. This correlated with elevated Cdc2 tyrosine 15 phosphorylation, decreased Cdc2 activity, and decreased Cdc25C protein levels. Caffeine treatment or removal of MEK1/2 inhibitors from cells 6 h after irradiation reduced the proportion of cells present in G(2)/M phase at 24 h and abolished the ability of MAPK inhibition to potentiate radiation-induced apoptosis. These data argue that MAPK signaling plays an important role in the progression/release of cells through G(2)/M phase after radiation exposure and that an impairment of this progression/release enhances radiation-induced apoptosis. Surprisingly, the ability of irradiation/MAPK inhibition to increase the proportion of cells in G(2)/M at 24 h was found to be dependent on basal p21 expression. Transient inhibition of basal p21 expression increased the control level of apoptosis as well as the abilities of both radiation and MEK1/2 inhibitors to cause apoptosis. In addition, loss of basal p21 expression significantly reduced the capacity of MAPK inhibition to potentiate radiation-induced apoptosis. Collectively, our data argue that MAPK signaling and p21 can regulate cell cycle checkpoint control in carcinoma cells at the G(1)/S transition shortly after exposure to radiation. In contrast, inhibition of MAPK increases the proportion of irradiated cells in G(2)/M, and basal expression of p21 is required to maintain this effect. Our data suggest that basal and radiation-stimulated p21 may play different roles in regulating cell cycle progression that affect cell survival after radiation exposure.     

Distribution of SH-SY5Y human neuroblastoma cells in the cell cycle following exposure to organophosphorus compounds

The current study investigated the relationship of the cell cycle phase (as G(0)/G(1), S, and G(2)/M) and cytotoxicity (as sub-G(1) DNA) to determine whether alterations in cell replication were associated with organophosphate (OP) compound induced cytotoxicity. Results demonstrated that, overall, OP compound--induced cell cycle changes were variable and depended on the OP compound, exposure concentration, and temporal relationship to cytotoxicity. Noncytotoxic OP compound treatments substantially decreased the percentage of cells in S phase of the cell cycle when compared to controls. A corresponding increase was seen in the percent of cells in G(0)/G(1) phase of the cell cycle. In the precytotoxic interval of exposure, most cytotoxic OP compound treatments substantially decreased the percentage of cells in G(2)/M phase of the cell cycle. Corresponding increases were seen primarily in G(0)/G(1) phase cells. Effects on cells in S stage of the cell cycle varied with the OP compound. In the during cytotoxic interval of exposure, most cytotoxic OP compound treatments substantially increased the percentage of cells in S phase of the cell cycle. A corresponding decrease in the percent of cells in G(0)/G(1) stage of the cell cycle was observed. Furthermore, treatments either increased or decreased the percentage of cells in G(2)/M phase of the cell cycle when compared to controls, with decreases more likely with the most cytotoxic OP compound exposures. Overall, the in vitro data suggest that exposure to OP compounds can alter the cell cycle status of SH-SY5Y neuroblastoma cells depending on compound, concentration, and interval from initial exposure. Changes in cell cycle, however, did not differentiate between OP compounds that are known for their ability to acutely inhibit acetylcholinesterase versus those inducing type I and type II delayed neurotoxicity.