Differentiation of HL-60 myeloid leukaemia cells is associated with a transient block in the G2 phase of the cell cycle

The human promyelocytic leukaemia cell line HL-60 can be induced to differentiate towards mature granulocytes by treatment with dibutyryl cyclic adenosine-3',5'-monophosphate (dbcAMP). Differentiation begins within 16-24 h of treatment and is associated with a time- and dose-dependent accumulation of cells in the G0/G1 phase of the cell cycle with a concomitant decrease in the number of cells in the S and G2 + M phases. Using acridine orange staining, we found that the RNA content of the cells also decreased following differentiation. Stathmokinetic analysis of HL-60 cell populations following dbcAMP treatment showed no effect on the total number of cells in the G0/G1 or S phases, or the rate of progression of cells through these cell cycle compartments. In contrast, dbcAMP was found to induce a transient arrest of the cells in the G2 phase. We also found that differentiation induced by dbcAMP did not require progression of the cells through the cell cycle. Cells arrested in either G1/S by hydroxyurea or G2 + M by colcemid eventually expressed markers of mature granulocytes. These results demonstrate that dbcAMP modulates cell cycle progression. However, these cell cycle changes alone are insufficient to induce granulocytic differentiation of HL-60 cells.     

Method for kinetic analysis of drug-induced cell cycle perturbations.

A method is described for quantitative study of the flux of cells through the cell cycle phases in in vitro systems perturbed by chemicals, such as chemotherapeutic agents. The method utilizes cell count and the flow cytometric technique of bromodeoxyuridine (BrdUrd) labeling, according to an optimized strategy. Cells are exposed to BrdUrd during the last minutes of drug treatment and fixed for analysis at 0, 1/3Ts, 2/3Ts, Ts, and Tc + TG1 recovery times, where Ts, TG1, Tc are the mean durations of phases S and G1 and of the whole cycle of control cells. As an example of application of the proposed procedure, a kinetic study of the effect of 1-(2-chloroethyl)-1-nitrosourea (CNU) on the L1210 cell cycle is described. Simple data analysis, requiring only a pocket calculator, showed that cells in phases G1 and G2M at the end of a 1 h treatment with 1 microgram/ml CNU were fully able to leave these phases but were destined to remain blocked in the following G2M phase (G1 for a minority of them). We also found that cells initially in S phase were slightly delayed in completing their S phase and that 50% of them remained temporarily blocked in the subsequent G2M phase, irrespective of their position in the S phase.     

Image analysis of blastema cell proliferation in denervated limb regenerates of the newt, Pleurodeles waltlii M.

When denervated at the medium bud stage, limb blastemas of the newt, Pleurodeles waltlii Michah, stop growing. In order to better understand the role of nerves in the cell cycle in blastemas, we studied the distribution of mesenchymal cells in the G0-1, G1, S, G2 and M phases 48 and 96 h after denervation. The cell-cycle phases were determined by examining Feulgen-stained nuclei using a SAMBA 200 (System for Analytical Microscopy in Biological Applications) cell image processor. The cell nuclei were automatically analyzed by calculating 18 parameters related to the densitometry and texture of chromatin, and the shape of each nucleus. Cell-cycle phases were classified according to the unsupervised recognition method using a SAMBA 200 system as proposed by Moustafa and Brugal for cell-kinetics analysis. The classification obtained was tested against the results of stepwise linear discriminant analysis performed according to the method of Giroud. Our results show that, in blastemas 96 h after denervation, the percentage of cells in the S, G2, and M phases decreases significantly, while the percentage of G1 and G0-1 cells increases (+ 51% for G1 cells; + 30% for G0-1 cells). Thus, it appears that denervation of medium-bud-stage limb blastemas promotes the lengthening of G1 and premature exiting of cells from the cycle into the G0-1 phase. These results show that nerves (i.e., neurotrophic factor) regulate cell kinetics during newt limb regeneration by maintaining blastema mesenchymal cells in the cell-cycle.     

cAMP-mediated growth inhibition of a B-lymphoid precursor cell line Reh is associated with an early transient delay in G2/M, followed by an accumulation of cells in G1

This study was undertaken to gain more insight into the effects of cyclic adenosine monophosphate (cAMP) on cell-cycle progression in the B-lymphoid precursor cell line Reh. The adenylate cyclase activator forskolin reduced the proliferation of asynchronously growing Reh cells by 50% after 72 hr culture. Growth inhibition was associated with an accumulation of cells in G1. Furthermore, we demonstrated that forskolin provoked a delay of cells for approximately 10 hr in G2/M prior to the G1 arrest. Two different methods were applied to elucidate how cells in different phases of the cell cycle were affected by an elevated cAMP level. One method was based on centrifugal elutriation, whereby synchronous cell populations from the different phases of the cell cycle were isolated. By the other method, S-phase cells were selectively stained by pulsing asynchronously growing cells with bromo-deoxyuridine (BrdU). The data demonstrate that the position of a cell in the cell cycle is critical in determining how the cell will respond to an elevated cAMP level. Thus cells in G1 at the time forskolin is added are not delayed in G2/M, but they will subsequently accumulate in G1 after 48 hr. Cells given forskolin in G2/m, however, are delayed for 10 hr in G2/M, but they do not accumulate in G1. Cells given forskolin in the S phase are delayed in G2/M as well as arrested in G1. The results suggest that cAMP inhibits growth of the Reh cells by preventing the cells from passing important restriction points located in the G1 and G2 phases of the cell cycle.     

Synchronization of the cell cycle using Lovastatin

Synchronization by Lovastatin arrests many cell types reversibly in the G1 phase of the cell cycle. Here we show that Lovastatin (10 µM) mediates cell cycle arrest in human breast cancer cells, MCF-7 and MDA-MB-231, where 85% of cells accumulate in the G1 phase of the cell cycle. Addition of mevalonate (at 100X the Lovastatin concentration) releases the cells from the G1 arrest and allows for synchronous entry into late G1, S and G2/M phases of the cell cycle. The expressions of different cyclins as a marker for different phases of the cell cycle are detected by western blot analysis and indicative of synchronous transition into each of cell cycle phases following the initial G1 arrest. Due to its level of synchrony and high yield of synchronous populations of cells, Lovastatin method of cell synchronization can be used for examining gene expression patterns in a variety of different cell lines.     

The retinoblastoma protein is phosphorylated during specific phases of the cell cycle

p105-RB is the product of the retinoblastoma tumor suppressor gene. It is a nuclear phosphoprotein hypothesized to act as an inhibitor of cellular proliferation, yet surprisingly it is present in actively dividing cells. To look for changes in p105-RB that may regulate its activity during the cell cycle, we generated synchronized cell populations and followed their progression through the cell cycle. p105-RB is synthesized throughout the cycle, but is phosphorylated in a phase-specific manner. In the G0 and G1 phases of the cell cycle, an unphosphorylated species of the protein is the only detectable form, whereas in the S and G2/M phases, multiple phosphorylated species of p105-RB are detected.     

Flow cytometric cell cycle analysis of cultured porcine fetal fibroblast cells

Normal development of nuclear transfer embryos is thought to be dependent on transferral of nuclei in G0 or G1 phases of the cell cycle. Therefore, we investigated the cell cycle characteristics of porcine fetal fibroblast cells cultured under a variety of cell cycle-arresting treatments. This was achieved by using flow cytometry to simultaneously measure cellular DNA and protein content, enabling the calculation of percentages of cells in G0, G1, S, and G2+M phases of the cell cycle. Cultures that were serum starved for 5 days contained higher (p < 0.05) percentages of G0+G1 (87.5 +/- 0. 7) and G0 cells alone (48.3 +/- 9.7) compared with rapidly cycling cultures (G0+G1: 74.1 +/- 3.0; G0: 2.8 +/- 1.2). Growth to confluency increased (p < 0.05) G0+G1 percentages (85.1 +/- 2.8) but did not increase G0 percentages (6.0 +/- 5.3) compared to those in cycling cultures. Separate assessment of small-, medium-, and large-sized cells showed that as the cell size decreased from large to small, percentages of cells in G0+G1 and G0 alone increased (p < 0.05). We found 95.2 +/- 0.3% and 72.2 +/- 12.0% of small serum-starved cells in G0+G1 and G0 alone, respectively. Cultures were also treated with cell cycle inhibitors. Treatment with dimethyl sulfoxide (1%) or colchicine (0.5 microM) increased percentages of cells in G0 (24.8 +/- 20.0) or G2+M (37.4 +/- 4.6), respectively. However, cells were only slightly responsive to mimosine treatment. A more complete understanding of the cell cycle of donor cells should lead to improvements in the efficiency of nuclear transfer procedures.     

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.     

Cell cycle-dependent expression of cyclooxygenase-2 in human fibroblasts.

The purpose of this investigation is to determine whether the levels of cyclooxygenase-2 (COX-2) expression are cell cycle dependent. We used a serum-starved human foreskin fibroblast model to determine changes in COX-2 mRNA, protein, and promoter activity in response to stimulation with interleukin-1b (IL-1b) and phorbol 12-myristate 13-acetate (PMA) at G0, G1, S and G2/M phases of the cell cycle. IL-1b (1 ng/ml) and PMA (100 nM) induced robust COX-2 expression in the G0 cells, and the level of COX-2 expression declined progressively after the cells had entered the cell cycle. The COX-2 mRNA level at G1, S and G2/M phases of the cell cycle was 76%, 46%, and 30% of that at G0, respectively. A 5-flanking promoter fragment of COX-2 constructed into a luciferase expression vector was transfected into cells. The promoter activity in response to PMA stimulation was significantly higher in G0 than in S phase cells. These results imply that G0 cells are the key players in inflammation and other COX-2-dependent pathophysiological processes. When the cells are in the proliferative phase, COX-2 inducibility becomes restrained probably by an endogenous control mechanism to avoid COX-2 mediated oxidative DNA damage.     

Susceptibility of Hep3B cells in different phases of cell cycle to tBid

tBid is a pro-apoptotic molecule. Apoptosis inducers usually act in a cell cycle-specific fashion. The aim of this study was to elucidate whether effect of tBid on hepatocellular carcinoma (HCC) Hep3B cells was cell cycle phase specific. We synchronized Hep3B cells at G0/G1, S or G2/M phases by chemicals or flow sorting and tested the susceptibility of the cells to recombinant tBid. Cell viability was measured by MTT assay and apoptosis by TUNEL. The results revealed that tBid primarily targeted the cells at G0/G1 phase of cell cycle, and it also increased the cells at the G2/M phase. 5-Fluorouracil (5-FU), on the other hand, arrested Hep3B cells at the G0/G1 phase, but significantly reduced cells at G2/M phase. The levels of cell cycle-related proteins and caspases were altered in line with the change in the cell cycle. The combination of tBid with 5-FU caused more cells to be apoptotic than either agent alone. Therefore, the complementary effect of tBid and 5-FU on different phases of the cell cycle may explain their synergistric effect on Hep3B cells. The elucidation of the phase-specific effect of tBid points to a possible therapeutic option that combines different phase specific agents to overcome resistance of HCC.     

Population study of cell cycle in a continuous culture ofCandida utilis

The mean lengths of G1, S, G2 and M phases of the cell cycle were determined on the basis of the population distribution ofCandida utilis grown in a continuous culture under steady-state conditions by using an original mathematical method. The length of the G2 phase was proportional to that of G1; the length of M was effectively independent of the growth rate. The length of S was proportional to the mean number of mitochondria in the cell.     

Increased levels of cyclins D1 and D3 after inhibition of gap junctional communication in astrocytes

We showed previously that the inhibition of gap junctional communication in astrocytes increased bromodeoxyuridine (BrdU) incorporation and promoted changes in the metabolic phenotype destined to fulfil the requirements of cell proliferation. In the present study we investigated the changes in the cell cycle of astrocytes promoted by the inhibition of intercellular communication through gap junctions. Thus, the presence of endothelin-1 and carbenoxolone, two gap junction uncouplers, promoted an increase in the percentage of astrocytes found in the S, G2 and M phases of the cell cycle, with a concomitant decrease in G0 and G1 phases. In addition, the levels of Ki-67, a protein present during all active phases of the cell cycle but absent from resting cells, increased after the inhibition of gap junctional communication. These effects were not observed when the inhibition of gap junctions was prevented with tolbutamide, indicating that the inhibition of gap junctional communication promotes the entry of astrocytes into the cell cycle. The passage of the cells from a quiescent state to the cell cycle is ultimately regulated by the degree of retinoblastoma phosphorylation. Inhibition of gap junctions increased the phosphorylation of retinoblastoma at Ser 780 but not at Ser 795 or Ser 807/811. In addition, the levels of cyclins D1 and D3 increased, whereas those of p21 and p27 were not significantly modified. Because D-type cyclins are key regulators of retinoblastoma protein phosphorylation, it is suggested that the phosphorylation of retinoblastoma protein at Ser 780, observed under our experimental conditions, is a consequence of the increase in the levels of cyclins D1 and D3. Our work provides evidence for the involvement of cyclins D1 and D3 as sensors of the inhibition of gap junctional communication in astrocytes.     

Characterization of the effects of butyric acid on cell proliferation, cell cycle distribution and apoptosis

We examined concentration-dependent changes in cell cycle distribution and cell cycle-related proteins induced by butyric acid. Butyric acid enhanced or suppressed the proliferation of Jurkat human T lymphocytes depending on concentration. A low concentration of butyric acid induced a massive increase in the number of cells in S and G2/M phases, whereas a high concentration significantly increased the accumulation of cells in G2/M phase, suppressed the accumulation of cells in G0/G1 and S phases, and induced apoptosis that cell cycle-related protein expression in Jurkat cells treated with high levels of butyric acid caused a marked decrease in cyclin A, cyclin E, cyclin-dependent kinase 2 (CDK2), CDK4 and CDK6 protein levels in G0/G1 and S phases, with apoptosis induction, and a decrease in cyclin B, Cdc25c and p27KIP1 protein levels, as well as an increase in p21CIP1/WAF1 protein level, in the G2/M phase. Taken together, our results indicate that butyric acid has bimodal effects on cell proliferation and survival. The inhibition of cell growth followed by the increase in apoptosis induced by high levels of butyric acid were related to an increase in cell death in G0/G1 and S phases, as well as G2/M arrest of cells. Finally, these results were further substantiated by the expression profile of butyric acid-treated Jurkat cells obtained by means of cDNA array.     

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.     

Protein tyrosine nitration in the cell cycle

Nitration of tyrosine residues in proteins is associated with cell response to oxidative/nitrosative stress. Tyrosine nitration is relatively low abundant post-translational modification that may affect protein functions. Little is known about the extent of protein tyrosine nitration in cells during progression through the cell cycle. Here we report identification of proteins enriched for tyrosine nitration in cells synchronized in G0/G1, S or G2/M phases of the cell cycle. We identified 27 proteins in cells synchronized in G0/G1 phase, 37 proteins in S phase synchronized cells, and 12 proteins related to G2/M phase. Nineteen of the identified proteins were previously described as regulators of cell proliferation. Thus, our data indicate which tyrosine nitrated proteins may affect regulation of the cell cycle.     

A dual‐color marker system for in vivo visualization of cell cycle progression in Arabidopsis

Visualization of the spatiotemporal pattern of cell division is crucial to understand how multicellular organisms develop and how they modify their growth in response to varying environmental conditions. The mitotic cell cycle consists of four phases: S (DNA replication), M (mitosis and cytokinesis), and the intervening G1 and G2 phases; however, only G2/M‐specific markers are currently available in plants, making it difficult to measure cell cycle duration and to analyze changes in cell cycle progression in living tissues. Here, we developed another cell cycle marker that labels S‐phase cells by manipulating Arabidopsis CDT1a, which functions in DNA replication origin licensing. Truncations of the CDT1a coding sequence revealed that its carboxy‐terminal region is responsible for proteasome‐mediated degradation at late G2 or in early mitosis. We therefore expressed this region as a red fluorescent protein fusion protein under the S‐specific promoter of a histone 3.1‐type gene, HISTONE THREE RELATED2 (HTR2), to generate an S/G2 marker. Combining this marker with the G2/M‐specific CYCB1‐GFP marker enabled us to visualize both S to G2 and G2 to M cell cycle stages, and thus yielded an essential tool for time‐lapse imaging of cell cycle progression. The resultant dual‐color marker system, Cell Cycle Tracking in Plant Cells (Cytrap), also allowed us to identify root cells in the last mitotic cell cycle before they entered the endocycle. Our results demonstrate that Cytrap is a powerful tool for in vivo monitoring of the plant cell cycle, and thus for deepening our understanding of cell cycle regulation in particular cell types during organ development.     

Endothelial cell subpopulations in vitro: cell volume, cell cycle, and radiosensitivity

Vascular endothelial cells (EC) are important clinical targets of radiation and other forms of free radical/oxidant stresses. In this study, we found that the extent of endothelial damage may be determined by the different cytotoxic responses of EC subpopulations. The following characteristics of EC subpopulations were examined: 1) cell volume; 2) cell cycle position; and 3) cytotoxic indexes for both acute cell survival and proliferative capacity after irradiation (137Cs, gamma, 0-10 Gy). EC cultured from bovine aortas were separated by centrifugal elutriation into subpopulations of different cell volumes. Through flow cytometry, we found that cell volume was related to the cell cycle phase distribution. The smallest EC were distributed in G1 phase and the larger cells were distributed in either early S, middle S, or late S + G2M phases. Cell cycle phase at the time of irradiation was not associated with acute cell loss. However, distribution in the cell cycle did relate to cell survival based on proliferative capacity (P less than 0.01). The order of increasing radioresistance was cells in G1 (D0 = 110 cGy), early S (135 cGy), middle S (145 cGy), and late S + G2M phases (180 cGy). These findings 1) suggest an age-related response to radiation in a nonmalignant differentiated cell type and 2) demonstrate EC subpopulations in culture.     

Apical migration of nuclei during G2 is a prerequisite for all nuclear motion in zebrafish neuroepithelia

Nuclei in the proliferative pseudostratified epithelia of vastly different organisms exhibit a characteristic dynamics - the so-called interkinetic nuclear migration (IKNM). Although these movements are thought to be intimately tied to the cell cycle, little is known about the relationship between IKNM and distinct phases of the cell cycle and the role that this association plays in ensuring balanced proliferation and subsequent differentiation. Here, we perform a quantitative analysis of modes of nuclear migration during the cell cycle using a marker that enables the first unequivocal differentiation of all four phases in proliferating neuroepithelial cells in vivo. In zebrafish neuroepithelia, nuclei spend the majority of the cell cycle in S phase, less time in G1, with G2 and M being noticeably shorter still in comparison. Correlating cell cycle phases with nuclear movements shows that IKNM comprises rapid apical nuclear migration during G2 phase and stochastic nuclear motion during G1 and S phases. The rapid apical migration coincides with the onset of G2, during which we find basal actomyosin accumulation. Inhibiting the transition from G2 to M phase induces a complete stalling of nuclei, indicating that IKNM and cell cycle continuation cannot be uncoupled and that progression from G2 to M is a prerequisite for rapid apical migration. Taken together, these results suggest that IKNM involves an actomyosin-driven contraction of cytoplasm basal to the nucleus during G2, and that the stochastic nuclear movements observed in other phases arise passively due to apical migration in neighboring cells.